Your search keyword '"de Villena, Fernando Pardo-Manuel"' showing total 21 results

1. The mutant mouse resource and research center (MMRRC) consortium: the US-based public mouse repository system

Author

Agca, Yuksel, Amos-Landgraf, James, Araiza, Renee, Brennan, Jennifer, Carlson, Charisse, Ciavatta, Dominic, Clary, Dave, Franklin, Craig, Korf, Ian, Lutz, Cathleen, Magnuson, Terry, de Villena, Fernando Pardo-Manuel, Mirochnitchenko, Oleg, Patel, Samit, Port, Dan, Reinholdt, Laura, and Lloyd, K. C. Kent

Published

2024

2. Genetic Background Shapes Phenotypic Response to Diet for Adiposity in the Collaborative Cross

Author

Yam, Phoebe, Albright, Jody, VerHague, Melissa, Gertz, Erik R, de Villena, Fernando Pardo-Manuel, and Bennett, Brian J

Subjects

Biological Sciences, Genetics, Biotechnology, Obesity, Prevention, Nutrition, Aetiology, 2.1 Biological and endogenous factors, Metabolic and endocrine, Stroke, Oral and gastrointestinal, Cancer, Cardiovascular, collaborative cross, diet, nutrigenomics and nutrigenetics, genetics, obesity, Clinical Sciences, Law

Abstract

Defined as chronic excessive accumulation of adiposity, obesity results from long-term imbalance between energy intake and expenditure. The mechanisms behind how caloric imbalance occurs are complex and influenced by numerous biological and environmental factors, especially genetics, and diet. Population-based diet recommendations have had limited success partly due to the wide variation in physiological responses across individuals when they consume the same diet. Thus, it is necessary to broaden our understanding of how individual genetics and diet interact relative to the development of obesity for improving weight loss treatment. To determine how consumption of diets with different macronutrient composition alter adiposity and other obesity-related traits in a genetically diverse population, we analyzed body composition, metabolic rate, clinical blood chemistries, and circulating metabolites in 22 strains of mice from the Collaborative Cross (CC), a highly diverse recombinant inbred mouse population, before and after 8 weeks of feeding either a high protein or high fat high sucrose diet. At both baseline and post-diet, adiposity and other obesity-related traits exhibited a broad range of phenotypic variation based on CC strain; diet-induced changes in adiposity and other traits also depended largely on CC strain. In addition to estimating heritability at baseline, we also quantified the effect size of diet for each trait, which varied by trait and experimental diet. Our findings identified CC strains prone to developing obesity, demonstrate the genotypic and phenotypic diversity of the CC for studying complex traits, and highlight the importance of accounting for genetic differences when making dietary recommendations.

Published

2021

3. Content and Performance of the MiniMUGA Genotyping Array: A New Tool To Improve Rigor and Reproducibility in Mouse Research

Author

Sigmon, John Sebastian, Blanchard, Matthew W, Baric, Ralph S, Bell, Timothy A, Brennan, Jennifer, Brockmann, Gudrun A, Burks, A Wesley, Calabrese, J Mauro, Caron, Kathleen M, Cheney, Richard E, Ciavatta, Dominic, Conlon, Frank, Darr, David B, Faber, James, Franklin, Craig, Gershon, Timothy R, Gralinski, Lisa, Gu, Bin, Gaines, Christiann H, Hagan, Robert S, Heimsath, Ernest G, Heise, Mark T, Hock, Pablo, Ideraabdullah, Folami, Jennette, J Charles, Kafri, Tal, Kashfeen, Anwica, Kulis, Mike, Kumar, Vivek, Linnertz, Colton, Livraghi-Butrico, Alessandra, Lloyd, KC Kent, Lutz, Cathleen, Lynch, Rachel M, Magnuson, Terry, Matsushima, Glenn K, McMullan, Rachel, Miller, Darla R, Mohlke, Karen L, Moy, Sheryl S, Murphy, Caroline EY, Najarian, Maya, O’Brien, Lori, Palmer, Abraham A, Philpot, Benjamin D, Randell, Scott H, Reinholdt, Laura, Ren, Yuyu, Rockwood, Steve, Rogala, Allison R, Saraswatula, Avani, Sassetti, Christopher M, Schisler, Jonathan C, Schoenrock, Sarah A, Shaw, Ginger D, Shorter, John R, Smith, Clare M, St. Pierre, Celine L, Tarantino, Lisa M, Threadgill, David W, Valdar, William, Vilen, Barbara J, Wardwell, Keegan, Whitmire, Jason K, Williams, Lucy, Zylka, Mark J, Ferris, Martin T, McMillan, Leonard, and de Villena, Fernando Pardo Manuel

Subjects

Biological Sciences, Genetics, Human Genome, Biotechnology, Aetiology, 2.6 Resources and infrastructure (aetiology), Animals, Female, Genome-Wide Association Study, Genotype, Genotyping Techniques, Male, Mice, Mice, Inbred C57BL, Oligonucleotide Array Sequence Analysis, Polymorphism, Genetic, Reproducibility of Results, Sex Determination Processes, genetic QC, genetic background, substrains, chromosomal sex, genetic constructs, diagnostic SNPs, Developmental Biology, Biochemistry and cell biology

