Your search keyword '"Mary E. Delany"' showing total 61 results

1. An atlas of regulatory elements in chicken:A resource for chicken genetics and genomics

Author

Zhangyuan Pan, Ying Wang, Mingshan Wang, Yuzhe Wang, Xiaoning Zhu, Shenwen Gu, Conghao Zhong, Liqi An, Mingzhu Shan, Joana Damas, Michelle M. Halstead, Dailu Guan, Nares Trakooljul, Klaus Wimmers, Ye Bi, Shang Wu, Mary E. Delany, Xuechen Bai, Hans H. Cheng, Congjiao Sun, Ning Yang, Xiaoxiang Hu, Harris A. Lewin, Lingzhao Fang, and Huaijun Zhou

Subjects

Genome, Multidisciplinary, Nucleic Acid, Enhancer Elements, Prevention, Human Genome, Genomics, Chromatin, Vaccine Related, Genetic, Genetics, Animals, Immunization, Vaccine Related (AIDS), Chickens, Regulatory Sequences, Biotechnology

Abstract

A comprehensive characterization of regulatory elements in the chicken genome across tissues will have substantial impacts on both fundamental and applied research. Here, we systematically identified and characterized regulatory elements in the chicken genome by integrating 377 genome-wide sequencing datasets from 23 adult tissues. In total, we annotated 1.57 million regulatory elements, representing 15 distinct chromatin states, and predicted about 1.2 million enhancer-gene pairs and 7662 super-enhancers. This functional annotation of the chicken genome should have wide utility on identifying regulatory elements accounting for gene regulation underlying domestication, selection, and complex trait regulation, which we explored. In short, this comprehensive atlas of regulatory elements provides the scientific community with a valuable resource for chicken genetics and genomics.

Published

2023

2. The Gallus gallus RJF reference genome reveals an MHCY haplotype organized in gene blocks that contain 107 loci including 45 specialized, polymorphic MHC class I loci, 41 C-type lectin-like loci, and other loci amid hundreds of transposable elements

Author

Ronald M Goto, Charles D Warden, Takashi Shiina, Kazuyoshi Hosomichi, Jibin Zhang, Tae Hyuk Kang, Xiwei Wu, Marla C Glass, Mary E Delany, and Marcia M Miller

Subjects

Haplotypes, DNA Transposable Elements, Genetics, Animals, Genes, MHC Class I, Lectins, C-Type, Chickens, Molecular Biology, In Situ Hybridization, Fluorescence, Genetics (clinical)

Abstract

MHCY is a second major histocompatibility complex-like gene region in chickens originally identified by the presence of major histocompatibility complex class I-like and class II-like gene sequences. Up to now, the MHCY gene region has been poorly represented in genomic sequence data. A high density of repetitive sequence and multiple members of several gene families prevented the accurate assembly of short-read sequence data for MHCY. Identified here by single-molecule real-time sequencing sequencing of BAC clones for the Gallus gallus Red Jungle Fowl reference genome are 107 MHCY region genes (45 major histocompatibility complex class I-like, 41 c-type-lectin-like, 8 major histocompatibility complex class IIβ, 8 LENG9-like, 4 zinc finger protein loci, and a single only zinc finger-like locus) located amid hundreds of retroelements within 4 contigs representing the region. Sequences obtained for nearby ribosomal RNA genes have allowed MHCY to be precisely mapped with respect to the nucleolar organizer region. Gene sequences provide insights into the unusual structure of the MHCY class I molecules. The MHCY class I loci are polymorphic and group into 22 types based on predicted amino acid sequences. Some MHCY class I loci are full-length major histocompatibility complex class I genes. Others with altered gene structure are considered gene candidates. The amino acid side chains at many of the polymorphic positions in MHCY class I are directed away rather than into the antigen-binding groove as is typical of peptide-binding major histocompatibility complex class I molecules. Identical and nearly identical blocks of genomic sequence contribute to the observed multiplicity of identical MHCY genes and the large size (>639 kb) of the Red Jungle Fowl MHCY haplotype. Multiple points of hybridization observed in fluorescence in situ hybridization suggest that the Red Jungle Fowl MHCY haplotype is made up of linked, but physically separated genomic segments. The unusual gene content, the evidence of highly similar duplicated segments, and additional evidence of variation in haplotype size distinguish polymorphic MHCY from classical polymorphic major histocompatibility complex regions.

Published

2022

3. Marek's Disease Virus Telomeric Integration Profiles of Neoplastic Host Tissues Reveal Unbiased Chromosomal Selection and Loss of Cellular Diversity during Tumorigenesis

Author

Justin M. Smith, Marla C. Glass, Mary E. Delany, and Hans H. Cheng

Subjects

animal structures, Lymphoma, Carcinogenesis, animal diseases, viruses, T-Lymphocytes, Virus Integration, chicken, Biology, QH426-470, medicine.disease_cause, Virus, Article, herpesvirus, FISH, immune system diseases, Host chromosome, hemic and lymphatic diseases, medicine, Genetics, Marek Disease, Animals, Herpesvirus 2, Gallid, Genetics (clinical), In Situ Hybridization, Fluorescence, Poultry Diseases, Marek’s disease virus (MDV), Marek's disease, telomere, cytogenomics, medicine.diagnostic_test, viral integration, Splenic Neoplasms, avian genomics, virus diseases, viral oncogenesis, medicine.disease, biology.organism_classification, Molecular biology, Phenotype, Telomere, Host-Pathogen Interactions, Chickens, Fluorescence in situ hybridization

Abstract

The avian α-herpesvirus known as Marek’s disease virus (MDV) linearly integrates its genomic DNA into host telomeres during infection. The resulting disease, Marek’s disease (MD), is characterized by virally-induced lymphomas with high mortality. The temporal dynamics of MDV-positive (MDV+) transformed cells and expansion of MD lymphomas remain targets for further understanding. It also remains to be determined whether specific host chromosomal sites of MDV telomere integration confer an advantage to MDV-transformed cells during tumorigenesis. We applied MDV-specific fluorescence in situ hybridization (MDV FISH) to investigate virus-host cytogenomic interactions within and among a total of 37 gonad lymphomas and neoplastic splenic samples in birds infected with virulent MDV. We also determined single-cell, chromosome-specific MDV integration profiles within and among transformed tissue samples, including multiple samples from the same bird. Most mitotically-dividing cells within neoplastic samples had the cytogenomic phenotype of ‘MDV telomere-integrated only’, and tissue-specific, temporal changes in phenotype frequencies were detected. Transformed cell populations composing gonad lymphomas exhibited significantly lower diversity, in terms of heterogeneity of MDV integration profiles, at the latest stages of tumorigenesis (&gt, 50 days post-infection (dpi)). We further report high interindividual and lower intraindividual variation in MDV integration profiles of lymphoma cells. There was no evidence of integration hotspots into a specific host chromosome(s). Collectively, our data suggests that very few transformed MDV+ T cell populations present earlier in MDV-induced lymphomas (32–50 dpi), survive, and expand to become the dominant clonal population in more advanced MD lymphomas (51–62 dpi) and establish metastatic lymphomas.

Published

2021

4. Functional annotations of three domestic animal genomes provide vital resources for comparative and agricultural research

Author

Xiaoqin Xu, Ruidong Xiang, Ganrea Chanthavixay, Paul Flicek, Ian F Korf, Amanda J. Chamberlain, Gerald Quon, Catherine W. Ernst, Zhangyuan Pan, Susan Waters, Perot Saelao, Christopher K. Tuggle, Michelle M. Halstead, Ying Wang, Mary E. Delany, Colin Kern, Alison L. Van Eenennaam, Huaijun Zhou, Hans H. Cheng, Pablo J. Ross, and Juan F. Medrano

Subjects

Epigenomics, 0301 basic medicine, Swine, Amino Acid Motifs, General Physics and Astronomy, Genome-wide association study, Regulatory Sequences, Nucleic Acid, Genome, Epigenesis, Genetic, Mice, 0302 clinical medicine, Domestic, Phylogeny, Multidisciplinary, Single Nucleotide, Enhancer Elements, Genetic, Organ Specificity, Regulatory sequence, Animals, Domestic, Chromatin Immunoprecipitation Sequencing, Zero Hunger, Biotechnology, Agricultural genetics, Enhancer Elements, Science, Biology, ENCODE, Polymorphism, Single Nucleotide, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Genetic, Phylogenetics, Genetics, Animals, Polymorphism, Domestication, Gene, Nucleic Acid, General Chemistry, Gene regulation, 030104 developmental biology, Gene Expression Regulation, Evolutionary biology, Cattle, Generic health relevance, Regulatory Sequences, Chickens, 030217 neurology & neurosurgery, Epigenesis, Genome-Wide Association Study, Transcription Factors

Abstract

Gene regulatory elements are central drivers of phenotypic variation and thus of critical importance towards understanding the genetics of complex traits. The Functional Annotation of Animal Genomes consortium was formed to collaboratively annotate the functional elements in animal genomes, starting with domesticated animals. Here we present an expansive collection of datasets from eight diverse tissues in three important agricultural species: chicken (Gallus gallus), pig (Sus scrofa), and cattle (Bos taurus). Comparative analysis of these datasets and those from the human and mouse Encyclopedia of DNA Elements projects reveal that a core set of regulatory elements are functionally conserved independent of divergence between species, and that tissue-specific transcription factor occupancy at regulatory elements and their predicted target genes are also conserved. These datasets represent a unique opportunity for the emerging field of comparative epigenomics, as well as the agricultural research community, including species that are globally important food resources., In order to interpret non-coding variants, information about regulatory elements in the genome is essential. Here, the authors annotate regulatory elements in chicken, pig and cattle, and characterize conservation of these elements between species.

Published

2021

5. One-step generation of a targeted knock-in calf using the CRISPR-Cas9 system in bovine zygotes

Author

Pablo J. Ross, Sadie L. Hennig, Tamer A. Mansour, Josephine F. Trott, Bret R. McNabb, Jason C. Lin, Joseph R. Owen, Amy E. Young, Mary E. Delany, James D. Murray, Alison L. Van Eenennaam, and Justin M. Smith

Subjects

Male, DNA End-Joining Repair, Knock-in, lcsh:QH426-470, Inverted repeat, Zygote, Bioinformatics, lcsh:Biotechnology, Locus (genetics), Biology, Medical and Health Sciences, Homology (biology), Homology directed repair, 03 medical and health sciences, 0302 clinical medicine, Gene knockin, lcsh:TP248.13-248.65, Information and Computing Sciences, Genetics, Animals, Clustered Regularly Interspaced Short Palindromic Repeats, Gene Knock-In Techniques, Gene, 030304 developmental biology, Gene Editing, 0303 health sciences, Embryos, Wild type, Bovine, Biological Sciences, Molecular biology, Bos taurus, lcsh:Genetics, CRISPR, Cattle, Female, Generic health relevance, CRISPR-Cas Systems, Homologous recombination, 030217 neurology & neurosurgery, Research Article, Biotechnology

Abstract

Background The homologous recombination (HR) pathway is largely inactive in early embryos prior to the first cell division, making it difficult to achieve targeted gene knock-ins. The homology-mediated end joining (HMEJ)-based strategy has been shown to increase knock-in efficiency relative to HR, non-homologous end joining (NHEJ), and microhomology-mediated end joining (MMEJ) strategies in non-dividing cells. Results By introducing gRNA/Cas9 ribonucleoprotein complex and a HMEJ-based donor template with 1 kb homology arms flanked by the H11 safe harbor locus gRNA target site, knock-in rates of 40% of a 5.1 kb bovine sex-determining region Y (SRY)-green fluorescent protein (GFP) template were achieved in Bos taurus zygotes. Embryos that developed to the blastocyst stage were screened for GFP, and nine were transferred to recipient cows resulting in a live phenotypically normal bull calf. Genomic analyses revealed no wildtype sequence at the H11 target site, but rather a 26 bp insertion allele, and a complex 38 kb knock-in allele with seven copies of the SRY-GFP template and a single copy of the donor plasmid backbone. An additional minor 18 kb allele was detected that looks to be a derivative of the 38 kb allele resulting from the deletion of an inverted repeat of four copies of the SRY-GFP template. Conclusion The allelic heterogeneity in this biallelic knock-in calf appears to have resulted from a combination of homology directed repair, homology independent targeted insertion by blunt-end ligation, NHEJ, and rearrangement following editing of the gRNA target site in the donor template. This study illustrates the potential to produce targeted gene knock-in animals by direct cytoplasmic injection of bovine embryos with gRNA/Cas9, although further optimization is required to ensure a precise single-copy gene integration event.

