Organization and evolutionary progress of a dispersed repetitive family of sequences in widely separated rodent genomes

The genomes of Mus musculus and other rodent species share a long conserved family of sequences that are dispersed and abundant (approx. 20,000 copies), and that have several novel features of organization and evolution. EcoR1 restriction of M. musculus DNA reveals a prominent 1350 bp² set of sequences. Two nonhomologous sequences of 850 and 500 bp, representing almost the total population of the 1350 bp repeats, were used to examine the detailed organization of the dispersed family and its surrounding sequences using a combination of restriction analysis and “Southern” hybridization. The 1350 bp sequence is contained within a longer repeating unit of approximately 3 kb that is dispersed amongst a wide variety of non-homologous and seemingly non-repetitive sequences. At some sites within the 3 kb repeat, considerable sequence heterogeneity has been found between members of the family, such that the family can be divided into largely non-overlapping subsets (or “segments”) according to the positioning of HinIII sites. Underlying the segmental organization there is a low background overlap of each segment with every other. Some but not all members of the family and its variants have been located on the X-chromosome in a Chinese hamster, M. musculus, X chromosome cell line: suggesting a wide genomic dispersion of the family. Homologous repeated sequences to the M. musculus 1350 bp repeat have been identified in species of Mus and Apodemus, with strikingly similar features of organization and dispersion. In M. spretus a 1350 bp sequence is contained within a dispersed repeat of at least 2·9 kb. However, the majority of M. spretus repeats contain an additional restriction site not present in the equivalent M. musculus array, suggesting a mechanism of widespread substitution or “conversion” of one variant by another in each genome. Apodemus sylvaticus possesses two dispersed and homologous families of 1350 bp and 1850 bp repetition, respectively, which contain sequences that have diverged from M. musculus to differing extents. A. mystacinus possesses only one family of dispersed and homologous repeats of 1850 bp. The majority of members within each Apodemus homologous family also contain characteristic variant restriction-site arrangements. The mechanisms underlying the spread of such variants within each array; the generation of segmental patterns; and the evolutionary conservation of this mouse interspersed family (MIF-1) are discussed in relation to the present knowledge of the organization and activity of other dispersed sequence families.     

Evolution of a long-range repeat family in Chromosome 1 of the genus Mus

Copy numbers and variation of a clustered long-range repeat family on Chromosome (Chr) 1 have been studied in different species of the genus Mus. The repeat sequence was present in all, as inferred from cross-hybridization with probes derived from the Mus musculus repeat family. Copy numbers determined by dot blot hybridization were very low, from three to six per haploid genome in M. caroli, M. cervicolor, and M. cookii. These species form one branch of the phylogenetic tree in the genus Mus. In the other group of phylogenetically related species—M. spicilegus, M. spretus, M. musculus and M. macedonicus—copy numbers ranged from 6 to 1810 per haploid genome. The repeat cluster is cytogenetically visible as a fine C-band in M. macedonicus and as a C-band positive homogeneously staining region (HSR) in several populations of M. m. domesticus and M. m. musculus. When cytogenetically visible, the clusters contained from 179 to 1810 repeats. Intragenomic restriction fragment length polymorphisms (RFLPs), which reflect sequence variation among different copies of the long-range repeat family, increased with higher copy numbers. The high similarity of the RFLP pattern among genomes with C-band positive regions in Chr 1 of M. m. musculus, M. m. domesticus, and M. macedonicus points to a close evolutionary relationship of their Chr 1 repeat families.     

Polymorphic HSRs in chromosome 1 of the two semispecies Mus musculus musculus and M. m. domesticus have a common origin in an ancestral population

