Your search keyword '"Chicken Special/Letters"' showing total 7 results

1. Comparison of splice sites in mammals and chicken

Author

Robert Castelo, Roderic Guigó, and Josep F. Abril

Subjects

Rodent, Gene Conversion, Pollastres, Mice, biology.animal, Regulació genètica, Genetics, Animals, Humans, splice, Genetics (clinical), Mammals, Splice site mutation, Base Sequence, biology, Genètica animal, Mutació (Biologia), ARN empalmament, Intron, Mutation (Biology), Ribonucleoprotein, U2 Small Nuclear, Ribonucleoproteins, Small Nuclear, Introns, Rats, Homogeneous, RNA Splice Sites, Animal genetics, Chicken Special/Letters, Chickens, Mamífers

Abstract

We have carried out an initial analysis of the dynamics of the recent evolution of the splice-sites sequences on a large collection of human, rodent (mouse and rat), and chicken introns. Our results indicate that the sequences of splice sites are largely homogeneous within tetrapoda. We have also found that orthologous splice signals between human and rodents and within rodents are more conserved than unrelated splice sites, but the additional conservation can be explained mostly by background intron conservation. In contrast, additional conservation over background is detectable in orthologous mammalian and chicken splice sites. Our results also indicate that the U2 and U12 intron classes seem to have evolved independently since the split of mammals and birds; we have not been able to find a convincing case of interconversion between these two classes in our collections of orthologous introns. Similarly, we have not found a single case of switching between AT-AC and GT-AG subtypes within U12 introns, suggesting that this event has been a rare occurrence in recent evolutionary times. Switching between GT-AG and the noncanonical GC-AG U2 subtypes, on the contrary, does not appear to be unusual; in particular, T to C mutations appear to be relatively well tolerated in GT-AG introns with very strong donor sites.

Published

2004

2. Evolution and functional classification of vertebrate gene deserts

Author

Lisa Stubbs, Ivan Ovcharenko, Webb Miller, Ross C. Hardison, Gabriela G. Loots, and Marcelo A. Nobrega

Subjects

complex mixtures, Evolution, Molecular, Mice, chemistry.chemical_compound, Untranslated Regions, biology.animal, Genetics, Transcriptional regulation, Animals, Humans, Stable gene, Gene, Transcription factor, Conserved Sequence, Genetics (clinical), Short Interspersed Nucleotide Elements, Genes, Essential, Genome, biology, Genome, Human, DNA Sequence, Unstable, Gene Amplification, Vertebrate, Genes, chemistry, Human genome, Chicken Special/Letters, Chickens, Neutral theory of molecular evolution, DNA

Abstract

Large tracts of the human genome, known as gene deserts, are devoid of protein-coding genes. Dichotomy in their level of conservation with chicken separates these regions into two distinct categories, stable and variable. The separation is not caused by differences in rates of neutral evolution but instead appears to be related to different biological functions of stable and variable gene deserts in the human genome. Gene Ontology categories of the adjacent genes are strongly biased toward transcriptional regulation and development for the stable gene deserts, and toward distinctively different functions for the variable gene deserts. Stable gene deserts resist chromosomal rearrangements and appear to harbor multiple distant regulatory elements physically linked to their neighboring genes, with the linearity of conservation invariant throughout vertebrate evolution.

Published

2004

3. Structural and functional analysis of a 0.5-Mb chicken region orthologous to the imprinted mammalianAscl2/Mash2–Igf2–H19region

Author

Yoshiyuki Sakaki, Masahira Hattori, Atsushi Toyoda, Yoh Ichi Matsuda, Hiroyuki Sasaki, Masaoki Tsudzuki, Hisao Shirohzu, Takaaki Yokomine, Hisakazu Iwama, Kazuho Ikeo, Tetsuya Hori, Wahyu Purbowasito, and Shigeki Mizuno

Subjects

Genetic Markers, Ribosomal Proteins, Chromosomes, Artificial, Bacterial, RNA, Untranslated, animal structures, Sequence analysis, Molecular Sequence Data, Chick Embryo, Regulatory Sequences, Nucleic Acid, Biology, Tetraspanin 28, Mitochondrial Proteins, Genomic Imprinting, Mice, Tandem repeat, Antigens, CD, Insulin-Like Growth Factor II, Sequence Homology, Nucleic Acid, Genetics, Animals, Humans, Amino Acid Sequence, Imprinting (psychology), Gene, Genetics (clinical), Base Sequence, Chromosome Mapping, Membrane Proteins, Sequence Analysis, DNA, DNA Methylation, CpG site, Tandem Repeat Sequences, Regulatory sequence, embryonic structures, DNA methylation, CpG Islands, Chicken Special/Letters, Genomic imprinting