Published

2021

6. Mapping of the chicken cleft primary palate mutation on chromosome 11 and sequencing of the 4.9 Mb linked region

Author

Mary E. Delany and I. A. Youngworth

Subjects

0301 basic medicine, facial truncation, Mutant, Congenic, Single-nucleotide polymorphism, Biology, capture array, Frameshift mutation, 03 medical and health sciences, Genetics, Animals, development, Poultry Diseases, cleft palate, Full Paper, 0402 animal and dairy science, Chromosome, 04 agricultural and veterinary sciences, General Medicine, Sequence Analysis, DNA, Articles, 040201 dairy & animal science, SNP genotyping, 030104 developmental biology, Phenotype, Mutation (genetic algorithm), Mutation, Animal Science and Zoology, ESRP2, Chickens, SNP array

Abstract

Summary An embryonic lethal mutation in chicken named cleft primary palate (cpp) is inherited in an autosomal recessive mode and results in a severely truncated upper beak. In this study, genotyping and sequencing techniques were employed to advance our genetic and genomic knowledge of the mutation’s chromosomal location, candidate region and possible causative element using a congenic inbred line. Herein, the candidate region for the cpp developmental mutation was established as a ca. 5.1 Mb region of chicken chromosome 11 (GGA 11) through the use of a 600K Affymetrix SNP array. The SNPs identified from this array linked to cpp were used to genotype individuals from the congenic inbred line over several generations and thereby fine‐map the causative region resulting in an approximately 200 kb size reduction. This candidate region (4.9 Mb) was sequenced via capture array in a cohort of 24 individuals, including carriers, mutants and their wild type (wt) siblings. Interestingly, the GGA 11 region for cpp encompasses the predicted centromere location and is thus unlikely to be highly disrupted by further recombination. Here we report on the variation unique to the cpp mutation, i.e. single‐nucleotide variants and insertions or deletions. Although the candidate region contains several genes of interest with regard to the cpp phenotype, only one cpp‐linked variant was predicted to have a significant physiological effect by causing a frameshift mutation in ESRP2, which has a role in tissue‐specific splicing during development.

Published

2020

7. A Premature Stop Codon in RAF1 Is the Priority Candidate Causative Mutation of the Inherited Chicken

Author

Ingrid, Youngworth and Mary E, Delany

Subjects

Embryo, Nonmammalian, Bird Diseases, chicken, Limb Deformities, Congenital, Syndrome, Feathers, Article, capture array, Avian Proteins, Proto-Oncogene Proteins c-raf, RASopathy, Codon, Nonsense, limb development, Mutation, Animals, Wings, Animal, Chickens, development

Abstract

The chicken wingless-2 (wg-2) mutation is inherited in an autosomal recessive fashion, and the resulting phenotype in mutant (wg-2/wg-2) individuals is a developmental syndrome characterized by absent wings, truncated legs, craniofacial as well as skin and feather defects, and kidney malformations. Mapping and genotyping established that the mutation resides within 227 kilobases (kb) of chromosome 12 in a wg-2 congenic inbred line. A capture array was designed to target and sequence the candidate region along with flanking DNA in 24 birds from the line. Many point mutations and insertions or deletions were identified, and analysis of the linked variants indicated a point mutation predicted to cause a premature stop codon in the RAF1 gene. Expression studies were conducted inclusive of all genes in the candidate region. Interestingly, RAF1 transcription was elevated, yet the protein was absent in the mutants relative to normal individuals. RAF1 encodes a protein integral to the Ras/Raf/MAPK signaling pathway controlling cellular proliferation, and notably, human RASopathies are developmental syndromes caused by germline mutations in genes of this pathway. Our work indicates RAF1 as the priority candidate causative gene for wg-2 and provides a new animal model to study an important signaling pathway implicated in limb development, as well as RASopathies.

Published

2019

8. Marek’s disease herpesvirus vaccines integrate into chicken host chromosomes yet lack a virus-host phenotype associated with oncogenic transformation

Author

Mary E. Delany, Hans H. Cheng, and Marla C. McPherson

Subjects

0301 basic medicine, 040301 veterinary sciences, Marek Disease Vaccines, Virus Integration, Biology, Serogroup, Marek’s disease virus, Genome, Chromosomes, Virus, Viral integration, 0403 veterinary science, Cytogenetics, 03 medical and health sciences, Immunity, Immunology and Microbiology(all), Marek Disease, Animals, Alphaherpesvirus, Herpesvirus 2, Gallid, Poultry Diseases, Genetics, General Veterinary, General Immunology and Microbiology, Viral Vaccine, Public Health, Environmental and Occupational Health, Viral Vaccines, 04 agricultural and veterinary sciences, Cell Transformation, Viral, Chicken, Virology, veterinary(all), Vaccination, Phenotype, 030104 developmental biology, Infectious Diseases, Viral replication, Molecular Medicine, Oncogenic Viruses, Chickens, Vaccine, Oncovirus

Abstract

Marek’s disease (MD) is a lymphotropic and oncogenic disease of chickens that can lead to death in susceptible and unvaccinated host birds. The causative pathogen, MD virus (MDV), a highly oncogenic alphaherpesvirus, integrates into host genome near the telomeres. MD occurrence is controlled across the globe by biosecurity, selective breeding for enhanced MD genetic resistance, and widespread vaccination of flocks using attenuated serotype 1 MDV or other serotypes. Despite over 40 years of usage, the specific mechanism(s) of MD vaccine-related immunity and anti-tumor effects are not known. Here we investigated the cytogenetic interactions of commonly used MD vaccine strains of all three serotypes (HVT, SB-1, and Rispens) with the host to determine if all were equally capable of host genome integration. We also studied the dynamic profiles of chromosomal association and integration of the three vaccine strains, a first for MD vaccine research. Our cytogenetic data provide evidence that all three MD vaccine strains tested integrate in the chicken host genome as early as 1 day after vaccination similar to oncogenic strains. However, a specific, transformation-associated virus-host phenotype observed for oncogenic viruses is not established. Our results collectively provide an updated model of MD vaccine-host genome interaction and an improved understanding of the possible mechanisms of vaccinal immunity. Physical integration of the oncogenic MDV genome into host chromosomes along with cessation of viral replication appears to have joint signification in MDV’s ability to induce oncogenic transformation. Whereas for MD vaccine serotypes, a sustained viral replication stage and lack of the chromosome-integrated only stage were shared traits during early infection.

Published

2016

9. Utilizing the chicken as an animal model for human craniofacial ciliopathies

Author

Mary E. Delany, Ingrid A. Youngworth, Elizabeth N. Schock, Ching-Fang Chang, Megan Davey, and Samantha A. Brugmann

Subjects

0301 basic medicine, Mutant, Cell Cycle Proteins, Chick Embryo, Biology, Ciliopathies, Retina, Article, Joubert syndrome, Animals, Genetically Modified, Craniofacial Abnormalities, Mice, 03 medical and health sciences, 0302 clinical medicine, Animal model, Genome editing, Cerebellum, medicine, Animals, Humans, Abnormalities, Multiple, Eye Abnormalities, Craniofacial, Maxillofacial Development, Molecular Biology, Gene, Genetic Association Studies, Poultry Diseases, Genetics, Cell Biology, Kidney Diseases, Cystic, Orofaciodigital Syndromes, medicine.disease, Disease Models, Animal, Polydactyly, 030104 developmental biology, Mutation, Genes, Lethal, Chickens, 030217 neurology & neurosurgery, Large size, Developmental Biology

Abstract

The chicken has been a particularly useful model for the study of craniofacial development and disease for over a century due to their relatively large size, accessibility, and amenability for classical bead implantation and transplant experiments. Several naturally occurring mutant lines with craniofacial anomalies also exist and have been heavily utilized by developmental biologist for several decades. Two of the most well known lines, talpid(2) (ta(2)) and talpid(3) (ta(3)), represent the first spontaneous mutants to have the causative genes identified. Despite having distinct genetic causes, both mutants have recently been identified as ciliopathic. Excitingly, both of these mutants have been classified as models for human craniofacial ciliopathies: Oral-facial-digital syndrome (ta(2)) and Joubert syndrome (ta(3)). Herein, we review and compare these two models of craniofacial disease and highlight what they have revealed about the molecular and cellular etiology of ciliopathies. Furthermore, we outline how applying classical avian experiments and new technological advances (transgenics and genome editing) with naturally occurring avian mutants can add a tremendous amount to what we currently know about craniofacial ciliopathies.

Published

2016

10. Virus and host genomic, molecular, and cellular interactions during Marek's disease pathogenesis and oncogenesis

Author

Mary E. Delany and Marla C. McPherson

Subjects

0301 basic medicine, animal structures, Dairy & Animal Science, Carcinogenesis, chicken, viruses, Mardivirus, Context (language use), Models, Biological, Mareks disease, Microbiology, Genome, Virus, 03 medical and health sciences, Food Sciences, 0302 clinical medicine, Animal Production, Viral life cycle, Models, hemic and lymphatic diseases, Marek Disease, Animals, fluorescence in situ hybridization, Poultry Diseases, Phylogeny, Genetics, telomere, Marek's disease, biology, General Medicine, Immunology, Health and Disease, Biological, biology.organism_classification, Virology, 030104 developmental biology, Lytic cycle, 030220 oncology & carcinogenesis, genome integration, Animal Science and Zoology, Oncovirus

Abstract

Marek's Disease Virus (MDV) is a chicken alphaherpesvirus that causes paralysis, chronic wasting, blindness, and fatal lymphoma development in infected, susceptible host birds. This disease and its protective vaccines are highly relevant research targets, given their enormous impact within the poultry industry. Further, Marek's disease (MD) serves as a valuable model for the investigation of oncogenic viruses and herpesvirus patterns of viral latency and persistence--as pertinent to human health as to poultry health. The objectives of this article are to review MDV interactions with its host from a variety of genomic, molecular, and cellular perspectives. In particular, we focus on cytogenetic studies, which precisely assess the physical status of the MDV genome in the context of the chicken host genome. Combined, the cytogenetic and genomic research indicates that MDV-host genome interactions, specifically integration of the virus into the host telomeres, is a key feature of the virus life cycle, contributing to the viral achievement of latency, transformation, and reactivation of lytic replication. We present a model that outlines the variety of virus-host interactions, at the multiple levels, and with regard to the disease states.

Published

2016

11. Genome-wide identification of tissue-specific long non-coding RNA in three farm animal species

Author

Hans H. Cheng, Ian F Korf, Juan F. Medrano, Alison L. Van Eenennaam, Colin Kern, Huaijun Zhou, Pablo J. Ross, Ying Wang, Mary E. Delany, James L. Chitwood, and Catherine W. Ernst

Subjects

0301 basic medicine, Male, lcsh:QH426-470, Swine, Bioinformatics, lcsh:Biotechnology, ved/biology.organism_classification_rank.species, Computational biology, Biology, Proteomics, Genome, Medical and Health Sciences, 03 medical and health sciences, 0302 clinical medicine, lcsh:TP248.13-248.65, Information and Computing Sciences, Genetics, Animals, Epigenetics, Model organism, Gene, Domestic, Regulation of gene expression, ved/biology, Gene Expression Profiling, Human Genome, High-Throughput Nucleotide Sequencing, Molecular Sequence Annotation, Biological Sciences, Long non-coding RNA, Gene regulation, lcsh:Genetics, 030104 developmental biology, Gene Expression Regulation, Organ Specificity, Animals, Domestic, 030220 oncology & carcinogenesis, Long non-coding RNAs, RNA, RNA, Long Noncoding, Cattle, Long Noncoding, Generic health relevance, DNA microarray, Chickens, Biotechnology

Abstract

Background Numerous long non-coding RNAs (lncRNAs) have been identified and their roles in gene regulation in humans, mice, and other model organisms studied; however, far less research has been focused on lncRNAs in farm animal species. While previous studies in chickens, cattle, and pigs identified lncRNAs in specific developmental stages or differentially expressed under specific conditions in a limited number of tissues, more comprehensive identification of lncRNAs in these species is needed. The goal of the FAANG Consortium (Functional Annotation of Animal Genomes) is to functionally annotate animal genomes, including the annotation of lncRNAs. As one of the FAANG pilot projects, lncRNAs were identified across eight tissues in two adult male biological replicates from chickens, cattle, and pigs. Results Comprehensive lncRNA annotations for the chicken, cattle, and pig genomes were generated by utilizing RNA-seq from eight tissue types from two biological replicates per species at the adult developmental stage. A total of 9393 lncRNAs in chickens, 7235 lncRNAs in cattle, and 14,429 lncRNAs in pigs were identified. Including novel isoforms and lncRNAs from novel loci, 5288 novel lncRNAs were identified in chickens, 3732 in cattle, and 4870 in pigs. These transcripts match previously known patterns of lncRNAs, such as generally lower expression levels than mRNAs and higher tissue specificity. An analysis of lncRNA conservation across species identified a set of conserved lncRNAs with potential functions associated with chromatin structure and gene regulation. Tissue-specific lncRNAs were identified. Genes proximal to tissue-specific lncRNAs were enriched for GO terms associated with the tissue of origin, such as leukocyte activation in spleen. Conclusions LncRNAs were identified in three important farm animal species using eight tissues from adult individuals. About half of the identified lncRNAs were not previously reported in the NCBI annotations for these species. While lncRNAs are less conserved than protein-coding genes, a set of positionally conserved lncRNAs were identified among chickens, cattle, and pigs with potential functions related to chromatin structure and gene regulation. Tissue-specific lncRNAs have potential regulatory functions on genes enriched for tissue-specific GO terms. Future work will include epigenetic data from ChIP-seq experiments to further refine these annotations.