HSRs (homogeneously staining regions) are the cytological correlates of DNA amplification. In the house mouse, Mus musculus, many populations are polymorphic for the presence or absence of HSRs on chromosome 1. In the semispecies M. m. domesticus the amplified DNA is present within one HSR, whereas in M. m. musculus chromosomes 1 with two HSRs are found. Hybridization of HSR-specific probes to Southern blots of HSR-carrying genomic DNAs from different localities and semispecies revealed similar complex band patterns. the remaining variation is restricted to sequences with a low degree of amplification. Variation is higher between semispecies than within one semispecies. It is assumed that HSRs are derived from one original amplification event and that unequal recombination is the mechanism underlying the length variation of HSRs present today in both semispecies. Evidence from G-banding and in situ hybridization shows that the two HSRs of M. m. musculus originated from a single HSR by means of a paracentric inversion, where one break-point was located within the single HSR and the second outside the HSR. As a consequence of the paracentric inversion the two HSRs of M. m. musculus are permanently linked together. Since exchange of genes between the two semispecies is restricted to a narrow hybrid zone the amplification that gave rise to the HSR most probably occurred prior to the divergence into the semispecies M. m. domesticus and M. m. musculus about 1 million years ago.by D. Schweizer     

Gene flow of unique sequences between Mus musculus domesticus and Mus spretus

Allelic diversity has been examined from a variety of Mus musculus subspecies and Mus spretus strains by sequencing at a 453-bp unique sequence locus. One M. m. domesticus classic inbred strain, C57BL/KsJ, contained a sequence identical to that in the M. spretus wild-derived inbred strain SEG, and other wild M. spretus isolates. Such a result should have been precluded by the expected divergence between the species unless there has been interspecies gene flow. Examination of C57BL/KsJ for M. spretus-specific repetitive sequences shows that it is neither a mis-identified spretus strain nor a domesticus/spretus hybrid. Thus, in addition to the previously reported presence of small amounts of Mus spretus-specific repetitive DNA in M. m. domesticus, there is a detectable flow of unique sequence between the two species. There was also ancestral polymorphism observed among the spretus alleles. The difficulty of distinguishing ancestral polymorphism from horizontal transfer is discussed. Received: 14 May 1999 / Accepted: 5 November 1999     

Phylogenetic relationship and time of divergence of <Emphasis Type="Italic">Mus terricolor</Emphasis> with reference to other <Emphasis Type="Italic">Mus</Emphasis> species

Mitochondrial DNA control region of Mus terricolor, three aboriginal species M. spretus, M. macedonicus, M. spicilegus; the Asian lineage M. caroli, M. cervicolor, M. cookii; and the two house mice, M. musculus domesticus and M. m. castaneus were analysed to estimate the substitution rate, phylogenetic relationship and the probable time of divergence. Results showed that M. spretus, M. caroli and M. terricolor are highly diverged from each other (caroli/terricolor = 0.146, caroli/spretus = 0.147 and terricolor/spretus = 0.122), whereas M. spretus showed less divergence with two house mice species (0.070 and 0.071). Sequence divergence between M. terricolor and the Palearctic group were found to be ranging from 0.121 to 0.134. Phylogenetic analysis by minimum evolution, neighbour-joining, unweighed pair group method with arithmetic mean and maximum parsimony showed almost similar topology. Two major clusters were found, one included the Asian lineage, M. caroli, M. cookii and M. cervicolor and the other included the house mice M. m. domesticus, M. m. castaneus and the aboriginal mice M. macedonicus and M. spicilegus along with M. spretus, forming the Palearctic clade. M. terricolor was positioned between the Palearctic and Asian clades. Results showed that Palearctic-terricolor and the Asian lineages diverged 5.47 million years ago (Mya), while M. terricolor had split around 4.63 Mya from their ancestor. M. cervicolor, M. cookii and M. caroli diverged between 4.70 and 3.36 Mya, which indicates that M. terricolor and the Asian lineages evolved simultaneously. M. spretus is expected to have diverged nearly 2.9 Mya from their most recent common ancestor.     

The chromosomal distribution of the major and minor satellite is not conserved in the genusMus

The cytological distribution of the major and minor satellite first identified inMus musculus was studied in the karyotypes of three related subspecies and two other species of the genusMus. Both the major and minor satellite showed species dependent hybridization patterns. The major satellite is confined to the centromere region inM. musculus and related subspecies. However, inM spretus andM. caroli, the chromosomal arm regions contain this sequence class. In contrast the minor satellite is found at the kinetochore region inM. musculus and related subspecies but is distributed throughout the entire centromeric domain inM. spretus and appears to be excluded from the chromosomes ofM. caroli. There is an apparent correlation between the chromosomal location of these satellites and their phylogenetic relationship. Determination of the biological roles of the major and minor satellites fromM. musculus must take into account their differential chromosomal distribution in otherMus species.     

