Your search keyword '"Yadgary L"' showing total 15 results

1. Changes in yolk sac membrane absorptive area and fat digestion during chick embryonic development

Author

Yadgary, L., Kedar, O., Adepeju, O., and Uni, Z.

Published

2013

2. Gene expression of nutrient transporters and digestive enzymes in the yolk sac membrane and small intestine of the developing embryonic chick

Author

Speier, J.S., Yadgary, L., Uni, Z., and Wong, E.A.

Published

2012

3. Nutritional limitations during poultry embryonic development

Author

Uni, Z., Yadgary, L., and Yair, R.

Published

2012

4. Yolk sac carbohydrate levels and gene expression of key gluconeogenic and glycogenic enzymes during chick embryonic development

Author

Yadgary, L. and Uni, Z.

Published

2012

5. The chick embryo yolk sac membrane expresses nutrient transporter and digestive enzyme genes

Author

Yadgary, L., Yair, R., and Uni, Z.

Published

2011

6. The viability and performance under hot conditions of featherless broilers versus fully feathered broilers

Author

Azoulay, Y., Druyan, S., Yadgary, L., Hadad, Y., and Cahaner, A.

Published

2011

7. Yolk sac nutrient composition and fat uptake in late-term embryos in eggs from young and old broiler breeder hens

Author

Yadgary, L., Cahaner, A., Kedar, O., and Uni, Z.

Published

2010

8. R2d2 Drives Selfish Sweeps in the House Mouse.

Author

Didion, JP, Morgan, AP, Yadgary, L, Bell, TA, McMullan, RC, Ortiz de Solorzano, L, Britton-Davidian, J, Bult, CJ, Campbell, KJ, Castiglia, R, Ching, Y-H, Chunco, AJ, Crowley, JJ, Chesler, EJ, Förster, DW, French, JE, Gabriel, SI, Gatti, DM, Garland, T, Giagia-Athanasopoulou, EB, Giménez, MD, Grize, SA, Gündüz, İ, Holmes, A, Hauffe, HC, Herman, JS, Holt, JM, Hua, K, Jolley, WJ, Lindholm, AK, López-Fuster, MJ, Mitsainas, G, da Luz Mathias, M, McMillan, L, Ramalhinho, MDGM, Rehermann, B, Rosshart, SP, Searle, JB, Shiao, M-S, Solano, E, Svenson, KL, Thomas-Laemont, P, Threadgill, DW, Ventura, J, Weinstock, GM, Pomp, D, Churchill, GA, Pardo-Manuel de Villena, F, Didion, JP, Morgan, AP, Yadgary, L, Bell, TA, McMullan, RC, Ortiz de Solorzano, L, Britton-Davidian, J, Bult, CJ, Campbell, KJ, Castiglia, R, Ching, Y-H, Chunco, AJ, Crowley, JJ, Chesler, EJ, Förster, DW, French, JE, Gabriel, SI, Gatti, DM, Garland, T, Giagia-Athanasopoulou, EB, Giménez, MD, Grize, SA, Gündüz, İ, Holmes, A, Hauffe, HC, Herman, JS, Holt, JM, Hua, K, Jolley, WJ, Lindholm, AK, López-Fuster, MJ, Mitsainas, G, da Luz Mathias, M, McMillan, L, Ramalhinho, MDGM, Rehermann, B, Rosshart, SP, Searle, JB, Shiao, M-S, Solano, E, Svenson, KL, Thomas-Laemont, P, Threadgill, DW, Ventura, J, Weinstock, GM, Pomp, D, Churchill, GA, and Pardo-Manuel de Villena, F

Abstract

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 in multiple 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.

Published

2016

9. Large changes in detected selection signatures after a selection limit in mice bred for voluntary wheel-running behavior.

Author

Hillis DA, Yadgary L, Weinstock GM, de Villena FP, Pomp D, and Garland T Jr

Subjects

Animals, Mice, Gene Frequency, Running, Male, Phenotype, Genotype, Female, Behavior, Animal physiology, Selective Breeding genetics, Selection, Genetic, Polymorphism, Single Nucleotide