Published

2018

12. Two Proximally Close Priority Candidate Genes for diplopodia-1, an Autosomal Inherited Craniofacial-Limb Syndrome in the Chicken: MRE11 and GPR83

Author

Elizabeth A. O'Hare, Mary E. Delany, and Parker B. Antin

Subjects

0106 biological sciences, 0301 basic medicine, Candidate gene, Mutant, DNA Mutational Analysis, Limb Deformities, Congenital, Single-nucleotide polymorphism, Biology, 010603 evolutionary biology, 01 natural sciences, capture array, Receptors, G-Protein-Coupled, Craniofacial Abnormalities, 03 medical and health sciences, Diplopodia, vertebrate development, Genetics, medicine, Animals, Indel, Molecular Biology, Gene, Genetics (clinical), MRE11 Homologue Protein, Chromosome Mapping, High-Throughput Nucleotide Sequencing, Syndrome, Original Articles, medicine.disease, Phenotype, developmental mutation, 030104 developmental biology, Mutation (genetic algorithm), Mutation, next-generation sequencing, Chickens, congenital malformations, Biotechnology

Abstract

Next-generation sequencing (NGS) and expression technologies were utilized to investigate the genes and sequence elements in a 586 kb region of chicken chromosome 1 associated with the autosomal recessive diplopodia-1 (dp-1) mutation. This mutation shows a syndromic phenotype similar to known human developmental abnormalities (e.g., cleft palate, polydactyly, omphalocele [exposed viscera]). Toward our goal to ascertain the variant responsible, the entire 586 kb region was sequenced following utilization of a specifically designed capture array and to confirm/validate fine-mapping results. Bioinformatic analyses identified a total of 6142 sequence variants, which included SNPs, indels, and gaps. Of these, 778 SNPs, 146 micro-indels, and 581 gaps were unique to the UCD-Dp-1.003 inbred congenic line; those found within exons and splice sites were studied for contribution to the mutant phenotype. Upon further validation with additional mutant samples, a smaller subset (of variants [51]) remains linked to the mutation. Additionally, utilization of specific samples in the NGS technology was advantageous in that fine-mapping methodologies eliminated an additional 326 kb of sequence information on chromosome 1. Predicted and confirmed protein-coding genes within the smaller 260 kb region were assessed for their developmental expression patterns over several stages of early embryogenesis in regions/tissues of interest (e.g., digits, craniofacial region). Based on these results and known function in other vertebrates, 2 genes within 5 kb of each other, MRE11 and GPR83, are proposed as high-priority candidates for the dp-1 mutation.

Published

2018

13. Narrowing the wingless-2 mutation to a 227 kb candidate region on chicken chromosome 12

Author

A.E. Webb, B. May, Elizabeth A. O'Hare, C.L. Gitter, Mary E. Delany, Ingrid A. Youngworth, Hans H. Cheng, and Muhammet Kaya

Subjects

0301 basic medicine, Candidate gene, Congenic, Biology, 03 medical and health sciences, symbols.namesake, Animals, Exome sequencing, Chromosome 12, Genetics, Autosome, Chromosome Mapping, candidate gene, Genetics and Genomics, General Medicine, SNP genotyping, 030104 developmental biology, Phenotype, limb development, Mutation, Mendelian inheritance, symbols, Animal Science and Zoology, Chickens, SNP array

Abstract

Wingless-2 (wg-2) is an autosomal recessive mutation in chicken that results in an embryonic lethal condition. Affected individuals exhibit a multisystem syndrome characterized by absent wings, truncated legs, and craniofacial, kidney, and feather malformations. Previously, work focused on phenotype description, establishing the autosomal recessive pattern of Mendelian inheritance and placing the mutation on an inbred genetic background to create the congenic line UCD Wingless-2.331. The research described in this paper employed the complementary tools of breeding, genetics, and genomics to map the chromosomal location of the mutation and successively narrow the size of the region for analysis of the causative element. Specifically, the wg-2 mutation was initially mapped to a 7 Mb region of chromosome 12 using an Illumina 3 K SNP array. Subsequent SNP genotyping and exon sequencing combined with analysis from improved genome assemblies narrowed the region of interest to a maximum size of 227 kb. Within this region, 3 validated and 3 predicted candidate genes are found, and these are described. The wg-2 mutation is a valuable resource to contribute to an improved understanding of the developmental pathways involved in chicken and avian limb development as well as serving as a model for human development, as the resulting syndrome shares features with human congenital disorders.

Published

2017

14. The cellular and molecular etiology of the craniofacial defects in the avian ciliopathic mutant talpid2

Author

Mary E. Delany, Elizabeth A. O'Hare, Samantha A. Brugmann, Elizabeth N. Schock, William M. Muir, Ching-Fang Chang, Hans H. Cheng, Jerry B. Dodgson, and Richard E. Edelmann

Subjects

Heterozygote, Gli processing, animal structures, Mutant, Kruppel-Like Transcription Factors, Hedgehog signaling, Chick Embryo, Zinc Finger Protein Gli2, Biology, Craniofacial Abnormalities, Craniofacial, Primary cilia, Ciliogenesis, GLI2, GLI3, Animals, Hedgehog Proteins, Cilia, Molecular Biology, Gene, Alleles, Research Articles, Centrioles, Cell Nucleus, Genetics, Polymorphism, Genetic, Cilium, Cell Membrane, Chromosome Mapping, Sequence Analysis, DNA, Fibroblasts, talpid2, Chicken, Phenotype, Ciliopathies, Hedgehog signaling pathway, Mutation, Codon, Terminator, Protein Processing, Post-Translational, Signal Transduction, Developmental Biology

Abstract

talpid(2) is an avian autosomal recessive mutant with a myriad of congenital malformations, including polydactyly and facial clefting. Although phenotypically similar to talpid(3), talpid(2) has a distinct facial phenotype and an unknown cellular, molecular and genetic basis. We set out to determine the etiology of the craniofacial phenotype of this mutant. We confirmed that primary cilia were disrupted in talpid(2) mutants. Molecularly, we found disruptions in Hedgehog signaling. Post-translational processing of GLI2 and GLI3 was aberrant in the developing facial prominences. Although both GLI2 and GLI3 processing were disrupted in talpid(2) mutants, only GLI3 activator levels were significantly altered in the nucleus. Through additional fine mapping and whole-genome sequencing, we determined that the talpid(2) phenotype was linked to a 1.4 Mb region on GGA1q that contained the gene encoding the ciliary protein C2CD3. We cloned the avian ortholog of C2CD3 and found its expression was ubiquitous, but most robust in the developing limbs and facial prominences. Furthermore, we found that C2CD3 is localized proximal to the ciliary axoneme and is important for docking the mother centriole to the ciliary vesicle and cell membrane. Finally, we identified a 19 bp deletion in talpid(2) C2CD3 that produces a premature stop codon, and thus a truncated protein, as the likely causal allele for the phenotype. Together, these data provide insight into the cellular, molecular and genetic etiology of the talpid(2) phenotype. Our data suggest that, although the talpid(2) and talpid(3) mutations affect a common ciliogenesis pathway, they are caused by mutations in different ciliary proteins that result in differences in craniofacial phenotype.

Published

2014

15. Comparative cytogenomics of poultry: mapping of single gene and repeat loci in the Japanese quail (Coturnix japonica)

Author

Lida P. Gehlen, Mary E. Delany, Charmaine M. Robinson, and Marla C. McPherson

Subjects

animal structures, Genetic Linkage, Locus (genetics), Coturnix, Poultry, Major Histocompatibility Complex, Species Specificity, Chromosome regions, biology.animal, Genetics, medicine, Animals, Telomerase, Ribosomal DNA, In Situ Hybridization, Fluorescence, Synteny, biology, medicine.diagnostic_test, Coturnix japonica, Telomere, biology.organism_classification, Quail, RNA, Ribosomal, Cytogenetic Analysis, embryonic structures, Microchromosome, Fluorescence in situ hybridization

Abstract

Well-characterized molecular and cytogenetic maps are yet to be established in Japanese quail (Coturnix japonica). The aim of the current study was to cytogenetically map and determine linkage of specific genes and gene complexes in Japanese quail through the use of chicken (Gallus gallus) and turkey (Meleagris gallopavo) genomic DNA probes and conduct a comparative study among the three genomes. Chicken and turkey clones were used as probes on mitotic metaphase and meiotic pachytene stage chromosomes of the three species for the purpose of high-resolution fluorescence in situ hybridization (FISH). The genes and complexes studied included telomerase RNA (TR), telomerase reverse transcriptase (TERT), 5S rDNA, 18S-5.8S-28S rDNA (i.e., nucleolus organizer region (NOR)), and the major histocompatibility complex (MHC). The telomeric profile of Japanese quail was investigated through the use of FISH with a TTAGGG-PNA probe. A range of telomeric array sizes were confirmed as found for the other poultry species. Three NOR loci were identified in Japanese quail, and single loci each for TR, TERT, 5S rDNA and the MHC-B. The MHC-B and one NOR locus were linked on a microchromosome in Japanese quail. We confirmed physical linkage of 5S rDNA and the TR gene on an intermediate-sized chromosome in quail, similar to both chicken and turkey. TERT localized to CJA 2 in quail and the orthologous chromosome region in chicken (GGA 2) and in turkey (MGA 3). The cytogenetic profile of Japanese quail was further developed by this study and synteny was identified among the three poultry species.

Published

2014

16. Temporal Kinetics of Marek's Disease Herpesvirus: Integration Occurs Early after Infection in Both B and T Cells

Author

Hans H. Cheng, Charmaine M. Robinson, and Mary E. Delany

Subjects

Cell type, animal structures, T-Lymphocytes, Virus Integration, viruses, Spleen, Genome, Viral, Thymus Gland, Biology, Virus, Molecular cytogenetics, Pathogenesis, Bursa of Fabricius, Immune system, Genetics, medicine, Animals, Cell Lineage, Herpesvirus 2, Gallid, Molecular Biology, Crosses, Genetic, In Situ Hybridization, Fluorescence, Genetics (clinical), B-Lymphocytes, Gene Expression Profiling, Virology, Phenotype, medicine.anatomical_structure, Viral replication, Immunology, Chickens

Abstract

Marek's disease virus (MDV) is an oncogenic α-herpesvirus that induces Marek's disease characterized by fatal lymphomas in chickens. Here, we explored the timing during pathogenesis when the virus integrates into the host genome, the cell type involved, the role of viral integration on cellular transformation, and tumor clonality. Three immune organs of chicken (thymus, bursa, and spleen) were extracted following infection with either an oncogenic or a non-oncogenic strain of MDV. Using molecular cytogenetics, cells were investigated for viral integration at key time points throughout pathogenesis. Integration profiling of tumors (early to late stage) was conducted. Virus integration was widespread in B and T lymphocytes based on their abundance in bursa and thymus, respectively. Viral replication was detected early after infection as was viral integration into the host genome. Integration is a natural part of the MDV herpesvirus life cycle. In addition, our data using a non-oncogenic virus establish that although integration is a hallmark of tumor cell populations, integration alone is not sufficient for cellular transformation. Our results provide evidence for progression of lineage clonality within tumors. Understanding the features of integration provides insight into the mechanisms of herpesvirus pathology which could lead to disease mitigation strategies.

Published

2014

17. A Premature Stop Codon in RAF1 Is the Priority Candidate Causative Mutation of the Inherited Chicken Wingless-2 Developmental Syndrome

Author

Ingrid A. Youngworth and Mary E. Delany

Subjects

0301 basic medicine, lcsh:QH426-470, chicken, Mutant, Congenic, Biology, RASopathy, capture array, Avian Proteins, Congenital, 03 medical and health sciences, Rare Diseases, 0302 clinical medicine, Germline mutation, Wings, Genetics, medicine, Animals, Codon, development, Gene, Genetics (clinical), Chromosome 12, Pediatric, Nonmammalian, Bird Diseases, Animal, Point mutation, Syndrome, Feathers, medicine.disease, Phenotype, Proto-Oncogene Proteins c-raf, lcsh:Genetics, Limb Deformities, 030104 developmental biology, Nonsense, Embryo, limb development, 030220 oncology & carcinogenesis, Mutation, Chickens, Biotechnology

Abstract

The chicken wingless-2 (wg-2) mutation is inherited in an autosomal recessive fashion, and the resulting phenotype in mutant (wg-2/wg-2) individuals is a developmental syndrome characterized by absent wings, truncated legs, craniofacial as well as skin and feather defects, and kidney malformations. Mapping and genotyping established that the mutation resides within 227 kilobases (kb) of chromosome 12 in a wg-2 congenic inbred line. A capture array was designed to target and sequence the candidate region along with flanking DNA in 24 birds from the line. Many point mutations and insertions or deletions were identified, and analysis of the linked variants indicated a point mutation predicted to cause a premature stop codon in the RAF1 gene. Expression studies were conducted inclusive of all genes in the candidate region. Interestingly, RAF1 transcription was elevated, yet the protein was absent in the mutants relative to normal individuals. RAF1 encodes a protein integral to the Ras/Raf/MAPK signaling pathway controlling cellular proliferation, and notably, human RASopathies are developmental syndromes caused by germline mutations in genes of this pathway. Our work indicates RAF1 as the priority candidate causative gene for wg-2 and provides a new animal model to study an important signaling pathway implicated in limb development, as well as RASopathies.

