Physical performance and soleus muscle fiber composition in wild-derived and laboratory inbred mouse strains.

We compared four inbred mouse strains in their physical performance, measured as a maximal treadmill running time, characteristics of soleus muscle, anatomic character, and growth. The strains used were Mus musculus domesticus [C57BL/6 (B6) and BALB/c], Mus musculus molossinus (MSM/Ms), and Mus spretus. Maximal running time was significantly different among these four mouse strains. Running time until exhaustion was highest in MSM/Ms and lowest in M. spretus. Maximal times for the laboratory mouse strains were nearly identical. Soleus muscle fiber type and cross-sectional area also differed significantly among the species. In particular, M. spretus was significantly different from the other inbred mouse strains. Growth in the wild-derived inbred mice appeared to be complete earlier than in the laboratory mice, and the body size of the wild strains was about half that of the laboratory strains. From these results, we propose that wild-derived inbred mouse strains are useful models for enhancing phenotypic variation in physical performance and adaptability.     

Altered Turnover of Hypoxanthine Phosphoribosyltransferase in Erythroid Cells of Mice Expressing Hprt a and Hprt b Alleles

We have previously shown that mice expressing Hprt a allele(s) have erythrocyte hypoxanthine phosphoribosyltransferase (HPRT) levels that are approximately 25-fold (Mus musculus castaneus) and 70-fold (Mus spretus) higher than in mice that express the Hprt b allele (Mus musculus domesticus; C57BI/6J; C3H/HeHa), and that these differences in erythrocyte HPRT levels are due to differences in the turnover rates of the HPRT A and B proteins as reticulocytes mature to erythrocytes. We show here that: the taxonomic subgroups of the genus Mus are essentially monomorphic for the occurrence of either the Hprt a or the Hprt b allele, with Hprt a being common in the aboriginal species (M. spretus, Mus hortulanus and Mus abbotti) and in several commensal species (Mus musculus musculus, M. m. castaneus, Mus musculus molossinus), while Hprt b is common in feral M. m. domesticus populations as well as in all inbred strains of mice tested; in all these diverse Mus subgroups there is a strict association of Hprt a with high and Hprt b with low levels of erythrocyte HPRT; and, the association between the occurrence of the Hprt a allele and elevated erythrocyte HPRT levels is retained following repeated backcrosses of wild-derived Hprt a allele(s) into the genetic background of inbred strains of mice with the Hprt b allele. Collectively, these observations indicate that the elevated and low levels of erythrocyte HPRT are specified by differences in the Hprt a and b structural genes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Polymorphism of C lambda genes and units of duplication in the genus Mus

The number of Ig C lambda genes in nine geographically widespread species from the four subgenera in the genus Mus was estimated from the number of Bam HI and Eco RI restriction fragments that hybridize under high stringency conditions to cDNA probes of BALB/c inbred mouse origin (Mus musculus domesticus). Three closely related species in the subgenus Mus, M. musculus, M. spretus, and M. spicelegus, show considerable variation in the number of C lambda genes. Estimates of gene numbers in these animals range from two C lambda genes in M. spretus from Puerto Real, Spain to 12 C lambda genes in M. musculus musculus from Studenec, Czechoslovakia. Strains of mice carrying either six or 10 C lambda genes were derived from a single population of M. musculus domesticus from Centreville, MD. The hybridization patterns of mice exhibiting C lambda gene amplification indicate that duplications are of relatively recent origin and probably occurred by reiteration of a DNA segment closely related to the 6.5 kb [C lambda 3 - C lambda 1] unit found in BALB/c inbred mice. Three more distantly related species in the subgenus Mus, and a species representing the Nannomys subgenus all appear to carry only four C lambda genes. DNA of species representing the Coelomys and Pyromys subgenera hybridized weakly to the C lambda cDNA probes, but these animals also have no more than four C lambda genes. Thus, there may be a base number of four C lambda genes in most species in the genus Mus. All inbred strains of mice so far examined also have only four C lambda genes, but no feral M. musculus examined have fewer than six C lambda genes. One explanation of the discrepancy in the number of genes between inbred and feral M. musculus is that C lambda genes were deleted during the process of inbreeding.     