Evolutionary History of B1 Retroposons in the Genus Mus

Short interspersed DNA elements (SINEs) amplify by retroposition either by (i) successive waves of amplification from one or a few evolving master genes or by (ii) the generation of new master genes that coexist with their progenitors. Individual, highly conserved, elements of the B1 SINE family were identified from the GenBank nucleotide database using various B1 subfamily consensus query sequences to determine their integration times into the mouse genome. A comparison of orthologous loci in various species of the genus Mus demonstrated that four subfamilies of B1 elements have been amplifying within the last 1–3 million years. Therefore, B1 sequences are generated by coexisting source genes. Additionally, three B1 subfamilies have been concurrently propagated during subspecies divergence and strain formation in Mus, indicating very recent activity of this retroposon family. The patterns of intra- and interspecies variations of orthologous loci demonstrate the usefulness of B1 integrations as a phylogenetic tool. A single inconsistency in the phylogenetic trends was depicted by the presence of a B1 insert in an orthologous locus exclusively in M. musculus and M. pahari. However, DNA sequence analysis revealed that these were independent integrations at the same genomic site. One highly conserved B1 element that integrated at least 4–6 million years ago suggests the possibility of occasional function for B1 integrations. Received: 25 February 2000 / Accepted: 5 June 2000     

Targeted cloning of a subfamily of LINE-1 elements by subfamily-specific LINE-1-PCR

Subfamily-specific LINE-1 PCR (SSL1-PCR) is the targeted amplification and cloning of defined subfamilies of LINE-1 elements and their flanking sequences. The targeting is accomplished by incorporating a subfamily-specific sequence difference at the 3 end of a LINE-1 PCR primer and pairing it with a primer to an anchor ligated within the flanking region. SSL1-PCR was demonstrated by targeting amplification of a Mus spretus-specific LINE-1 subfamily. The amplified fragments were cloned to make an SSL1-PCR library, which was found to be 100-fold enriched for the targeted elements. PCR primers were synthesized based on the sequence flanking the LINE-1 element of four different clones. Three of the clones were recovered from Mus spretus DNA. A fourth clone was recovered from a congenic mouse containing both Mus spretus and Mus domesticus DNA. Amplification between these flanking primers and LINE-1 PCR primers produced a product in Mus spretus and not in Mus domesticus. These dimorphisms were further verified to be due to insertion of Mus spretus-specific LINE-1 elements into Mus spretus DNA and not into Mus domesticus DNA.     

Differences in the organization and chromosomal allocation of satellite DNA between the European long tailed house miceMus domesticus andMus musculus

We compared the organization of satellite DNA (stDNA) and its chromosomal allocation inMus domesticus and inMus musculus. The two stDNAs show similar restriction fragment profiles after digestion (probed withM. domesticus stDNA) with some endonucleases of which restriction sequences are present in the 230–240 bp repetitive unit of theM. domesticus stDNA. In contrast, EcoRI digestion reveals thatM. musculus stDNA lacks most of the GAATTC restriction sites, particularly at the level of the half-monomer. The chromosome distribution of stDNA (revealed by anM. domesticus stDNA probe) shows different patterns in theM. domesticus andM. musculus karyotypes, with about 60% ofM. domesticus stDNA retained in theM. musculus genome. It is particularly noteworthy that the pericentromeric regions ofM. musculus chromosomes 1 and X are totally devoid ofM. domesticus stDNA sequences. In both groups, the differences in energy transfer between the stDNA-bound fluorochromes Hoechst 33258 and propidium iodide suggest that AT-rich repeated sequences have a much more clustered array in theM. domesticus stDNA, as if they are organized in tandem repeats longer than those ofM. musculus. Considering the data as a whole, it seems likely that the evolutionary paths of the two stDNAs diverged after the generation of the ancestral 230–240 bp stDNA repetitive unit through the amplification, in theM. domesticus genome, of a family repeat which included the EcoRI GAATTC restriction sequence.     

