Genomic islands of differentiation between house mouse subspecies

Understanding the genes that contribute to reproductive isolation is essential to understanding speciation, but isolating such genes has proven very difficult. In this study I apply a multilocus test statistic to >10,000 SNP markers assayed in wild-derived inbred strains of house mice to identify genomic regions of elevated differentiation between two subspecies of house mice, Mus musculus musculus and M. m. domesticus. Differentiation was high through approximately 90% of the X chromosome. In addition, eight regions of high differentiation were identified on the autosomes, totaling 7.5% of the autosomal genome. Regions of high differentiation were confirmed by direct sequencing of samples collected from the wild. Some regions of elevated differentiation have an overrepresentation of genes with host-pathogen interactions and olfaction. The most strongly differentiated region on the X has previously been shown to fail to introgress across a hybrid zone between the two subspecies. This survey indicates autosomal regions that should also be examined for differential introgression across the hybrid zone, as containing potential genes causing hybrid unfitness.     

Investigation of the influence of the Mm musculus MyoD1 allele on the efficiency of skeletal muscle regeneration

MyoD1 alleles distinguish between the Mm musculus and Mm domesticus subspecies of Mus musculus . SJL/J mice, which belong to the Mm musculus subspecies, are able to regenerate skeletal muscle more efficiently than BALB/c mice which possess the Mm domesticus MyoD1 allele. Hence the possibility that regeneration responses are due to species-specific genetic differences including MyoD1 was investigated in this study. Quantitative morphometric analysis following muscle crush injury of 2 Mm musculus strains, MBK and MGL, has indicated that regeneration phenotype is not species-specific and may not be directly related to MyoD1 alleles. These results contrast with prior investigations conducted in SJL/J and BALB/c mice, and indicate that other genes may have a direct influence on skeletal muscle regeneration.     

Allelic variation linked to adenine phosphoribosyltransferase locus in mouse teratocarcinoma cell line and feral-derived mouse strains

Southern blot analysis reveals two distinct adenine phosphoribosyltransferase (APRT)alleles in the P-19 mouse teratocarcinoma cell line. One allele is identical to that observed in common laboratory mouse strains (Mus musculus domesticus).The restriction enzyme site variations between the two alleles occur in sequences located both upstream and downstream of the APRTgene, but not within it. Although the P-19 cell line was established from a C3H strain embryo (Mus musculus domesticus),a sixth generation ancestor of this embryo was a feral mouse (Mus musculus musculus).The restriction pattern of the variant APRTallele in P-19 is identical to that of a feral-derived Mus musculus musculusanimal, establishing the origin of this allele in the P-19 cell line. A third, distinct APRTallele was found in a Mus spretusferal-derived mouse. Exploiting the differences between the two APRTalleles in the P-19 cell line, we have demonstrated their sequential loss in APRT-deficient clones.     

Mouse inter-subspecific consomic strains for genetic dissection of quantitative complex traits

Consomic strains, also known as chromosome substitution strains, are powerful tools for assigning polygenes that control quantitative complex traits to specific chromosomes. Here, we report generation of a full set of mouse consomic strains, in which each chromosome of the common laboratory strain C57BL/6J (B6) is replaced by its counterpart from the inbred strain MSM/Ms, which is derived from Japanese wild mouse, Mus musculus molossinus. The genome sequence of MSM/Ms is divergent from that of B6, whose genome is predominantly derived from Western European wild mouse, Mus musculus domesticus. MSM/Ms exhibits a number of quantitative complex traits markedly different from those of B6. We systematically determined phenotypes of these inter-subspecific consomic strains, focusing on complex traits related to reproduction, growth, and energy metabolism. We successfully detected more than 200 statistically significant QTLs affecting 26 traits. Furthermore, phenotyping of the consomic strains revealed that the measured values for quantitative complex traits often far exceed the range between B6 host and MSM/Ms donor strains; this may result from segregation of alleles or nonadditive interactions among multiple genes derived from the two mouse subspecies (that is, epistasis). Taken together, the results suggest that the inter-subspecific consomic strains will be very useful for identification of latent genetic components underlying quantitative complex traits.     

