Your search keyword '"John C. Schimenti"' showing total 17 results

1. Chronic DNA Replication Stress Reduces Replicative Lifespan of Cells by TRP53-Dependent, microRNA-Assisted MCM2-7 Downregulation

Author

Marcus B. Smolka, Gongshi Bai, and John C. Schimenti

Subjects

0301 basic medicine, Genome instability, Senescence, DNA Replication, Cancer Research, Cell cycle checkpoint, lcsh:QH426-470, Biology, Genomic Instability, 03 medical and health sciences, Mice, Minichromosome maintenance, Downregulation and upregulation, Genetics, Animals, Humans, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Cell Proliferation, Minichromosome Maintenance Proteins, Cell growth, DNA replication, Gene Expression Regulation, Developmental, Transfection, Cell Cycle Checkpoints, Fibroblasts, Cell biology, MicroRNAs, lcsh:Genetics, 030104 developmental biology, Research Article

Abstract

Circumstances that compromise efficient DNA replication, such as disruptions to replication fork progression, cause a state known as DNA replication stress (RS). Whereas normally proliferating cells experience low levels of RS, excessive RS from intrinsic or extrinsic sources can trigger cell cycle arrest and senescence. Here, we report that a key driver of RS-induced senescence is active downregulation of the Minichromosome Maintenance 2–7 (MCM2-7) factors that are essential for replication origin licensing and which constitute the replicative helicase core. Proliferating cells produce high levels of MCM2-7 that enable formation of dormant origins that can be activated in response to acute, experimentally-induced RS. However, little is known about how physiological RS levels impact MCM2-7 regulation. We found that chronic exposure of primary mouse embryonic fibroblasts (MEFs) to either genetically-encoded or environmentally-induced RS triggered gradual MCM2-7 repression, followed by inhibition of replication and senescence that could be accelerated by MCM hemizygosity. The MCM2-7 reduction in response to RS is TRP53-dependent, and involves a group of Trp53-dependent miRNAs, including the miR-34 family, that repress MCM expression in replication-stressed cells before they undergo terminal cell cycle arrest. miR-34 ablation partially rescued MCM2-7 downregulation and genomic instability in mice with endogenous RS. Together, these data demonstrate that active MCM2-7 repression is a physiologically important mechanism for RS-induced cell cycle arrest and genome maintenance on an organismal level., Author Summary Duplication of the genome by DNA replication is essential for cell proliferation. DNA replication is initiated from many sites (“origins”) along chromosomes that are bound by replication licensing proteins, including MCM2-7. They are also core components of the replication helicase complex that unwinds double stranded DNA to expose single stranded DNA that is the template for DNA polymerase. Eukaryotic DNA replication machinery faces many challenges to duplicate the complex and massive genome. Circumstances that inhibit progression of the replication machinery cause “replication stress” (RS). Cells can counteract RS by utilizing “dormant” or “backup” origins. Abundant MCM2-7 expression sufficiently licenses dormant origins, but reducing MCMs compromises cellular responses to RS. We show that MCM2-7 expression is downregulated in cells experiencing chronic RS, and this depends on the TRP53 tumor suppressor and microRNAs it regulates. Extended RS eventually reduces MCMs to a point that terminal cell cycle arrest occurs. We propose that this mechanism is a crucial protection against neoplasia.

Published

2016

2. Correction: Mouse Pachytene Checkpoint 2 () Is Required for Completing Meiotic Recombination but Not Synapsis

Author

Xin Chenglin Li and John C Schimenti

Subjects

lcsh:Genetics, lcsh:QH426-470

Published

2007

3. Correction: Mouse Pachytene Checkpoint 2 (Trip13) Is Required for Completing Meiotic Recombination but Not Synapsis

Author

Xin Chenglin Li and John C. Schimenti

Subjects

Cancer Research, TRIP13, Synapsis, Correction, Genetics and Genomics, Pachytene checkpoint, Mus (Mouse), Biology, QH426-470, Cell biology, Genetics, Homologous recombination, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics

