Male-driven biased gene conversion governs the evolution of base composition in human alu repeats

Regional biases in substitution pattern are likely to be responsible for the large-scale variation in base composition observed in vertebrate genomes. However, the evolutionary forces responsible for these biases are still not clearly defined. In order to study the processes of mutation and fixation across the entire human genome, we analyzed patterns of substitution in Alu repeats since their insertion. We also studied patterns of human polymorphism within the repeats. There is a highly significant effect of recombination rate on the pattern of substitution, whereas no such effect is seen on the pattern of polymorphism. These results suggest that regional biases in substitution are caused by biased gene conversion, a process that increases the probability of fixation of mutations that increase GC content. Furthermore, the strongest correlate of substitution patterns is found to be male recombination rates rather than female or sex-averaged recombination rates. This indicates that in addition to sexual dimorphism in recombination rates, the sexes also differ in the relative rates of crossover and gene conversion.     

Alu-SINE exonization: en route to protein-coding function

The majority of more than one million primate-specific Alu elements map to nonfunctional parts of introns or intergenic sequences. Once integrated, they have the potential to become exapted as functional modules, e.g., as protein-coding domains via alternative splicing. This particular process is also termed exonization and increases protein versatility. Here we investigate 153 human chromosomal loci where Alu elements were conceivably exonized. In four selected examples, we generated, with the aid of representatives of all primate infraorders, phylogenetic reconstructions of the evolutionary steps presumably leading to exonization of Alu elements. We observed a variety of possible scenarios in which Alu elements led to novel mRNA splice forms and which, like most evolutionary processes, took different courses in different lineages. Our data show that, once acquired, some exonizations were lost again in some lineages. In general, Alu exonization occurred at various time points over the evolutionary history of primate lineages, and protein-coding potential was acquired either relatively soon after integration or millions of years thereafter. The course of these paths can probably be generalized to the exonization of other elements as well.     

The Biased Distribution of Alus in Human Isochores Might Be Driven by Recombination

Alu retrotransposons do not show a homogeneous distribution over the human genome but have a higher density in GC-rich (H) than in AT-rich (L) isochores. However, since they preferentially insert into the L isochores, the question arises: What is the evolutionary mechanism that shifts the Alu density maximum from L to H isochores? To disclose the role played by each of the potential mechanisms involved in such biased distribution, we carried out a genome-wide analysis of the density of the Alus as a function of their evolutionary age, isochore membership, and intron vs. intergene location. Since Alus depend on the retrotransposase encoded by the LINE1 elements, we also studied the distribution of LINE1 to provide a complete evolutionary scenario. We consecutively check, and discard, the contributions of the Alu/LINE1 competition for retrotransposase, compositional matching pressure, and Alu overrepresentation in introns. In analyzing the role played by unequal recombination, we scan the genome for Alu trimers, a direct product of Alu–Alu recombination. Through computer simulations, we show that such trimers are much more frequent than expected, the observed/expected ratio being higher in L than in H isochores. This result, together with the known higher selective disadvantage of recombination products in H isochores, points to Alu–Alu recombination as the main agent provoking the density shift of Alus toward the GC-rich parts of the genome. Two independent pieces of evidence—the lower evolutionary divergence shown by recently inserted Alu subfamilies and the higher frequency of old stand-alone Alus in L isochores—support such a conclusion. Other evolutionary factors, such as population bottlenecks during primate speciation, may have accelerated the fast accumulation of Alus in GC-rich isochores.     

Genomic and phylogenetic analysis of the S100A7 (Psoriasin) gene duplications within the region of the S100 gene cluster on human chromosome 1q21

Abstract The human S100 gene family encodes the EF-hand superfamily of calcium-binding proteins, with at least 14 family members clustered relatively closely together on chromosome 1q21. We have analyzed the most recently available genomic sequence of the human S100 gene cluster for evidence of tandem gene duplications during primate evolutionary history. The sequences obtained from both GenBank and GoldenPath were analyzed in detail using various comparative sequence analysis tools. We found that of the S100A genes clustered relatively closely together within a genomic region of 260 kb, only the S100A7 (psoriasin) gene region showed evidence of recent duplications. The S100A7 gene duplicated region is composed of three distinct genomic regions, 33, 11, and 31 kb, respectively, that together harbor at least five identifiable S100A7-like genes. Regions 1 and 3 are in opposite orientation to each other, but each region carries two S100A7-like genes separated by an 11-kb intergenic region (region 2) that has only one S100A7-like gene, providing limited sequence resemblance to regions 1 and 3. The duplicated genomic regions 1 and 3 share a number of different retroelements including five Alu subfamily members that serve as molecular clocks. The shared (paralogous) Alu S insertions suggest that regions 1 and 3 were probably duplicated during or after the phase of AluS amplification some 30–40 mya. We used PCR to amplify an indel within intron 1 of the S100A7a and S100A7c genes that gave the same two expected product sizes using 40 human DNA samples and 1 chimpanzee sample, therefore confirming the presence of the region 1 and 3 duplication in these species. Comparative genomic analysis of the other S100 gene members shows no similarity between intergenic regions, suggesting that they diverged long before the emergence of the primates. This view was supported by the phylogenetic analysis of different human S100 proteins including the human S100A7 protein members. The S100A7 protein, also known as psoriasin, has important functions as a mediator and regulator in skin differentiation and disease (psoriasis), in breast cancer, and as a chemotactic factor for inflammatory cells. This is the first report of five copies of the S100A7 gene in the human genome, which may impact on our understanding of the possible dose effects of these genes in inflammation and normal skin development and pathogenesis.     

