Two distinct endogenous type C viruses isolated from the asian rodent Mus cervicolor: conservation of virogene sequences in related rodent species.

The cocultivation of a lung cell line from the Southeast Asian mouse Mus cervicolor with cells from heterologous species has resulted in the isolation of two new distinct type C viruses. Both viruses are endogenous to M. cervicolor and are present in multiple copies in the cellular DNA of these mice. One of the viruses, designated M. cervicolor type CI, replicates readily in the SIRC rabbit cell line and is antigenically related to the infectious primate type C viruses isolated from a woolly monkey (simian sarcoma-associated virus) and gibbon apes (gibbon ape leukemia virus). This virus is also closely related by both immunological and nucleic acid hybridization criteria to a type C virus previously isolated from a second Asian murine species, Mus caroli. The isolation of the M. cervicolor type C I virus thus provides further evidence that the infectious primate type C viruses originated by trans-species infection of primates by an endogenous virus of mice. The second virus, designated M. cervicolor type C II, replicates well in various cell lines derived from the laboratory mouse Mus musculus. While antigenically related to type C viruses derived from M. musculus, the M. cervicolor type C II virus isolate can be readily distinguished from standard murine leukemia viruses. Both new type C viruses from M. cervicolor are unrelated to the previously described retrovirus (M432) isolated from the same Mus species. The DNA of M. cervicolor therefore contains multiple copies of at least three distinct classes of endogenous viral genes. An examination of the cellular DNA of other rodent species for nucleic acid sequences related to the genomes of both M. cervicolor type C I and II reveals that both viruses have been highly conserved evolutionarily, and that other species of rodents, such as laboratory mice and rats, contain endogenous virogenes related to those in the DNA of M. cervicolor.     

Genome-wide survey for biologically functional pseudogenes

According to current estimates there exist about 20,000 pseudogenes in a mammalian genome. The vast majority of these are disabled and nonfunctional copies of protein-coding genes which, therefore, evolve neutrally. Recent findings that a Makorin1 pseudogene, residing on mouse Chromosome 5, is, indeed, in vivo vital and also evolutionarily preserved, encouraged us to conduct a genome-wide survey for other functional pseudogenes in human, mouse, and chimpanzee. We identify to our knowledge the first examples of conserved pseudogenes common to human and mouse, originating from one duplication predating the human–mouse species split and having evolved as pseudogenes since the species split. Functionality is one possible way to explain the apparently contradictory properties of such pseudogene pairs, i.e., high conservation and ancient origin. The hypothesis of functionality is tested by comparing expression evidence and synteny of the candidates with proper test sets. The tests suggest potential biological function. Our candidate set includes a small set of long-lived pseudogenes whose unknown potential function is retained since before the human–mouse species split, and also a larger group of primate-specific ones found from human–chimpanzee searches. Two processed sequences are notable, their conservation since the human–mouse split being as high as most protein-coding genes; one is derived from the protein Ataxin 7-like 3 (ATX7NL3), and one from the Spinocerebellar ataxia type 1 protein (ATX1). Our approach is comparative and can be applied to any pair of species. It is implemented by a semi-automated pipeline based on cross-species BLAST comparisons and maximum-likelihood phylogeny estimations. To separate pseudogenes from protein-coding genes, we use standard methods, utilizing in-frame disablements, as well as a probabilistic filter based on Ka/Ks ratios.     

Multiple independent pseudogene derivations indicate increased instability of the <Emphasis Type="Italic">Mdm2</Emphasis> locus in <Emphasis Type="Italic">Mus caroli</Emphasis>