Abstract

doi:10.1371/journal.pgen.0030130 Correction for: Citation: Li X, Schimenti JC (2007) Mouse pachytene checkpoint 2 (Trip13) is required for completing meiotic recombination but not synapsis. PLoS Genet 3(8): e130. doi:10.1371/journal.pgen.0030130 Xin Chenglin Li's name was incorrectly listed as Xin Li. The correct citation is: Li XC, Schimenti JC (2007) Mouse pachytene checkpoint 2 (Trip13) is required for completing meiotic recombination but not synapsis. PLoS Genet 3(8): e130. doi:10.1371/journal.pgen.0030130

Published

2007

4. Hypersensitivity of Primordial Germ Cells to Compromised Replication-Associated DNA Repair Involves ATM-p53-p21 Signaling

Author

Naoko Shima, Yunhai Luo, Teresa L. Southard, Suzanne Hartford, John C. Schimenti, and Ruizhu Zeng

Subjects

DNA Replication, rho GTP-Binding Proteins, Genome instability, endocrine system, Cancer Research, lcsh:QH426-470, DNA Repair, DNA damage, DNA repair, Apoptosis, Ataxia Telangiectasia Mutated Proteins, Biology, medicine.disease_cause, Genomic Instability, Mice, Fanconi anemia, Genetics, medicine, Animals, Humans, FANCM, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Mutation, Hypogonadism, Organisms, DNA replication, Biology and Life Sciences, medicine.disease, Molecular biology, 3. Good health, Cell biology, lcsh:Genetics, Fanconi Anemia, Germ Cells, medicine.anatomical_structure, Tumor Suppressor Protein p53, Germ cell, Research Article, Developmental Biology, Signal Transduction

Abstract

Genome maintenance in germ cells is critical for fertility and the stable propagation of species. While mechanisms of meiotic DNA repair and chromosome behavior are well-characterized, the same is not true for primordial germ cells (PGCs), which arise and propagate during very early stages of mammalian development. Fanconi anemia (FA), a genomic instability syndrome that includes hypogonadism and testicular failure phenotypes, is caused by mutations in genes encoding a complex of proteins involved in repair of DNA lesions associated with DNA replication. The signaling mechanisms underlying hypogonadism and testicular failure in FA patients or mouse models are unknown. We conducted genetic studies to show that hypogonadism of Fancm mutant mice is a result of reduced proliferation, but not apoptosis, of PGCs, resulting in reduced germ cells in neonates of both sexes. Progressive loss of germ cells in adult males also occurs, overlaid with an elevated level of meiotic DNA damage. Genetic studies indicated that ATM-p53-p21 signaling is partially responsible for the germ cell deficiency., Author Summary The precursors to sperm and eggs begin are a group of

Published

2014

5. Phosphorylation of Chromosome Core Components May Serve as Axis Marks for the Status of Chromosomal Events during Mammalian Meiosis

Author

Christer Höög, John C. Schimenti, James M. A. Turner, Tomoyuki Fukuda, Florencia Pratto, and R. Daniel Camerini-Otero

Subjects

Male, Cancer Research, lcsh:QH426-470, Chromosomal Proteins, Non-Histone, Cell Cycle Proteins, Biology, Chromosomes, Chromosomal crossover, Chromosome segregation, Mice, Prophase, Meiosis, Spermatocytes, Chromosome Segregation, Molecular Cell Biology, Genetics, Homologous chromosome, Animals, Meiotic Prophase I, Phosphorylation, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Recombination, Genetic, Synaptonemal Complex, Synapsis, Nuclear Proteins, Phosphoproteins, Chromatin, DNA-Binding Proteins, Mice, Inbred C57BL, Chromosome Pairing, lcsh:Genetics, Synaptonemal complex, Chondroitin Sulfate Proteoglycans, Homologous recombination, Protein Processing, Post-Translational, Research Article