Nomenclature and overview of the mouse (Mus musculus and Mus sp.) immunoglobulin kappa (IGK) genes

'Nomenclature and overview of the mouse (Mus musculus and Mus sp.) immunoglobulin kappa (IGK) Genes', the 19th report of the 'IMGT Locus in Focus' section, provides the first complete list of all the mouse (M. musculus) IGK genes. The mouse (M. musculus) locus spans 3,200 kb. The total number of mouse (M. musculus) IGK genes per haploid genome is 164 (174 if the orphons are included). The functional genomic repertoire comprises 93 IGKV belonging to 18 subgroups, 5 IGKJ and 1 IGKC gene. IMGT gene names and definitions of the mouse (M. musculus) IGK genes on chromosome 6 and IGK orphons are provided with the gene functionality and the number of alleles, according to the concepts of IMGT-ONTOLOGY and to rules of the IMGT Scientific chart, with the accession numbers of the IMGT reference sequences. These tables and figures are available at the IMGT Marie-Paule page of IMGT, the international ImMunoGeneTics database (http://imgt.cines.fr) created by Marie-Paule Lefranc, Université Montpellier II, CNRS, France.     

Structure and evolution of mouse interleukin 6 gene

Restriction fragment length polymorphism in the interleukin 6 gene of murine rodents extending phylogenetically from Mus musculus domesticus to the rat has been analyzed. Most species exhibit distinct restriction site patterns. In contrast, limited polymorphism was found in the tumor necrosis factor alpha gene indicating different selective pressure acting on both genes. The gene encoding interleukin 6 was isolated from a genomic library and the exon/intron organization was determined by restriction analysis and limited DNA sequence analysis. It consists of five exons which distribute over about seven kilobases, thus resembling in structure and organization the human counterpart. Furthermore, no restriction fragment length polymorphisms in the interleukin 6 gene of autoimmune strains NZB, NZW, MRL-lpr/lpr and BxSB could be detected for either EcoRI, BamHI or HindIII.     

Regional variations in the distributions of small intestinal intraepithelial lymphocytes (IELs) in outbred laboratory mice (Mus musculus domesticus) and the inbred strain of mice established from Japanese fancy mice (Mus musculus molossinus)

Previously, we reported regional variations in small intestinal IELs of mice. In this study, we examined the regional variations of IELs in outbred laboratory mice (ddY: Mus musculus domesticus) and the inbred strain of mice established from Japanese fancy mice (JF1: Mus musculus molossinus). IELs were isolated from the proximal, middle and distal parts of the small intestine and analyzed by flow cytometry. The percentages of gammadelta T cells and alphabeta T cell subset of extrathymic origin were higher in the proximal part while the percentages of alphabeta T cell subset(s) of thymic origin were higher in the distal part in both ddY and JF1 mice. Such trends in regional variations of IELs were almost the same as those found in the inbred strains of laboratory mice in our previous reports. This strongly suggests that these regional variations of IELs may be common phenomena in Mus musculus species.     

Contrasting evolution of expression differences in the testis between species and subspecies of the house mouse

Regulatory changes in genes involved in reproduction are thought to be prime targets for divergence during speciation, since they are expected to play an important role in sexual selection and sexual conflict. We used microarray analysis of RNA from different wild populations of house mouse subspecies (including Mus m. musculus, Mus m. domesticus, and Mus m. castaneus) and from the sister species Mus spretus to test this assumption. A comparison of expression divergence in brain, liver/kidney, and testis shows a major difference in the evolutionary dynamics of testis-related genes. While the comparison between species confirms an excess in divergence in testis genes, we find that all comparisons between subspecies yield only a very small number of genes with significantly different expression levels in the testis. These results suggest that the early phase of the speciation process may not be driven by regulatory changes in genes that are potential targets of sexual selection, and that the divergence in these genes is only established during a later phase of the speciation process.     

The mouse (Mus musculus) T cell receptor beta variable (TRBV), diversity (TRBD) and joining (TRBJ) genes

'The Mouse (Mus musculus) T cell Receptor Beta Variable (TRBV), Diversity (TRBD), and Joining (TRBJ) Genes', the 14th report of the 'IMGT Locus in Focus' section, comprises 8 tables entitled: (1) 'Number of mouse (Mus musculus) germline TRBV genes at 6A-C and potential repertoire'; (2) 'Mouse (Mus musculus) germline TRBV genes at 6A-C'; (3) 'Mouse (Mus musculus) TRBV allele table'; (4) 'Mouse (Mus musculus) germline TRBD genes and alleles'; (5) 'Mouse (Mus musculus) germline TRBJ genes'; (6) 'Mouse (Mus musculus) TRBJ allele table'; (7) 'Correspondence between the different mouse (Mus musculus) TRBV gene nomenclatures'; (8) 'Mouse (Mus musculus) TRBV genes and related human TRBV genes'. These tables are available at the IMGT Marie-Paule page from IMGT, the international ImMunoGeneTics database (http://imgt.cines.fr:8104) created by Marie-Paule Lefranc, Université Montpellier II, CNRS, Montpellier, France.     