Abstract

The laboratory mouse is the most widely used animal model for biomedical research, due in part to its well-annotated genome, wealth of genetic resources, and the ability to precisely manipulate its genome. Despite the importance of genetics for mouse research, genetic quality control (QC) is not standardized, in part due to the lack of cost-effective, informative, and robust platforms. Genotyping arrays are standard tools for mouse research and remain an attractive alternative even in the era of high-throughput whole-genome sequencing. Here, we describe the content and performance of a new iteration of the Mouse Universal Genotyping Array (MUGA), MiniMUGA, an array-based genetic QC platform with over 11,000 probes. In addition to robust discrimination between most classical and wild-derived laboratory strains, MiniMUGA was designed to contain features not available in other platforms: (1) chromosomal sex determination, (2) discrimination between substrains from multiple commercial vendors, (3) diagnostic SNPs for popular laboratory strains, (4) detection of constructs used in genetically engineered mice, and (5) an easy-to-interpret report summarizing these results. In-depth annotation of all probes should facilitate custom analyses by individual researchers. To determine the performance of MiniMUGA, we genotyped 6899 samples from a wide variety of genetic backgrounds. The performance of MiniMUGA compares favorably with three previous iterations of the MUGA family of arrays, both in discrimination capabilities and robustness. We have generated publicly available consensus genotypes for 241 inbred strains including classical, wild-derived, and recombinant inbred lines. Here, we also report the detection of a substantial number of XO and XXY individuals across a variety of sample types, new markers that expand the utility of reduced complexity crosses to genetic backgrounds other than C57BL/6, and the robust detection of 17 genetic constructs. We provide preliminary evidence that the array can be used to identify both partial sex chromosome duplication and mosaicism, and that diagnostic SNPs can be used to determine how long inbred mice have been bred independently from the relevant main stock. We conclude that MiniMUGA is a valuable platform for genetic QC, and an important new tool to increase the rigor and reproducibility of mouse research.

Published

2020

4. Dissecting the Genetic Architecture of Cystatin C in Diversity Outbred Mice

Author

Huda, M Nazmul, VerHague, Melissa, Albright, Jody, Smallwood, Tangi, Bell, Timothy A, Que, Excel, Miller, Darla R, Roshanravan, Baback, Allayee, Hooman, de Villena, Fernando Pardo Manuel, and Bennett, Brian J

Subjects

Biotechnology, Genetics, Kidney Disease, 2.1 Biological and endogenous factors, Aetiology, Inflammatory and immune system, Renal and urogenital, Animals, Biomarkers, Collaborative Cross Mice, Cystatin C, Female, Mice, Quantitative Trait Loci, Quantitative trait loci, Multi parental models, Kidney biomarkers, Type-I interferon signalling pathway, Multiparent Advanced Generation Inter-Cross, multiparental populations, MPP

Abstract

Plasma concentration of Cystatin C (CysC) level is a biomarker of glomerular filtration rate in the kidney. We use a Systems Genetics approach to investigate the genetic determinants of plasma CysC concentration. To do so we perform Quantitative Trait Loci (QTL) and expression QTL (eQTL) analysis of 120 Diversity Outbred (DO) female mice, 56 weeks of age. We performed network analysis of kidney gene expression to determine if the gene modules with common functions are associated with kidney biomarkers of chronic kidney diseases. Our data demonstrates that plasma concentrations and kidney mRNA levels of CysC are associated with genetic variation and are transcriptionally coregulated by immune genes. Specifically, Type-I interferon signaling genes are coexpressed with Cst3 mRNA levels and associated with CysC concentrations in plasma. Our findings demonstrate the complex control of CysC by genetic polymorphisms and inflammatory pathways.

Published

2020

5. A mutation in Themis contributes to anaphylaxis severity following oral peanut challenge in CC027 mice.

Author

Risemberg, Ellen L., Smeekens, Johanna M., Cruz Cisneros, Marta C., Hampton, Brea K., Hock, Pablo, Linnertz, Colton L., Miller, Darla R., Orgel, Kelly, Shaw, Ginger D., de Villena, Fernando Pardo Manuel, Burks, A. Wesley, Valdar, William, Kulis, Michael D., and Ferris, Martin T.

Abstract

The development of peanut allergy is due to a combination of genetic and environmental factors, although specific genes have proven difficult to identify. Previously, we reported that peanut-sensitized Collaborative Cross strain CC027/GeniUnc (CC027) mice develop anaphylaxis upon oral challenge to peanut, in contrast to C3H/HeJ (C3H) mice. This study aimed to determine the genetic basis of orally induced anaphylaxis to peanut in CC027 mice. A genetic mapping population between CC027 and C3H mice was designed to identify the genetic factors that drive oral anaphylaxis. A total of 356 CC027xC3H backcrossed mice were generated, sensitized to peanut, then challenged to peanut by oral gavage. Anaphylaxis and peanut-specific IgE were quantified for all mice. T-cell phenotyping was conducted on CC027 mice and 5 additional Collaborative Cross strains. Anaphylaxis to peanut was absent in 77% of backcrossed mice, with 19% showing moderate anaphylaxis and 4% having severe anaphylaxis. There were 8 genetic loci associated with variation in response to peanut challenge—6 associated with anaphylaxis (temperature decrease) and 2 associated with peanut-specific IgE levels. There were 2 major loci that impacted multiple aspects of the severity of acute anaphylaxis, at which the CC027 allele was associated with worse outcome. At one of these loci, CC027 has a private genetic variant in the Themis gene. Consistent with described functions of Themis , we found that CC027 mice have more immature T cells with fewer CD8+, CD4+, and CD4+CD25+CD127− regulatory T cells. Our results demonstrate a key role for Themis in the orally reactive CC027 mouse model of peanut allergy. [ABSTRACT FROM AUTHOR]

Published

2024

6. IsoDOT Detects Differential RNA-Isoform Expression/Usage With Respect to a Categorical or Continuous Covariate With High Sensitivity and Specificity

Author

Sun, Wei, Liu, Yufeng, Crowley, James J, Chen, Ting-Hued, Zhou, Hua, Chu, Haitao, Huang, Shunping, Kuan, Pei-Fen, Li, Yuan, Miller, Darla R, Shaw, Ginger D, Wu, Yichao, Zhabotynsky, Vasyl, McMillan, Leonard, Zou, Fei, Sullivan, Patrick F, and de Villena, Fernando Pardo-Manuel

Subjects

Economics, Statistics, Econometrics, Mathematical Sciences, Genetics, Cancer, Differential isoform expression, Differential isoform usage, Isoform, Penalized regression, RNA-seq, differential isoform expression, differential isoform usage, isoform, penalized regression, Demography, Statistics & Probability

