L1 (LINE-1) elements constitute a large family of mammalian retrotransposons that have been replicating and evolving in mammals for more than 100 Myr and now compose 20% or more of the DNA of some mammals. Here, we investigated the evolutionary dynamics of the active human Ta L1 family and found that it arose approximately 4 MYA and subsequently differentiated into two major subfamilies, Ta-0 and Ta-1, each of which contain additional subsets. Ta-1, which has not heretofore been described, is younger than Ta-0 and now accounts for at least 50% of the Ta family. Although Ta-0 contains some active elements, the Ta-1 subfamily has replaced it as the replicatively dominant subfamily in humans; 69% of the loci that contain Ta-1 inserts are polymorphic for the presence or absence of the insert in human populations, as compared with 29% of the loci that contain Ta-0 inserts. This value is 90% for loci that contain Ta-1d inserts, which are the youngest subset of Ta-1 and now account for about two thirds of the Ta-1 subfamily. The successive emergence and amplification of distinct Ta L1 subfamilies shows that L1 evolution has been as active in recent human history as it has been found to be for rodent L1 families. In addition, Ta-1 elements have been accumulating in humans at about the same rate per generation as recently evolved active rodent L1 subfamilies.
We compared sex chromosomal and autosomal regions of similar GC contents and found that the human Y chromosome contains nine times as many full-length (FL) ancestral LINE-1 (L1) elements per megabase as do autosomes and that the X chromosome contains three times as many. In addition, both sex chromosomes contain a ca. twofold excess of elements that are >500 bp but not long enough to be capable of autonomous replication. In contrast, the autosomes are not deficient in short (<500 bp) L1 elements or SINE elements relative to the sex chromosomes. Since neither the Y nor the X chromosome, when present in males, can be cleared of deleterious genetic loci by recombination, we conclude that most FL L1s were deleterious and thus subject to purifying selection. Comparison between nonrecombining and recombining regions of autosome 21 supported this conclusion. We were able to identify a subset of loci in the human DNA database that once contained active L1 elements, and we found by using the polymerase chain reaction that 72% of them no longer contain L1 elements in a representative of each of eight different ethnic groups. Genetic damage produced by both L1 retrotransposition and ectopic (nonallelic) recombination between L1 elements could provide the basis for their negative selection.
The self-replicating LINE-1 (L1) retrotransposon family is the dominant retrotransposon family in mammals and has generated 30 -40% of their genomes. Active L1 families are present in modern mammals but the important question of whether these currently active families affect the genetic fitness of their hosts has not been addressed. This issue is of particular relevance to humans as Homo sapiens contains the active L1 Ta1 subfamily of the human specific Ta (L1Pa1) L1 family. Although DNA insertions generated by the Ta1 subfamily can cause genetic defects in current humans, these are relatively rare, and it is not known whether Ta1-generated inserts or any other property of Ta1 elements have been sufficiently deleterious to reduce the fitness of humans. Here we show that full-length (FL) Ta1 elements, but not the truncated Ta1 elements or SINE (Alu) insertions generated by Ta1 activity, were subject to negative selection. Thus, one or more properties unique to FL L1 elements constitute a genetic burden for modern humans. We also found that the FL Ta1 elements became more deleterious as the expansion of Ta1 has proceeded. Because this expansion is ongoing, the Ta1 subfamily almost certainly continues to decrease the fitness of modern humans.genetics ͉ retrotransposon L INE-1 (L1) retrotransposons have had a profound effect on mammalian genomes having generated 30-40% of their mass (1, 2). Modern mammals contain active L1 families, and in Homo sapiens, essentially all of the L1 activity is due to the Ta1 subfamily of the human-specific Ta (L1Pa1) L1 family (3, 4). Here we determined whether the Ta1 subfamily has been deleterious enough to reduce human fitness. An active L1 element could produce three deleterious effects (e.g., ref. 5): First, its replicative products (novel DNA inserts) could act as insertional mutagens. Second, its replicative products could participate in ectopic homologous recombination and cause genetic rearrangements. Third, L1 RNA transcripts or their encoded proteins (or both) could be toxic.Although L1 replication can generate potentially active, fulllength (FL, Ϸ6 kb) elements, most of its replication products are inactive: these are truncated (TR, mean length, 0.9 kb) L1 elements (6), and members of the SINE (Alu, 0.3 kb) repeated DNA family (1, 7). Here we used a population genetics approach to determine whether the Ta1 subfamily was deleterious. As natural selection against a mutation is expected to keep it at low frequencies within a population, comparing the population frequencies of TR and FL elements should reveal whether natural selection is operating specifically against FL elements. We found that FL Ta1-containing alleles, but not those that contain TR elements or SINE (Alu) inserts, were subject to negative selection. Therefore, some consequence of L1 activity other than generating insertional mutagens, an effect of L1 uniquely related to its length, or both constitute a genetic burden for humans. ResultsBecause the Ta1 family continues to expand in present day humans (4), the h...
As humans contain a currently active L1 (LINE-1) non-LTR retrotransposon family (Ta-1), the human genome database likely provides only a partial picture of Ta-1-generated diversity. We used a non-biased method to clone Ta-1 retrotransposon-containing loci from representatives of four ethnic populations. We obtained 277 distinct Ta-1 loci and identified an additional 67 loci in the human genome database. This collection represents ∼90% of the Ta-1 population in the individuals examined and is thus more representative of the insertional history of Ta-1 than the human genome database, which lacked ∼40% of our cloned Ta-1 elements. As both polymorphic and fixed Ta-1 elements are as abundant in the GC-poor genomic regions as in ancestral L1 elements, the enrichment of L1 elements in GC-poor areas is likely due to insertional bias rather than selection. Although the chromosomal distribution of Ta-1 inserts is generally a function of chromosomal length and gene density, chromosome 4 significantly deviates from this pattern and has been much more hospitable to Ta-1 insertions than any other chromosome. Also, the intra-chromosomal distribution of Ta-1 elements is not uniform. Ta-1 elements tend to cluster, and the maximal gaps between Ta-1 inserts are larger than would be expected from a model of uniform random insertion.
The content of elongation factor Tu in E. coli B has been determined both by radioimmune assay and by GDP binding. The two assays gave comparable results: cells growing at 2 doublings per hour contained about 8 molecules of Tu per ribosome, whereas those growing at 0.22
We traced the sequence evolution of the active lineage of LINE-1 (L1) retrotransposons over the last approximately 25 Myr of human evolution. Five major families (L1PA5, L1PA4, L1PA3B, L1PA2, and L1PA1) of elements have succeeded each other as a single lineage. We found that part of the first open-reading frame (ORFI) had a higher rate of nonsynonymous (amino acid replacement) substitution than synonymous substitution during the evolution of the ancestral L1PA5 through the L1PA3B families. This segment encodes the coiled coil region of the protein-protein interaction domain of the ORFI protein (ORFIp). Statistical analysis of these changes indicates that positive selection had been acting on this region. In contrast, the coiled coil segment hardly changed during the evolution of the L1PA3B to the present L1PA1 family. Therefore, selective pressure on the coiled coil segment has changed over time. We suggest that the fast rate of amino acid replacement in the coiled coil segment reflects the adaptation of L1 either to a changing genomic environment or to host repression factors. In contrast, the second open-reading frame and the nucleic acid-binding domain of the first open-reading frame are extremely well conserved, attesting to the strong purifying selection acting on these regions.
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