Under conditions of genomic stress, the Mdm locus in human and in mouse is prone to instability manifested as amplification and oncogenesis. The Mdm2 gene is a known oncogene that is amplified in approximately one-third of sarcomas and whose protein product interacts with the tumor suppressor p53. Concimitant with such gene amplification events is the activation and mobilization of endogenous retroelements, typically through the relaxation of epigenetic controlling mechanisms. Processed pseudogenes, which can be formed through endogenous LINE retroelement activity, may indicate increased genomic instability. We have isolated processed pseudogenes for Mdm2 in Mus caroli DNA, likely formed from independent events in different individuals. This is the first identification and characterization of an Mdm2 pseudogene in any organism. Multiple retrotransposition events are suggested by the variable sequence and genomic structure of the identified pseudogenes across all exons and the 3UTR. The high degree of similarity between the gene and each pseudogene, as well as the lack of evidence for an Mdm2 pseudogene in several other species of Mus, indicate evolutionarily recent retrotransposition events leading to the formation of the Mdm2 pseudogenes in M. caroli. Previous studies on the Mdm2 locus in Mus caroli showed amplification and overexpression of this gene on double minute chromosomes in a Mus musculus × Mus caroli interspecific hybrid. The identification of an Mdm2 retropseudogene within this species further highlights the predisposition to instability for this region of the genome.     

Phylogenetic position and description of a new species of subgenus Mus (Rodentia, Mammalia) from Thailand

Molecular, chromosomal and morphometric analyses of wild-caught mice of subgenus Mus from the central plain of Thailand are presented. These specimens are distinct from all species previously described in the literature. This has led to the characterization of Mus fragilicauda sp. n., a new member of the set of closely related species encompassed by the subgenus . While this species may be considered as a sibling and sympatric species of the Asian M. cervicolor , M. fragilicauda sp. n. is phylogenetically closer to the M. musculus complex of species and to the other European species of Mus .     

The Muridae glyceraldehyde-3-phosphate dehydrogenase family

Summary Although only one gene is known to be functional, numerous glyceraldehyde-3-phosphate dehydrogenase (GAPDH) related sequences are scattered throughoutMus musculus andRattus rattus genomes. In this report we show that: (1) GAPDH pseudogenes are repeated to comparable extents, at least 400 copies, in 12 other Muridae species; (2) the complete, or nearly so, sequence of GAPDH messenger RNA is amplified, and a high proportion, if not all of these copies, are intronless; (3) GAPDH pseudogenes are preferentially located in heavily methylated and DNAse I-insensitive regions of chromatin; and (4) the presence of atypical GAPDH-related mRNAs in different cellular contexts raises the possibility that more than one GAPDH gene is transcribed.     

Temporal, spatial, and ecological modes of evolution of Eurasian Mus based on mitochondrial and nuclear gene sequences

We sequenced mitochondrial (cytochrome b, 12S rRNA) and nuclear (IRBP, RAG1) genes for 17 species of the Old World murine genus Mus, drawn primarily from the Eurasian subgenus Mus. Phylogenetic analysis of the newly and previously available sequences support recognition of four subgenera within Mus (Mus, Coelomys, Nannomys, and Pyromys), with an unresolved basal polytomy. Our data further indicate that the subgenus Mus contains three distinct 'species groups': (1) a Mus booduga Species Group, also including Mus terricolor and Mus fragilicauda (probably also Mus famulus); (2) a Mus cervicolor Species Group, also including Mus caroli and Mus cookii; and (3) a Mus musculus Species Group, also including Mus macedonicus, Mus spicilegus, and Mus spretus. Species diversity in Eurasian Mus is probably explicable in terms of several phases of range expansion and vicariance, and by a propensity within the group to undergo biotope transitions. IRBP and RAG1 molecular clocks for Mus date the origin of subgenera to around 5-6 mya and the origin of Species Groups within subgenus Mus to around 2-3 mya. The temporal pattern of evolution among Eurasian Mus is more complex than that within the Eurasian temperate genus Apodemus.     

Molecular phylogeny of the genus Mus (Rodentia: Murinae) based on mitochondrial and nuclear data