Abstract

In various organisms, sequencing of selectively bred lines at apparent selection limits has demonstrated that genetic variation can remain at many loci, implying that evolution at the genetic level may continue even if the population mean phenotype remains constant. We compared selection signatures at generations 22 and 61 of the "High Runner" mouse experiment, which includes 4 replicate lines bred for voluntary wheel-running behavior (HR) and 4 non-selected control (C) lines. Previously, we reported multiple regions of differentiation between the HR and C lines, based on whole-genome sequence data for 10 mice from each line at generation 61, which was >31 generations after selection limits had been reached in all HR lines. Here, we analyzed pooled sequencing data from ~20 mice for each of the 8 lines at generation 22, around when HR lines were reaching limits. Differentiation analyses of allele frequencies at ~4.4 million SNP loci used the regularized T-test and detected 258 differentiated regions with FDR = 0.01. Comparable analyses involving pooling generation 61 individual mouse genotypes into allele frequencies by line produced only 11 such regions, with almost no overlap among the largest and most statistically significant peaks between the two generations. These results implicate a sort of "genetic churn" that continues at loci relevant for running. Simulations indicate that loss of statistical power due to random genetic drift and sampling error are insufficient to explain the differences in selection signatures. The 13 differentiated regions at generation 22 with strict culling measures include 79 genes related to a wide variety of functions. Gene ontology identified pathways related to olfaction and vomeronasal pathways as being overrepresented, consistent with generation 61 analyses, despite those specific regions differing between generations. Genes Dspp and Rbm24 are also identified as potentially explaining known bone and skeletal muscle differences, respectively, between the linetypes., Competing Interests: The authors have no competing interests., (Copyright: © 2024 Hillis et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

10. Genetic Basis of Aerobically Supported Voluntary Exercise: Results from a Selection Experiment with House Mice.

Author

Hillis DA, Yadgary L, Weinstock GM, Pardo-Manuel de Villena F, Pomp D, Fowler AS, Xu S, Chan F, and Garland T Jr

Subjects

Animals, Cadherins genetics, Chromosomes genetics, Eye Proteins genetics, Female, Hybridization, Genetic, Male, Membrane Transport Proteins genetics, Mice, Mice, Inbred ICR, Multifactorial Inheritance, Receptors, LDL genetics, Directed Molecular Evolution, Polymorphism, Single Nucleotide, Running, Selection, Genetic

Abstract

The biological basis of exercise behavior is increasingly relevant for maintaining healthy lifestyles. Various quantitative genetic studies and selection experiments have conclusively demonstrated substantial heritability for exercise behavior in both humans and laboratory rodents. In the "High Runner" selection experiment, four replicate lines of Mus domesticus were bred for high voluntary wheel running (HR), along with four nonselected control (C) lines. After 61 generations, the genomes of 79 mice (9-10 from each line) were fully sequenced and single nucleotide polymorphisms (SNPs) were identified. We used nested ANOVA with MIVQUE estimation and other approaches to compare allele frequencies between the HR and C lines for both SNPs and haplotypes. Approximately 61 genomic regions, across all somatic chromosomes, showed evidence of differentiation; 12 of these regions were differentiated by all methods of analysis. Gene function was inferred largely using Panther gene ontology terms and KO phenotypes associated with genes of interest. Some of the differentiated genes are known to be associated with behavior/motivational systems and/or athletic ability, including Sorl1 , Dach1 , and Cdh10 Sorl1 is a sorting protein associated with cholinergic neuron morphology, vascular wound healing, and metabolism. Dach1 is associated with limb bud development and neural differentiation. Cdh10 is a calcium ion binding protein associated with phrenic neurons. Overall, these results indicate that selective breeding for high voluntary exercise has resulted in changes in allele frequencies for multiple genes associated with both motivation and ability for endurance exercise, providing candidate genes that may explain phenotypic changes observed in previous studies., (Copyright © 2020 by the Genetics Society of America.)

Published

2020

11. The Evolutionary Fates of a Large Segmental Duplication in Mouse.

Author

Morgan AP, Holt JM, McMullan RC, Bell TA, Clayshulte AM, Didion JP, Yadgary L, Thybert D, Odom DT, Flicek P, McMillan L, and de Villena FP

Subjects

Alleles, Animals, Animals, Wild genetics, Evolution, Molecular, Gene Conversion, Gene Dosage, Genes, Duplicate, Genetic Variation, Mice, Phylogeny, RNA-Binding Proteins, Biological Evolution, Gene Duplication, Nuclear Proteins genetics, Segmental Duplications, Genomic

Abstract

Gene duplication and loss are major sources of genetic polymorphism in populations, and are important forces shaping the evolution of genome content and organization. We have reconstructed the origin and history of a 127-kbp segmental duplication, R2d, in the house mouse (Mus musculus). R2d contains a single protein-coding gene, Cwc22 De novo assembly of both the ancestral (R2d1) and the derived (R2d2) copies reveals that they have been subject to nonallelic gene conversion events spanning tens of kilobases. R2d2 is also a hotspot for structural variation: its diploid copy number ranges from zero in the mouse reference genome to >80 in wild mice sampled from around the globe. Hemizygosity for high copy-number alleles of R2d2 is associated in cis with meiotic drive; suppression of meiotic crossovers; and copy-number instability, with a mutation rate in excess of 1 per 100 transmissions in some laboratory populations. Our results provide a striking example of allelic diversity generated by duplication and demonstrate the value of de novo assembly in a phylogenetic context for understanding the mutational processes affecting duplicate genes., (Copyright © 2016 by the Genetics Society of America.)