Abstract

Meiotic recombination and chromosome synapsis between homologous chromosomes are essential for proper chromosome segregation at the first meiotic division. While recombination and synapsis, as well as checkpoints that monitor these two events, take place in the context of a prophase I-specific axial chromosome structure, it remains unclear how chromosome axis components contribute to these processes. We show here that many protein components of the meiotic chromosome axis, including SYCP2, SYCP3, HORMAD1, HORMAD2, SMC3, STAG3, and REC8, become post-translationally modified by phosphorylation during the prophase I stage. We found that HORMAD1 and SMC3 are phosphorylated at a consensus site for the ATM/ATR checkpoint kinase and that the phosphorylated forms of HORMAD1 and SMC3 localize preferentially to unsynapsed chromosomal regions where synapsis has not yet occurred, but not to synapsed or desynapsed regions. We investigated the genetic requirements for the phosphorylation events and revealed that the phosphorylation levels of HORMAD1, HORMAD2, and SMC3 are dramatically reduced in the absence of initiation of meiotic recombination, whereas BRCA1 and SYCP3 are required for normal levels of phosphorylation of HORMAD1 and HORMAD2, but not of SMC3. Interestingly, reduced HORMAD1 and HORMAD2 phosphorylation is associated with impaired targeting of the MSUC (meiotic silencing of unsynapsed chromatin) machinery to unsynapsed chromosomes, suggesting that these post-translational events contribute to the regulation of the synapsis surveillance system. We propose that modifications of chromosome axis components serve as signals that facilitate chromosomal events including recombination, checkpoint control, transcription, and synapsis regulation., Author Summary Meiosis is a specialized cell division to generate haploid sperm and eggs. For accurate segregation of homologous chromosomes during the first meiotic division, chromosome synapsis and recombination should be properly established between them during the prophase I stage. Chromosome synapsis and recombination proceed in the context of the meiotic chromosome axis. While studies using knockout mouse models have revealed that chromosome axis components play roles in multiple chromosomal events during mammalian meiosis, it remains to be elucidated how they contribute to the processes. Here, we show that many mammalian meiotic chromosome axis proteins are phosphorylated in a spatially and temporally distinct manner during the prophase I stage. Especially, phosphorylation of HORMAD1 and SMC3 was observed preferentially in chromosomal regions where synapsis has not occurred. Moreover, phosphorylation of HORMAD1 and HORMAD2 was reduced in mutant testicular cells that were defective in recombination initiation or chromosome axis organization. Additionally, the mutant spermatocytes failed to correctly distribute checkpoint proteins that coordinate chromosome synapsis with gene expression and meiotic progression. Thus, it is suggested that phosphorylation of chromosome axis proteins serves as integrative axis marks for the status of events that take place on meiotic chromosomes.

Published

2012

6. Aneuploidy and Improved Growth Are Coincident but Not Causal in a Yeast Cancer Model

Author

Xin Chenglin Li, Bik Kwoon Tye, and John C. Schimenti

Subjects

G2 Phase, Saccharomyces cerevisiae Proteins, QH301-705.5, Saccharomyces cerevisiae, Aneuploidy, Cell Cycle Proteins, Chromosomal translocation, medicine.disease_cause, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Biology (General), Allele, Alleles, 030304 developmental biology, Genetics, 0303 health sciences, Mutation, General Immunology and Microbiology, biology, General Neuroscience, food and beverages, Cancer, Genetics and Genomics, Neoplasms, Experimental, medicine.disease, biology.organism_classification, Minichromosome Maintenance Complex Component 4, DNA-Binding Proteins, Genetics and Genomics/Disease Models, Oncology/Breast Cancer, 030220 oncology & carcinogenesis, Cancer cell, General Agricultural and Biological Sciences, Carcinogenesis, Cell Division, Research Article