The mouse (Mus musculus) T cell receptor delta variable (TRDV), diversity (TRDD) and joining (TRDJ) genes

'The Mouse (Mus musculus) T Cell Receptor Delta Variable (TRDV), Diversity (TRDD) and Joining (TRDJ) Genes', the 15th report of the 'IMGT Locus in Focus' section, comprises 7 tables entitled: (1) 'Number of mouse (Mus musculus) germline TRDV genes at 14D1-D2 and potential repertoire'; (2) 'Mouse (Mus musculus) germline TRDV genes at 14D1-D2'; (3) 'Mouse (Mus musculus) TRDV allele table'; (4) 'Mouse (Mus musculus) germline TRDD genes and alleles'; (5) 'Mouse (Mus musculus) germline TRDJ genes'; (6) 'Mouse (Mus musculus) TRDJ allele table', and (7) 'Correspondence between the different mouse (Mus musculus) TRDV gene nomenclatures'. These tables are available at the IMGT Marie-Paule page from IMGT, the international ImMunoGeneTics database (http://imgt.cines. fr:8104) created by Marie-Paule Lefranc, Université Montpellier II, CNRS, Montpellier, France.     

Breaking the species barrier: derivation of germline-competent embryonic stem cells from Mus spretus x C57BL/6 hybrids

Embryonic stem (ES) cells, which can differentiate into almost all types of cells, have been derived from the house mouse Mus musculus, rat, rabbit, humans, and other species. Transmission of the genotype to the offspring of chimeras has been achieved only with M. musculus ES cells, limiting targeted mutagenesis using ES cells to this species. Mus spretus, which exhibits many genetic polymorphisms with M. musculus, displays dominant resistance to cancer and inflammation, making derived inbred strains very useful in positional cloning and interspecies mapping. We show here for the first time the derivation of ES cells from hybrid blastocysts, obtained by the mating of two different species, namely Mus musculus and Mus spretus, and their use for the generation of chimeric mice that transmit the Mus spretus genotype and phenotype to the offspring. These hybrid ES cells allow the genetic manipulation of Mus spretus, as an alternative to Mus musculus.     

Mouse consomic strains: exploiting genetic divergence between Mus m. musculus and Mus m. domesticus subspecies

Consomic (chromosome substitution) strains (CSs) represent the most recent addition to the mouse genetic resources aimed to genetically analyze complex trait loci (QTLs). In this study, we report the development of a set of 28 mouse intersubspecific CSs. In each CS, we replaced a single chromosome of the C57BL/6J (B6) inbred strain (mostly Mus m. domesticus) with its homolog from the PWD/Ph inbred strain of the Mus m. musculus subspecies. These two progenitor subspecies diverged less than 1 million years ago and accumulated a large number of genetic differences that constitute a rich resource of genetic variation for QTL analyses. Altogether, the 18 consomic, nine subconsomic, and one conplastic strain covered all 19 autosomes, X and Y sex chromosomes, and mitochondrial DNA. Most CSs had significantly lower reproductive fitness compared with the progenitor strains. CSs homosomic for chromosomes 10 and 11, and the C57BL/6J-Chr X males, failed to reproduce and were substituted by less affected subconsomics carrying either a proximal, central, or distal part of the respective chromosome. A genome-wide scan of 965 DNA markers revealed 99.87% purity of the B6 genetic background. Thirty-three nonsynonymous substitutions were uncovered in the protein-coding regions of the mitochondrial DNA of the B6.PWD-mt conplastic strain. A pilot-phenotyping experiment project revealed a high number of variations among B6.PWD consomics.     

Specific sequence deletions in two classes of murine leukemia virus-related proviruses in the mouse genome

Characteristic long terminal repeats (LTR) of approximately 700 and 750 bp were found, respectively, in the two classes (polytropic and modified polytropic) of murine leukemia virus (MuLV)-related nonecotropic nonxenotropic proviral sequences in eight individual molecular clones of RFM/Un mouse chromosomal DNA fragments. Three proviral clones, two polytropic and one modified polytropic, contained sequence deletions in the viral structural genes. Nucleotide sequence analysis revealed that 7-bp direct repeats occur at both ends of deleted sequences in intact structures and one of the repeats remains in genomes with the deletion. Specifically, the deleted sequences were a 1487-bp gag-pol sequence with ACTGCCC repeat, a 113-bp mid-pol sequence with CAGGCAA repeat, and a 1811-bp env sequence with GGTCCAG repeat. The same specific sequence deletions were found in both classes of MuLV-related proviral structures. Examination of chromosomal DNA from eight inbred laboratory mouse strains and six wild mouse species showed that a minor population of proviruses with these specific deletions were present in Mus musculus and Mus spretus, all of which contain prominent 700-bp LTR polytropic proviral structures. The 750-bp LTR modified polytropic proviral structures were phylogenetically more restricted, being equally predominant in Mus musculus domesticus mice, but minor to undetectable in Mus spretus subspecies, and absent in other wild mouse populations.     