Published

2019

18. Mapping Genes to Chicken Microchromosome 16 and Discovery of Olfactory and Scavenger Receptor Genes Near the Major Histocompatibility Complex

Author

Jason Abernathy, Melissa K. Hamilton, Huaijun Zhou, Ronald M. Goto, Mary E. Delany, Charmaine M. Robinson, and Marcia M. Miller

Subjects

Male, Genetic Linkage, Trisomy, Biology, Receptors, Odorant, Major histocompatibility complex, Chromosomes, Major Histocompatibility Complex, Centromere, Genetics, Animals, Gene family, Molecular Biology, Gene, In Situ Hybridization, Fluorescence, Genetics (clinical), Southern blot, Receptors, Scavenger, Comparative Genomic Hybridization, Polymorphism, Genetic, Chromosome Mapping, Genomics, Sequence Analysis, DNA, Nucleolar Organizer Region, Multigene Family, biology.protein, Microchromosome, Chickens, Biotechnology, Comparative genomic hybridization

Abstract

Trisomy mapping is a powerful method for assigning genes to chicken microchromosome 16 (GGA 16). The single chicken nucleolar organizer region (NOR), the 2 major histocompatibility complex regions (MHC-Y and MHC-B), and CD1 genes were all previously assigned to GGA 16 using trisomy mapping. Here, we combined array comparative genomic hybridization with trisomy mapping to screen unassigned genomic scaffolds (consigned temporarily to chrUn_random) for sequences originating from GGA 16. A number of scaffolds mapped to GGA 16. Among these were scaffolds that contain genes for olfactory (OR) and cysteine-rich domain scavenger (SRCR) receptors, along with a number of genes that encode putative immunoglobulin-like receptors and other molecules. We used high-resolution cytogenomic analyses to confirm assignment of OR and SRCR genes to GGA 16 and to pinpoint members of these gene families to the q-arm in partially overlapping regions between the centromere and the NOR. Southern blots revealed sequence polymorphism within the OR/SRCR region and linkage with the MHC-Y region, thereby providing evidence for conserved linkage between OR genes and the MHC within birds. This work localizes OR genes to the vicinity of the chicken MHC and assigns additional genes, including immune defense genes, to GGA 16.

Published

2013

19. Poultry Genome Sequences: Progress and Outstanding Challenges

Author

Hans H. Cheng, Jerry B. Dodgson, and Mary E. Delany

Subjects

Whole genome sequencing, Sanger sequencing, Genome, Base Sequence, Contig, Genetic Linkage, Shotgun sequencing, Genomics, Genome project, Biology, Poultry, Evolution, Molecular, symbols.namesake, Genetic Techniques, Evolutionary biology, Genetics, symbols, Animals, Humans, Molecular Biology, Genetics (clinical), Reference genome

Abstract

The first build of the chicken genome sequence appeared in March, 2004 – the first genome sequence of any animal agriculture species. That sequence was done primarily by whole genome shotgun Sanger sequencing, along with the use of an extensive BAC contig-based physical map to assemble the sequence contigs and scaffolds and align them to the known chicken chromosomes and linkage groups. Subsequent sequencing and mapping efforts have improved upon that first build, and efforts continue in search of missing and/or unassembled sequence, primarily on the smaller microchromosomes and the sex chromosomes. In the past year, a draft turkey genome sequence of similar quality has been obtained at a much lower cost primarily due to the development of ‘next-generation’ sequencing techniques. However, assembly and alignment of the sequence contigs and scaffolds still depended on a detailed BAC contig map of the turkey genome that also utilized comparison to the existing chicken sequence. These 2 land fowl (Galliformes) genomes show a remarkable level of similarity, despite an estimated 30–40 million years of separate evolution since their last common ancestor. Among the advantages offered by these sequences are routine re-sequencing of commercial and research lines to identify the genetic correlates of phenotypic change (for example, selective sweeps), a much improved understanding of poultry diversity and linkage disequilibrium, and access to high-density SNP typing and association analysis, detailed transcriptomic and proteomic studies, and the use of genome-wide marker- assisted selection to enhance genetic gain in commercial stocks.

Published

2011

20. Telomere biology of the chicken: A model for aging research

Author

Charmaine M. Robinson, Susan E. Swanberg, Hong Chang, Thomas H. O’Hare, Mary E. Delany, and Elizabeth A. Robb

Subjects

Male, Senescence, Aging, Telomerase, Context (language use), Chick Embryo, Biology, medicine.disease_cause, Biochemistry, Genome, Cell Line, Mice, Telomerase RNA component, Endocrinology, Species Specificity, Cell Line, Tumor, Genetics, medicine, Animals, Humans, Molecular Biology, Sex Chromosomes, Cell Biology, Fibroblasts, Telomere, Models, Animal, Female, Carcinogenesis, Chickens, Developmental biology

Abstract

Division-dependent telomere shortening correlating with age triggers senescence on a cellular level and telomere dysfunction can facilitate oncogenesis. Therefore, the study of telomere biology is critical to the understanding of aging and cancer. The domestic chicken, a classic model for the study of developmental biology, possesses a telomere genome with highly conserved aspects and distinctive features which make it uniquely suited for the study of telomere maintenance mechanisms, their function and dysfunction. The purpose of this review is to highlight the chicken as a model for aging research, specifically as a model for telomere and telomerase research, and to increase its utility as such by describing developments in the study of chicken telomeres and telomerase in the context of related research in human and mouse.

Published

2010

21. Host inflammatory response governs fitness in an avian ectoparasite, the northern fowl mite (Ornithonyssus sylviarum)

Author

Jeb P. Owen, Arthur A. Bickford, Bradley A. Mullens, Mary E. Delany, and Carol J. Cardona

Subjects

Male, Mite Infestations, Inflammation, medicine.disease_cause, Major Histocompatibility Complex, Immune system, Infestation, Mite, medicine, Animals, Ornithonyssus, Juvenile, Acari, Poultry Diseases, Skin, Population Density, Life Cycle Stages, Mites, integumentary system, biology, Host (biology), Feeding Behavior, biology.organism_classification, Logistic Models, Infectious Diseases, Immunology, Female, Parasitology, medicine.symptom, Chickens

Abstract

Vertebrate immune responses to ectoparasites influence pathogen transmission and host fitness costs. Few studies have characterized natural immune responses to ectoparasites and resultant fitness effects on the ectoparasite. These are critical gaps in understanding vertebrate–ectoparasite interaction, disease ecology and host-parasite co-adaptation. This study focused on an ectoparasite of birds—the northern fowl mite (NFM) (Ornithonyssus sylviarum). Based on prior evidence that chickens develop resistance to NFM, these experiments tested two hypotheses: (i) skin inflammation blocks mite access to blood, impairing development, reproduction and survival; and (ii) host immunogenetic variation influences the inflammatory response and subsequent effects on the ectoparasite. On infested hosts, histology of skin inflammation revealed increased epidermal cell number and size, immigration of leukocytes and deposition of serous exudates on the skin surface. Survival of adult mites and their offspring decreased as the area of skin inflammation increased during an infestation. Inflammation increased the distance to blood vessels beyond the length of mite mouthparts (100–160 μm) and prevented protonymphs and adults from reaching a blood source. Consequently, protonymphs could not complete development, evidenced by a significant inverse relationship between inflammation and protonymph feeding success, as well as an increasing protonymph/adult ratio. Adult females were unable to feed and reproduce, indicated by an inverse relationship between inflammation and egg production, and decreasing female/juvenile ratio. These combined impacts of host inflammation reversed NFM population growth. Intensity of inflammation was influenced by the genotype of the major histocompatibility complex (MHC), supporting previous research that linked these immunological loci with NFM resistance. Overall, these data provide a model for a mechanism of avian resistance to an ectoparasitic arthropod and the fitness costs to the parasite of that host defense.

Published

2009

22. Chromosomal mapping of chicken mega-telomere arrays to GGA9, 16, 28 and W using a cytogenomic approach

Author

Laura M. Daniels, Terri M. Gessaro, K. L. Rodrigue, and Mary E. Delany

Subjects

Genetics, medicine.diagnostic_test, Physical Chromosome Mapping, Chromosome, Mega-telomere, Genomics, In situ hybridization, Cell lineage, Telomere, Biology, Molecular biology, Cytogenetic Analysis, medicine, Animals, Cell Lineage, Chickens, Molecular Biology, Cells, Cultured, In Situ Hybridization, Genetics (clinical), Fluorescence in situ hybridization

Abstract

Four mega-telomere loci were mapped to chicken chromosomes 9, 16, 28, and the W sex chromosome by dual-color fluorescence in situ hybridization using a telomeric sequence probe and BAC clones previously assigned to chicken chromosomes. The in-common features of the mega-telomere chromosomes are that microchromosomes are involved rather than macrochromosomes; in three cases (9, 16, 28) acrocentrics are involved with the mega-telomeres mapping to the p arms. Three of the four chromosomes (9, 16, W) encode tandem repeats which in two cases (9 and 16) involve the ribosomal DNA arrays (the 5S and 18S-5.8S-28S gene repeats, respectively). All involved chromosomes have a typical-sized telomere on the opposite terminus. Intra- and interindividual variation for mega-telomere distribution are discussed in terms of karyotype abnormalities and the potential for mitotic instability of some telomeres. The diversity and distribution of telomere array quantity in the chicken genome should be useful in contributing to research related to telomere length regulation – how and by what mechanism genomes and individual chromosomes establish and maintain distinct sets of telomere array sizes, as well as for future studies related to stability of the chicken genome affecting development, growth, cellular lifespan and disease. An additional impact of this study includes the listing of BAC clones (26 autosomal and six W BACs tested) that were cytogenetically verified; this set of BACs provide a useful tool for future cytogenetic analyses of the microchromosomes.

Published

2007

23. Using the avian mutant talpid 2 as a disease model for understanding the oral-facial phenotypes of Oral-facial-digital syndrome

Author

Samantha A. Brugmann, Julie Chang, Jaime N. Struve, Ching-Fang Chang, Elizabeth N. Schock, Mary E. Delany, and Ya Ting Chang

Subjects

Organogenesis, Neuroscience (miscellaneous), lcsh:Medicine, Medicine (miscellaneous), Cell Cycle Proteins, Chick Embryo, Biology, medicine.disease_cause, Ciliopathies, General Biochemistry, Genetics and Molecular Biology, Avian Proteins, Craniofacial, Neural crest, Cranial neural crest, Primary cilia, Immunology and Microbiology (miscellaneous), Cell Movement, Ciliogenesis, lcsh:Pathology, medicine, Animals, Humans, Cilia, Cell Proliferation, Genetics, Mutation, Cilium, lcsh:R, Cell Differentiation, Orofaciodigital Syndromes, talpid2, medicine.disease, Chicken, Phenotype, Disease Models, Animal, stomatognathic diseases, Ciliopathy, Oral-facial-digital syndrome, Chickens, lcsh:RB1-214, Research Article

Abstract

Oral-facial-digital syndrome (OFD) is a ciliopathy that is characterized by oral-facial abnormalities, including cleft lip and/or palate, broad nasal root, dental anomalies, micrognathia and glossal defects. In addition, these individuals have several other characteristic abnormalities that are typical of a ciliopathy, including polysyndactyly, polycystic kidneys and hypoplasia of the cerebellum. Recently, a subset of OFD cases in humans has been linked to mutations in the centriolar protein C2 Ca2+-dependent domain-containing 3 (C2CD3). Our previous work identified mutations in C2CD3 as the causal genetic lesion for the avian talpid2 mutant. Based on this common genetic etiology, we re-examined the talpid2 mutant biochemically and phenotypically for characteristics of OFD. We found that, as in OFD-affected individuals, protein-protein interactions between C2CD3 and oral-facial-digital syndrome 1 protein (OFD1) are reduced in talpid2 cells. Furthermore, we found that all common phenotypes were conserved between OFD-affected individuals and avian talpid2 mutants. In light of these findings, we utilized the talpid2 model to examine the cellular basis for the oral-facial phenotypes present in OFD. Specifically, we examined the development and differentiation of cranial neural crest cells (CNCCs) when C2CD3-dependent ciliogenesis was impaired. Our studies suggest that although disruptions of C2CD3-dependent ciliogenesis do not affect CNCC specification or proliferation, CNCC migration and differentiation are disrupted. Loss of C2CD3-dependent ciliogenesis affects the dispersion and directional persistence of migratory CNCCs. Furthermore, loss of C2CD3-dependent ciliogenesis results in dysmorphic and enlarged CNCC-derived facial cartilages. Thus, these findings suggest that aberrant CNCC migration and differentiation could contribute to the pathology of oral-facial defects in OFD., Summary: This study utilizes a naturally occurring avian mutant known as talpid2 to determine the cellular basis for the oral-facial phenotypes present in oral-facial-digital syndrome.

Published

2015

24. Germline transmission of genetically modified primordial germ cells

Author

Susan E. Swanberg, Mary E. Delany, Renee Bradshaw, Marie-Cecile van de Lavoir, Jennifer H. Diamond, Christine Mather-Love, Philip A. Leighton, Robert J. Etches, Lisa T. Hooi, Terri M. Gessaro, Babette S. Heyer, and Allyn Kerchner

Subjects

Male, endocrine system, Embryonic Germ Cells, Somatic cell, Chick Embryo, Biology, Germline, Cell Line, Animals, Cell Lineage, Cells, Cultured, Germ-Line Mutation, Ovum, Germ plasm, Genetics, Genome, Multidisciplinary, urogenital system, Stem Cells, fungi, Embryo, Flow Cytometry, Spermatozoa, Embryonic stem cell, Cell biology, Germ Cells, Karyotyping, embryonic structures, Female, Germ line development, Genetic Engineering, Chickens, Developmental biology, Stem Cell Transplantation

Abstract

Primordial germ cells (PGCs) are the precursors of sperm and eggs. In most animals, segregation of the germ line from the somatic lineages is one of the earliest events in development; in avian embryos, PGCs are first identified in an extra-embryonic region, the germinal crescent, after approximately 18 h of incubation. After 50-55 h of development, PGCs migrate to the gonad and subsequently produce functional sperm and oocytes. So far, cultures of PGCs that remain restricted to the germ line have not been reported in any species. Here we show that chicken PGCs can be isolated, cultured and genetically modified while maintaining their commitment to the germ line. Furthermore, we show that chicken PGCs can be induced in vitro to differentiate into embryonic germ cells that contribute to somatic tissues. Retention of the commitment of PGCs to the germ line after extended periods in culture and after genetic modification combined with their capacity to acquire somatic competence in vitro provides a new model for developmental biology. The utility of the model is enhanced by the accessibility of the avian embryo, which facilitates access to the earliest stages of development and supplies a facile route for the reintroduction of PGCs into the embryonic vasculature. In addition, these attributes create new opportunities to manipulate the genome of chickens for agricultural and pharmaceutical applications.