Abstract

Aneuploidy is a hallmark of cancer cells and is assumed to play a causative role. This relationship is dissected in a yeast, with results that show that anueploidy can be removed, but cells maintain their proliferative advantage., Cancer cells have acquired mutations that alter their growth. Aneuploidy that typify cancer cells are often assumed to contribute to the abnormal growth characteristics. Here we test the idea of a link between aneuploidy and mutations allowing improved growth, using Saccharomyces cerevisiae containing a mcm4 helicase allele that was shown to cause cancer in mice. Yeast bearing this mcm4 allele are prone to undergoing a “hypermutable phase” characterized by a changing karyotype, ultimately yielding progeny with improved growth properties. When such progeny are returned to a normal karyotype by mating, their improved growth remains. Genetic analysis shows their improved growth is due to mutations in just a few loci. In sum, the effects of the mcm4 allele in mice are recapitulated in yeast, and the aneuploidy is not required to maintain improved growth., Author Summary Aneuploidy, an abnormality in chromosome number and structure, occurs commonly in cancers and has been suggested to be required to maintain accelerated cell proliferation. However, this hypothesis remains untested as it is not possible to selectively remove the acquired aneuploidy in cells that already have altered growth. Using a yeast model bearing mcm4Chaos3, an allele that causes mammary tumors in mice, these technical hurdles in animal cells can be overcome. We show that aneuploidy is not responsible for accelerated proliferation in yeast but mutations in just a few loci are. This study provides an excellent example of how a complex disease can be dissected in a simple model organism, and that the information extracted from yeast may be used to guide mammalian studies.

Published

2009

7. Mouse Pachytene Checkpoint 2 (Trip13) Is Required for Completing Meiotic Recombination but Not Synapsis

Author

Xin Chenglin Li and John C. Schimenti

Subjects

Male, Cancer Research, Spo11, Cell cycle checkpoint, DNA Repair, lcsh:QH426-470, Cell Cycle Proteins, Mice, Transgenic, Biology, Genetic recombination, Chromosomes, Chromosomal crossover, Mice, 03 medical and health sciences, 0302 clinical medicine, Meiosis, Spermatocytes, Genetics, Homologous chromosome, Animals, DNA Breaks, Double-Stranded, Molecular Biology, Phylogeny, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Adenosine Triphosphatases, Recombination, Genetic, 0303 health sciences, Ovary, 030302 biochemistry & molecular biology, Synapsis, Gene Expression Regulation, Developmental, Genetics and Genomics, Mus (Mouse), 3. Good health, Genes, cdc, Chromosome Pairing, lcsh:Genetics, Synaptonemal complex, Infertility, biology.protein, ATPases Associated with Diverse Cellular Activities, Female, Pachytene Stage, 030217 neurology & neurosurgery, Research Article

Abstract

In mammalian meiosis, homologous chromosome synapsis is coupled with recombination. As in most eukaryotes, mammalian meiocytes have checkpoints that monitor the fidelity of these processes. We report that the mouse ortholog (Trip13) of pachytene checkpoint 2 (PCH2), an essential component of the synapsis checkpoint in Saccharomyces cerevisiae and Caenorhabditis elegans, is required for completion of meiosis in both sexes. TRIP13-deficient mice exhibit spermatocyte death in pachynema and loss of oocytes around birth. The chromosomes of mutant spermatocytes synapse fully, yet retain several markers of recombination intermediates, including RAD51, BLM, and RPA. These chromosomes also exhibited the chiasmata markers MLH1 and MLH3, and okadaic acid treatment of mutant spermatocytes caused progression to metaphase I with bivalent chromosomes. Double mutant analysis demonstrated that the recombination and synapsis genes Spo11, Mei1, Rec8, and Dmc1 are all epistatic to Trip13, suggesting that TRIP13 does not have meiotic checkpoint function in mice. Our data indicate that TRIP13 is required after strand invasion for completing a subset of recombination events, but possibly not those destined to be crossovers. To our knowledge, this is the first model to separate recombination defects from asynapsis in mammalian meiosis, and provides the first evidence that unrepaired DNA damage alone can trigger the pachytene checkpoint response in mice., Author Summary It is critical that the chromosomes carried by sperm and eggs contain faithful representations of the genome of the individual that produced them. During the process of meiosis, the maternal and paternal copies of each chromosome “synapse” with each other (become tightly associated), exchange genetic material via the process of recombination, then separate into daughter cells in the first of two meiotic cell divisions. The intricate chromosome behavior is subject to errors, so most organisms have evolved meiotic “checkpoints” that monitor fidelity of chromosome synapsis and repair of DNA damage. These checkpoints cause defective cells to self destruct rather than generate defective sperm or eggs. We studied the effects of deleting mouse Trip13, a gene that in distant organisms plays a key role in meiotic checkpoint control. These experiments revealed that instead of having a checkpoint role, Trip13 is required for one of the two major classes of recombination in meiosis that is required for repairing broken DNA molecules. The chromosomes still synapsed normally, but animals were sterile due to massive death of oocytes and spermatocytes. These results indicate that, in addition to a checkpoint that responds to failed synapsis, one exists to specifically detect unrepaired DNA damage that is due to failed recombination.