Abstract

We have developed a statistical method named IsoDOT to assess differential isoform expression (DIE) and differential isoform usage (DIU) using RNA-seq data. Here isoform usage refers to relative isoform expression given the total expression of the corresponding gene. IsoDOT performs two tasks that cannot be accomplished by existing methods: to test DIE/DIU with respect to a continuous covariate, and to test DIE/DIU for one case versus one control. The latter task is not an uncommon situation in practice, e.g., comparing the paternal and maternal alleles of one individual or comparing tumor and normal samples of one cancer patient. Simulation studies demonstrate the high sensitivity and specificity of IsoDOT. We apply IsoDOT to study the effects of haloperidol treatment on the mouse transcriptome and identify a group of genes whose isoform usages respond to haloperidol treatment.

Published

2015

7. Genomic Profiling of Collaborative Cross Founder Mice Infected with Respiratory Viruses Reveals Novel Transcripts and Infection-Related Strain-Specific Gene and Isoform Expression

Author

Xiong, Hao, Morrison, Juliet, Ferris, Martin T, Gralinski, Lisa E, Whitmore, Alan C, Green, Richard, Thomas, Matthew J, Tisoncik-Go, Jennifer, Schroth, Gary P, de Villena, Fernando Pardo-Manuel, Baric, Ralph S, Heise, Mark T, Peng, Xinxia, and Katze, Michael G

Subjects

Lung, Biotechnology, Genetics, Infectious Diseases, Human Genome, 2.2 Factors relating to the physical environment, 2.1 Biological and endogenous factors, Aetiology, Infection, Animals, Female, Gene Expression Profiling, Gene Expression Regulation, Genome, Influenza A virus, Mice, Orthomyxoviridae Infections, Phenotype, RNA, Severe acute respiratory syndrome-related coronavirus, Sequence Analysis, RNA, Severe Acute Respiratory Syndrome, Species Specificity, Viral Load, RNA-seq, mouse transcriptome annotation, isoform differential expression, collaborative cross, viral infection

Abstract

Genetic variation between diverse mouse species is well-characterized, yet existing knowledge of the mouse transcriptome comes largely from one mouse strain (C57BL/6J). As such, it is unlikely to reflect the transcriptional complexity of the mouse species. Gene transcription is dynamic and condition-specific; therefore, to better understand the mouse transcriptional response to respiratory virus infection, we infected the eight founder strains of the Collaborative Cross with either influenza A virus or severe acute respiratory syndrome coronavirus and sequenced lung RNA samples at 2 and 4 days after infection. We found numerous instances of transcripts that were not present in the C57BL/6J reference annotation, indicating that a nontrivial proportion of the mouse genome is transcribed but poorly annotated. Of these novel transcripts, 2150 could be aligned to human or rat genomes, but not to existing mouse genomes, suggesting functionally conserved sequences not yet recorded in mouse genomes. We also found that respiratory virus infection induced differential expression of 4287 splicing junctions, resulting in strain-specific isoform expression. Of these, 59 were influenced by strain-specific mutations within 2 base pairs of key intron-exon boundaries, suggesting cis-regulated expression. Our results reveal the complexity of the transcriptional response to viral infection, previously undocumented genomic elements, and extensive diversity in the response across mouse strains. These findings identify hitherto unexplored transcriptional patterns and undocumented transcripts in genetically diverse mice. Host genetic variation drives the complexity and diversity of the host response by eliciting starkly different transcriptional profiles in response to a viral infection.

Published

2014

8. High-Resolution Sex-Specific Linkage Maps of the Mouse Reveal Polarized Distribution of Crossovers in Male Germline

Author

Liu, Eric Yi, Morgan, Andrew P, Chesler, Elissa J, Wang, Wei, Churchill, Gary A, and de Villena, Fernando Pardo-Manuel

Subjects

Biotechnology, Contraception/Reproduction, Genetics, Human Genome, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Animals, Chromosome Mapping, Crossing Over, Genetic, Female, Genomics, Genotyping Techniques, Male, Mice, Pedigree, Sex Characteristics, Siblings, Species Specificity, Spermatozoa, recombination, linkage map, sex effects, cold regions, mouse CC, Developmental Biology

Abstract

Since the publication of the first comprehensive linkage map for the laboratory mouse, the architecture of recombination as a basic biological process has become amenable to investigation in mammalian model organisms. Here we take advantage of high-density genotyping and the unique pedigree structure of the incipient Collaborative Cross to investigate the roles of sex and genetic background in mammalian recombination. Our results confirm the observation that map length is longer when measured through female meiosis than through male meiosis, but we find that this difference is modified by genotype at loci on both the X chromosome and the autosomes. In addition, we report a striking concentration of crossovers in the distal ends of autosomes in male meiosis that is absent in female meiosis. The presence of this pattern in both single- and double-recombinant chromosomes, combined with the absence of a corresponding asymmetry in the distribution of double-strand breaks, indicates a regulated sequence of events specific to male meiosis that is anchored by chromosome ends. This pattern is consistent with the timing of chromosome pairing and evolutionary constraints on male recombination. Finally, we identify large regions of reduced crossover frequency that together encompass 5% of the genome. Many of these "cold regions" are enriched for segmental duplications, suggesting an inverse local correlation between recombination rate and mutation rate for large copy number variants.

Published

2014

9. C57BL/6N Mutation in Cytoplasmic FMRP interacting protein 2 Regulates Cocaine Response

Author

Kumar, Vivek, Kim, Kyungin, Joseph, Chryshanthi, Kourrich, Saïd, Yoo, Seung-Hee, Huang, Hung Chung, Vitaterna, Martha H., de Villena, Fernando Pardo-Manuel, Churchill, Gary, Bonci, Antonello, and Takahashi, Joseph S.

