Phylogenetic analysis of a retroposon family in african great apes.

The SINE-R retroposon family has been identified by its relationship with the long terminal repeats (LTRs) of human endogenous retrovirus class K (HERV-K) as a mobile element that has evolved recently in the human genome. Here we examined the recent evolutionary history of this class of elements by a PCR approach to genomic DNA from the African great apes and by phylogenetic analysis including comparison with the HERV K10 parent sequence. With primers derived from a cDNA sequence from human brain, we identified 27 sequences from the chimpanzee and 16 from the gorilla. Phylogenetic comparisons with previously recognized sequences from the human and from the orangutan and gibbon revealed wide overlap of elements across species, suggesting multiple origins in the course of hominoid evolution. Two human elements SINE-R.C2 and HS307 were the furthest removed from the HERV-K10 sequence but these two elements were closely related to three elements from the chimpanzee and four elements from the gorilla. This group of elements (our clusters 14 and 15) appears to have transposed late in hominoid evolution. One element (Ch-M16) showed 99.1% sequence identity with the SINE-R.C2 element, which is human-specific. Thus the SINE-R family appears to have continued to be active in transposition throughout the course of primate evolution.

Phylogenetic analysis of HERV-K LTR-like elements in primates: presence in some new world monkeys and evidence of recent parallel evolution in these species and in homo sapiens.

Solitary long terminal repeats (LTRs) of the human endogenous retroviruses K family (HERV-K) have been found to be coexpressed with sequences of closely located genes. We identified forty-three HERV-K LTR-like elements in primates (African great apes, two Old World monkeys, and two New World monkeys) and analyzed them along with human-specific HERV-K LTRs. We report detection of HERV-K LTR-like elements from New World monkeys, as represented by the squirrel monkey and the night monkey, for the first time. Analysis revealed a high degree of sequence homology with human-specific HERV-K LTRs. A phylogenetic tree obtained by the neighbor-joining method revealed that five sequence (SMS-1, 2, 5, 6, 7) from the squirrel monkey and three sequences (NM6-4, 5, 9) from the night monkey are more closely related to human-specific HERV-K LTRs than they are to those of apes (the chimpanzee and gorilla) and Old World monkeys (the African green monkey and rhesus monkey). The findings are consistent with the concept the HERV-K LTR-like elements have proliferated independently and recently in the genome of primates, and that such proliferation has been more recent in Homo sapiens and in these representatives of New World monkeys than in some Old World monkeys.

SINE-R.C2 (a Homo sapiens specific retroposon) is homologous to CDNA from postmortem brain in schizophrenia and to two loci in the Xq21.3/Yp block linked to handedness and psychosis.

We investigated the retroviral/retroposon hypothesis of schizophrenia by generating sequences with PCR primers based on a retroviral sequence recovered by Yee et al. [1998: Schizophr Res 29:92] from a cDNA library from postmortem brain tissue from an individual with psychosis in a genomic region (Xq21.3) that has been tentatively linked to schizophrenia and schizoaffective disorder by Laval et al. [1998: Am. J. Med. Genet. (Neuropsychiatr. Genet.) 81:420-427]. Within the block of homology with Yp that was generated by a transposition between the chimpanzee and Homo sapiens we find two sequences, HS307 and HS408, with a high degree of homology to but not identity with the schizophrenic brain cDNA. The closest match of these three sequences is to a family of retroposons, that has evolved from the HERV-K family of endogenous retroviruses, some members of which (e.g., SINE-R.C2) appear to be specific to the human genome. This element has been reported as a cause of Fukuyama-type muscular dystrophy [Kobayashi et al., 1998: Nature 394:388-392]. Such retroposons, as agents of change in the human genome, provide a strategy for investigating pathogenesis. On account of their genomic location in a region that has been subject to change in the course of hominid evolution, and that may have a relationship to psychosis and/or cerebral asymmetry, we conclude that these particular insertions deserve further investigation.