Published

2007

8. Mutation in Mouse Hei10, an E3 Ubiquitin Ligase, Disrupts Meiotic Crossing-over

Author

Jeremy O Ward, Laura G Reinholdt, William W Motley, Lisa M Niswander, Dekker C Deacon, Laurie Beth Griffin, Kristofor Langlais, Vickie L Backus, Kerry Schimenti, Marilyn J O'Brien, John J Eppig, and John C. Schimenti

Subjects

Cancer Research, Genetics, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics

Published

2005

9. A novel function for CDK2 activity at meiotic crossover sites.

Author

Nathan Palmer, S Zakiah A Talib, Priti Singh, Christine M F Goh, Kui Liu, John C Schimenti, and Philipp Kaldis

Subjects

Biology (General), QH301-705.5

Abstract

Genetic diversity in offspring is induced by meiotic recombination, which is initiated between homologs at >200 sites originating from meiotic double-strand breaks (DSBs). Of this initial pool, only 1-2 DSBs per homolog pair will be designated to form meiotic crossovers (COs), where reciprocal genetic exchange occurs between parental chromosomes. Cyclin-dependent kinase 2 (CDK2) is known to localize to so-called "late recombination nodules" (LRNs) marking incipient CO sites. However, the role of CDK2 kinase activity in the process of CO formation remains uncertain. Here, we describe the phenotype of 2 Cdk2 point mutants with elevated or decreased activity, respectively. Elevated CDK2 activity was associated with increased numbers of LRN-associated proteins, including CDK2 itself and the MutL homolog 1 (MLH1) component of the MutLγ complex, but did not lead to increased numbers of COs. In contrast, reduced CDK2 activity leads to the complete absence of CO formation during meiotic prophase I. Our data suggest an important role for CDK2 in regulating MLH1 focus numbers and that the activity of this kinase is a key regulatory factor in the formation of meiotic COs.

Published

2020

10. Chronic DNA Replication Stress Reduces Replicative Lifespan of Cells by TRP53-Dependent, microRNA-Assisted MCM2-7 Downregulation.

Author

Gongshi Bai, Marcus B Smolka, and John C Schimenti

Subjects

Genetics, QH426-470

Abstract

Circumstances that compromise efficient DNA replication, such as disruptions to replication fork progression, cause a state known as DNA replication stress (RS). Whereas normally proliferating cells experience low levels of RS, excessive RS from intrinsic or extrinsic sources can trigger cell cycle arrest and senescence. Here, we report that a key driver of RS-induced senescence is active downregulation of the Minichromosome Maintenance 2-7 (MCM2-7) factors that are essential for replication origin licensing and which constitute the replicative helicase core. Proliferating cells produce high levels of MCM2-7 that enable formation of dormant origins that can be activated in response to acute, experimentally-induced RS. However, little is known about how physiological RS levels impact MCM2-7 regulation. We found that chronic exposure of primary mouse embryonic fibroblasts (MEFs) to either genetically-encoded or environmentally-induced RS triggered gradual MCM2-7 repression, followed by inhibition of replication and senescence that could be accelerated by MCM hemizygosity. The MCM2-7 reduction in response to RS is TRP53-dependent, and involves a group of Trp53-dependent miRNAs, including the miR-34 family, that repress MCM expression in replication-stressed cells before they undergo terminal cell cycle arrest. miR-34 ablation partially rescued MCM2-7 downregulation and genomic instability in mice with endogenous RS. Together, these data demonstrate that active MCM2-7 repression is a physiologically important mechanism for RS-induced cell cycle arrest and genome maintenance on an organismal level.

Published

2016

11. Hypersensitivity of primordial germ cells to compromised replication-associated DNA repair involves ATM-p53-p21 signaling.