The genus Mus encompasses at least 38 species divided into four subgenera: Mus , Pyromys , Nannomys and Coelomys . The subgenus Mus , which comprises the house mouse and related species, is by far the most extensively studied, although the subgenus Nannomys is the most speciose. Although the relationships within the subgenus Mus are rather well characterized, those between subgenera are still unclear. In the present study, phylogenetic analyses of the whole genus were performed using a larger species sample of Nannomys than in previous studies, and a nuclear gene (IRBP) in addition to mitochondrial data (cytochrome b and 12S rRNA). Members of the Acomyinae and Murinae were used as outgroups. Separate and combined analyses were performed with maximum parsimony, maximum likelihood and Bayesian methods, and divergence times were estimated. The results showed that the monophyly of the genus Mus and of each subgenus was strongly supported by the three genes and the combined analysis. The phylogenies derived from the three genes were on the whole congruent; however, several conflicting topologies were observed such as the relationships between the three Asian species of the subgenus Mus ( caroli , cervicolor and cookii ). Increasing the taxonomic sampling of Nannomys did not satisfactorily improve the resolution of relationships between the four subgenera. In addition, molecular calibrations indicate that the Mus and Nannomys radiation coincided with major environmental changes.  © 2005 The Linnean Society of London, Biological Journal of the Linnean Society , 2005, 84 , 417–427.     

Comparative Analysis of Evolution in a Rodent Histone H2a Pseudogene

Sequences were obtained from five species of rodents that are orthologous to an H2a histone pseudogene from Mus musculus. The pseudogene is part of the cluster of replication-dependent histone genes found on Mus musculus chromosome 13. Comparative analysis of these five sequences together with the previously published sequence from M. musculus shows that this gene has likely been a pseudogene throughout the evolution of the genus Mus, while the gene from Rattus norvegicus is likely functional. Three large (>20 bp) deletions were found among the Mus pseudogenes, a feature that is very unusual compared to surveys of processed pseudogenes. In addition, there are two single-base deletions and one 4-bp insertion among the Mus pseudogenes. The species distributions of one of the large deletions and the 4-bp insertion require either independent insertions of an identical sequence, independent deletions with identical boundaries, or a deletion followed by precise reintegration of the original sequence. The evidence favors the hypothesis of multiple deletions with identical boundaries. The ``coding' regions of the Mus pseudogenes show a much reduced level of among-species variability in the 3′ half of the pseudogene, compared both to the 5′ half and to flanking sequences. This supports a hypothesis that the 3′ end of the pseudogene is the target of frequent gene conversion by functional H2a genes. Received: 1 April 1997 / Accepted: 12 June 1997     

苏铁nrDNA ITS区的序列多态性:不完全致同进化的证据

本研究对苏铁(Cycas revoluta) nrDNA ITS进行克隆测序, 并以cDNA ITS为参照, 比较分析获得的序列的碱基变异、GC含量、5.8S二级结构的稳定性和5.8S保守基序的有无以及系统发育关系。结果发现苏铁nrDNA ITS存在较高的基因组内多样性, 同时, 这些分化的nrDNA ITS拷贝中包含有假基因的存在, 而且假基因与功能拷贝之间已经形成了较大的遗传分化, 这暗示假基因起源有较长历史。苏铁核仁组织区不仅多达16个, 而且分布在13条染色体上, 这可能是其nrDNA ITS致同进化不完全的主要原因。     

Mus spicilegus endogenous retrovirus HEMV uses murine sodium-dependent myo-inositol transporter 1 as a receptor

We sought to determine the relationship between two recent additions to the murine leukemia virus (MLV) ecotropic subgroup: Mus cervicolor isolate M813 and Mus spicilegus endogenous retrovirus HEMV. Though divergent in sequence, the two viruses share an Env protein with similarly curtailed VRA and VRB regions, and infection by both is restricted to mouse cells. HEMV and M813 displayed reciprocal receptor interference, suggesting that they share a receptor. Expression of the M813 receptor murine sodium-dependent myo-inositol transporter 1 (mSMIT1) allowed previously nonpermissive cells to be infected by HEMV, indicating that mSMIT1 also serves as a receptor for HEMV. Our findings add HEMV as a second member to the MLV subgroup that uses mSMIT1 to gain entry into cells.     