Published

2006

25. Avian Genetic Stocks: The High and lOw Points from an Academia Researcher

Author

Mary E. Delany

Subjects

Conservation of Natural Resources, Genetic Research, Land grant, National interest, business.industry, education, Genetic Variation, Chick Embryo, General Medicine, Breeding, Biology, Poultry, humanities, Biotechnology, Agriculture, Genetic resources, Animals, Inbreeding, Animal Science and Zoology, Marketing, business, Chickens, health care economics and organizations

Abstract

Poultry genetic resources, which are valuable for research, span an impressive gamut from breeds to highly specialized inbred lines. The community of scientists utilizing specialized lines is broad, including researchers in medicine, basic biology, and agricultural science. The majority of specialized research lines used by such scientists are held at land grant universities. Over the prior 2 decades, hundreds of lines were eliminated. This pattern continues today with no evidence of abatement. Awareness and visibility of the causes and ongoing problems have been highlighted via a number of high-profile forums. Given the large community of scientists and the negative impact on future advances in biological, medical, and agricultural research as these genetic resources dwindle, the issue is of national interest and warrants federal funding to support a united network of avian and poultry stocks centers.

Published

2006

26. High-grade transgenic somatic chimeras from chicken embryonic stem cells

Author

Philip A. Leighton, Allyn Kerchner, Mary E. Delany, Babette S. Heyer, Marie-Cecile van de Lavoir, Lei Zhu, Jennifer H. Diamond, Peggy Winters-Digiacinto, Terri M. Gessaro, Christine Mather-Love, Susan E. Swanberg, Robert J. Etches, and Rhys D. Roberts

Subjects

Male, Pluripotent Stem Cells, KOSR, Embryology, DNA, Complementary, Somatic cell, Disorders of Sex Development, Nerve Tissue Proteins, Chick Embryo, Embryoid body, Biology, Germline, Cell Line, Animals, Genetically Modified, Avian Proteins, 03 medical and health sciences, Animals, RNA, Messenger, Cell Proliferation, 030304 developmental biology, 0303 health sciences, Base Sequence, Chimera, 030302 biochemistry & molecular biology, Diploidy, Molecular biology, Embryonic stem cell, Germ Cells, Phenotype, Cell culture, Female, Stem cell, Chickens, Stem Cell Transplantation, Developmental Biology, Adult stem cell

Abstract

Male and female embryonic stem (ES) cell lines were derived from the area pellucidae of Stage X (EG&K) chicken embryos. These ES cell lines were grown in culture for extended periods of time and the majority of the cells retained a diploid karyotype. When reintroduced into Stage VI-X (EG&K) recipient embryos, the cES cells were able to contribute to all somatic tissues. By combining irradiation of the recipient embryo with exposure of the cES cells to the embryonic environment in diapause, a high frequency and extent of chimerism was obtained. High-grade chimeras, indistinguishable from the donor phenotype by feather pigmentation, were produced. A transgene encoding GFP was incorporated into the genome of cES cells under control of the ubiquitous promoter CX and GFP was widely expressed in somatic tissues. Although cES cells made extensive contributions to the somatic tissues, contribution to the germline was not observed.

Published

2006

27. Differential expression of genes associated with telomere length homeostasis and oncogenesis in an avian model

Author

Susan E. Swanberg and Mary E. Delany

Subjects

Pluripotent Stem Cells, Aging, Telomerase, animal structures, Chick Embryo, Biology, medicine.disease_cause, Gene expression, medicine, Animals, RNA, Messenger, Induced pluripotent stem cell, Gene, Cellular Senescence, Cell Line, Transformed, Gastrula, Fibroblasts, Telomere, Molecular biology, Up-Regulation, Cell culture, embryonic structures, Carcinogenesis, Cell aging, Developmental Biology

Abstract

Telomere-binding proteins, their interaction partners and transcription factors play a prominent role in telomere maintenance and telomerase activation. We examined mRNA expression levels of tankyrase 1 and 2, TRF1 and 2, c-myc, TERT and TR in Gallus domesticus, the domestic chicken, by quantitative real-time PCR, establishing expression profiles for three contrasting cell systems: the pluripotent gastrula, differentiated embryo fibroblasts and transformed DT40 cells. All seven genes were up-regulated in DT40 cells compared to telomerase-negative CEFs and a majority of the genes were also up-regulated in the gastrula relative to CEFs. Surprisingly, we found TERT and TR transcripts in CEFs, albeit at low levels. TRF1 was down-regulated in the six CEF cultures by the time of culture growth arrest. A marked increase in the TRF2:TRF1 ratio occurred at or near senescence in all of the CEF cultures studied, with the most elevated ratio found in a short-lived culture in which TRF1 mRNA levels decreased two-fold and TRF2 levels increased 21-fold. This culture also showed highly reduced, degraded telomeres by Southern blot analysis. These data suggest that genes involved in telomere maintenance and telomerase induction are expressed differentially in pluripotent, differentiated and transformed cell systems.

Published

2005

28. Integration of the cytogenetic and physical maps of chicken chromosome 17

Author

Jerry B. Dodgson, Laura M. Daniels, Mary E. Delany, and Michael N Romanov

Subjects

Genetics, Chromosomes, Artificial, Bacterial, Bacterial artificial chromosome, Genome, medicine.diagnostic_test, Chromosome Mapping, Chromosome, Biology, Physical Chromosome Mapping, Chromosome 17 (human), Gene density, Centromere, Microchromosome, medicine, Animals, SF, Chickens, QH426, Fluorescence in situ hybridization

Abstract

The chicken genome, like those of most avian species, contains numerous microchromosomes that cannot be distinguished by size alone. Unique properties attributed to the microchromosomes include high GC content and gene density, and an enhanced recombination rate. Previously, microchromosome GGA 17 was shown to align with the consensus genetic linkage group E41W17, and bacterial artificial chromosome (BAC) clones containing E41W17 markers were isolated and assigned on the physical BAC map as well as the recently assembled draft chicken genome sequence. For this study, these same BACS were utilized as probes for fluorescence in-situ hybridization (FISH) to develop the GGA 17 cytogenetic map. Here we detail the chromosome order of ten BAC DNAs, thereby deriving a cytogenetic map of GGA 17 that is simultaneously integrated with both the linkage map and genome sequence. The location of the FISH probes together with the morphological appearance of the chromosome suggested that GGA 17 is an acrocentric chromosome whose cytogenetic map orientation is reversed from that currently indicated by the linkage map and draft genome sequence. The reversed orientation and the centromere location of GGA 17 were confirmed experimentally by dual-colour FISH hybridization using terminal BACs and the centromere-specific CNM oligonucleotide as probes. An advantage of this cyto-genomic approach is the improved alignment of the sequence and linkage maps with cytogenetic features such as the centromere, telomeres, p and q arms, and staining patterns indicating GC versus AT content.

Published

2005

29. The chicken telomerase reverse transcriptase (chTERT): molecular and cytogenetic characterization with a comparative analysis

Author

Mary E. Delany and Laura M. Daniels

Subjects

Telomerase, DNA, Complementary, 5' Flanking Region, Xenopus, Molecular Sequence Data, Biology, Mice, Telomerase RNA component, Cricetinae, Genetics, Animals, Humans, Telomerase reverse transcriptase, Amino Acid Sequence, Cloning, Molecular, Gene, In Situ Hybridization, Fluorescence, Binding Sites, Sequence Homology, Amino Acid, Chromosome Mapping, RNA, Promoter, DNA, Sequence Analysis, DNA, General Medicine, Molecular biology, Reverse transcriptase, Chromosome Banding, Rats, Telomere, DNA-Binding Proteins, Cytogenetic Analysis, Chickens, Sequence Alignment, Transcription Factors

Abstract

Telomerase activity is essential for maintaining the termini of linear chromosomes. Telomerase consists of both a RNA and a specialized reverse transcriptase. Our objective for this study was to determine the molecular and cytogenetic features of the chicken telomerase reverse transcriptase (chTERT) gene and protein. The TERT mRNA from gastrula stage embryos was found to be 4497 bp in length, translating into a protein of 1346 amino acids (aa). The chTERT protein shares 45% aa identity with human TERT (hTERT). A distinctive feature of chTERT, as compared to human and other vertebrate TERTs, is the larger size of the protein due mainly to a considerably longer N-terminal flexible linker region (144 aa longer than in human). Chicken TERT was mapped to chromosome 2q21 near an interstitial telomere site. Several transcription factor binding motifs in the 5Vflanking/promoter region of chTERT were similar to those found associated with hTERT (E-box, Ik1, MAZ, Sp1 sites), whereas several c-Myb sites were found associated with chTERT only and c-Ets-2 and WT1 were associated with hTERT only. Results presented here should promote structure–function studies of chTERT, as well as contribute to the comparative analysis of TERT regulation and function in vertebrates utilizing the telomere clock mechanism to different degrees. D 2004 Elsevier B.V. All rights reserved.

Published

2004

30. Telomeres in the chicken: genome stability and chromosome ends

Author

Mary E. Delany, LM Daniels, HA Taylor, and SE Swanberg

Subjects

Chromosome Aberrations, Telomere-binding protein, Genetics, Aging, Telomerase, Genome, DNA Repair, Down-Regulation, Chicken Cells, Chromosome, General Medicine, Telomere, Biology, Tandem repeat, Animals, Animal Science and Zoology, Human genome, Chickens, Biotechnology

Abstract

Telomeres are the complex nucleoprotein structures at the termini of linear chromosomes. Telomeric DNA consists of a highly conserved hexanucleotide arranged in tandem repeats. Telomerase, a ribonucleoprotein of the reverse transcriptase family, specifies the sequence of telomeric DNA and maintains telomere array length. Numerous studies in model organisms established the significance of telomere structure and function in regulating genome stability, cellular aging, and oncogenesis. Our overall research objectives are to understand the organization of the telomere arrays in chicken in the context of the unusual organization and specialized features of this higher vertebrate genome (which include a compact genome, numerous microchromosomes, and high recombination rate) and to elucidate the role telomeres play in genome stability impacting cell function and life span. Recent studies found that the chicken genome contains three overlapping size classes of telomere arrays that differ in location and age-related stability: Class I 0.5 to 10 kb, Class II 10 to 40 kb, and Class III 40 kb to 2 Mb. Some notable features of chicken telomere biology are that the chicken genome contains ten times more telomeric DNA than the human genome and the Class III telomere arrays are the largest described for any vertebrate species. In vivo, chicken telomeres (Class II) shorten in an age-related fashion and telomerase activity is high in early stage embryos and developing organs but down-regulates during late embryogenesis or postnatally in most somatic tissues. In vitro, chicken cells down-regulate telomerase activity unless transformed. Knowledge of chicken telomere biology contributes information relevant to present and future biotechnology applications of chickens in vivo and chicken cells in vitro.

Published

2003

31. The chicken telomerase RNA gene: conservation of sequence, regulatory elements and synteny among viral, avian and mammalian genomes

Author

Laura M. Daniels and Mary E. Delany

Subjects

Chromosomes, Artificial, Bacterial, Telomerase, Molecular Sequence Data, Genome, Viral, Biology, Synteny, Avian Proteins, Mice, Telomerase RNA component, Sequence Homology, Nucleic Acid, Databases, Genetic, Genes, Regulator, Genetics, Animals, Humans, Telomerase reverse transcriptase, Molecular Biology, Gene, Conserved Sequence, Genetics (clinical), Genome, Base Sequence, Chromosome Mapping, RNA, Telomere, Mardivirus, Regulatory sequence, Chickens, Animals, Inbred Strains

Abstract

Telomerase RNA (TR) is essential for telomerase activity and the maintenance of telomere length in proliferating cell populations. The objective of the present research was to define the cytogenetic and molecular genomic organization of chicken TR (chTR). The chTR exists as a single copy gene (TERC, alias TR), mapping to chromosome 9 (GGA9). The loci on the q arm of GGA9 map to three chromosomes in human with five of the nine GGA9q loci mapping to HSA3q. Sequencing of the chTERC locus (3,763 bp) from the UCD 001 genome (Red Jungle Fowl) included: 604 bp 5′, 465 coding, and 2,694 bp 3′ (from –604 to +3159). Sequence analysis included homology searches conducted on several levels including comparisons among different chicken genotypes, Marek’s disease virus (MDV) sequences, plus human and murine. We provide evidence for distal 5′ and 3′ sequence homology between chTERC and the MDV genome among other known regions of homology (promoter and coding), elaborate on 5′ transcription factor binding motifs among the various genomes as well as show type and number of TERT-related motifs 3′ of chicken TR (e.g., Sp1, c-Myb, c-Myc, AP2, among others). Surrounding the gene are more than 25 Sp1 sites, over 20 oncogene transcription factor binding motifs and numerous hormonal and other specialized binding motifs. Knowledge of 5′ and 3′ chTERC regulatory elements will be useful for investigating normal control mechanisms during growth and development as well as investigating the potential for dysregulation of this important gene during oncogenesis, especially among different genotypes.