Published

2013

10. Inbred Strain Variant Database (ISVdb): A Repository for Probabilistically Informed Sequence Differences Among the Collaborative Cross Strains and Their Founders

Author

Oreper, Daniel, Cai, Yanwei, Tarantino, Lisa M., de Villena, Fernando Pardo-Manuel, and Valdar, William

Subjects

MPP, 0301 basic medicine, haplotype, Genotype, Population, Mice, Inbred Strains, QH426-470, Breeding, Web Browser, Biology, computer.software_genre, Collaborative Cross, Workflow, Mice, User-Computer Interface, 03 medical and health sciences, 0302 clinical medicine, Inbred strain, Multiparental Populations, Databases, Genetic, Genetic variation, Genetics, Animals, Genetics(clinical), Computer Simulation, education, variant imputation, Molecular Biology, Genotyping, Crosses, Genetic, Genetics (clinical), education.field_of_study, Database, Haplotype, Probabilistic logic, Genetic Variation, Genomics, online GUI, Metadata, 030104 developmental biology, Haplotypes, inbred strain, computer, Algorithms, 030217 neurology & neurosurgery, Imputation (genetics)

Abstract

The Collaborative Cross (CC) is a panel of recently established multiparental recombinant inbred mouse strains. For the CC, as for any multiparental population (MPP), effective experimental design and analysis benefit from detailed knowledge of the genetic differences between strains. Such differences can be directly determined by sequencing, but until now whole-genome sequencing was not publicly available for individual CC strains. An alternative and complementary approach is to infer genetic differences by combining two pieces of information: probabilistic estimates of the CC haplotype mosaic from a custom genotyping array, and probabilistic variant calls from sequencing of the CC founders. The computation for this inference, especially when performed genome-wide, can be intricate and time-consuming, requiring the researcher to generate nontrivial and potentially error-prone scripts. To provide standardized, easy-to-access CC sequence information, we have developed the Inbred Strain Variant Database (ISVdb). The ISVdb provides, for all the exonic variants from the Sanger Institute mouse sequencing dataset, direct sequence information for CC founders and, critically, the imputed sequence information for CC strains. Notably, the ISVdb also: (1) provides predicted variant consequence metadata; (2) allows rapid simulation of F1 populations; and (3) preserves imputation uncertainty, which will allow imputed data to be refined in the future as additional sequencing and genotyping data are collected. The ISVdb information is housed in an SQL database and is easily accessible through a custom online interface (http://isvdb.unc.edu), reducing the analytic burden on any researcher using the CC.

Published

2017

11. Subspecific origin and haplotype diversity in the laboratory mouse.

Author

Hyuna Yang, Wang, Jeremy R., Didion, John P., Buus, Ryan J., Bell, Timothy A., Welsh, Catherine E., Bonhomme, François, Yu, Alex Hon-Tsen, Nachman, Michael W., Pialek, Jaroslav, Tucker, Priscilla, Boursot, Pierre, McMillan, Leonard, Churchill, Gary A., and de Villena, Fernando Pardo-Manuel

Subjects

PHYLOGENY, GENOMES, MICE, LABORATORIES, GENETICS

Abstract

Here we provide a genome-wide, high-resolution map of the phylogenetic origin of the genome of most extant laboratory mouse inbred strains. Our analysis is based on the genotypes of wild-caught mice from three subspecies of Mus musculus. We show that classical laboratory strains are derived from a few fancy mice with limited haplotype diversity. Their genomes are overwhelmingly Mus musculus domesticus in origin, and the remainder is mostly of Japanese origin. We generated genome-wide haplotype maps based on identity by descent from fancy mice and show that classical inbred strains have limited and non-randomly distributed genetic diversity. In contrast, wild-derived laboratory strains represent a broad sampling of diversity within M. musculus. Intersubspecific introgression is pervasive in these strains, and contamination by laboratory stocks has played a role in this process. The subspecific origin, haplotype diversity and identity by descent maps can be visualized using the Mouse Phylogeny Viewer (see URLs). [ABSTRACT FROM AUTHOR]

Published

2011

12. Architecture of energy balance traits in emerging lines of the Collaborative Cross.

Author

Mathes, Wendy Foulds, Aylor, David L., Miller, Dana R., Churchill, Gary A., Chesler, Elissa J., de Villena, Fernando Pardo-Manuel, Threadgill, David W., and Pomp, Daniel

Subjects

FORCE & energy, PHENOTYPES, BODY weight, GENES, BIOENERGETICS, POPULATION

Abstract

The potential utility of the Collaborative Cross (CC) mouse resource was evaluated to better understand complex traits related to energy balance. A primary focus was to examine if genetic diversity in emerging CC lines (pre-CC) would translate into equivalent phenotypic diversity. Second, we mapped quantitative trait loci (QTL) for 15 metabolism- and exercise-related phenotypes in this population. We evaluated metabolic and voluntary exercise traits in 176 pre-CC lines, revealing phenotypic variation often exceeding that seen across the eight founder strains from which the pre-CC was derived. Many phenotypic correlations existing within the founder strains were no longer significant in the pre-CC population, potentially representing reduced linkage disequilibrium (LD) of regions harboring multiple genes with effects on energy balance or disruption of genetic structure of extant inbred strains with substantial shared ancestry. QTL mapping revealed five significant and eight suggestive QTL for body weight (Chr 4, 7.54 Mb; CI 3.32-10.34 Mb; Bwq14), body composition, wheel running (Chr 16, 33.2 Mb; CI 32.5-38.3 Mb), body weight change in response to exercise (1: Chr 6, 77.7Mb; CI 72.2-83.4 Mb and 2: Chr 6, 42.8 Mb; CI 39.4-48.1 Mb), and food intake during exercise (Chr 12, 85.1 Mb; CI 82.9-89.0 Mb). Some QTL overlapped with previously mapped QTL for similar traits, whereas other QTL appear to represent novel loci. These results suggest that the CC will be a powerful, high-precision tool for examining the genetic architecture of complex traits such as those involved in regulation of energy balance. [ABSTRACT FROM AUTHOR]