Structures of endogenous nonecotropic murine leukemia virus (MLV) long terminal repeats in wild mice: implication for evolution of MLVs

To develop a better understanding of the interaction between retroviruses and their hosts, we have investigated the polymorphism in endogenous murine leukemia proviruses (MLVs). We used genomic libraries of wild mouse DNAs and PCR to analyze genetic variation in the proviruses found in wild mouse species, including Mus musculus (M. m. castaneus, M. m. musculus, M. m. molossinus, and M. m. domesticus), Mus spretus, and Mus spicelegus, as well as some inbred laboratory strains. In this analysis, we detected several unique forms of sequence organization in the U3 regions of the long terminal repeats of these proviruses. The distribution of the proviruses with unique U3 structures demonstrated that xenotropic MLV-related proviruses were present only in M. musculus subspecies, while polytropic MLV-related proviruses were found in both M. musculus and M. spretus. Furthermore, one unique provirus from M. spicelegus was found to be equidistant from ecotropic provirus and nonecotropic provirus by phylogenetic analysis. This provirus, termed HEMV, was thus likely to be related to the common ancestor of these MLVs. Moreover, an ancestral type of polytropic MLV-related provirus was detected in M. spretus species. Despite their "ancestral" phylogenetic position, proviruses of these types are not widespread in mice, implying more-recent spread by infection rather than inheritance. These results imply that recent evolution of these proviruses involved alternating periods of replication as virus and residence in the germ line.     

Variation in V lambda genes in the genus Mus

The complement of Ig V lambda genes in nine species of feral mice representing the four extant subgenera of the genus Mus was examined and compared with that of BALB/c inbred mice. Although all inbred strains examined have two V lambda genes, there is variation in the number of copies of V lambda genes in the wild mice. All feral representatives of M. musculus domesticus, from which inbred strains are derived, have at least three V lambda genes, indicating that a V lambda gene may have been lost during the inbreeding process. At least three V lambda genes are also found in representatives of three other M. musculus subspecies, including the stock of M. musculus musculus "Czech II" shown to have at least 12 C lambda genes. In comparing the complement of V lambda and C lambda genes in these animals, evidence is found that supports a mechanism of lambda gene reiteration involving duplication of a unit containing a V lambda and two C lambda genes. However, the possibility that C lambda gene amplification occurred independent of V lambda gene evolution cannot be ruled out. M. spicelegus and M. spretus, species that are semifertile with M. musculus, have one to three V lambda genes. Species more distantly related to M. musculus, such as M. cookii and M. platythrix, appear to have more (four to six) V lambda genes. Greater V lambda gene heterogeneity is also found in these animals. We propose that the ancestors of the subgenus Mus had more V lambda genes than are seen in modern species and that the paucity of V lambda genes in M. musculus, M. spicelegus, and M. spretus may be the result of V lambda gene deletion events that occurred since the divergence of the ancestor of these three species and those of the distantly related species.     

Mus Spretus Line-1 Sequences Detected in the Mus Musculus Inbred Strain C57bl/6j Using Line-1 DNA Probes

The inbred mouse strain, C57BL/6J, was derived from mice of the Mus musculus complex. C57BL/6J can be crossed in the laboratory with a closely related mouse species, M. spretus to produce fertile offspring; however there has been no previous evidence of gene flow between M. spretus and M. musculus in nature. Analysis of the repetitive sequence LINE-1, using both direct sequence analysis and genomic Southern blot hybridization to species-specific LINE-1 hybridization probes, demonstrates the presence of LINE-1 elements in C57BL/6J that were derived from the species M. spretus. These spretus-like LINE-1 elements in C57BL/6J reveal a cross to M. spretus somewhere in the history of C57BL/6J. It is unclear if the spretus-like LINE-1 elements are still embedded in flanking DNA derived from M. spretus or if they have transposed to new sites. The number of spretus-like elements detected suggests a maximum of 6.5% of the C57BL/6J genome may be derived from M. spretus.     