Published

2003

32. Patterns of ribosomal gene variation in elite commercial chicken pure line populations

Author

Mary E. Delany

Subjects

Male, Genetics, Genetic diversity, Broiler, Genetic Variation, Locus (genetics), General Medicine, Ribosomal RNA, Biology, DNA, Ribosomal, Tandem Repeat Sequences, embryonic structures, Genetic variation, Nucleolus Organizer Region, Animals, Electrophoresis, Polyacrylamide Gel, Female, Animal Science and Zoology, Copy-number variation, Chickens, Ribosomes, Gene, Repeat unit

Abstract

The nucleolus organizer region (NOR) encodes the tandemly repeated 18S, 5 ·8S and 28S ribosomal (r) RNA genes. The NORs of broiler and layer commercial chicken pure lines were studied to establish the type and extent of genetic variation at this important locus. The parameters studied were gene copy number, repeat size, and diversity of NOR-types. The populations were organized into three groups for analysis including brown-egg broiler (13 lines), brown-egg layer (six lines), and white-egg layer (eight lines). The ribosomal gene copy number average of the white-egg layer populations was significantly lower (329 genes) than that of the brown-egg layers (372 genes); the brown-egg broiler ribosomal gene average was intermediate (350 genes). The white-egg layer populations exhibited a ribosomal repeat unit average size of 36 kb, significantly different from the brown-egg layer and brown-egg broiler average repeat unit size of 32 ·5 and 33 ·9 kb, respectively. NOR array size was similar among the three groups (6 mb). The brown-egg broiler populations exhibited polymorphic NOR patterns, intra-and interline, whereas the white-egg layer populations were essentially monomorphic for NOR-type; brown-egg layers exhibited an intermediate level of NOR diversity. Some NOR array characteristics may be a function of breed origin as brown-egg commercial populations, both broilers and layers, have similar breed origins and exhibited similarities for predominant repeat unit size as compared with white-egg layer populations. However, the finding that brown-egg broiler lines typically exhibit a greater number of segregating NOR-types than brown-egg layer lines suggests that the selection schemes of broiler vs. layer pure line populations may also have influenced the degree of variation at this gene complex.

Published

2000

33. Molecular characterization of ribosomal gene variation within and among NORs segregating in specialized populations of chicken

Author

Alex B. Krupkin and Mary E. Delany

Subjects

Genetics, Genotype, Gene Dosage, Genetic Variation, Locus (genetics), DNA Restriction Enzymes, General Medicine, Biology, Ribosomal RNA, Models, Biological, Gene dosage, RNA, Ribosomal, 28S ribosomal RNA, Genetic variation, Nucleolus Organizer Region, Animals, Copy-number variation, Nucleolus organizer region, Chickens, Molecular Biology, Gene, Biotechnology

Abstract

The molecular organization of the 18S, 5.8S, and 28S ribosomal RNA gene repeat units, located at the single nucleolus organizer region (NOR) locus in the chicken, was investigated in genetically distinct populations of research and commercial chickens. Substantial gene repeat variation within and among NORs was documented. Intact ribosomal gene repeat size ranged from 11 kb to over 50 kb. Unique combinations of ribosomal genes, of different size, were specific to particular populations. It was determined that the basis for the ribosomal gene repeat size variation was intergenic spacer (IGS) length heterogeneity. Interestingly, in different populations, the location of the variation that contributes to length heterogeneity was specific to particular IGS subregions. In addition to IGS variation, an inbred line of Red Jungle Fowl exhibited coding region variation. Ribosomal gene copy number variation was also studied, and line averages ranged from 279 to 368. Average rDNA array size (a function of copy number and gene repeat length) was calculated for each of the populations and found to vary over a range of two megabases, from 5 to 7 Mb.Key words: rDNA, NOR, IGS, genetic variation, chicken.

Published

1999

34. Ribosomal RNA gene copy number and nucleolar-size polymorphisms within and among chicken lines selected for enhanced growth

Author

M. H. Su and Mary E. Delany

Subjects

Male, Genetics, education.field_of_study, Polymorphism, Genetic, Nucleolus, Population, Genetic Variation, General Medicine, Ribosomal RNA, Biology, Molecular biology, Phenotype, RNA, Ribosomal, Genetic variation, Nucleolus Organizer Region, Animals, Female, Animal Science and Zoology, Copy-number variation, Nucleolus organizer region, Ploidy, education, Chickens, Gene, Cell Nucleolus

Abstract

Ribosomal (r) DNA genotypes (rRNA gene copy number) and nucleolar phenotypes (nucleoli number and size) were studied in dam and sire commercial broiler pure lines from three primary breeder sources. Thirteen lines were studied to determine whether directionally selected broiler pure lines contain higher numbers of rRNA genes than a control line unselected for performance traits. Eight of the 13 lines exhibited rRNA gene copy averages between 261 and 331 copies, three lines had averages between 365 and 380, and two lines had average copy numbers equal to or greater than 450 rRNA genes. The overall source copy number average from one breeder company exhibited a value (402 rRNA genes) significantly different from the control value (300 rRNA genes). Nucleoli number and relative-size were examined in 9 of the 13 lines to establish ploidy and determine the population incidence of nucleolar size polymorphisms. All of the individuals examined for nucleolar phenotype expressed two nucleoli, indicating that gene copy number variation in those lines was generally unrelated to haploidy, aneuploidy, or polyploidy. A high frequency of individuals exhibited nucleolar size polymorphisms (line values of 57 to 87%). The results suggest that multiple nucleolus organizer region (NOR) types are segregating within and among broiler pure lines and that these NOR types contain variable numbers of rRNA genes that differ in nucleogenesis capacity.

Published

1998

35. Effects of rRNA Gene Copy Number and Nucleolar Variation on Early Development: Inhibition of Gastrulation in rDNA-Deficient Chick Embryo

Author

Stephen E. Bloom, Mary E. Delany, and Donna E. Muscarella

Subjects

Male, Genetics, Polymorphism, Genetic, Nucleolus, Gene Amplification, Embryo, Chick Embryo, Gastrula, Ribosomal RNA, Biology, DNA, Ribosomal, Phenotype, Gastrulation, RNA, Ribosomal, Multigene Family, Animals, Female, Copy-number variation, Molecular Biology, Gene, Ribosomal DNA, Cell Nucleolus, Genetics (clinical), Biotechnology

Abstract

Because of their structural and catalytic functions during protein synthesis, the 18S, 5.8S, and 28S ribosomal RNAs (rRNAs) are essential for the support of differentiation, development, and growth. The genes encoding these RNAs are present in high copy number in all eukaryotes. Although there is evidence for the existence of variation for rRNA gene copy number within higher vertebrate species, there is little knowledge concerning the effects of such variation, especially reductions, on development and viability of homeothermic vertebrates. The main objective of this study was to determine the developmental potential of chick embryos containing defined deficiencies for rRNA gene copy number in order to assess the contribution of rDNA cluster size variation to embryonic mortality in homeothermic vertebrates. This was achieved by studying a strain of chickens containing nucleolar size polymorphisms that reflect rDNA cluster size polymorphisms. Embryos exhibiting a nucleolar phenotype of one large and one very small nucleolus (Pp) are heterozygous for a reduced rDNA cluster (+/p1) and were shown in the present study to contain about 66% of the complement of rRNA genes in normal individuals (+/+) that show two large equal-sized nucleoli (PP). The +/p1 embryos were found to develop and grow normally. Embryos exhibiting a nucleolar phenotype of two very small nucleoli (pp) are homozygous for the rDNA-deficient cluster (p1/p1) and contained about 45% of the normal rDNA complement of genes. These p1/p1 embryos were arrested in their development during early gastrulation. They exhibited a characteristic morphology consisting of a dorsal invagination that was strikingly different from the primitive streak formed in +/+ and +/p1 individuals.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1994

36. The expression of preaxial polydactyly is influenced by modifying genetic elements and is not maintained by chromosomal inversion in an avian biomedical model

Author

Mary E. Delany and Elizabeth A. Robb

Subjects

Candidate gene, Heterozygote, Molecular Sequence Data, Congenic, Biology, Regulatory Sequences, Nucleic Acid, Polymorphism, Single Nucleotide, Birds, Mice, Genetics, Animals, Humans, Point Mutation, Hedgehog Proteins, Molecular Biology, Genetics (clinical), In Situ Hybridization, Fluorescence, Chromosomal inversion, Retrospective Studies, Base Sequence, Point mutation, Preaxial polydactyly, Chromosome, Chromosome Mapping, Introns, Polydactyly, Wills, Phenotype, Mutation (genetic algorithm), Chromosome Inversion, Epistasis, Sequence Alignment

Abstract

Polydactyly (Po) is a common mutation found in many vertebrates. The UCD-Po.003 congenic chicken line was previously characterized for Po inheritance (autosomal dominant) and the mutation was mapped to chromosome 2p. Here, we describe for the first time the range and variability of the phenotype in this congenic line. Further, we studied the hypothesis that a chromosomal inversion was responsible for the maintenance of a large (6.3 Mb) candidate gene region. Fluorescence in situ hybridization employing BACs encompassing a 10.7-Mb region of GGA2p showed that the Po chromosome was normal, i.e. exhibits the wild-type BAC order. Continued fine-mapping along with a change in breeding strategy reduced the size of the causative region to 1.43 Mb. Recent research indicates that the cause of preaxial Po resides within a 794-bp highly conserved zone of polarizing activity regulatory sequence (ZRS) element located in intron 5 of the LMBR1 gene; however, the ZRS polymorphism of interest is found in some but not all breeds of polydactylous chicken. Therefore, we sequenced the ZRS in 101 heterozygous and 30 unaffected (wild-type) individuals to establish the relevance of this region to the Po condition in the UCD-Po.003 congenic line. A single point mutation (C/A at coordinate GGA2p: 8,414,121) within the ZRS segregated with carrier status. The polydactylous UCD-Silkie line also maintains this SNP in addition to a single base deletion. An inheritance analysis of the phenotypic variation in UCD-Po.003 suggests recessive epistasis as the mode of inheritance for the additional modifying genetic elements, residing outside the ZRS, to impact the preaxial polydactyl phenotype. These results contribute to our understanding of the cause of Po in an important vertebrate model.

Published

2011

37. Chromosomal mapping and candidate gene discovery of chicken developmental mutants and genome-wide variation analysis of MHC congenics

Author

Elizabeth A. Robb, Hans H. Cheng, Cynthia L. Gitter, and Mary E. Delany

Subjects

Candidate gene, Congenic, Single-nucleotide polymorphism, Chick Embryo, Major histocompatibility complex, medicine.disease_cause, Genome, Polymorphism, Single Nucleotide, Major Histocompatibility Complex, Animals, Congenic, Genetics, medicine, SNP, Animals, Genes, Developmental, Molecular Biology, Genetics (clinical), Genetic Association Studies, Mutation, biology, Chromosome Mapping, Phenotype, Haplotypes, biology.protein, Chickens, Biotechnology, SNP array

Abstract

The chicken has been widely used in experimental research given its importance to agriculture and its utility as a model for vertebrate biology and biomedical pursuits for over 100 years. Herein we used advanced technologies to investigate the genomic characteristics of specialized chicken congenic genetic resources developed on a highly inbred background. An Illumina 3K chicken single nucleotide polymorphism (SNP) array was utilized to study variation within and among major histocompatibility complex (MHC)-congenic lines as well as investigate line-specific genomic diversity, inbreeding coefficients, and MHC B haplotype-specific GGA 16 SNP profiles. We also investigated developmental mutant-congenic lines to map a number of single-gene mutations using both the Illumina 3K array and a recently developed Illumina 60K chicken SNP array. In addition to identifying the chromosomes and specific subregions, the mapping results affirmed prior analyses indicating recessive or dominant and autosomal or sex chromosome modes of inheritance. Priority candidate genes are described for each mutation based on association with similar phenotypes in other vertebrates. These single-gene mutations provide a means of studying amniote development and in particular serve as invaluable biomedical models for similar malformations found in human.