Published

2011

13. Meiotic drive at theOmlocus in wild-derived inbred mouse strains.

Author

Kuikwon Kim, Thomas, Sanlare, Howard, I. Brian, Bell, Timothy A., Doherty, Heather E., Ideraabdullah, Folami, Detwiler, David A., and De Villena, Fernando Pardo-Manuel

Subjects

BIOLOGICAL evolution, MICE, GENES, MEIOSIS, HEREDITY, BREEDING, BIOLOGY, GENETICS

Abstract

Meiotic drive is an evolutionary force in which natural selection is uncoupled from organismal fitness. Recently, it has been proposed that meiotic drive and genetic drift represent major forces in the evolution of the mammalian karyotype. Meiotic drive involves two types of genetic elements,RespondersandDistorters, the latter being required to induce transmission ratio distortion at the former. We have previously described theOmmeiotic drive system in mouse chromosome 11. To investigate the natural history of this drive system we have characterized the alleles present at the distorter in wild-derived inbred strains. Our analysis of transmission of maternal alleles in both classical and wild-derived inbred strains indicated that driving alleles are found at high frequency in natural populations and that the existence of driving alleles predates the split between theMus spicilegusandM. musculuslineages. © 2005 The Linnean Society of London,Biological Journal of the Linnean Society, 2005,84, 487–492. [ABSTRACT FROM AUTHOR]

Published

2005

14. Female Meiosis Drives Karyotypic Evolution in Mammals.

Author

de Villena, Fernando Pardo-Manuel and Sapienza, Carmen

Subjects

*MAMMALS, *CENTROMERE, *GENETICS

Abstract

Analyzes mammalian karyotypic evolution. Expansion of the principle of nonrandom segregation of chromosomes; Impact of the presence of differing numbers of centromeres; Role of the polarity of the meiotic spindle.

Published

2001

15. Efficient genome ancestry inference in complex pedigrees with inbreeding.

Author

Liu, Eric Yi, Qi Zhang, McMillan, Leonard, De Villena, Fernando Pardo-Manuel, and Wei Wang

Subjects

NUCLEOTIDE sequence, INBREEDING, GENOMES, GENEALOGY, ANIMAL pedigrees, GENETICS

Abstract

Motivation: High-density SNP data of model animal resources provides opportunities for fine-resolution genetic variation studies. These genetic resources are generated through a variety of breeding schemes that involve multiple generations of matings derived from a set of founder animals. In this article, we investigate the problem of inferring the most probable ancestry of resulting genotypes, given a set of founder genotypes. Due to computational difficulty, existing methods either handle only small pedigree data or disregard the pedigree structure. However, large pedigrees of model animal resources often contain repetitive substructures that can be utilized in accelerating computation. [ABSTRACT FROM PUBLISHER]

Published

2010

16. Sarbecovirus disease susceptibility is conserved across viral and host models.

Author

Leist, Sarah R., Schäfer, Alexandra, Risemberg, Ellen L., Bell, Timothy A., Hock, Pablo, Zweigart, Mark R., Linnertz, Colton L., Miller, Darla R., Shaw, Ginger D., de Villena, Fernando Pardo Manuel, Ferris, Martin T., Valdar, William, and Baric, Ralph S.

Subjects

*DISEASE susceptibility, *COVID-19, *SARS disease, *LOCUS (Genetics), *VIRUS diseases

Abstract

Coronaviruses have caused three severe epidemics since the start of the 21st century: SARS, MERS and COVID-19. The severity of the ongoing COVID-19 pandemic and increasing likelihood of future coronavirus outbreaks motivates greater understanding of factors leading to severe coronavirus disease. We screened ten strains from the Collaborative Cross mouse genetic reference panel and identified strains CC006/TauUnc (CC006) and CC044/Unc (CC044) as coronavirus-susceptible and resistant, respectively, as indicated by variable weight loss and lung congestion scores four days post-infection. We generated a genetic mapping population of 755 CC006xCC044 F2 mice and exposed the mice to one of three genetically distinct mouse-adapted coronaviruses: clade 1a SARS-CoV MA15 (n=391), clade 1b SARS-CoV-2 MA10 (n=274), and clade 2 HKU3-CoV MA (n=90). Quantitative trait loci (QTL) mapping in SARS-CoV MA15- and SARS-CoV-2 MA10-infected F2 mice identified genetic loci associated with disease severity. Specifically, we identified seven loci associated with variation in outcome following infection with either virus, including one, HrS43 , that is present in both groups. Three of these QTL, including HrS43 , were also associated with HKU3-CoV MA outcome. HrS43 overlaps with a QTL previously reported by our lab that is associated with SARS-CoV MA15 outcome in CC011xCC074 F2 mice and is also syntenic with a human chromosomal region associated with severe COVID-19 outcomes in humans GWAS. The results reported here provide: (a) additional support for the involvement of this locus in SARS-CoV MA15 infection, (b) the first conclusive evidence that this locus is associated with susceptibility across the Sarbecovirus subgenus, and (c) demonstration of the relevance of mouse models in the study of coronavirus disease susceptibility in humans. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

17. Instability of the Pseudoautosomal Boundary in House Mice.

Author

Morgan, Andrew P., Bell, Timothy A., Crowley, James J., and de Villena, Fernando Pardo-Manuel

Subjects

*INFERTILITY, *ANIMAL experimentation, *GENETIC polymorphisms, *MICE, *GENETIC mutation, *SEX chromosomes, *GENOTYPES, *GENETICS