Characterization of a V κ family in Mus musculus castaneus: sequence analysis

To examine genetic variation at immunoglobulin (Ig) multigene loci over short spans of evolutionary time, we have compared members of an Ig kappa chain variable (V ) region family from several mouse species. In this study, seven unique Igk-V24 family members have been isolated from Mus m. castaneus and characterized by nucleotide sequence determination for comparison to their counterparts in Mus m domesticus (BALB/c), and Mus pahari, representing 1–2 million years of evolution in the former case and 5–8 million years in the latter. Parsimony, together with evolutionary distances calculated for various paris of Igk-V24 family coding regions, relate all family members to a common progenitor existing roughly 24 million years ago (Mya). A significant portion of the M. m. castaneus family consists of pseudogene segments in various degrees of progressive degeneration. The substitution patterns and divergence rates for all gene segments are characteristic of their respective subsets, especially in the areas flanking the coding regions. Complex and variable patterns of diversity are seen in potentially expressed coding regions, which appear to reflect quite different selective pressures on various subregions within the V protein domain. These results indicate that evolutionary pressures are operating at the level of family subsets, their individual members, and subregions within similar molecules.The nucleotide sequence data presented in this report have been submitted to the GenBank nucleotide sequence database and assigned the accession numbers (Igk-CaV24) M80407; (Igk-CaV24A) M80408; (Igk-CaV24B.1) M80409; (Igk-CaV24B.2) M80410; (Igk-CaV24D.1) M80411; (Igk-CaV24D.2) M80412; and (Igk-CaV24D.3) M20892.     

Experimental hybridization and an evaluation of the fertility of some forms of the house mouse supraspecies complex <Emphasis Type="Italic">Mus musculus</Emphasis> (Rodentia,Muridae)

The degree of development of the mechanisms of postcopulatory isolation was evaluated on the basis of experimental hybridization of representatives of three subspecies of M. musculus (M. m. musculus, M. m. wagneri, and M. m. gansuensis) and remote populations of the subspecies M. m. musculus. Experimental crosses between the different subspecies and populations indicated the presence of initial stages of postcopulatory reproductive isolation between some forms of house mice. In a number of crosses conducted between different populations and subspecies of M. musculus, asymmetry was observed. In one variant of mating, M. m. musculus (male) × M. m. wagneri (female), a reduced intensity of breeding and nonviability of pups were observed. A decrease in the intensity of reproduction was found in all variants of crosses that used male M. m. musculus from the city of Ishim. These data are assumed to confirm the previous assumption about the hybrid origin of mice inhabiting that city. The results confirm a significant level of divergence of the subspecies M. m. musculus and M. m. wagneri. Thus, initial stages both of post- and precopulatory isolation mechanisms between M. m. wagneri and M. m. musculus were shown.     

Macromolecular organization and genetic mapping of a rapidly evolving chromosome-specific tandem repeat family (B77) in cotton (Gossypium)

Isolation and characterization of the most prominent repetitive element families in the genome of tetraploid cotton (Gossypium barbadense L; [39]) revealed a small subset of families that showed very different properties in tetraploids than in their diploid progenitors, separated by 1-2 million years. One element, B77, was characterized in detail, and compared to the well-conserved 5S and 45S rRNA genes. The 572 bp B77 repeat was found to be concentrated in several discontinuous tandem arrays confined to a single 550 kb SalI fragment in tetraploid cotton. Genetic mapping based on the absence of the pentameric rung in the G. barbadense ladder showed that B77 maps to a D-subgenome chromosome. In situ hybridization supports the contention that the array is confined largely to a single chromosomal site in the D-subgenome. The B77 repeat has undergone a substantial increase in copy number since formation of tetraploid cotton from its diploid relatives. RFLPs observed among tetraploid cotton species suggest that amplification and/or rearrangement of the repeat may have continued after divergence of the five tetraploid cotton species. B77 contains many short direct repeats and shares significant DNA sequence homology with a Nicotiana alata retrotransposon Tna1-2 integrase motif. The recent amplification of B77 on linkage group D04 suggests that the D-subgenome of tetraploid cotton may be subject to different evolutionary constraints than the D-genome diploid chromosomes, which exhibit few genome-specific elements. Further, the abundance of B77 in G. gossypioides supports independent evidence that it may be the closest extant relative of the D-genome ancestor of cotton.     