Published

2011

38. Defining the turkey MHC: identification of expressed class I- and class IIB-like genes independent of the MHC-B

Author

Kent M. Reed, L. D. Chaves, Miranda M. Bauer, Mary E. Delany, Melissa S. Monson, Benjamin Benoit, and Thomas H. O’Hare

Subjects

Turkeys, Neocentromere, Genetic Linkage, Immunology, Centromere, Genes, MHC Class II, Molecular Sequence Data, Gene Expression, Genes, MHC Class I, chemical and pharmacologic phenomena, Locus (genetics), Biology, Major histocompatibility complex, Genetics, medicine, Animals, Amino Acid Sequence, Gene, Phylogeny, medicine.diagnostic_test, Haplotype, Chromosome Mapping, Amplicon, Haplotypes, Genetic Loci, biology.protein, Chickens, Fluorescence in situ hybridization

Abstract

The MHC of the turkey (Meleagris gallopavo) is divided into two genetically unlinked regions; the MHC-B and MHC-Y. Although previous studies found the turkey MHC-B to be highly similar to that of the chicken, little is known of the gene content and extent of the MHC-Y. This study describes two partially overlapping large-insert BAC clones that genetically and physically map to the turkey MHC chromosome (MGA18) but to a region that assorts independently of MHC-B. Within the sequence assembly, 14 genes were predicted including new class I- and class IIB-like loci. Additional unassembled sequences corresponded to multiple copies of the ribosomal RNA repeat unit (18S–5.8S–28S). Thus, this newly identified MHC region appears to represent a physical boundary of the turkey MHC-Y. High-resolution multi-color fluorescence in situ hybridization studies confirm rearrangement of MGA18 relative to the orthologous chicken chromosome (GGA16) in regard to chromosome architecture, but not gene order. The difference in centromere position between the species is indicative of multiple chromosome rearrangements or alternate events such as neocentromere formation/centromere inactivation in the evolution of the MHC chromosome. Comparative sequencing of commercial turkeys (six amplicons totaling 7.6 kb) identified 68 single nucleotide variants defining nine MHC-Y haplotypes. Sequences of the new class I- and class IIB-like genes are most similar to MHC-Y genes in the chicken. All three loci are expressed in the spleen. Differential transcription of the MHC-Y class IIB-like loci was evident as one class IIB-like locus was only expressed in some individuals.

Published

2011

39. Multi-Platform Next-Generation Sequencing of the Domestic Turkey (Meleagris gallopavo): Genome Assembly and Analysis

Author

Guillaume Marçais, Stephen M. J. Searle, Dennis Prickett, Pascal Bouffard, Edward J. Smith, Jerry B. Dodgson, Magali Ruffier, Michael C. Schatz, Thero Modise, Steve Hoffmann, Pieter J. de Jong, Sungwon Kim, Le Ann Blomberg, Karin M. Frederickson, Heebal Kim, Clive Evans, Mikhail Nefedov, Carl J. Schmidt, Rami A. Dalloul, Mary E. Delany, Taeheon Lee, Richard P. M. A. Crooijmans, Paul Flicek, Daniela Puiu, David Langenberger, Jennifer J Dong, Chantel F. Scheuring, James A. Yorke, Curtis P. Van Tassell, Mi-Kyung Lee, Javier Herrero, Julie A. Long, Martien A. M. Groenen, David W. Burt, Shrinivasrao P. Mane, Liliana Florea, Peter F. Stadler, Kyu-Won Kim, Kent M. Reed, Zhijian Jake Tu, Oswald Crasta, Jacqueline Smith, Roger A. Coulombe, Manja Marz, Otto Folkerts, William S. Payne, Emanuele Raineri, A. P. McElroy, Hakim Tafer, Xiaojun Zhang, Ian R. Paton, Steven L. Salzberg, Geo Pertea, Albert J. Vilella, Hendrik-Jan Megens, Kathryn Beal, Dan Qioa, Kelly P. Williams, Liqing Zhang, Hong-Bin Zhang, Supriyo De, Luqman Aslam, Steven Schroeder, Cedric Notredame, Yang Zhang, Kristal L. Cooper, Aleksey V. Zimin, Tad S. Sonstegard, Tim Harkins, Peter K. Kaiser, Andrew Jiang, Animal and Poultry Sciences, Biochemistry, Computer Science, and Fralin Life Sciences Institute

Subjects

Life Sciences & Biomedicine - Other Topics, 0106 biological sciences, DIVERSITY, Sequence assembly, Computational Biology/Comparative Sequence Analysis, 01 natural sciences, Genome, Biology (General), Evolutionary Biology/Genomics, high-throughput, 2. Zero hunger, Genetics, 0303 health sciences, galliformes, Agricultural and Biological Sciences(all), biology, General Neuroscience, Chromosome Mapping, Genome project, Genetics and Genomics/Bioinformatics, gene family, Genetics and Genomics/Genetics of the Immune System, Genetics and Genomics/Comparative Genomics, General Agricultural and Biological Sciences, Research Article, Biochemistry & Molecular Biology, Turkeys, MOLECULAR PHYLOGENY, QH301-705.5, Neuroscience(all), CHICKEN GENOME, BIOLOGY, GENE FAMILY, Animal Breeding and Genomics, HIGH-THROUGHPUT, 010603 evolutionary biology, Polymorphism, Single Nucleotide, General Biochemistry, Genetics and Molecular Biology, diversity, 03 medical and health sciences, Species Specificity, Immunology and Microbiology(all), Sequence Homology, Nucleic Acid, evolution, monodelphis-domestica, Animals, Fokkerij en Genomica, Zebra finch, molecular phylogeny, 030304 developmental biology, Comparative genomics, Whole genome sequencing, IDENTIFICATION, BIRDS, General Immunology and Microbiology, Base Sequence, Biochemistry, Genetics and Molecular Biology(all), DNA, Sequence Analysis, DNA, MONODELPHIS-DOMESTICA, chicken genome, biology.organism_classification, EVOLUTION, Genetics and Genomics/Genome Projects, Evolutionary biology, GALLIFORMES, birds, WIAS, identification, Meleagris gallopavo, Reference genome, Computational Biology/Genomics

Abstract

The combined application of next-generation sequencing platforms has provided an economical approach to unlocking the potential of the turkey genome., A synergistic combination of two next-generation sequencing platforms with a detailed comparative BAC physical contig map provided a cost-effective assembly of the genome sequence of the domestic turkey (Meleagris gallopavo). Heterozygosity of the sequenced source genome allowed discovery of more than 600,000 high quality single nucleotide variants. Despite this heterozygosity, the current genome assembly (∼1.1 Gb) includes 917 Mb of sequence assigned to specific turkey chromosomes. Annotation identified nearly 16,000 genes, with 15,093 recognized as protein coding and 611 as non-coding RNA genes. Comparative analysis of the turkey, chicken, and zebra finch genomes, and comparing avian to mammalian species, supports the characteristic stability of avian genomes and identifies genes unique to the avian lineage. Clear differences are seen in number and variety of genes of the avian immune system where expansions and novel genes are less frequent than examples of gene loss. The turkey genome sequence provides resources to further understand the evolution of vertebrate genomes and genetic variation underlying economically important quantitative traits in poultry. This integrated approach may be a model for providing both gene and chromosome level assemblies of other species with agricultural, ecological, and evolutionary interest., Author Summary In contrast to the compact sequence of viruses and bacteria, determining the complete genome sequence of complex vertebrate genomes can be a daunting task. With the advent of “next-generation” sequencing platforms, it is now possible to rapidly sequence and assemble a vertebrate genome, especially for species for which genomic resources—genetic maps and markers—are currently available. We used a combination of two next-generation sequencing platforms, Roche 454 and Illumina GAII, and unique assembly tools to sequence the genome of the agriculturally important turkey, Meleagris gallopavo. Our draft assembly comprises approximately 1.1 gigabases of which 917 megabytes are assigned to specific chromosomes. Comparisons of the turkey genome sequence with those of the chicken, Gallus gallus, and the zebra finch, Taeniopygia guttata, provide insights into the evolution of the avian lineage. This genome sequence will facilitate discovery of agriculturally important genetic variants.

Published

2010

40. The effects of MHC chromosome dosage on bursal B-cell subpopulations in embryonic and neonatal chickens

Author

Stephen E. Bloom, Mary E. Delany, and Rodney R. Dietert

Subjects

animal structures, Cellular differentiation, Immunology, B-Lymphocyte Subsets, Chick Embryo, Major histocompatibility complex, Major Histocompatibility Complex, Andrology, Bursa of Fabricius, Antigen, medicine, Animals, B cell, MHC class II, biology, Embryogenesis, Histocompatibility Antigens Class II, Cell Differentiation, Embryo, Aneuploidy, Embryonic stem cell, medicine.anatomical_structure, Animals, Newborn, Immunoglobulin M, Immunoglobulin G, embryonic structures, biology.protein, Chickens, Cell Division, Developmental Biology

Abstract

The effect of MHC dosage on the population structure of developing bursal lymphocytes was studied in the Trisomic strain of chickens. These chickens contain either 2 (disomic), 3 (trisomic), or 4 (tetrasomic) copies of the MHC-encoding chromosome. To assess the developmental profile of bursal cell populations, bursal cells were characterized in the older embryo (18 days of incubation) and at two neonatal ages (1 day and 1 week post hatch) by a number of cellular parameters. Both transient and persistent alterations in cellular composition were revealed in the bursal subpopulations of trisomics and tetrasomics (aneuploids). Aneuploid bursal cells showed increased cell surface expression of MHC class II Ia antigen, at each age, compared to normal disomic cells. Aneuploid cell populations showed an increased incidence of small cells, at each age, a decreased incidence of Ia+ and IgM+ cells during late embryogenesis, and an increased incidence of IgG+ cells in the late embryo and 1-day-old chick. Significantly fewer proliferating cells were observed in the aneuploids, as compared to disomics, in the late embryo and 1-week-old chick. Three subpopulations were observed to be persistently altered in the MHC-aneuploids: an increased pool of Ia , small, IgM+ cells; a decreased pool of Ia+, large, IgM+ cells; and a decreased pool of Ia+, large, IgM- cells. Thus, increasing MHC-chromosome dosage is accompanied by specific alterations in B-cell differentiation. The elevated surface Ia antigen expression found on developing aneuploid B cells may play a role in these alterations.

Published

1992

41. Architecture and organization of chicken microchromosome 16: order of the NOR, MHC-Y, and MHC-B subregions

Author

Ronald M. Goto, Charmaine M. Robinson, Marcia M. Miller, and Mary E. Delany

Subjects

Genetics, Bacterial artificial chromosome, Secondary constriction, Nucleolus, Chromosome Mapping, chemical and pharmacologic phenomena, Context (language use), Biology, Major histocompatibility complex, Chromosomes, Major Histocompatibility Complex, Evolutionary biology, Centromere, biology.protein, Microchromosome, Nucleolus Organizer Region, Animals, Molecular Biology, Ribosomal DNA, Chickens, Genetics (clinical), In Situ Hybridization, Fluorescence, Biotechnology

Abstract

Here we present a high-resolution cytogenomic analysis of chicken microchromosome 16. We established the location of the major histocompatibility complex (MHC)-B and -Y subregions relative to each other and to the nucleolus organizer region (NOR) encoding the 18S-5.8S-28S ribosomal DNA. To do so, we employed multicolor fluorescence in situ hybridization using large-insert bacterial artificial chromosome clones with fully sequenced inserts or repetitive sequence probes specific for the subregion of interest. We show that the MHC-Y and -B regions are located on the same side of the NOR, rather than opposite ends, as previously proposed. On the q arm, the MHC-Y is closely adjacent to the NOR, whereas the MHC-B is distal near the q-terminus. A relatively large GC-rich region separates the 2 MHC subregions and includes a specialized structure, a secondary constriction. We propose that the GC-rich large physical distance is the basis for the lack of genetic linkage between the NOR and MHC-B and between the MHC-Y and -B. An integrated model for GGA 16 is presented that incorporates gene complex order in the context of key architectural features including p and q arms, primary (centromere) and secondary constrictions, telomeres, as well as AT- and GC-rich regions.

Published

2009

42. Formation of Nucleolar Polymorphisms in Trisomic Chickens and Subsequent Microevolution of rRNA Gene Clusters in Diploids

Author

Stephen E. Bloom, D. E. Muscarella, and Mary E. Delany

Subjects

Male, medicine.medical_specialty, Trisomy, Biology, Loss of heterozygosity, symbols.namesake, Nucleolus Organizer Region, Genetics, medicine, Animals, Copy-number variation, Molecular Biology, Gene, Crosses, Genetic, Genetics (clinical), Polymorphism, Genetic, Cytogenetics, Nucleic Acid Hybridization, Chromosome, Biological Evolution, Diploidy, Pedigree, Meiosis, RNA, Ribosomal, Multigene Family, Mendelian inheritance, symbols, Female, Ploidy, Nucleolus organizer region, Chickens, Biotechnology

Abstract

Variations in nucleolar size are common in animals and man, yet the basis and significance of this variation are not well understood. In this report, we describe the generation de novo of individuals that express nucleolar size variations (polymorphisms) and the underlying basis for this phenotype in a vertebrate animal system (Gallus domesticus). Individuals that express nucleolar size polymorphisms were produced from mating chickens trisomic for the nucleolar organizer (NO) chromosome; 10%-18% of progeny demonstrated nucleolar polymorphisms. These progeny were incorporated into a diploid genetic line in which the polymorphic trait was observed to segregate in Mendelian fashion. An even more dramatic nucleolar size polymorphism (one macro- plus one micronucleolus) evolved in one diploid family over the course of only two generations. These individuals were used to ascertain that the polymorphic-nucleoli phenotype was expressed in tissues derived from the three primary embryonic cell layers in embryos and neonates. Image analysis was conducted on cells of these birds to quantitate the size differences between macro- and micronucleoli (5 mu2 versus 1 mu2, respectively). Finally, these birds were studied with the technique of in situ hybridization, which showed that gene number differences between homologous NO chromosomes (i.e., heterozygosity for rRNA gene copy number), underlies the polymorphic-nucleoli phenotype. Thus, the chicken emerges as an experimental system through which heterozygosity for the rRNA gene copy number can be induced, easily identified, transmitted, and expressed in all somatic tissues.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1991