Potential for retroposition by old Alu subfamilies

Alu elements sharing sequence characteristics of the old subfamilies are thought to currently be retrotranspositionally inactive. We analyzed one of these old subfamilies of Alu elements, Sx, for sequence conservation relative to the consensus and the length of the A-tail as parameters to define the presence of potential Alu Sx source genes in the human genome. Sequence identity to the left half or the right half of the Alu Sx consensus sequence was evaluated for 4424 complete elements obtained from the human genome draft sequence. A small subset of Alu Sx left halves were found to be more conserved than any of the Alu Sx right halves. Selection for promoter function in active elements may explain the slightly higher conservation of the left half. In order to determine whether this sequence identity was the result of recent activity, or simply sequence conservation for older elements, PCR amplification of some of the loci containing Sx elements with conserved left/right halves from different primate genomes was carried out. Several of these Sx Alus were found to have amplified at a later evolutionary period (<35 mya) than expected based on previous studies of Sx elements. Analysis of A-tail length, a feature correlated with current retroposition activity, varied between Alu Sx element loci in different primates, where the length increased in specific Alu elements in the human genome. The presence of few conserved Alu Sx elements and the dynamic expansion/contraction of the A-tail suggests that some of these older subfamilies may still be active at very low levels or in a few individuals. Present address: (Claudina Alemán Stevenson) Laboratory of Cell Biology, NCI/NIH Building 37/Rm 1A09, Bethesda, MD 20892, USA     

Duplication and Diversification of the Apolipoprotein CI (APOCI) Genomic Segment in Association with Retroelements

We have previously shown that several multicopy gene families within the major histocompatibility complex (MHC) arose from a process of segmental duplication. It has also been observed that retroelements play a role in generating diversity within these duplicated segments. The objective of this study was to compare the genomic organization of a gene duplication within another multicopy gene family outside the MHC. Using new continuous genomic sequence encompassing the APOE-CII gene cluster, we show that APOCI and its pseudogene, APOCI′, are contained within large duplicated segments which include sequences from the hepatic control region (HCR). Flanking Alu sequences are observed at both ends of the duplicated unit, suggesting a possible role in the integration of these segments. As observed previously within the MHC, the major differences between the segments are the insertion of sequences (approximately 200–1000 bp in length), consisting predominantly of Alu sequences. Ancestral retroelements also contribute to the generation of sequence diversity between the segments, especially within the 3′ poly(A) tract of Alu sequences. The exonic and regulatory sequences of the APOCI and HCR loci show limited sequence diversity, with exon 3 being an exception. Finally, the typing of pre- and postduplication Alus from both segments indicates an estimated time of duplication of approximately 37 million years ago (mya), some time prior to the separation of Old and New World monkeys. Received: 17 July 1999 / Accepted: 6 November 1999     

Using Alu J Elements as Molecular Clocks to Trace the Evolutionary Relationships Between Duplicated HLA Class I Genomic Segments

The class I region of the major histocompatibility complex contains two subgenomic blocks (250–350 kb each), known as the alpha and beta blocks. These blocks contain members of multicopy gene families including HLA class I, HERV-16 (previously called P5 sequences), and PERB11 (MIC). We have previously shown that each block consists of imperfect duplicated segments (duplicons) containing linked members of different gene families, retroelements and transposons that have coevolved as part of two separate evolutionary events. Another region provisionally designated here as the kappa block is located between the alpha and the beta blocks and contains HLA-E, -30, and -92, HERV-16 (P5.3), and PERB11.3 (MICC) within about 250 kb of sequence. Using Alu elements to trace the evolutionary relationships between different class I duplicons, we have found that (a) the kappa block contains paralogous (duplicated) Alu J sequences and other retroelement patterns more in common with the beta than the alpha block; (b) the retroelement pattern associated with the HLA-E duplicon is different from all other HLA class I duplicons, indicating a more complex evolution; (c) the HLA-92 duplicon, although substantially shorter, is closely related in sequence to the HLA-B and -C duplicons; (d) two of the six paralogous Alu J elements within the HLA-B and -C duplicons are associated with the HLA-X duplicon, confirming their evolutionary relationships within the beta block; and (e) the paralogous Alu J elements within the alpha block are distinctly different from those identified within the beta and kappa blocks. The sequence conservation and location of duplicated (paralogous) Alu J elements in the MHC class I region show that the beta and kappa blocks have evolved separately from the alpha block beginning at a time before or during the evolution of Alu J elements in primates. Received: 22 September 1999 / Accepted: 24 January 2000     

Identification of a unique Alu-based polymorphism and its use in human population studies

Alu elements represent a family of short interspersed DNA elements (SINEs) found in primate genomes. These are members of a group of transposable elements that integrate into the genome by the process of retrotransposition. Recent integrations of Alu elements within the human genome have generated presence/absence variants useful as DNA markers in human population studies as well as in forensic and paternity analyses. Besides the ease of use, this type of marker is unique because the absence of the Alu represents the ancestral form. We have identified an Alu-based polymorphism that consists of four alleles in which we can predict the evolutionary order. Additionally, we have developed a simple PCR plus restriction endonuclease assay to readily distinguish the four alleles. We have thus far analyzed DNA from a small set of samples comprising ten different ethnic groups. The three populations of African descent exhibited a relatively low frequency of the absence allele in contrast to the other populations, as well as being the only populations in which all four alleles were identified. One presence allele was not found in both European Caucasian and South American populations that were sampled, whereas a different presence allele was not observed among the sampled Asian populations. Additionally, the four-allele system identified variations among populations not observed by simply scoring as presence/absence variants. Therefore, extending beyond the two-allele dimorphic Alu system further elucidates population variations. These features afford this marker as a unique tool in the study of both global and regional analyses of human populations.