Abstract

Faithful segregation of homologous chromosomes at meiosis requires pairing and recombination. In taxa with dimorphic sex chromosomes, pairing between them in the heterogametic sex is limited to a narrow interval of residual sequence homology known as the pseudoautosomal region (PAR). Failure to form the obligate crossover in the PAR is associated with male infertility in house mice (Mus musculus) and humans. Yet despite this apparent functional constraint, the boundary and organization of the PAR is highly variable in mammals, and even between subspecies of mice. Here, we estimate the genetic map in a previously documented expansion of the PAR in the M. musculus castaneus subspecies and show that the local recombination rate is 100-fold higher than the autosomal background. We identify an independent shift in the PAR boundary in the M. musculus musculus subspecies and show that it involves a complex rearrangement, but still recombines in heterozygous males. Finally, we demonstrate pervasive copy-number variation at the PAR boundary in wild populations of M. m. domesticus, M. m. musculus, and M. m. castaneus. Our results suggest that the intensity of recombination activity in the PAR, coupled with relatively weak constraints on its sequence, permit the generation and maintenance of unusual levels of polymorphism in the population of unknown functional significance. [ABSTRACT FROM AUTHOR]

Published

2019

18. Allelic Variation in the Toll-Like Receptor Adaptor Protein Ticam2 Contributes to SARS-Coronavirus Pathogenesis in Mice.

Author

Gralinski, Lisa E., Menachery, Vineet D., Morgan, Andrew P., Totura, Allison L., Beall, Anne, Kocher, Jacob, Plante, Jessica, Harrison-Shostak, D. Corinne, Schäfer, Alexandra, de Villena, Fernando Pardo-Manuel, Ferris, Martin T., and Baric, Ralph S.

Subjects

*ADAPTOR protein structure, *SARS disease, *DISEASE susceptibility, *GENETICS

Abstract

Host genetic variation is known to contribute to differential pathogenesis following infection. Mouse models allow direct assessment of host genetic factors responsible for susceptibility to Severe Acute Respiratory Syndrome coronavirus (SARS-CoV). Based on an assessment of early stage lines from the Collaborative Cross mouse multi-parent population, we identified two lines showing highly divergent susceptibilities to SARS-CoV: the resistant CC003/Unc and the susceptible CC053/Unc. We generated 264 F2 mice between these strains, and infected them with SARS-CoV. Weight loss, pulmonary hemorrhage, and viral load were all highly correlated disease phenotypes. We identified a quantitative trait locus of major effect on chromosome 18 (27.1-58.6 Mb) which affected weight loss, viral titer and hemorrhage. Additionally, each of these three phenotypes had distinct quantitative trait loci [Chr 9 (weight loss), Chrs 7 and 12 (virus titer), and Chr 15 (hemorrhage)]. We identified Ticam2, an adaptor protein in the TLR signaling pathways, as a candidate driving differential disease at the Chr 18 locus. Ticam22/2 mice were highly susceptible to SARS-CoV infection, exhibiting increased weight loss and more pulmonary hemorrhage than control mice. These results indicate a critical role for Ticam2 in SARS-CoV disease, and highlight the importance of host genetic variation in disease responses. [ABSTRACT FROM AUTHOR]

Published

2017

19. The Paternal Gene of the DDK Syndrome Maps to the Schlafen Gene Cluster on Mouse Chromosome 11.

Author

Bell, Timothy A., de la Casa-Esperón, Elena, Doherty, Heather E., Ideraabdullah, Folami, Kuikwon Kim, Yunfei Wang, Lange, Leslie A., Wilhemsen, Kirk, Lange, Ethan M., Sapienza, Carmen, and de Villena, Fernando Pardo-Manuel

Subjects

*SYNDROMES, *PHENOTYPES, *MICE, *CHROMOSOMES, *GENES, *GENETICS

Abstract

The DDK syndrome is an early embryonic lethal phenotype observed in crosses between females of the DDK inbred mouse strain and many non-DDK males. Lethality results from an incompatibility between a maternal DDK factor and a non-DDK paternal gene, both of which have been mapped to the Ovum mutant (Om) locus on mouse chromosome 11. Here we define a 465-kb candidate interval for the paternal gene by recombinant progeny testing. To further refine the candidate interval we determined whether males from 17 classical and wild-derived inbred strains are interfertile with DDK females. We conclude that the incompatible paternal allele arose in the Mus musculus domesticus lineage and that incompatible strains should share a common haplotype spanning the paternal gene. We tested for association between paternal allele compatibility/incompatibility and 167 genetic variants located in the candidate interval. Two diallelic SNPs, located in the Schlafen gene cluster, are completely predictive of the polar-lethal phenotype. These SNPs also predict the compatible or incompatible status of males of five additional strains. [ABSTRACT FROM AUTHOR]

Published

2006

20. Maternal Transmission Ratio Distortion at the Mouse Om Locus Results From Meiotic Drive at the Second Meiotic Division.

Author

Guangming Wu, Lanping Hao, Thiming Han, Shaorong Gao, Latham, Keith E., de Villena, Fernando Pardo-Manuel, and Sapienza, Carmen

Subjects

*MEIOSIS, *GENETIC polymorphisms, *GENETIC mutation, *CHROMOSOMES, *GENOTYPE-environment interaction, *GENETICS

Abstract

We have observed maternal transmission ratio distortion (TRD) in favor of DDK alleles at the Ovum mutant (Ore) locus on mouse chromosome 11 among the offspring of (C57BL/6 × DDK) F1 females and C57BL/6 males. Although significant lethality occurs in this backcross (∼50%), differences in the level of TRD found in recombinant vs. nonrecombinant chromosomes among offspring argue that TRD is due to nonrandom segregation of chromatids at the second meiotic division, i.e., true meiotic drive. We tested this hypothesis directly, by determining the centromere and Om genotypes of individual chromatids in zygote stage embryos. We found similar levels of TRD in favor of DDK alleles at Om in the female pronucleus and TRD in favor of C57BL/6 alleles at Om in the second polar body. In those embryos for which complete dyads have been reconstructed, TRD was present only in those inheriting heteromorphic dyads. These results demonstrate that meiotic drive occurs at MII and that preferential death of one genotypic class of embryo does not play a large role in the TRD. [ABSTRACT FROM AUTHOR]