43. MHC haplotype involvement in avian resistance to an ectoparasite

Author

Bradley A. Mullens, Mary E. Delany, and Jeb P. Owen

Subjects

Genetics, Mite Infestations, Mites, biology, Genotype, Immunology, Haplotype, Congenic, Immunogenetics, Major histocompatibility complex, biology.organism_classification, Major Histocompatibility Complex, Immune system, Haplotypes, Genetic variation, biology.protein, Mite, Microsatellite, Animals, Female, Chickens, Poultry Diseases

Abstract

Research on immune function in evolutionary ecology has frequently focused on avian ectoparasites (e.g., mites and lice). However, host immunogenetics involved with bird resistance to ectoparasites has not been determined. The critical role of the major histocompatibility complex (MHC) in adaptive immunity and high genetic variation found within the MHC make this gene complex useful for exploring the immunogenetic basis for bird resistance to ectoparasites. The objective of this study was to determine if the avian MHC influenced resistance to a blood-feeding ectoparasite. Four congenic lines of chickens, differing only at the MHC, were comparatively infested with a cosmopolitan ectoparasite of birds—northern fowl mite (NFM)—which is also a serious pest species of poultry. Mite infestations were monitored over time and mite densities (weekly and maximum) were compared among lines. Chickens with the MHC haplotype B21 were relatively resistant to NFM, compared with birds in the B15 congenic line (P

Published

2008

44. Genome-wide assessment of worldwide chicken SNP genetic diversity indicates significant absence of rare alleles in commercial breeds

Author

Huanmin Zhang, William M. Muir, Sean MacEachern, Annemieke P Jungerius, Cindy Lawley, Jun Wang, Addie Vereijken, Martien A. M. Groenen, Ronald Okimoto, G. Albers, Hendrik-Jan Megens, Mary E. Delany, Gane Ka-Shu Wong, Richard P. M. A. Crooijmans, Yong Zhang, and Hans H. Cheng

Subjects

Conservation genetics, breeds, myostatin gene, population-structure, polymorphism, genetische diversiteit, Gene Frequency, single nucleotide polymorphism, pluimvee, biodiversity, Genetics, education.field_of_study, Genome, Multidisciplinary, animal production, poultry, dierveredeling, inteelt, animal breeding, genetic diversity, Biological Sciences, allelen, alleles, rassen (dieren), Inbreeding, Genotype, phenotype, growth, Population, inbreeding, selection, dierlijke productie, Biology, Animal Breeding and Genomics, Polymorphism, Single Nucleotide, Genetic variation, Animals, Fokkerij en Genomica, Genetic variability, education, Allele frequency, Genetic diversity, biodiversiteit, Genetic Variation, Genetic distance, genotyping, cattle, WIAS, mutation, Chickens, linkage disequilibrium

Abstract

Breed utilization, genetic improvement, and industry consolidation are predicted to have major impacts on the genetic composition of commercial chickens. Consequently, the question arises as to whether sufficient genetic diversity remains within industry stocks to address future needs. With the chicken genome sequence and more than 2.8 million single-nucleotide polymorphisms (SNPs), it is now possible to address biodiversity using a previously unattainable metric: missing alleles. To achieve this assessment, 2551 informative SNPs were genotyped on 2580 individuals, including 1440 commercial birds. The proportion of alleles lacking in commercial populations was assessed by ( 1 ) estimating the global SNP allele frequency distribution from a hypothetical ancestral population as a reference, then determining the portion of the distribution lost, and then ( 2 ) determining the relationship between allele loss and the inbreeding coefficient. The results indicate that 50% or more of the genetic diversity in ancestral breeds is absent in commercial pure lines. The missing genetic diversity resulted from the limited number of incorporated breeds. As such, hypothetically combining stocks within a company could recover only preexisting within-breed variability, but not more rare ancestral alleles. We establish that SNP weights act as sentinels of biodiversity and provide an objective assessment of the strains that are most valuable for preserving genetic diversity. This is the first experimental analysis investigating the extant genetic diversity of virtually an entire agricultural commodity. The methods presented are the first to characterize biodiversity in terms of allelic diversity and to objectively link rate of allele loss with the inbreeding coefficient.

Published

2008

45. Meiotic Models to Explain Classical Linkage, Pseudolinkage, and Chromosomal Pairing in Tetraploid Derivative Salmonid Genomes: II. Wright is Still Right

Author

Mary E. Delany and Bernie May

Subjects

Male, Linkage (software), Genetics, Biology, Genome, Chromosomal pairing, Evolution, Molecular, Polyploidy, Wright, Genetics, Population, Meiosis, Animals, Female, Pseudolinkage, Molecular Biology, Salmonidae, Genetics (clinical), Biotechnology

Published

2015

46. Complicated RNA splicing of chicken telomerase reverse transcriptase revealed by profiling cells both positive and negative for telomerase activity

Author

Hong Chang and Mary E. Delany

Subjects

Male, Telomerase, animal structures, RNA Splicing, Chick Embryo, Biology, Polymorphism, Single Nucleotide, Avian Proteins, Telomerase RNA component, Genetics, Animals, Humans, Telomerase reverse transcriptase, Cells, Cultured, DNA Primers, Models, Genetic, Gene Expression Profiling, Alternative splicing, Intron, General Medicine, Molecular biology, Exon skipping, Telomere, DNA-Binding Proteins, Codon, Nonsense, embryonic structures, RNA splicing, RNA Splice Sites, Chickens

Abstract

Telomerase reverse transcriptase (TERT) is an essential component of the telomerase ribonucleoprotein complex which maintains telomeres. The objective of this study was to investigate chicken TERT (cTERT) alternative RNA splicing profiles of samples varying for telomerase activity and immortalization parameters. These included systems both in vivo (gastrula embryo, embryo and adult liver) and in vitro (chicken embryo fibroblasts (CEFs) and DT40 cells). Nineteen cTERT variants were discovered, which were generated through exon skipping, intron retention, and alternative usage of splice donor and acceptor sites. Three variants were predicted to introduce in-frame mutations, whereas the others were predicted to have premature termination codons. The number of cTERT variants detected ranged from 10 in adult liver to 13 in CEFs. One variant (V4) was found in all samples and was predicted to generate a truncated protein lacking telomerase catalytic activity. Interestingly, the standard TERT expected from the full-length transcript was expressed not only in telomerase-positive, but also in telomerase-negative samples. The complicated expression profiles of cTERT in various cell systems suggest that sophisticated regulatory pathways are involved in cTERT pre-mRNA editing. Further, these results support the body of increasing evidence that alternative splicing of TERT, both in human and chicken, contributes to telomerase activity regulation.

Published

2006

47. Meiotic instability of chicken ultra-long telomeres and mapping of a 2.8 megabase array to the W-sex chromosome

Author

K. L. Rodrigue, Bernie May, Thomas R. Famula, and Mary E. Delany

Subjects

Genetics, Male, Sex Chromosomes, medicine.diagnostic_test, Chromosome, Biology, Telomere, Genome, W chromosome, Meiosis, Genetic variation, Microchromosome, medicine, Animals, Female, Chickens, In Situ Hybridization, Fluorescence, Fluorescence in situ hybridization

Abstract

The objective of this research was to study the meiotic stability of a subset of chicken telomere arrays, which are the largest reported for any vertebrate species. Inheritance of these ultra-long telomere arrays (200 kb to 3 mb) was studied in a highly homozygous inbred line, UCD 003 (For= 99.9). Analysis of array transmission in four families indicated unexpected heterogeneity and non-Mendelian segregation including high-frequency-generation of novel arrays. Additionally, the largest array detected (2.8 Mb) was female-specific and correlated to the most intense telomeric DNA signal on the W-sex chromosome by fluorescence in situ hybridization (FISH). These results are discussed in regard to the potential functions of the ultra-long telomere arrays in the chicken genome including generation of genetic variation through enhanced recombination, protection against erosion by providing a buffer for gene-dense regions, and sex-chromosome organization.

Published

2005

48. Second report on chicken genes and chromosomes 2005

Author

Marcus W. Feldman, Valerie Fillon, Darren K. Griffin, Alexander V. Rodionov, Mary E. Delany, Jacqueline Smith, Michael Schmid, Frédérique Pitel, Andrew H. Sinclair, Catharine A. Conley, Velia M. Fowler, M. Vignoles, Shigeki Mizuno, Thomas Haaf, Mireille Morisson, Steffen Weigend, Uri Lavi, Craig A. Smith, Richard P. M. A. Crooijmans, Martien A. M. Groenen, T. Twito, Joël Gellin, Svetlana Galkina, Roseline Godbout, Quanah J. Hudson, Shula Blum, N. A. Lukina, Holger Hoehn, Manfred Schartl, David W. Burt, Jossi Hillel, Lior David, A. Garrigues, Giora Ben-Ari, Julio S. Masabanda, Alain Vignal, Randolph B. Caldwell, I. Nanda, Sachin Katyal, Jean-Marie Buerstedde, S.B. Hedges, Hiroshi Arakawa, Laboratoire de Génétique Cellulaire (LGC), Institut National de la Recherche Agronomique (INRA)-Ecole Nationale Vétérinaire de Toulouse (ENVT), Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées, and ProdInra, Migration

Subjects

medicine.medical_specialty, Chickens/genetics, [SDV]Life Sciences [q-bio], Single-nucleotide polymorphism, Animal Breeding and Genomics, in-situ hybridization, Major histocompatibility complex, Chromosomes, 5S ribosomal RNA, Molecular genetics, single-nucleotide polymorphisms, MHC class I, Genetics, medicine, Animals, mhc class-i, translation initiation factor-4a, Fokkerij en Genomica, CYTOGENETIC MAPS, Molecular Biology, Gene, expressed sequence tags, Genetics (clinical), ComputingMilieux_MISCELLANEOUS, nucleolar-size polymorphisms, Expressed sequence tag, CHICKENS, Models, Genetic, biology, Chromosomes/genetics, dt40 cell-line, telomerase rna gene, major histocompatibility complex, Human genetics, [SDV] Life Sciences [q-bio], GENETIC MAPS, 5s ribosomal-rna, WIAS, biology.protein

Abstract

International audience

Published

2005

49. Karyotype stability of the DT40 chicken B cell line: macrochromosome variation and cytogenetic mosaicism

Author

Mary E. Delany and Hong Chang

Subjects

Genetics, medicine.medical_specialty, Monosomy, B-Lymphocytes, Mosaicism, Cytogenetics, Chromosome, Aneuploidy, Karyotype, Biology, medicine.disease, Human genetics, Cell Line, Chromosome 4, Chromosomal Instability, Karyotyping, Cytogenetic Analysis, medicine, Animals, Trisomy, Chickens, Metaphase

Abstract

The DT40 transformed chicken B-cell line is an important and widely used vertebrate cell line. Knowledge of the 'wild-type' DT40 karyotype is a significant consideration for most research applications and for extrapolation of results to normal cells. Here we present data indicating that (1) modal karyotype differences exist between DT40 cultures from different sources, (2) DT40 cultures are cytogenetically mosaic, and (3) the mosaic features can change over time with media conditions influencing the degree and type of non-modal karyotypes that emerge. In addition to the previously reported trisomy for chromosome 2, a monosomy for chromosome 4 and a variant 4p– are described. The macrochromosomal variation and mosaic nature of the DT40 system should alert researchers using this important cell line to consider whether such variation will impact experimental results and interpretation. The results are discussed in regard to current knowledge of cytogenetic anomalies associated with chicken cancers.

Published

2004

50. Molecular and cytogenetic organization of the 5S ribosomal DNA array in chicken (Gallus gallus)

Author

Laura M, Daniels and Mary E, Delany

Subjects

Gene Components, Base Sequence, Species Specificity, Tandem Repeat Sequences, Molecular Sequence Data, RNA, Ribosomal, 5S, Animals, Chromosome Mapping, Sequence Analysis, DNA, Chickens, In Situ Hybridization, Fluorescence, DNA Primers

Abstract

The 5S ribosomal (r) RNA genes encode a small (approximately 120-bp) highly-conserved component of the large ribosomal subunit. The objective of the present research was to study the molecular and cytogenetic organization of the chicken 5S rDNA. A predominant 2.2-kb gene (5Salpha) consisting of a coding and intergenic spacer (IGS) region was identified in ten research and commercial populations. A variant gene repeat of 0.6kb (5Sbeta) was observed in some of the populations. Genetic linkage analysis and cytogenetic localization by fluorescence in-situ hybridization assigned the 5S rDNA to chromosome 9. The 5S rDNA array was determined to be 80.2 +/- 7.0 kb upon electrophoretic sizing following EcoRV digestion. Sequence analysis of 5Salpha IGS regions revealed considerable conservation between chicken subspecies (98.4% identity) as well as homology with vertebrate Pol III promoter and regulatory sequence motifs. Minor intraindividual sequence variation within 1000 bp of IGS was observed in four cloned Red Jungle Fowl (Gallus gallus gallus) 5Salpha repeats (95.5% identity in this region). Sequence comparisons between IGS regions of 5Salpha and 5Sbeta genes indicated two short continuous (20bp) and many short non-continuous homologous regions as well as other conserved features such as promoter and termination motifs.

Published

2003