B1 insertions as easy markers for mouse population studies

Few simple, easy-to-score PCR markers are available for studying genetic variation in wild mice populations belonging to Mus musculus at the population and subspecific levels. In this study, we show the abundant B1 family of short interspersed DNA elements (SINEs) is a very promising source of such markers. Thirteen B1 sequences from different regions of the genome were retrieved on the basis of their high degree of homology to a mouse consensus sequence, and the presence of these elements was screened for in wild derived mice representing M. spretus, macedonicus and spicilegus and the different subspecies of M. musculus. At five of these loci, varying degrees of insertion polymorphism were found in M. m. domesticus mice. These insertions were almost totally absent in the mice representing the other subspecies and species. Six other B1 elements were fixed in all the Mus species tested. At these loci, polymorphism associated with three restriction sites in the B1 consensus sequence was found in M. musculus. Most of these polymorphisms appear to be ancestral as they are shared by at least one of the other Mus species tested. Both insertion and restriction polymorphism revealed differences between five inbred laboratory strains considered to be of mainly domesticus origin, and at the six restriction loci a surprising number of these strains carried restriction variants that were either not found or very infrequent in domesticus. This suggests that in this particular group of loci, alleles of far Eastern origin are more frequent than expected.     

Segregation distortion of X-linked marker genes in interspecific crosses between Mus musculus and M. spretus

An interspecific cross was made between females of the C3H/HeHa.Pgk-1 a inbred laboratory strain of Mus musculus and males of the separate species Mus spretus. The F1 males are sterile but the F1 females are fertile and they were backcrossed to both C3H and spretus males. Evidence is presented from the segregation of X-linked marker genes that the interspecific F1 female has a genetically deleterious effect on the C3H X chromosome that is expressed as a male-lethal effect with the spretus Y chromosome but not with the musculus Y chromosome of C3H.     

Mx1 causes resistance against influenza A viruses in the Mus spretus-derived inbred mouse strain SPRET/Ei

Inbred SPRET/Ei mice, derived from Mus spretus, were found to be extremely resistant to infection with a mouse adapted influenza A virus. The resistance was strongly linked to distal chromosome 16, where the interferon-inducible Mx1 gene is located. This gene encodes for the Mx1 protein which stimulates innate immunity to Orthomyxoviruses. The Mx1 gene is defective in most inbred mouse strains, but PCR revealed that SPRET/Ei carries a functional allele. The Mx1 proteins of M. spretus and A2G, the other major resistant strain derived from Mus musculus, share 95.7% identity. We were interested whether the sequence variations between the two Mx1 alleles have functional significance. To address this, we used congenic mouse strains containing the Mx1 gene from M. spretus or A2G in a C57BL/6 background. Using a highly pathogenic influenza virus strain, we found that the B6.spretus-Mx1 congenic mice were better protected against infection than the B6.A2G-Mx1 mice. This effect may be due to different Mx1 induction levels, as was shown by RT-PCR and Western blot. We conclude that SPRET/Ei is a novel Mx1-positive inbred strain useful to study the biology of Mx1.     

Segregation of restriction fragment length polymorphism in an interspecies cross of laboratory and wild mice indicates tight linkage of the murine IFN-beta gene to the murine IFN-alpha genes.

Southern blot analysis with murine (Mu) interferon (IFN)-alpha cDNA of restricted genomic DNA of three inbred strains of mice belonging to the species Mus musculus domesticus (BALB/c, C57BL/6, and DBA/2) revealed only a limited degree of polymorphism. For example, with HindIII there were only two polymorphic bands out of 14 hybridizing fragments. With Mu IFN-beta cDNA there was no polymorphism at all between BALB/c and C57BL/6 in DNA restricted with seven different enzymes. In contrast, HindIII-restricted DNA of an inbred strain of wild mice (M. spretus Lataste) hybridized with the IFN-alpha probe displayed a high degree of polymorphism compared with the three strains of laboratory mice and was also polymorphic when probed with IFN-beta cDNA. Although M. musculus domesticus and M. spretus Lataste represent different species, certain interspecies crosses are possible in the laboratory. This enabled us to follow segregation of restriction fragment length polymorphism in HindIII-restricted DNA obtained from 18 backcross progeny of a (DBA/2 X M. spretus)F1 X DBA/2 interspecies cross. There was complete coincidence between the segregation of parental (DBA/2) and (DBA/2 X M. spretus)F1-type IFN-beta and IFN-alpha restriction fragment length polymorphism, indicating tight linkage of the IFN-beta and IFN-alpha genes. In addition, in 15 of 18 progeny the segregation coincided with that of the brown locus on chromosome 4, in accord with previous results obtained with the IFN-alpha probe in strains derived from crosses between BALB/c and C57BL/6 mice. Thus, the Mu IFN-beta gene is tightly linked to the Mu IFN-alpha gene cluster on chromosome 4 near the brown locus.     