Author

Yunhai Luo, Suzanne A Hartford, Ruizhu Zeng, Teresa L Southard, Naoko Shima, and John C Schimenti

Subjects

Genetics, QH426-470

Abstract

Genome maintenance in germ cells is critical for fertility and the stable propagation of species. While mechanisms of meiotic DNA repair and chromosome behavior are well-characterized, the same is not true for primordial germ cells (PGCs), which arise and propagate during very early stages of mammalian development. Fanconi anemia (FA), a genomic instability syndrome that includes hypogonadism and testicular failure phenotypes, is caused by mutations in genes encoding a complex of proteins involved in repair of DNA lesions associated with DNA replication. The signaling mechanisms underlying hypogonadism and testicular failure in FA patients or mouse models are unknown. We conducted genetic studies to show that hypogonadism of Fancm mutant mice is a result of reduced proliferation, but not apoptosis, of PGCs, resulting in reduced germ cells in neonates of both sexes. Progressive loss of germ cells in adult males also occurs, overlaid with an elevated level of meiotic DNA damage. Genetic studies indicated that ATM-p53-p21 signaling is partially responsible for the germ cell deficiency.

Published

2014

12. Phosphorylation of chromosome core components may serve as axis marks for the status of chromosomal events during mammalian meiosis.

Author

Tomoyuki Fukuda, Florencia Pratto, John C Schimenti, James M A Turner, R Daniel Camerini-Otero, and Christer Höög

Subjects

Genetics, QH426-470

Abstract

Meiotic recombination and chromosome synapsis between homologous chromosomes are essential for proper chromosome segregation at the first meiotic division. While recombination and synapsis, as well as checkpoints that monitor these two events, take place in the context of a prophase I-specific axial chromosome structure, it remains unclear how chromosome axis components contribute to these processes. We show here that many protein components of the meiotic chromosome axis, including SYCP2, SYCP3, HORMAD1, HORMAD2, SMC3, STAG3, and REC8, become post-translationally modified by phosphorylation during the prophase I stage. We found that HORMAD1 and SMC3 are phosphorylated at a consensus site for the ATM/ATR checkpoint kinase and that the phosphorylated forms of HORMAD1 and SMC3 localize preferentially to unsynapsed chromosomal regions where synapsis has not yet occurred, but not to synapsed or desynapsed regions. We investigated the genetic requirements for the phosphorylation events and revealed that the phosphorylation levels of HORMAD1, HORMAD2, and SMC3 are dramatically reduced in the absence of initiation of meiotic recombination, whereas BRCA1 and SYCP3 are required for normal levels of phosphorylation of HORMAD1 and HORMAD2, but not of SMC3. Interestingly, reduced HORMAD1 and HORMAD2 phosphorylation is associated with impaired targeting of the MSUC (meiotic silencing of unsynapsed chromatin) machinery to unsynapsed chromosomes, suggesting that these post-translational events contribute to the regulation of the synapsis surveillance system. We propose that modifications of chromosome axis components serve as signals that facilitate chromosomal events including recombination, checkpoint control, transcription, and synapsis regulation.

Published

2012

13. Tissue-specific functional networks for prioritizing phenotype and disease genes.

Author

Yuanfang Guan, Dmitriy Gorenshteyn, Margit Burmeister, Aaron K Wong, John C Schimenti, Mary Ann Handel, Carol J Bult, Matthew A Hibbs, and Olga G Troyanskaya

