Instability of interstitial telomeric sequences in the human genome

The length variability of four human interstitial telomeric sequences (ITs) is described. Three of the ITs contain short telomeric stretches ranging between 53 and 84 bp and are localized in 21q22, 2q31, and 7q36; the fourth IT derives from the subtelomeric domain of chromosome 6p and contains a tract of a few hundred basepairs of exact and degenerate repeats. Using primers flanking the repeats, we amplified the genomic DNA from unrelated individuals and from family members, and we found that all the loci are polymorphic. At the 21q22 IT locus, two equally frequent alleles were found, while the number of alleles at the 2q31, 7q36, and 6pter IT loci was 8, 6, and 4, respectively. Sequence analysis revealed that in the three loci containing short ITs the alleles differ from one another for multiples of the hexanucleotide; it is likely that the mechanism leading to the polymorphism is DNA polymerase slippage. These loci were also unstable in gastric tumor cells characterized by microsatellite instability. At the 6pter IT locus, the four alleles range in length from about 500 to about 700 bp; this variability is probably due to unequal exchange or gene conversion. Our data indicate that stretches of exact internal telomeric repeats can be highly unstable, like microsatellites with shorter units, and that they can be useful polymorphic markers for linkage analysis, for forensic applications, and for the detection of genetic instability in tumors.     

Fast-evolving noncoding sequences in the human genome

Background

Gene regulation is considered one of the driving forces of evolution. Although protein-coding DNA sequences and RNA genes have been subject to recent evolutionary events in the human lineage, it has been hypothesized that the large phenotypic divergence between humans and chimpanzees has been driven mainly by changes in gene regulation rather than altered protein-coding gene sequences. Comparative analysis of vertebrate genomes has revealed an abundance of evolutionarily conserved but noncoding sequences. These conserved noncoding (CNC) sequences may well harbor critical regulatory variants that have driven recent human evolution.

Results

Here we identify 1,356 CNC sequences that appear to have undergone dramatic human-specific changes in selective pressures, at least 15% of which have substitution rates significantly above that expected under neutrality. The 1,356 'accelerated CNC' (ANC) sequences are enriched in recent segmental duplications, suggesting a recent change in selective constraint following duplication. In addition, single nucleotide polymorphisms within ANC sequences have a significant excess of high frequency derived alleles and high F _ST values relative to controls, indicating that acceleration and positive selection are recent in human populations. Finally, a significant number of single nucleotide polymorphisms within ANC sequences are associated with changes in gene expression. The probability of variation in an ANC sequence being associated with a gene expression phenotype is fivefold higher than variation in a control CNC sequence.

Conclusion

Our analysis suggests that ANC sequences have until very recently played a role in human evolution, potentially through lineage-specific changes in gene regulation.     

Organization and integration sites in the human genome of endogenous retroviral sequences belonging to HERV-E family

The present paper reports the characterization of HERV-E endogenous retroviral sequences in the human genome by using three complementary approaches. Firstly, we identified genomic clones containing HERV-E by BLAST screening of human DNA databases by using the entire sequence of a characterized HERV-E clone (M10976) as a query. The genomic structure and integration sites of the HERV-E elements were characterized. Secondly, new integration sites of HERV-E elements were revealed by a retroviral LTR-arbitrary primer-PCR (RELAP-PCR) technique. BLAST analysis of the PCR products identified a subgroup that shows low identity (75%) to the original clone M10976 and slightly higher identity (80%) to a closely related HERV-E (Ac. n. K02166). Finally, we performed FISH mapping, which revealed sites of integration of HERV-E not previously identified at the cytogenetic level. A preliminary analysis of genes mapping in the same bands as HERV-E integration sites was performed: several loci relevant to physiological and/or pathological processes were detected. Our findings may provide clues to identify HERV-E integration sites adjacent to genes with important biological roles.     