Hippocampal Morphology and Open-Field Behavior in Mus musculus domesticus and Mus spretus Inbred Mice

Mus spretus is extensively used in interspecific mouse backcross analyses employed to generate genetic linkage maps. However, little is known about its behavior and neuroanatomy, phenotypes for which large interstrain differences have been observed in Mus musculus domesticus. Behavioral and hippocampai neuroanatomical variables were measured in adult male mice from the inbred strains C57BL/6J (Mus musculus domesticus) and SEG (Mus spretus). Clear differences were found for behavioral responses to novelty in an open field, SEG being much less active than C57BL/6J. Morphometrical analysis of hippocampai terminal fields, visualized with Timm's stain, revealed strain differences only for the size of the intra- and infrapyramidal mossy fiber terminal fields, which were about 3× larger in C57BL/6J than in SEG. In addition, absolute left-right differences were larger in SEG for the stratum radiatum and stratum oriens. In spite of these behavioral and neuroanatomical differences, the phenotypical scores obtained for SEG do not exceed the range observed for Mus musculus domesticus inbred strains.     

Potential significance of genomic imprinting defects for reproduction and assisted reproductive technology

Recent studies suggest a possible link between human assisted reproductive technology and genomic imprinting disorders. Assisted reproductive technology includes the isolation, handling and culture of gametes and early embryos at times when imprinted genes are likely to be particularly vulnerable to external influences. Evidence of sex-specific differences in imprint acquisition suggests that male and female germ cells may be susceptible to perturbations in imprinted genes at specific prenatal and postnatal stages. Imprints acquired first during gametogenesis must be maintained during preimplantation development when reprogramming of the overall genome occurs. In this review, we will discuss both new developments in our understanding of genomic imprinting including the mechanisms and timing of imprint erasure, acquisition and maintenance during germ cell development and early embryogenesis as well as the implications of this research for future epigenetic studies in reproduction and assisted reproductive technology.     

SLAM: cross-species gene finding and alignment with a generalized pair hidden Markov model

Comparative-based gene recognition is driven by the principle that conserved regions between related organisms are more likely than divergent regions to be coding. We describe a probabilistic framework for gene structure and alignment that can be used to simultaneously find both the gene structure and alignment of two syntenic genomic regions. A key feature of the method is the ability to enhance gene predictions by finding the best alignment between two syntenic sequences, while at the same time finding biologically meaningful alignments that preserve the correspondence between coding exons. Our probabilistic framework is the generalized pair hidden Markov model, a hybrid of (1). generalized hidden Markov models, which have been used previously for gene finding, and (2). pair hidden Markov models, which have applications to sequence alignment. We have built a gene finding and alignment program called SLAM, which aligns and identifies complete exon/intron structures of genes in two related but unannotated sequences of DNA. SLAM is able to reliably predict gene structures for any suitably related pair of organisms, most notably with fewer false-positive predictions compared to previous methods (examples are provided for Homo sapiens/Mus musculus and Plasmodium falciparum/Plasmodium vivax comparisons). Accuracy is obtained by distinguishing conserved noncoding sequence (CNS) from conserved coding sequence. CNS annotation is a novel feature of SLAM and may be useful for the annotation of UTRs, regulatory elements, and other noncoding features.     

The evolutionary turnover of recombination hot spots contributes to speciation in mice

Meiotic recombination is required for the segregation of homologous chromosomes and is essential for fertility. In most mammals, the DNA double-strand breaks (DSBs) that initiate meiotic recombination are directed to a subset of genomic loci (hot spots) by sequence-specific binding of the PRDM9 protein. Rapid evolution of the DNA-binding specificity of PRDM9 and gradual erosion of PRDM9-binding sites by gene conversion will alter the recombination landscape over time. To better understand the evolutionary turnover of recombination hot spots and its consequences, we mapped DSB hot spots in four major subspecies of Mus musculus with different Prdm9 alleles and in their F1 hybrids. We found that hot spot erosion governs the preferential usage of some Prdm9 alleles over others in hybrid mice and increases sequence diversity specifically at hot spots that become active in the hybrids. As crossovers are disfavored at such hot spots, we propose that sequence divergence generated by hot spot turnover may create an impediment for recombination in hybrids, potentially leading to reduced fertility and, eventually, speciation.