Abstract

Previous studies revealed thatIgf2andMpr/Igf2rare imprinted in eutherian mammals and marsupials but not in monotremes or birds.Igf2lies in a large imprinted cluster in eutherians, and its imprinting is regulated by long-range mechanisms. As a step to understand how the imprinted cluster evolved, we have determined a 490-kb chicken sequence containing the orthologs of mammalianAscl2/Mash2, Ins2andIgf2. We found that most of the genes in this region are conserved between chickens and mammals, maintaining the same transcriptional polarities and exon–intron structures. However,H19, an imprinted noncoding transcript, was absent from the chicken sequence. ChickenASCL2/CASH4andINS, the orthologs of the imprinted mammalian genes, showed biallelic expression, further supporting the notion that imprinting evolved after the divergence of mammals and birds. TheH19imprinting center and many of the local regulatory elements identified in mammals were not found in chickens. Also, a large segment of tandem repeats and retroelements identified between the two imprinted subdomains in mice was not found in chickens. Our findings show that the imprinted genes were clustered before the emergence of imprinting and that the elements associated with imprinting probably evolved after the divergence of mammals and birds.

Published

2004

4. Comparative architectures of mammalian and chicken genomes reveal highly variable rates of genomic rearrangements across different lineages

Author

Evgeny M. Zdobnov, Guillaume Bourque, Pavel A. Pevzner, Peer Bork, and Glenn Tesler

Subjects

Chickens/genetics, Synteny/genetics, Lineage (evolution), Biology, Synteny, Genome, Chromosomes, Evolution, Molecular, Mice, Molecular evolution, Gene orders, Genetics, Chromosomes, Human, Animals, Humans, Genes/genetics, Gene, Genetics (clinical), Gene Rearrangement, Whole genome sequencing, Chromosomes/genetics, Genetic Variation, Chromosomes, Human/genetics, Gene rearrangement, Gene Rearrangement/genetics, Rats, Genes, Genetic Variation/genetics, Human genome, Chicken Special/Letters, Chickens

Abstract

Molecular evolution studies are usually based on the analysis of individual genes and thus reflect only small-range variations in genomic sequences. A complementary approach is to study the evolutionary history of rearrangements in entire genomes based on the analysis of gene orders. The progress in whole genome sequencing provides an unprecedented level of detailed sequence data to infer genome rearrangements through comparative approaches. The comparative analysis of recently sequenced rodent genomes with the human genome revealed evidence for a larger number of rearrangements than previously thought and led to the reconstruction of the putative genomic architecture of the murid rodent ancestor, while the architecture of the ancestral mammalian genome and the rate of rearrangements in the human lineage remained unknown. Sequencing the chicken genome provides an opportunity to reconstruct the architecture of the ancestral mammalian genome by using chicken as an outgroup. Our analysis reveals a very low rate of rearrangements and, in particular, interchromosomal rearrangements in chicken, in the early mammalian ancestor, or in both. The suggested number of interchromosomal rearrangements between the mammalian ancestor and chicken, during an estimated 500 million years of evolution, only slightly exceeds the number of interchromosomal rearrangements that happened in the mouse lineage, over the course of about 87 million years.

Published

2005

5. Comparison of the chicken and turkey genomes reveals a higher rate of nucleotide divergence on microchromosomes than macrochromosomes

Author

David W. Burt, Matthew T. Webster, Hans Ellegren, Erik Axelsson, and Nick G.C. Smith

Subjects

Genetics, Recombination, Genetic, Base Composition, Turkeys, Genome, Nucleotides, Molecular Sequence Data, Intron, Chromosome, Genetic Variation, Biology, Chromosomes, Evolution, Molecular, Mutagenesis, Gene density, Microchromosome, Animals, Chicken Special/Letters, Synonymous substitution, Gene, Chickens, Genetics (clinical), GC-content

Abstract

A distinctive feature of the avian genome is the large heterogeneity in the size of chromosomes, which are usually classified into a small number of macrochromosomes and numerous microchromosomes. These chromosome classes show characteristic differences in a number of interrelated features that could potentially affect the rate of sequence evolution, such as GC content, gene density, and recombination rate. We studied the effects of these factors by analyzing patterns of nucleotide substitution in two sets of chicken-turkey sequence alignments. First, in a set of 67 orthologous introns, divergence was significantly higher in microchromosomes (chromosomes 11-38; 11.7% divergence) than in both macrochromosomes (chromosomes 1-5; 9.9% divergence; P = 0.016) and intermediate-sized chromosomes (chromosomes 6-10; 9.5% divergence; P = 0.026). At least part of this difference was due to the higher incidence of CpG sites on microchromosomes. Second, using 155 orthologous coding sequences we noted a similar pattern, in which synonymous substitution rates on microchromosomes (13.1%) were significantly higher than were rates on macrochromosomes (10.3%; P = 0.024). Broadly assuming neutrality of introns and synonymous sites, or constraints on such sequences do not differ between chromosomal classes, these observations imply that microchromosomal genes are exposed to more germ line mutations than those on other chromosomes. We also find that dN/dS ratios for genes located on microchromosomes (average, 0.094) are significantly lower than those of macrochromosomes (average, 0.185; P = 0.025), suggesting that the proteins of genes on microchromosomes are under greater evolutionary constraint.