Triplex-forming oligonucleotide target sequences in the human genome

The existence of sequences in the human genome which can be a target for triplex formation, and accordingly are candidates for anti-gene therapies, has been studied by using bioinformatics tools. It was found that the population of triplex-forming oligonucleotide target sequences (TTS) is much more abundant than that expected from simple random models. The population of TTS is large in all the genome, without major differences between chromosomes. A wide analysis along annotated regions of the genome allows us to demonstrate that the largest relative concentration of TTS is found in regulatory regions, especially in promoter zones, which suggests a tremendous potentiality for triplex strategy in the control of gene expression. The dependence of the stability and selectivity of the triplexes on the length of the TTS is also analysed using knowledge-based rules.     

Transposable element derived DNaseI-hypersensitive sites in the human genome

Background  

Transposable elements (TEs) are abundant genomic sequences that have been found to contribute to genome evolution in unexpected ways. Here, we characterize the evolutionary and functional characteristics of TE-derived human genome regulatory sequences uncovered by the high throughput mapping of DNaseI-hypersensitive (HS) sites.     

Overlapping alternative donor splice sites in the human genome

Over 50% of donor splice sites in the human genome have a potential alternative donor site at a distance of three to six nucleotides. Conservation of these potential sites is determined by the consensus requirements and by its exonic or intronic location. Several hundred pairs of overlapping sites are confirmed to be alternatively spliced as both sites in a pair are supported by a protein, by a full-length mRNA, or by expressed sequence tags (ESTs) from at least two independent clone libraries. Overlapping sites may clash with consensus requirements. Pairs with a site shift of four nucleotides are the most abundant, despite the frameshift in the protein-coding region that they introduce. The site usage in pairs is usually uneven, and the major site is more frequently conserved in other mammalian genomes. Overlapping alternative donor sites and acceptor sites may have different functional roles: alternative splicing of overlapping acceptor sites leads mainly to microvariations in protein sequences; whereas alternative donor sites often lead to frameshifts and thus either yield major differences in the protein sequence and structure, or generate nonsense-mediated decay-inducing mRNA isoforms likely involved in regulated unproductive splicing pathways.     

T-DNA integration into the Arabidopsis genome depends on sequences of pre-insertion sites

A statistical analysis of 9000 flanking sequence tags characterizing transferred DNA (T-DNA) transformants in Arabidopsis sheds new light on T-DNA insertion by illegitimate recombination. T-DNA integration is favoured in plant DNA regions with an A-T-rich content. The formation of a short DNA duplex between the host DNA and the left end of the T-DNA sets the frame for the recombination. The sequence immediately downstream of the plant A-T-rich region is the master element for setting up the DNA duplex, and deletions into the left end of the integrated T-DNA depend on the location of a complementary sequence on the T-DNA. Recombination at the right end of the T-DNA with the host DNA involves another DNA duplex, 2–3 base pairs long, that preferentially includes a G close to the right end of the T-DNA.     

Absence of methylation at HpaII sites in three human genomic tRNA sequences.

It has been known since the development of nearest neighbor analysis that the frequency of the dinucleotide CpG is markedly suppressed in vertebrate DNA (i.e. less than %C x %G). This suppression appears to be heterogeneous since it was shown some years ago that three vertebrate tRNA genes did not exhibit CpG suppression. We have analyzed 13 different human tRNA genes and found that they also do not exhibit CpG suppression. Because CpG suppression has been linked, to some extent at least, to the methylation-deamination process by which a methylated CpG is mutated to TpG, we investigated whether the lack of suppression of CpG in tRNAs could originate from an absence of methylation. Three human tRNA genes were selected from Genbank (lysine, Proline, and Phenylalanine) and examined for methylation at HpaII sites by polymerase chain reaction (PCR) and Southern blot analysis. The observed patterns were consistent with the absence of methylation at the seven HpaII sites analyzed in and around the tRNA genes, and we predict that the remaining CpGs in these genes will be unmethylated. Since GC-rich promoter regions also escape CpG suppression and since they are generally unmethylated, avoidance of methylation may be a general explanation for the absence of CpG suppression in selected regions of vertebrate genomes.     