Diverse wild mouse origins of xenotropic, mink cell focus-forming, and two types of ecotropic proviral genes

We analyzed wild mouse DNAs for the number and type of proviral genes related to the env sequences of various murine leukemia viruses (MuLVs). Only Mus species closely related to laboratory mice carried these retroviral sequences, and the different subclasses of viral env genes tended to be restricted to specific taxonomic groups. Only Mus musculus molossinus carried proviral genes which cross-reacted with the inbred mouse ecotropic MuLV env gene. The ecotropic viral env sequence associated with the Fv-4 resistance gene was found in the Asian mice M. musculus molossinus and Mus musculus castaneus and in California mice from Lake Casitas (LC). Both M. musculus castaneus and LC mice carried many additional Fv-4 env-related proviruses, two of which are common to both mouse populations, which suggests that these mice share a recent common ancestry. Xenotropic and mink cell focus-forming (MCF) virus env sequences were more widely dispersed in wild mice than the ecotropic viral env genes, which suggests that nonecotropic MuLVs were integrated into the Mus germ line at an earlier date. Xenotropic MuLVs represented the major component of MuLV env-reactive genes in Asian and eastern European mice classified as M. musculus molossinus, M. musculus castaneus, and Mus musculus musculus, whereas Mus musculus domesticus from western Europe, the Mediterranean, and North America contained almost exclusively MCF virus env copies. M. musculus musculus mice from central Europe trapped near the M. musculus domesticus/M. musculus musculus hybrid zone carried multiple copies of both types of env genes. LC mice also carried both xenotropic and MCF viral env genes, which is consistent with the above conclusion that they represent natural hybrids of M. musculus domesticus and M. musculus castaneus.     

Genome comparison in the genus Mus: a study with B1, MIF (mouse interspersed fragment), centromeric, and Y-chromosomal repetitive sequences

Using four repetitive sequences, we compared DNAs isolated from Mus caroli, M. cookii, M. hortulanus, M. musculus, M. pahari, M. saxicola, and M. spretus. Except for B1, these probes showed species-specific hybridization patterns. Mouse interspersed fragment (MIF) sequences were present in all species examined, but those defined by the 1.3-kb EcoR1 band were fewer in M. pahari and M. saxicola than in the other species. The Y-chromosomal probe showed male-specific accumulation only in M. hortulanus, M. musculus, and M. spretus, which are known to be closely related. The genetic difference between M. spretus and the other two species (M. hortulanus and M. musculus) was clearly demonstrated by a M. musuclus centromeric sequence that hybridized strongly to M. hortulanus and M. musculus DNA but was underrepresented in the genome of M. spretus. These results may suggest the usefulness of these repetitive sequences in the classification of Mus species that display only subtle morphological differences.     

Mus musculus and Mus spretus homologues of the human telomere-associated protein TIN2

Telomere length is regulated by TRF1, which binds telomeric DNA, and TIN2, which binds TRF1. Laboratory mice (Mus musculus) have long telomeres, although a related mouse species, Mus spretus, has human-sized telomeres. Because differences in TIN2 might explain these differences in telomere length, we cloned cDNAs encoding murine TIN2s and compared their sequence to that of human TIN2. M. musculus (Mm) and M. spretus TIN2s were >95% identical, but shared only 67% identity with human TIN2. An N-terminal truncation, or N-terminal fragment, of MmTIN2 elongated M. spretus telomeres. These findings suggest that mouse TIN2, like human TIN2, negatively regulates telomere length, and that N-terminal perturbations have dominant-negative effects. Our findings suggest that differences in TIN2 cannot explain the telomere length differences among Homo sapiens, M. musculus, and M. spretus. Nonetheless, M. spretus cells appear be a good system for studying the function of mouse telomere-associated proteins.     