Genetic relationship between the Mus cervicolor M432 retrovirus and the Mus Musculus intracisternal type A particle

The genetic relationship between the retrovirus-like intracisternal type A particle (IAP) from Mus musculus and the novel retrovirus (M432) from M. cervicolor has been determined by heteroduplex and restriction endonuclease analyses of molecular clones of the respective genomes. We have found a major homology region (3.7 kilobase pairs) which probably begins near the 3' end of the M432 gag gene, spans the pol gene, and ends in the env gene. A second region (0.6 kilobase pairs) of weak homology was also observed adjacent to the 3' long terminal repeats of the respective genomes. The IAP genome is well conserved in the cellular DNA of all species of the genus Mus. In contrast, cellular DNA sequences related to the 5' end of the M432 genome, which shares no homology with the IAP genome, are found only in M. cervicolor and the closely related species M. cookii. These results suggest that the infectious M432 retroviral genome arose as a result of a recombinational event(s) between the IAP genome and another, as yet unidentified, class of retrovirus-related sequences or other cellular sequences.     

Human glyceraldehyde-3-phosphate dehydrogenase pseudogenes: Molecular evolution and a possible mechanism for amplification

We screened two human genomic libraries and isolated 14 different clones, designated λG1 and EG1-EG13, homologous to human glyceraldehyde-3-phosphate dehydrogenase (GAPD) cDNA. Subcloning and sequencing these recombinant phages led us to classify them as five different pseudogenes (ψG1–ψG5). All these sequences show such features typical of processed pseudogenes as numerous mutations, insertions, and deletions. The identity of numerous mutated sites among these pseudogenes and the presence of two Alu sequences flanking both ends of ψG1 suggest that GAPD pseudogenes originated from a unique reverse transcribed mRNA followed by gene duplication. The rate of nucleotide substitutions per site per year for known GAPD functional genes is low both for the synonymous substitutions (1.87×10⁻⁹) and for the nonsynonymous substitutions (0.12￠10⁻⁹) and indicates that the GAPD cDNA sequence is well conserved not only at the amino acid level, but also at the nucleotide level. The rate of nucleotide substitutions per site per year for GAPD pseudogenes shows a higher value (5.9×10⁻⁹) and suggests that these pseudogenes do not have any functional role. This work was supported by grants from the Consiglio Nazionale delle Ricerche and the Ministero Pubblica Istruzione (Rome, Italy). Special acknowledgment is given to the “Progetto Finalizzato Ingegneria Genetica e Basi Molecolari delle Malattie Ereditarie.”     

Phylogenetic relationships in the genus mus,based on paternally,maternally, and biparentally inherited characters

Several species in the rodent genus Mus are used as model research organisms, but comparative studies of these mice have been hampered by the lack of a well-supported phylogeny. We used DNA sequences from six genes representing paternally, maternally, and biparentally inherited regions of the genome to infer phylogenetic relationships among 10 species of Mus commonly used in laboratory research. Our sample included seven species from the subgenus Mus; one species each from the subgenera Pyromys, Coelomys, and Nannomys; and representatives from three additional murine genera, which served as outgroups in the phylogenetic analyses. Although each of the six genes yielded a unique phylogeny, several clades were supported by four or more gene trees. Nodes that conflicted between trees were generally characterized by weak support for one or both of the alternative topologies, thus providing no compelling evidence that any individual gene, or part of the genome, was misleading with respect to the evolutionary history of these mice. Analysis of the combined data resulted in a fully resolved tree that strongly supports monophyly of the genus Mus, monophyly of the subgenus Mus, division of the subgenus Mus into Palearctic (M. musculus, M. macedonicus, M. spicilegus, and M. spretus) and Asian (M. cervicolor, M. cookii, and M. caroli) clades, monophyly of the house mice (M. m. musculus, "M. m. molossinus," M. m. castaneus, and M. m. domesticus), and a sister-group relationship between M. macedonicus and M. spicilegus. Other clades that were strongly supported by one or more gene partitions were not strongly supported by the combined data. This appears to reflect a localized homoplasy in one partition obscuring the phylogenetic signal from another, rather than differences in gene or genome histories.     