Medium reiteration frequency repetitive sequences in the human genome.

Fourteen novel medium reiteration frequency (MER) families were found, in the human genome, by using two different methods. Repetition frequencies per haploid human genome were estimated for each of these families as well as for six previously described MER DNA families. By these measurements, the families were found to contain variable numbers of elements, ranging from 200 to 10,000 copies per haploid human genome.     

A genome-wide analysis of FRT-like sequences in the human genome

Efficient and precise genome manipulations can be achieved by the Flp/FRT system of site-specific DNA recombination. Applications of this system are limited, however, to cases when target sites for Flp recombinase, FRT sites, are pre-introduced into a genome locale of interest. To expand use of the Flp/FRT system in genome engineering, variants of Flp recombinase can be evolved to recognize pre-existing genomic sequences that resemble FRT and thus can serve as recombination sites. To understand the distribution and sequence properties of genomic FRT-like sites, we performed a genome-wide analysis of FRT-like sites in the human genome using the experimentally-derived parameters. Out of 642,151 identified FRT-like sequences, 581,157 sequences were unique and 12,452 sequences had at least one exact duplicate. Duplicated FRT-like sequences are located mostly within LINE1, but also within LTRs of endogenous retroviruses, Alu repeats and other repetitive DNA sequences. The unique FRT-like sequences were classified based on the number of matches to FRT within the first four proximal bases pairs of the Flp binding elements of FRT and the nature of mismatched base pairs in the same region. The data obtained will be useful for the emerging field of genome engineering.     

The distribution of interspersed repetitive DNA sequences in the human genome

The distribution of interspersed repetitive DNA sequences in the human genome has been investigated, using a combination of biochemical, cytological, computational, and recombinant DNA approaches. "Low-resolution" biochemical experiments indicate that the general distribution of repetitive sequences in human DNA can be adequately described by models that assume a random spacing, with an average distance of 3 kb. A detailed "high-resolution" map of the repetitive sequence organization along 400 kb of cloned human DNA, including 150 kb of DNA fragments isolated for this study, is consistent with this general distribution pattern. However, a higher frequency of spacing distances greater than 9.5 kb was observed in this genomic DNA sample. While the overall repetitive sequence distribution is best described by models that assume a random distribution, an analysis of the distribution of Alu repetitive sequences appearing in the GenBank sequence database indicates that there are local domains with varying Alu placement densities. In situ hybridization to human metaphase chromosomes indicates that local density domains for Alu placement can be observed cytologically. Centric heterochromatin regions, in particular, are at least 50-fold underrepresented in Alu sequences. The observed distribution for repetitive sequences in human DNA is the expected result for sequences that transpose throughout the genome, with local regions of "preference" or "exclusion" for integration.     

A ubiquitous family of repeated DNA sequences in the human genome

Renatured DNA from human and many other eukaryotes is known to contain 300-nucleotide duplex regions formed from renatured repeated sequences. These short repeated DNA sequences are widely believed to be interspersed with single copy DNA sequences. In this work we show that at least half of these 300-nucleotide duplexes share a cleavage site for the restriction enzyme AluI. This site is located 170 nucleotides from one end. This Alu family of repeated sequences makes up at least 3% of the genome and is present in several hundred thousand copies.Inverted repeated sequences are also known to contain a short 300-nucleotide duplex region. We find that at least half of the 300-nucleotide duplex regions in inverted repeated sequences also have an AluI restriction site located 170 nucleotides from one end.By driven renaturation techniques, the Alu family is shown to be distributed over a minimum range of 30% to 60% of the genome. (The breadth of this range reflects the presence of inverted repeated sequences which, in part, include the Alu family.) These findings imply that the interspersion pattern of repeated and single copy sequences in human DNA is largely dominated by one family of repeated sequences.