Analysis of wild-derived mice for Fv-1 and Fv-2 murine leukemia virus restriction loci: a novel wild mouse Fv-1 allele responsible for lack of host range restriction.

Wild-derived mice originally obtained from Asia, Africa, North America, and Europe were typed for in vitro sensitivity to ecotropic murine leukemia viruses and for susceptibility to Friend virus-induced disease. Cell cultures established from some wild mouse populations were generally less sensitive to exogenous virus than were cell cultures from laboratory mice. Wild mice also differed from inbred strains in their in vitro sensitivity to the host range subgroups defined by restriction at the Fv-1 locus. None of the wild mice showed the Fv-1n or Fv-1b restriction patterns characteristic of most inbred strains, several mice resembled the few inbred strains carrying Fv-1nr, and most differed from laboratory mice in that they did not restrict either N- or B-tropic murine leukemia viruses. Analysis of genetic crosses of Mus spretus and Mus musculus praetextus demonstrated that the nonrestrictive phenotype is controlled by a novel allele at the Fv-1 locus, designated Fv-10. The wild mice were also tested for sensitivity to Friend virus complex-induced erythroblastosis to type for Fv-2. Only M. spretus was resistant to virus-induced splenomegaly and did not restrict replication of Friend virus helper murine leukemia virus. Genetic studies confirmed that this mouse carries the resistance allele at Fv-2.     

Genetic dissection of X-linked interspecific hybrid placental dysplasia in congenic mouse strains.

Interspecific hybridization in the genus Mus results in male sterility and X-linked placental dysplasia. We have generated several congenic laboratory mouse lines (Mus musculus) in which different parts of the maternal X chromosome were derived from M. spretus. A strict positive correlation between placental weight and length of the M. spretus-derived part of the X chromosome was shown. Detailed analysis was carried out with one congenic strain that retained a M. spretus interval between 12.0 and 30.74 cM. This strain consistently produced hyperplastic placentas that exhibited an average weight increase of 180% over the weight of control placentas. In derived subcongenic strains, however, increased placental weight could no longer be observed. Morphometric analysis of these placentas revealed persistence of abnormal morphology. Fully developed placental hyperplasia could be reconstituted by recombination of proximal and central M. spretus intervals with an intervening M. musculus region. These results may suggest that placental dysplasia of interspecific mouse hybrids is caused by multiple loci clustered on the X chromosome that act synergistically. Alternatively, it is possible that changes in chromatin structure in interspecific hybrids that influence gene expression are dependent on the length of the alien chromosome.     

Mus Spretus Line-1s in the Mus Musculus Domesticus Inbred Strain C57bl/6j Are from Two Different Mus Spretus Line-1 Subfamilies

A LINE-1 element, L1C105, was found in the Mus musculus domesticus inbred strain, C57BL/6J. Upon sequencing, this element was found to belong to a M. spretus LINE-1 subfamily originating within the last 0.2 million years. This is the second spretus-specific LINE-1 subfamily found to be represented in C57BL/6J. Although it is unclear how these M. spretus LINE-1s transferred from M. spretus to M. m. domesticus, it is now clear that at least two different spretus LINE-1 sequences have recently transferred. The limited divergence between the C57BL/6J spretus-like LINE-1s and their closest spretus ancestors suggests that the transfer did not involve an exceptionally long lineage of sequential transpositions.     

Diversity of mammary tumor viral genes within the genus Mus, the species Mus musculus, and the strain C3H.