Published

2005

6. Evolution of the Beckwith-Wiedemann syndrome region in vertebrates

Author

Martina Paulsen, Christopher Burgard, Sascha Tierling, Tarang Khare, and Jörn Walter

Subjects

Armadillos, Beckwith-Wiedemann Syndrome, Biology, Takifugu, Conserved sequence, Birds, Evolution, Molecular, Genomic Imprinting, Mice, Species Specificity, biology.animal, Chiroptera, Gene Duplication, Sequence Homology, Nucleic Acid, Genetics, Animals, Humans, Epigenetics, Imprinting (psychology), Genetics (clinical), Conserved Sequence, Zebrafish, Synteny, Repetitive Sequences, Nucleic Acid, Mammals, Base Composition, Fugu, fungi, Fishes, Vertebrate, biology.organism_classification, Cattle, CpG Islands, Chicken Special/Letters, Genomic imprinting, Chickens

Abstract

In the animal kingdom, genomic imprinting appears to be restricted to mammals. It remains an open question how structural features for imprinting evolved in mammalian genomes. The clustering of genes around imprinting control centers (ICs) is regarded as a hallmark for the coordinated imprinted regulation. Hence imprinted clusters might be structurally distinct between mammals and nonimprinted vertebrates. To address this question we compared the organization of the Beckwith Wiedemann syndrome (BWS) gene cluster in mammals, chicken, Fugu (pufferfish), and zebrafish. Our analysis shows that gene synteny is apparently well conserved between mammals and birds, and is detectable but less pronounced in fish. Hence, clustering apparently evolved during vertebrate radiation and involved two major duplication events that took place before the separation of the fish and mammalian lineages. A cross-species analysis of imprinting center regions showed that some structural features can already be recognized in nonimprinted amniotes in one of the imprinting centers (IC2). In contrast, the imprinting center IC1 is absent in chicken. This suggests a progressive and stepwise evolution of imprinting control elements. In line with that, imprinting centers in mammals apparently exhibit a high degree of structural and sequence variation despite conserved epigenetic marking.

Published

2004

7. The repetitive landscape of the chicken genome

Author

Robert Ivarie, Jon S. Robertson, Jason A. Morrison, F. Alex Feltus, Vincent Magrini, Stefan R. Schulze, Thomas Wicker, Andrew H. Paterson, Daniel G. Peterson, Elaine R. Mardis, and Richard K. Wilson

Subjects

Genetics, Genome evolution, Genome, Retroelements, Genetic Vectors, Terminal Repeat Sequences, Sequence assembly, Hybrid genome assembly, Genome project, Computational biology, Biology, Evolution, Molecular, Cot analysis, DNA Transposable Elements, Direct repeat, Animals, Chicken Special/Letters, Chickens, Genetics (clinical), Reference genome, Gene Library, Repetitive Sequences, Nucleic Acid

Abstract

Cot-based cloning and sequencing (CBCS) is a powerful tool for isolating and characterizing the various repetitive components of any genome, combining the established principles of DNA reassociation kinetics with high-throughput sequencing. CBCS was used to generate sequence libraries representing the high, middle, and low-copy fractions of the chicken genome. Sequencing high-copy DNA of chicken to about 2.7× coverage of its estimated sequence complexity led to the initial identification of several new repeat families, which were then used for a survey of the newly released first draft of the complete chicken genome. The analysis provided insight into the diversity and biology of known repeat structures such as CR1 and CNM, for which only limited sequence data had previously been available. Cot sequence data also resulted in the identification of four novel repeats (Birddawg, Hitchcock, Kronos, and Soprano), two new subfamilies of CR1 repeats, and many elements absent from the chicken genome assembly. Multiple autonomous elements were found for a novel Mariner-like transposon, Galluhop, in addition to nonautonomous deletion derivatives. Phylogenetic analysis of the high-copy repeats CR1, Galluhop, and Birddawg provided insight into two distinct genome dispersion strategies. This study also exemplifies the power of the CBCS method to create representative databases for the repetitive fractions of genomes for which only limited sequence data is available.

Published

2004