Published

2005

21. R2d2 drives selfish sweeps in the house mouse

Author

David W. Threadgill, Wesley J. Jolley, Maria da Graça Ramalhinho, James Holt, Amanda J. Chunco, Lydia Ortiz de Solorzano, Daniel W. Förster, Daniel Pomp, Andrew Holmes, Fernando Pardo-Manuel de Villena, Sofia A. Grize, Leonard McMillan, Sofia I. Gabriel, Mabel D. Giménez, John P. Didion, Jeremy S. Herman, Jeremy B. Searle, George M. Weinstock, Riccardo Castiglia, İslam Gündüz, Kunjie Hua, Timothy A. Bell, Karl J. Campbell, John E. French, Janice Britton-Davidian, Karen L. Svenson, Andrew P. Morgan, Elissa J. Chesler, Carol J. Bult, Maria da Luz Mathias, Daniel M. Gatti, George P. Mitsainas, James J. Crowley, Rachel C. McMullan, Pat Thomas-Laemont, Heidi C. Hauffe, Yung-Hao Ching, Meng Shin Shiao, Stephan P. Rosshart, Liran Yadgary, María José López-Fuster, Emanuela Solano, Barbara Rehermann, Gary A. Churchill, Jacint Ventura Queija, Eva B. Giagia-Athanasopoulou, Theodore Garland, Anna K. Lindholm, University of Zurich, de Villena, Fernando Pardo-Manuel, Lineberger Comprehensive Cancer Center (UNC Lineberger), University of North Carolina [Chapel Hill] (UNC), University of North Carolina System (UNC)-University of North Carolina System (UNC), Carolina Center for Genome Sciences, Institut des Sciences de l'Evolution de Montpellier (UMR ISEM), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-École Pratique des Hautes Études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Montpellier (UM)-Institut de recherche pour le développement [IRD] : UR226-Centre National de la Recherche Scientifique (CNRS), The Jackson Laboratory [Bar Harbor] (JAX), Island Conservation, University of Queensland [Brisbane], Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome] (UNIROMA), Elon University [NC, USA], University of North Carolina System (UNC), Leibniz Institute for Zoo and Wildlife Research (IZW), Leibniz Association, National Institute of Environmental Health Sciences [Durham] (NIEHS-NIH), National Institutes of Health [Bethesda] (NIH), Centre for Environmental and Marine Studies [Aveiro] (CESAM), Universidade de Aveiro, Universidade de Lisboa = University of Lisbon (ULISBOA), University of California [Riverside] (UC Riverside), University of California (UC), Department of Biology [Patras], University of Patras, Consejo Nacional de Investigaciones Científicas y Técnicas [Buenos Aires] (CONICET), Universidad Nacional de Misiones, Universität Zürich [Zürich] = University of Zurich (UZH), Ondokuz Mayis University (OMU), National Institute on Alcohol Abuse and Alcoholism (NIAAA), Fondazione Edmund Mach - Edmund Mach Foundation [Italie] (FEM), Department of Computer Science [Chapel Hill], Universitat de Barcelona (UB), National Institute of Diabetes and Digestive and Kidney Diseases [Bethesda], Department of Ecology and Evolutionary Biology [Ithaca], Cornell University [New York], Mahidol University [Bangkok], Texas A&M University [College Station], Universitat Autònoma de Barcelona (UAB), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-École pratique des hautes études (EPHE), Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Universidade de Lisboa (ULISBOA), University of California [Riverside] (UCR), University of California, University of Patras [Patras], Ondokuz Mayis University, and OMÜ

Subjects

Male, 0301 basic medicine, MESH: Selection, Genetic, Meiotic Drive, House Mouse, purl.org/becyt/ford/1 [https], Mice, Settore BIO/05 - ZOOLOGIA, 0302 clinical medicine, Darwinian Fitness, MUS MUSCULUS DOMESTICUS, MESH: Animals, MESH: Genetic Variation, MESH: Models, Genetic, Selective sweep, MESH: Evolution, Molecular, 2. Zero hunger, Genetics, Selfish Genes, education.field_of_study, Nuclear Proteins, RNA-Binding Proteins, Meiotic drive, Adaptation, Physiological, Biological Evolution, Fixation (population genetics), Fast Track, 590 Animals (Zoology), Female, MESH: DNA Copy Number Variations, CIENCIAS NATURALES Y EXACTAS, Selective Sweep, Selfish genes, MESH: Mutation, DNA Copy Number Variations, Otras Ciencias Biológicas, Population, MESH: Genetics, Population, MESH: Biological Evolution, Biology, R2d2, Evolution, Molecular, Ciencias Biológicas, 03 medical and health sciences, 10127 Institute of Evolutionary Biology and Environmental Studies, Genetic drift, 1311 Genetics, Genetic variation, 1312 Molecular Biology, Animals, Selection, Genetic, purl.org/becyt/ford/1.6 [https], education, Molecular Biology, MESH: Mice, Alleles, Ecology, Evolution, Behavior and Systematics, Repetitive Sequences, Nucleic Acid, MESH: Repetitive Sequences, Nucleic Acid, [SDV.GEN.GPO]Life Sciences [q-bio]/Genetics/Populations and Evolution [q-bio.PE], Models, Genetic, MESH: Alleles, Genetic Variation, MESH: Adaptation, Physiological, MESH: Male, House mouse, [SDV.GEN.GA]Life Sciences [q-bio]/Genetics/Animal genetics, Genetics, Population, 030104 developmental biology, MESH: RNA-Binding Proteins, 1105 Ecology, Evolution, Behavior and Systematics, Mutation, 570 Life sciences, biology, MESH: Nuclear Proteins, MESH: Female, 030217 neurology & neurosurgery

