The decline of human endogenous retroviruses: extinction and survival

For millions of years, retroviral infections have challenged vertebrates, occasionally leading to germline integration and inheritance as ERVs, genetic parasites whose remnants today constitute some 7% to 8% of the human genome. Although they have had significant evolutionary side effects, it is useful to view ERVs as fossil representatives of retroviruses extant at the time of their insertion into the germline and not as direct players in the evolutionary process itself. Expression of particular ERVs is associated with several positive physiological functions as well as certain diseases, although their roles in human disease as etiological agents, possible contributing factors, or disease markers-well demonstrated in animal models-remain to be established. Here we discuss ERV contributions to host genome structure and function, including their ability to mediate recombination, and physiological effects on the host transcriptome resulting from their integration, expression, and other events.

Knowledge of the rate of point mutation is of fundamental importance, because mutations are a vital source of genetic novelty and a significant cause of human diseases. Currently, mutation rate is thought to vary many fold among genes within a genome and among lineages in mammals. We have conducted a computational analysis of 5,669 genes (17,208 sequences) from species representing major groups of placental mammals to characterize the extent of mutation rate differences among genes in a genome and among diverse mammalian lineages. We find that mutation rate is approximately constant per year and largely similar among genes. Similarity of mutation rates among lineages with vastly different generation lengths and physiological attributes points to a much greater contribution of replication-independent mutational processes to the overall mutation rate. Our results suggest that the average mammalian genome mutation rate is 2.2 x 10(-9) per base pair per year, which provides further opportunities for estimating species and population divergence times by using molecular clocks.

Retroviral replication involves the formation of a DNA provirus integrated into the host genome. Through this process, retroviruses can colonize the germ line to form endogenous retroviruses (ERVs). ERV inheritance can have multiple adverse consequences for the host, some resembling those resulting from exogenous retrovirus infection but others arising by mechanisms unique to ERVs. Inherited retroviruses can also confer benefits on the host. To meet the different threats posed by endogenous and exogenous retroviruses, various host defences have arisen during evolution, acting at various stages on the retrovirus life cycle. In this Review, I describe our current understanding of the distribution and architecture of ERVs, the consequences of their acquisition for the host and the emerging details of the intimate evolutionary relationship between virus and vertebrate host.