Subjects

Biology (General), QH301-705.5

Abstract

Integrated analyses of functional genomics data have enormous potential for identifying phenotype-associated genes. Tissue-specificity is an important aspect of many genetic diseases, reflecting the potentially different roles of proteins and pathways in diverse cell lineages. Accounting for tissue specificity in global integration of functional genomics data is challenging, as "functionality" and "functional relationships" are often not resolved for specific tissue types. We address this challenge by generating tissue-specific functional networks, which can effectively represent the diversity of protein function for more accurate identification of phenotype-associated genes in the laboratory mouse. Specifically, we created 107 tissue-specific functional relationship networks through integration of genomic data utilizing knowledge of tissue-specific gene expression patterns. Cross-network comparison revealed significantly changed genes enriched for functions related to specific tissue development. We then utilized these tissue-specific networks to predict genes associated with different phenotypes. Our results demonstrate that prediction performance is significantly improved through using the tissue-specific networks as compared to the global functional network. We used a testis-specific functional relationship network to predict genes associated with male fertility and spermatogenesis phenotypes, and experimentally confirmed one top prediction, Mbyl1. We then focused on a less-common genetic disease, ataxia, and identified candidates uniquely predicted by the cerebellum network, which are supported by both literature and experimental evidence. Our systems-level, tissue-specific scheme advances over traditional global integration and analyses and establishes a prototype to address the tissue-specific effects of genetic perturbations, diseases and drugs.

Published

2012

14. Interallelic and intergenic incompatibilities of the Prdm9 (Hst1) gene in mouse hybrid sterility.

Author

Petr Flachs, Ondřej Mihola, Petr Simeček, Soňa Gregorová, John C Schimenti, Yasuhisa Matsui, Frédéric Baudat, Bernard de Massy, Jaroslav Piálek, Jiří Forejt, and Zdenek Trachtulec

Subjects

Genetics, QH426-470

Abstract

The Dobzhansky-Muller model of incompatibilities explains reproductive isolation between species by incorrect epistatic interactions. Although the mechanisms of speciation are of great interest, no incompatibility has been characterized at the gene level in mammals. The Hybrid sterility 1 gene (Hst1) participates in the arrest of meiosis in F(1) males of certain strains from two Mus musculus subspecies, e.g., PWD from M. m. musculus and C57BL/6J (henceforth B6) from M. m. domesticus. Hst1 has been identified as a meiotic PR-domain gene (Prdm9) encoding histone 3 methyltransferase in the male offspring of PWD females and B6 males, (PWD×B6)F(1). To characterize the incompatibilities underlying hybrid sterility, we phenotyped reproductive and meiotic markers in males with altered copy numbers of Prdm9. A partial rescue of fertility was observed upon removal of the B6 allele of Prdm9 from the azoospermic (PWD×B6)F(1) hybrids, whereas removing one of the two Prdm9 copies in PWD or B6 background had no effect on male reproduction. Incompatibility(ies) not involving Prdm9(B6) also acts in the (PWD×B6)F(1) hybrids, since the correction of hybrid sterility by Prdm9(B6) deletion was not complete. Additions and subtractions of Prdm9 copies, as well as allelic replacements, improved meiotic progression and fecundity also in the progeny-producing reciprocal (B6×PWD)F(1) males. Moreover, an increased dosage of Prdm9 and reciprocal cross enhanced fertility of other sperm-carrying male hybrids, (PWD×B6-C3H.Prdm9)F(1), harboring another Prdm9 allele of M. m. domesticus origin. The levels of Prdm9 mRNA isoforms were similar in the prepubertal testes of all types of F(1) hybrids of PWD with B6 and B6-C3H.Prdm9 despite their different prospective fertility, but decreased to 53% after removal of Prdm9(B6). Therefore, the Prdm9(B6) allele probably takes part in posttranscriptional dominant-negative hybrid interaction(s) absent in the parental strains.

Published

2012

15. Incremental genetic perturbations to MCM2-7 expression and subcellular distribution reveal exquisite sensitivity of mice to DNA replication stress.

Author

Chen-Hua Chuang, Marsha D Wallace, Christian Abratte, Teresa Southard, and John C Schimenti

