Phylogeographic study using nuclear genome sequences of Asip to infer the origins of ventral fur color variation in the house mouse Mus musculus.

While the house mouse (Mus musculus), widely distributed in Eurasia, is known to have substantial coat color variation between and within local populations, in both primary and secondary distribution areas, including the Japanese archipelago, the evolutionary history of the color variation is poorly understood. To address the ventral fur color variation, we quantified the lightness of museum skin specimens, and found that the southern subspecies, M. m. castaneus (CAS), has high and low lightness in dry and rainy geographic regions, respectively. The northern subspecies, M. m. musculus (MUS), has low and high levels of lightness in the high and middle latitudes of northern Eurasia, respectively. We examined sequence variation of the agouti signaling protein gene (Asip), which is known to be responsible for the ventral fur color. We performed phylogenetic analyses with 196 haplotype sequences of Asip (~180 kb) generated by phasing the whole-genome data of 98 wild mice reported previously. Network and phylogenetic tree construction revealed clustering of haplotypes representing the two subspecies, MUS and CAS. A number of subclusters with geographic affinities appeared within the subspecies clusters, in which the essential results were consistent with those reconstructed with whole mitochondrial genome data, indicating that the phased haplotype genome sequences of the nuclear genome can be a useful tool for tracing the dispersal of geographical lineages. The results of phylogeographic analysis showed that CAS mice with darker ventral fur possessed similar Asip haplotypes across the geographic distribution, suggesting that these haplotypes are major causes of the historical introduction of Asip haplotypes for darker ventral fur in mice from northern India to the peripheral areas, including the Japanese archipelago. Similarly, MUS in East Asia, which has a white abdomen, formed an Asip haplogroup with that from northern Iran, also with a white abdomen.

Reproductive isolation in hybrid mice due to spermatogenesis defects at three meiotic stages.

Early in the process of speciation, reproductive failures occur in hybrid animals between genetically diverged populations. The sterile hybrid animals are often males in mammals and they exhibit spermatogenic disruptions, resulting in decreased number and/or malformation of mature sperms. Despite the generality of this phenomenon, comparative study of phenotypes in hybrid males from various crosses has not been done, and therefore the comprehensive genetic basis of the disruption is still elusive. In this study, we characterized the spermatogenic phenotype especially during meiosis in four different cases of reproductive isolation: B6-ChrX(MSM), PGN-ChrX(MSM), (B6 × Mus musculus musculus-NJL/Ms) F(1), and (B6 × Mus spretus) F(1). The first two are consomic strains, both bearing the X chromosome of M. m. molossinus; in B6-ChrX(MSM), the genetic background is the laboratory strain C57BL/6J (predominantly M. m. domesticus), while in PGN-ChrX(MSM) the background is the PGN2/Ms strain purely derived from wild M. m. domesticus. The last two cases are F(1) hybrids between mouse subspecies or species. Each of the hybrid males exhibited cell-cycle arrest and/or apoptosis at either one or two of three distinct meiotic stages: premeiotic stage, zygotene-to-pachytene stage of prophase I, and metaphase I. This study shows that the sterility in hybrid males is caused by spermatogenic disruptions at multiple stages, suggesting that the responsible genes function in different cellular processes. Furthermore, the stages with disruptions are not correlated with the genetic distance between the respective parental strains.

Unique inbred strain MSM/Ms established from the Japanese wild mouse.

Most laboratory mice belong to a species of house mouse, Mus musculus. So far, at least three subspecies groups have been recognized; domesticus subspecies group (DOM) distributed in western Europe, musculus subspecies group (MUS) distributed in eastern Europe and northeast Asia, and castaneus subspecies group (CAS) found in southwest and southeast Asia including southern China. These subspecies are estimated to have branched off roughly one million years ago. Genetic comparison between subspecies' groups and common inbred strains (CIS) have revealed that the genetic background of CIS is derived mainly from DOM. This shows the importance of non-DOM wild mice as valuable genetic resources. We started to establish our unique strain, MSM/Ms, from MUS in Japan in 1978. In the beginning, we kept wild mice trapped in Mishima in large plastic buckets. In 1979, breeding by sister-brother mating started. The MSM/Ms inbred strain was established in 1986 and 21 years later it reached F(100). During breeding, no significant fluctuations in litter size and sex ratios have been observed. Extensive genetic analyses of chromosome C-banding pattern, biochemical markers and microsatellite DNA (MIT) markers of this strain have demonstrated the characteristics of MUS. A phylogenetic tree constructed from MIT markers has confirmed the MUS nature of MSM strain. Taken together with its genetic remoteness from CIS, MSM appears to maintain many valuable alleles for investigation of biological functions and diseases. Some of these alleles have avoided selection during breeding as either fancy mice or laboratory mice. The MSM-specific genetic traits discovered to date are discussed.

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.

Disruption of genetic interaction between two autosomal regions and the X chromosome causes reproductive isolation between mouse strains derived from different subspecies.

Reproductive isolation that initiates speciation is likely caused by incompatibility among multiple loci in organisms belonging to genetically diverging populations. Laboratory C57BL/6J mice, which predominantly originated from Mus musculus domesticus, and a MSM/Ms strain derived from Japanese wild mice (M. m. molossinus, genetically close to M. m. musculus) are reproductively isolated. Their F1 hybrids are fertile, but successive intercrosses result in sterility. A consomic strain, C57BL/6J-ChrX(MSM), which carries the X chromosome of MSM/Ms in the C57BL/6J background, shows male sterility, suggesting a genetic incompatibility of the MSM/Ms X chromosome and other C57BL/6J chromosome(s). In this study, we conducted genomewide linkage analysis and subsequent QTL analysis using the sperm shape anomaly that is the major cause of the sterility of the C57BL/6J-ChrX(MSM) males. These analyses successfully detected significant QTL on chromosomes 1 and 11 that interact with the X chromosome. The introduction of MSM/Ms chromosomes 1 and 11 into the C57BL/6J-ChrX(MSM) background failed to restore the sperm-head shape, but did partially restore fertility. This result suggests that this genetic interaction may play a crucial role in the reproductive isolation between the two strains. A detailed analysis of the male sterility by intracytoplasmic sperm injection and zona-free in vitro fertilization demonstrated that the C57BL/6J-ChrX(MSM) spermatozoa have a defect in penetration through the zona pellucida of eggs.

Hybrid breakdown caused by substitution of the X chromosome between two mouse subspecies.

Hybrid breakdown is a type of reproductive failure that appears after the F2 generation of crosses between different species or subspecies. It is caused by incompatibility between interacting genes. Genetic analysis of hybrid breakdown, particularly in higher animals, has been hampered by its complex nature (i.e., it involves more than two genes, and the phenotype is recessive). We studied hybrid breakdown using a new consomic strain, C57BL/6J-X(MSM), in which the X chromosome of C57BL/6J (derived mostly from Mus musculus domesticus) is substituted by the X chromosome of the MSM/Ms strain (M. m. molossinus). Males of this consomic strain are sterile, whereas F1 hybrids between C57BL/6J and MSM/Ms are completely fertile. The C57BL/6J-X(MSM) males showed reduced testis weight with variable defects in spermatogenesis and abnormal sperm head morphology. We conducted quantitative trait locus (QTL) analysis for these traits to map the X-linked genetic factors responsible for the sterility. This analysis successfully detected at least three distinct loci for the sperm head morphology and one for the testis weight. This study revealed that incompatibility of interactions of X-linked gene(s) with autosomal and/or Y-linked gene(s) causes the hybrid breakdown between the genetically distant C57BL/6J and MSM/Ms strains.