Published

2016

12. R2d2 Drives Selfish Sweeps in the House Mouse.

Author

Didion JP, Morgan AP, Yadgary L, Bell TA, McMullan RC, Ortiz de Solorzano L, Britton-Davidian J, Bult CJ, Campbell KJ, Castiglia R, Ching YH, Chunco AJ, Crowley JJ, Chesler EJ, Förster DW, French JE, Gabriel SI, Gatti DM, Garland T Jr, Giagia-Athanasopoulou EB, Giménez MD, Grize SA, Gündüz İ, Holmes A, Hauffe HC, Herman JS, Holt JM, Hua K, Jolley WJ, Lindholm AK, López-Fuster MJ, Mitsainas G, da Luz Mathias M, McMillan L, Ramalhinho Mda G, Rehermann B, Rosshart SP, Searle JB, Shiao MS, Solano E, Svenson KL, Thomas-Laemont P, Threadgill DW, Ventura J, Weinstock GM, Pomp D, Churchill GA, and Pardo-Manuel de Villena F

Subjects

Adaptation, Physiological genetics, Alleles, Animals, Biological Evolution, DNA Copy Number Variations genetics, Evolution, Molecular, Female, Genetic Variation, Genetics, Population, Male, Mice, Models, Genetic, Mutation, Selection, Genetic, Nuclear Proteins genetics, RNA-Binding Proteins genetics, Repetitive Sequences, Nucleic Acid

Abstract

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 in multiple 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., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2016

13. The Mouse Universal Genotyping Array: From Substrains to Subspecies.

Author

Morgan AP, Fu CP, Kao CY, Welsh CE, Didion JP, Yadgary L, Hyacinth L, Ferris MT, Bell TA, Miller DR, Giusti-Rodriguez P, Nonneman RJ, Cook KD, Whitmire JK, Gralinski LE, Keller M, Attie AD, Churchill GA, Petkov P, Sullivan PF, Brennan JR, McMillan L, and Pardo-Manuel de Villena F

Subjects

Alleles, Animals, Computational Biology methods, Gene Dosage, Genetics, Population, Mice, Mice, Inbred Strains, Oligonucleotide Array Sequence Analysis, Phylogeny, Polymorphism, Single Nucleotide, Chromosome Mapping methods, Genome, Genomics methods, Genotype

Abstract

Genotyping microarrays are an important resource for genetic mapping, population genetics, and monitoring of the genetic integrity of laboratory stocks. We have developed the third generation of the Mouse Universal Genotyping Array (MUGA) series, GigaMUGA, a 143,259-probe Illumina Infinium II array for the house mouse (Mus musculus). The bulk of the content of GigaMUGA is optimized for genetic mapping in the Collaborative Cross and Diversity Outbred populations, and for substrain-level identification of laboratory mice. In addition to 141,090 single nucleotide polymorphism probes, GigaMUGA contains 2006 probes for copy number concentrated in structurally polymorphic regions of the mouse genome. The performance of the array is characterized in a set of 500 high-quality reference samples spanning laboratory inbred strains, recombinant inbred lines, outbred stocks, and wild-caught mice. GigaMUGA is highly informative across a wide range of genetically diverse samples, from laboratory substrains to other Mus species. In addition to describing the content and performance of the array, we provide detailed probe-level annotation and recommendations for quality control., (Copyright © 2016 Morgan et al.)

Published

2015

14. A multi-megabase copy number gain causes maternal transmission ratio distortion on mouse chromosome 2.

Author

Didion JP, Morgan AP, Clayshulte AM, Mcmullan RC, Yadgary L, Petkov PM, Bell TA, Gatti DM, Crowley JJ, Hua K, Aylor DL, Bai L, Calaway M, Chesler EJ, French JE, Geiger TR, Gooch TJ, Garland T Jr, Harrill AH, Hunter K, McMillan L, Holt M, Miller DR, O'Brien DA, Paigen K, Pan W, Rowe LB, Shaw GD, Simecek P, Sullivan PF, Svenson KL, Weinstock GM, Threadgill DW, Pomp D, Churchill GA, and Pardo-Manuel de Villena F