Abstract

Mitsainas, George/0000-0003-4976-8275; Lindholm, Anna K/0000-0001-8460-9769; Mathias, Maria da Luz/0000-0003-3876-958X; Foerster, Daniel/0000-0002-6934-0404; Hauffe, Heidi Christine C/0000-0003-3098-8964; Threadgill, David W/0000-0003-3538-1635; Gabriel, Sofia I/0000-0003-3702-4631; Chesler, Elissa/0000-0002-5642-5062; Didion, John/0000-0002-8111-6261; solano, emanuela/0000-0001-8482-9243; Weinstock, George/0000-0002-2997-4592; McMullan, Rachel/0000-0003-0297-4549; Holt, James/0000-0001-6411-9236; Rehermann, Barbara/0000-0001-6832-9951 WOS: 000376170300001 PubMed: 26882987 A selective sweep is the result of strong positive selection driving newly occurring or standing genetic variants to fixation, and can dramatically alter the pattern and distribution of allelic diversity in a population. Population-level sequencing data have enabled discoveries of selective sweeps associated with genes involved in recent adaptations in many species. In contrast, much debate but little evidence addresses whether "selfish" genes are capable of fixation-thereby leaving signatures identical to classical selective sweeps-despite being neutral or deleterious to organismal fitness. We previously described R2d2, a large copy-number variant that causes nonrandom segregation of mouse Chromosome 2 in females due to meiotic drive. Here we show population-genetic data consistent with a selfish sweep driven by alleles of R2d2 with high copy number (R2d2(HC)) in natural populations. We replicate this finding inmultiple closed breeding populations from six outbred backgrounds segregating for R2d2 alleles. We find that R2d2(HC) rapidly increases in frequency, and in most cases becomes fixed in significantly fewer generations than can be explained by genetic drift. R2d2(HC) is also associated with significantly reduced litter sizes in heterozygous mothers, making it a true selfish allele. Our data provide direct evidence of populations actively undergoing selfish sweeps, and demonstrate that meiotic drive can rapidly alter the genomic landscape in favor of mutations with neutral or even negative effects on overall Darwinian fitness. Further study will reveal the incidence of selfish sweeps, and will elucidate the relative contributions of selfish genes, adaptation and genetic drift to evolution. National Institutes of HealthUnited States Department of Health & Human ServicesNational Institutes of Health (NIH) - USA [T32GM067553, F30MH103925, P50GM076468, K01MH094406, DK-076050, DK-056350, AG038070]; National Science FoundationNational Science Foundation (NSF) [IOS-1121273]; Vaadia-BARD Postdoctoral Fellowship AwardUS-Israel Binational Science Foundation [FI-478-13]; U.S. Army Medical Research and Materiel CommandU.S. Army Medical Research & Materiel Command (USAMRMC) [W81XWH-11-1-0762]; Jackson Laboratory new investigator funds; National Center for Scientific Research, France [ISEM 2016-002]; University of Rome "La Sapienza"; Claraz-Stiftung; Natural Environment Research Council (UK)NERC Natural Environment Research Council; EU Human Capital and Mobility Programme [CHRX-CT93-0192]; Foundation for Science and Technology, PortugalPortuguese Foundation for Science and Technology [PTDC/BIA-EVF/116884/2010, UID/AMB/50017/2013]; Spanish "Ministerio de Ciencia y Tecnologia"Spanish Government [CGL2007-62111]; "Ministerio de Economia y Competitividad"Spanish Government [CGL2010-15243]; School of Medicine at University of North Carolina We wish to thank all the scientists and research personnel who collected and processed the samples used in this study. In particular we acknowledge Luanne Peters and Alex Hong-Tsen Yu for providing critical samples; Ryan Buus and T. Justin Gooch for isolating DNA for high-density genotyping of wild-caught mice; and Vicki Cappa, A. Cerveira, Guila Ganem, Ron and Annabelle Lesher, K. Said, Toni Schelts, Dan Small, and J. Tapisso for aiding in mouse trapping. We thank Muriel Davisson at the Jackson Laboratory for maintaining, for several decades, tissue samples from breeding colonies used to generate wild-derived inbred strains. We also thank Francis Collins, Jim Evans, Matthew Hahn, and Corbin Jones for comments on an earlier version of this manuscript. This work was supported by the National Institutes of Health T32GM067553 to J.P.D. and A.P.M., F30MH103925 to A.P.M., P50GM076468 to E.J.C., G.A.C., and F.P.M.V., K01MH094406 to J.J.C., DK-076050 and DK-056350 to D.P., AG038070 to G.A.C, and the intramural research program to B.R. and S.P.R.; National Science Foundation IOS-1121273 to T.G.; Vaadia-BARD Postdoctoral Fellowship Award FI-478-13 to L.Y.; U.S. Army Medical Research and Materiel Command W81XWH-11-1-0762 to C.J.B.; The Jackson Laboratory new investigator funds to E.J.C.; The National Center for Scientific Research, France to J.B.D. (this is contribution no ISEM 2016-002); the University of Rome "La Sapienza" to R.C. and E.S.; Claraz-Stiftung to S.G. and A.L.; Natural Environment Research Council (UK) to M.D.G., H.C.H., and J.B.S.; EU Human Capital and Mobility Programme (CHRX-CT93-0192) to H.C.H. and J.B.S.; Foundation for Science and Technology, Portugal PTDC/BIA-EVF/116884/2010 and UID/AMB/50017/2013 to S.I.G., M.L.M., and J.B.S.; Spanish "Ministerio de Ciencia y Tecnologia" CGL2007-62111 and "Ministerio de Economia y Competitividad" CGL2010-15243 to J.V.;and the Oliver Smithies Investigator funds provided by the School of Medicine at University of North Carolina to F.P.M.V. All data are made available at http://csbio.unc.edu/r2d2/. The authors declare no competing financial interests. Correspondence and requests for materials should be addressed to F.P.M.V. (fernando@med.unc.edu).

Published

2016