Subjects

Genetics, QH426-470

Abstract

Mutations causing replication stress can lead to genomic instability (GIN). In vitro studies have shown that drastic depletion of the MCM2-7 DNA replication licensing factors, which form the replicative helicase, can cause GIN and cell proliferation defects that are exacerbated under conditions of replication stress. To explore the effects of incrementally attenuated replication licensing in whole animals, we generated and analyzed the phenotypes of mice that were hemizygous for Mcm2, 3, 4, 6, and 7 null alleles, combinations thereof, and also in conjunction with the hypomorphic Mcm4(Chaos3) cancer susceptibility allele. Mcm4(Chaos3/Chaos3) embryonic fibroblasts have ∼40% reduction in all MCM proteins, coincident with reduced Mcm2-7 mRNA. Further genetic reductions of Mcm2, 6, or 7 in this background caused various phenotypes including synthetic lethality, growth retardation, decreased cellular proliferation, GIN, and early onset cancer. Remarkably, heterozygosity for Mcm3 rescued many of these defects. Consistent with a role in MCM nuclear export possessed by the yeast Mcm3 ortholog, the phenotypic rescues correlated with increased chromatin-bound MCMs, and also higher levels of nuclear MCM2 during S phase. The genetic, molecular and phenotypic data demonstrate that relatively minor quantitative alterations of MCM expression, homeostasis or subcellular distribution can have diverse and serious consequences upon development and confer cancer susceptibility. The results support the notion that the normally high levels of MCMs in cells are needed not only for activating the basal set of replication origins, but also "backup" origins that are recruited in times of replication stress to ensure complete replication of the genome.

Published

2010

16. Mutation in mouse hei10, an e3 ubiquitin ligase, disrupts meiotic crossing over.

Author

Jeremy O Ward, Laura G Reinholdt, William W Motley, Lisa M Niswander, Dekker C Deacon, Laurie B Griffin, Kristofor K Langlais, Vickie L Backus, Kerry J Schimenti, Marilyn J O'Brien, John J Eppig, and John C Schimenti

Subjects

Genetics, QH426-470

Abstract

Crossing over during meiotic prophase I is required for sexual reproduction in mice and contributes to genome-wide genetic diversity. Here we report on the characterization of an N-ethyl-N-nitrosourea-induced, recessive allele called mei4, which causes sterility in both sexes owing to meiotic defects. In mutant spermatocytes, chromosomes fail to congress properly at the metaphase plate, leading to arrest and apoptosis before the first meiotic division. Mutant oocytes have a similar chromosomal phenotype but in vitro can undergo meiotic divisions and fertilization before arresting. During late meiotic prophase in mei4 mutant males, absence of cyclin dependent kinase 2 and mismatch repair protein association from chromosome cores is correlated with the premature separation of bivalents at diplonema owing to lack of chiasmata. We have identified the causative mutation, a transversion in the 5' splice donor site of exon 1 in the mouse ortholog of Human Enhancer of Invasion 10 (Hei10; also known as Gm288 in mouse and CCNB1IP1 in human), a putative B-type cyclin E3 ubiquitin ligase. Importantly, orthologs of Hei10 are found exclusively in deuterostomes and not in more ancestral protostomes such as yeast, worms, or flies. The cloning and characterization of the mei4 allele of Hei10 demonstrates a novel link between cell cycle regulation and mismatch repair during prophase I.

Published

2007

17. A dominant, recombination-defective allele of Dmc1 causing male-specific sterility.

Author

Laura A Bannister, Roberto J Pezza, Janet R Donaldson, Dirk G de Rooij, Kerry J Schimenti, R Daniel Camerini-Otero, and John C Schimenti

Subjects

Biology (General), QH301-705.5

Abstract

DMC1 is a meiosis-specific homolog of bacterial RecA and eukaryotic RAD51 that can catalyze homologous DNA strand invasion and D-loop formation in vitro. DMC1-deficient mice and yeast are sterile due to defective meiotic recombination and chromosome synapsis. The authors identified a male dominant sterile allele of Dmc1, Dmc1(Mei11), encoding a missense mutation in the L2 DNA binding domain that abolishes strand invasion activity. Meiosis in male heterozygotes arrests in pachynema, characterized by incomplete chromosome synapsis and no crossing-over. Young heterozygous females have normal litter sizes despite having a decreased oocyte pool, a high incidence of meiosis I abnormalities, and susceptibility to premature ovarian failure. Dmc1(Mei11) exposes a sex difference in recombination in that a significant portion of female oocytes can compensate for DMC1 deficiency to undergo crossing-over and complete gametogenesis. Importantly, these data demonstrate that dominant alleles of meiosis genes can arise and propagate in populations, causing infertility and other reproductive consequences due to meiotic prophase I defects.

Published

2007