Proviral sequences complementary to the C3H mouse mammary tumor virus RNA genome are present in the DNA of early occurring mammary tumors of C3H/HeN mice and are absent from apparently normal C3H/HeN tissues; these sequences are non-germ line transmitted in C3H/HeN mice and have been termed tumor-associated sequences; (W. Drohan et al., J. Virol. 21:986-995, 1977). We report here that tumor-associated sequences are present in the DNA of spontaneous mammary tumors that occur early in the life of several inbred, high-tumor-incidence mouse strains but are absent in mammary tumors that occur later in life in low- and moderate-tumor-incidence strains. These sequences are also absent in apparently normal organs tested from numerous laboratory mouse strains, feral mice, Mus musculus subspecies, and other Mus species. Sequences represented in tumor-associated sequence RNA, however, are present as endogenous provirus in GR mice (at approximately four copies per haploid genome) and in two of five substrains of C3H mice tested (at approximately one copy per haploid genome). The two substrains of C3H mice positive for endogenous tumor-associated sequence provirus were recently (circa 1930) separated from the negative substrains of C3H mice. The results may be explained by the unlikely chance segregation of proviral sequences or by the recent integration of viral genes (within the last few decades). Whereas radioactively labeled mouse mammary tumor virus 60-70S RNA or complementary DNA detected mouse mammary tumor virus-related proviral information in all laboratory mouse strains, feral mice, subspecies of M. musculus, and other species of Mus, the use of tumor-associated sequence RNA clearly revealed the genetic diversity that may exist between different colonies or substrains of "inbred" laboratory mice commonly used in cancer research.     

The amplified long genomic sequence (ALGS) located in the centromeric regions of mouse chromosomes.

We reported previously that the haploid genome of standard strains of laboratory mice contains approximately 70 copies of an amplified long genomic sequence, designated ALGS, that includes a retroposon of the gene for elongation factor 2 (MER). The length of each repeating unit is more than 60 kb, and the sequence of the unit is highly conserved among the repeats. In the present study, Southern blot analysis of the genomes of wild rodents demonstrated that the ALGS is present in all subspecies of Mus musculus and is abundant in M. spicilegus, whereas it is absent in M. spretus as well as in Rattus and other closely related genera. This result indicates that the amplification occurred after the species differentiation with the genus Mus and at least prior to the differentiation of subspecies of M. musculus. To locate chromosomal positions of the ALGS, in situ hybridization was carried out with laboratory strains and wild mice. It appears that the ALGS is located in the centromeric regions of most chromosomes in laboratory mice, M. musculus and M. spicilegus, whereas no positive signals were observed with M. spretus, in accordance with the results from the Southern blotting analysis.     

Isolation and Characterization of a Mouse Y Chromosomal Repetitive Sequence

The Y chromosome plays a dominant role in mammalian sex determination, and characterization of this chromosome is essential to understand the mechanism responsible for testicular differentiation. Male mouse genomic DNA fragments, cloned into pBR322, were screened for the presence of Bkm (a female snake satellite DNA)-related sequences, and we obtained a clone (AC11) having a DNA fragment from the mouse Y chromosome. In addition to a Bkm-related sequence, this fragment contained a Y chromosomal repetitive sequence. DNA isolated from the XX sex-reversed male genome produced a hybridization pattern indistinguishable to that obtained with normal female DNA, suggesting that the AC11 sequence is not contained within the Y chromosomal DNA present in the sex-reversed male genome. Based on the hybridization patterns against mouse Y chromosomal DNA, AC11 classified 16 inbred laboratory strains into two categories; those with the Mus musculus musculus type Y chromosome and those with the M.m. domesticus type Y chromosome. Three European subspecies of Mus musculus (M.m. brevirostris, M.m. poschiavinus and M.m. praetextus) possessed the M.m. domesticus type Y chromosome, whereas the Japanese mouse, M.m. molossinus, had the M.m. musculus type Y chromosome. The survey was also extended to six other species that belong to the genus Mus, of which M. spretus and M. hortulamus showed significant amounts of AC11-related sequences in their Y chromosomes. The male-specific accumulation of AC11-related sequences was not found in M. caroli, M. cookii, M. pahari or M. platythrix. This marked difference among Mus species indicates that the amplification of AC11-related sequences in the mouse Y chromosome was a recent evolutionary event.