Identification ofTnr3, aSuppressor-Mutator/Enhancer-like transposable element from rice

We isolated members of the retroposon family p-SINE1 in rice and found that one member contained an insertion. A 3-bp sequence at the insertion site within p-SINE1 appeared duplicated. The insertion sequence, 1536 bp in length, carried imperfect inverted repeats of about 13 bp at its termini which begin with 5-CACTA--- -3; these repeats are similar to those found in members of theEn/Spm transposable element family. These results indicate that the insertion sequence is a transposable element belonging to theEn/Spm family and is thus namedTnr3 (transposable element inrice no.3). In fact,Tnr3 carried long subterminal regions containing direct and inverted repeats of short DNA sequences of 15 bp, another characteristic of theEN/Spm family. The subterminal repeat sequences inTnr3 are, however, of two kinds, although they share homology with each other.Tnr3 and its relatives were present in multiple copies in rice. Considering the length ofTnr3, it cannot represent an autonomous type element, but is a non-autonomous element probably derived by deletion from an autonomous transposon.     

Evidence for the presence of two sympatric species of mice (genus Mus L.) in southern France based on biochemical genetics

Populations of mice established outdoors as well as indoors have been investigated at 24 loci using starch gel electrophoresis. Two reproductively isolated groups are recognized, one of which is referable to a house mouse subspecies, Mus musculus brevirostris, and the other to a different species, Mus spretus, contrary to the view of Schwarz and Schwarz that only one species of Mus is present in the Mediterranean Basin. The genetic distance between these two groups is larger than between any pair of investigated subspecies of M. musculus. M. m. brevirostris is biochemically almost indistinguishable from M. m. domesticus. On the other hand, M. spretus exhibits several allelic variants unknown or at most very infrequent in M. musculus, as for instance at the lactate dehydrogenase B-chain locus.This work was supported by research grants from the Centre National de la Recherche Scientifique (E.R.A. No. 261) and the Ecole Pratique des Hautes Etudes.     

Evolution of the major histocompatibility complex: a hundred-fold amplification of MHC class I genes in the African pigmy mouse Nannomys setulosus

The genome of the African murine rodent Nannomys setulosus was found to harbor several thousand major histocompatibility complex (MHC) class I genes instead of the 30–40 genes found in conventional laboratory mice, which are mostly of Mus musculus domesticus origin. Other genes of N. setulosus, either functionally or physically linked to class I genes, are not amplified. Amplified genes derive from as few as three ancestors and amplification has likely occured after the divergence of the two Nannomys species, N. setulosus and N. minutoides, which took place about three million years ago. Amplified genes are mostly pseudogenes. Statistical analysis of dinucleotide frequencies leads us to propose that inactivation of the genes has occured through the repeat induced mutation process, a possible newcomer in the evolution of the MHC.The nucleotide sequence data reported in this paper have been submitted to the EMBL nucleotide data library and have been assigned the accession numbers X61685 and X61686. Correspondence to : G. Gachelin.     

Quantitative variation of “Mus musculus-like” constitutive heterochromatin and satellite DNA-sequences in the genus Mus

The extent of conservation of constitutive heterochromatin in three species of Mus viz. M. musculus, M. booduga and M. dunni, with shared cytological properties and homologous DNA sequences has been studied. The cytological properties were investigated by doing fluorescence staining and condensation inhibition of their chromosomes with Hoechst 33258. Both the parameters indicate the occurrence of a reduced quantum of M. musculus like heterochromatin at specific sites in the other two genomes. In situ hybridization of the nick translated ³H-labelled M. musculus satellite DNA with M. booduga and M. dunni chromosomes, also corroborates our Hoechst 33258 findings and comparable variation in the amount and site of occurrence of sequences homologous to M. musculus satellite DNA in these species are noticed. The study thus provides a good example of a gradual quantitative variation of a particular type of heterochromatin and in turn of the repetitive DNA constituting it in different related species. Further since the heterochromatin in M. booduga and M. dunni is expected to contain different repetitive DNA sequences in addition to those homologous to M. musculus satellite DNA, it is proposed that a change in the balance between two or more repetitive sequences in heterochromatin may be more crucial in its evolutionary consequences rather than a mere increase or decrease of a homogeneous repetitive sequence.