Subjects

Alleles, Animals, Chromosomes genetics, Crosses, Genetic, Female, Genotyping Techniques, Haplotypes genetics, Male, Mice, Mutation, DNA Copy Number Variations genetics, Genomics, Inheritance Patterns genetics, Meiosis genetics

Abstract

Significant departures from expected Mendelian inheritance ratios (transmission ratio distortion, TRD) are frequently observed in both experimental crosses and natural populations. TRD on mouse Chromosome (Chr) 2 has been reported in multiple experimental crosses, including the Collaborative Cross (CC). Among the eight CC founder inbred strains, we found that Chr 2 TRD was exclusive to females that were heterozygous for the WSB/EiJ allele within a 9.3 Mb region (Chr 2 76.9 - 86.2 Mb). A copy number gain of a 127 kb-long DNA segment (designated as responder to drive, R2d) emerged as the strongest candidate for the causative allele. We mapped R2d sequences to two loci within the candidate interval. R2d1 is located near the proximal boundary, and contains a single copy of R2d in all strains tested. R2d2 maps to a 900 kb interval, and the number of R2d copies varies from zero in classical strains (including the mouse reference genome) to more than 30 in wild-derived strains. Using real-time PCR assays for the copy number, we identified a mutation (R2d2WSBdel1) that eliminates the majority of the R2d2WSB copies without apparent alterations of the surrounding WSB/EiJ haplotype. In a three-generation pedigree segregating for R2d2WSBdel1, the mutation is transmitted to the progeny and Mendelian segregation is restored in females heterozygous for R2d2WSBdel1, thus providing direct evidence that the copy number gain is causal for maternal TRD. We found that transmission ratios in R2d2WSB heterozygous females vary between Mendelian segregation and complete distortion depending on the genetic background, and that TRD is under genetic control of unlinked distorter loci. Although the R2d2WSB transmission ratio was inversely correlated with average litter size, several independent lines of evidence support the contention that female meiotic drive is the cause of the distortion. We discuss the implications and potential applications of this novel meiotic drive system.

Published

2015

15. Temporal transcriptome analysis of the chicken embryo yolk sac.

Author

Yadgary L, Wong EA, and Uni Z

Subjects

Animals, Bile metabolism, Blood Proteins biosynthesis, Chick Embryo, Chromosome Mapping, Cluster Analysis, Computational Biology, Embryonic Development, Epithelium embryology, Epithelium metabolism, Fats metabolism, Gene Expression Regulation, Developmental, Hematopoiesis genetics, Hemoglobins metabolism, Molecular Sequence Annotation, Yolk Sac cytology, Gene Expression Profiling, Transcriptome, Yolk Sac metabolism

Abstract

Background: The yolk sac (YS) is an extra-embryonic tissue that surrounds the yolk and absorbs, digests and transports nutrients during incubation of the avian embryo as well as during early term mammalian embryonic development. Understanding YS functions and development may enhance the efficient transfer of nutrients and optimize embryo development. To identify temporal large-scale patterns of gene expression and gain insights into processes and mechanisms in the YS, we performed a transcriptome study of the YS of chick embryos on embryonic days (E) E13, E15, E17, E19, and E21 (hatch)., Results: 3547 genes exhibited a significantly changed expression across days. Clustering and functional annotation of these genes as well as histological sectioning of the YS revealed that we monitored two cell types: the epithelial cells and the erythropoietic cells of the YS. We observed a significant up-regulation of epithelial genes involved in lipid transport and metabolism between E13 and E19. YS epithelial cells expressed a vast array of lipoprotein receptors and fatty acid transporters. Several lysosomal genes (CTSA, PSAP, NPC2) and apolipoproteins genes (apoA1, A2, B, C3) were among the highest expressed, reflecting the intensive digestion and re-synthesis of lipoproteins in YS epithelial cells. Genes associated with cytoskeletal structure were down-regulated between E17 and E21 supporting histological evidence of a degradation of YS epithelial cells towards hatch. Expression patterns of hemoglobin synthesis genes indicated a high erythropoietic capacity of the YS between E13 and E15, which decreased towards hatch. YS histological sections confirmed these results. We also observed that YS epithelial cells expressed high levels of genes coding for plasma carrier proteins (ALB, AFP, LTF, TTR), normally produced by the liver., Conclusions: Here we expand current knowledge on developmental, nutritional and molecular processes in the YS. We demonstrate that in the final week of chick embryonic development, the YS plays different roles to support or replace the functions of several organs that have not yet reached their full functional capacity. The YS has a similar functional role as the intestine in digestion and transport of nutrients, the liver in producing plasma carrier proteins and coagulation factors, and the bone marrow in synthesis of blood cells.

Published

2014