人类基因组中加工假基因分布与重组率和基因密度的关系

分析了人类加工假基因在染色体上的分布,发现加工假基因密度与重组率负相关,而与基因密度正相关。加工假基因在低重组区的积累与插入有害模型和异位重组模型相吻合：在插入有害模型下,低重组区的选择强度由于Hill．Robertson干涉而变弱,所以加工假基因较多地插入到低重组区;在异位重组模型下,同源加工假基因家族（包括同源祖先基因）之内可能发生异位重组而对机体造成危害,所以加工假基因在高重组区的插入受到较强的负选择,导致加工假基因较多地分布在低重组区。除以上两种模型以外,加工假基因还可能通过降低重组率的方式对加工假基因密度与重组率的负相关有所贡献。加工假基因偏好分布在基因密区,这可能与异位重组在该区较少发生有关。     

The first human genes for tRNA(ArgICG), tRNA(GlyUCC), and tRNA(ThrIGU) and more tRNA(Val) pseudogenes: expression and pre-tRNA maturation in HeLa cell-free extracts.

A functional tRNA(Val) gene, which codes for the major tRNA(ValIAC) isoacceptor species, and three new tRNA(Val) pseudogenes have been isolated from human genomic DNA. Two tRNA(Val) pseudogenes and a tRNA(Val) variant gene were found to be associated with tRNA genes encoding tRNA(ArgICG), tRNA(GlyUCC), and tRNA(ThrIGU), respectively, on distinct DNA fragments. All tRNA genes, including the pseudogenes, are actively transcribed in HeLa nuclear extract. Pre-tRNAs of tRNA(Val), tRNA(Arg), tRNA(Thr), and tRNA(Gly) genes are correctly processed to mature-sized tRNAs, whereas the three tRNA(Val) pseudogenes yield stable pre-tRNAs in vitro. These findings reveal that, together with the three known pseudogenes, half of the members of the human tRNA(Val) gene family are pseudogenes, all of which are active in homologous nuclear extracts in vitro and presumably also in vivo.     

Phylogenetic distribution in the genus Mus of t-complex-specific DNA and protein markers: inferences on the origin of t-haplotypes

We have examined the phylogenetic distribution of two t-specific markers among representatives of various taxa belonging to the genus Mus. The centromeric TCP-1a marker (a testicular protein variant specific for all t-haplotypes so far studied) has also been apparently detected in several non-t representatives of the Mus IVA, Mus IVB, and probably M. cervicolor species. By contrast, a t-specific restriction- fragment-length polymorphism allele (RFLP) of the telomeric alpha- globin pseudogene DNA marker alpha-psi-4 was found only in animals belonging to the M. musculus-complex species either bearing genuine t- haplotypes or, like the M. m. bactrianus specimen studied here, likely to do so. This t-specific alpha-psi-4 RFLP allele was found to be as divergent from the RFLP alleles of the latter, non-t, taxonomical groups as it is from Mus 4A, Mus 4B, or M. spretus ones. These results suggest the presence of t-haplotypes and of t-specific markers in populations other than those belonging to the M. m. domesticus and M. m. musculus subspecies, implying a possible origin for t-haplotypes prior to the radiation of the most recent offshoot of the Mus genus (i.e., the spretus/domesticus divergence), some 1-3 Myr ago.      

Genetic variation in mouse apolipoprotein A-IV due to insertion and deletion in a region of tandem repeats.

We have detected three unique apolipoprotein A-IV (apoA-IV) charge isoforms in strains of commensal mice. The cDNA sequences for one representative of each isoform (Mus domestesticus strains C57BL/6J and 129/J and Mus castaneus) revealed a polymorphism within a series of four imperfect repeats encoding the sequence Glu-Gln-Ala/Val-Gln. Insertions or deletions of 12 nucleotides within this repetitive region have given rise to three genotypes characterized by three (129), four (C57BL/6), or five (M. castaneus) copies of the repeat unit. To ascertain the extent of this variation among other species of the Mus genus, we sequenced this region of apoA-IV cDNAs from eight additional M. domesticus inbred strains and from five wild-derived Mus species. All eight additional M. domesticus strains examined had four repeat units, as found in C57BL/6. Among wild-derived mice, however, one species (Mus spretus) had three repeats, two species (Mus cookii and Mus cervicolor) had four repeats, and two species (Mus hortulanus and Mus minutoides) had five repeats. A lack of correlation between the number of repeat units and the phylogeny of Mus species indicates that independent mutations may have occurred throughout the evolution of specific mouse lineages. We suggest that the repetitive nature of the polymorphic sequence may predispose this region to slippage errors during DNA replication, resulting in frequent deletion/insertion mutations.