Establishment of a genome-wide and quantitative protocol for assessment of transcriptional activity at human retrotransposon L1 antisense promoters.

Long interspersed element 1 (L1) retrotransposon sequences are widespread in the human genome, occupying ~500,000 locations. The majority of L1s have lost their retrotransposition capability, although a significant population of human L1s maintains bidirectional transcriptional activity from the internal promoter. While the sense promoter drives transcription of the entire L1 mRNA and leads to L1 retrotransposition, the antisense promoter (ASP) transcribes L1-gene chimeric RNAs that include neighboring exon sequences. Activation mechanisms and functional impacts of L1ASP transcription are thought to vary at every L1ASP location. To explore the locus-specific regulation and function of L1ASP transcription, quantitative methodology is necessary for identifying the genomic positions of highly active L1ASPs on a genome-wide scale. Here, we employed deep-sequencing techniques and built a 3' RACE-based experimental and bioinformatics protocol, named the L1 antisense transcriptome protocol (LATRAP). In LATRAP, the PCR primer and the read mapping scheme were designed to reduce false positives and negatives, which may have been included as hits in previous cloning studies. LATRAP was here applied to the A549 human lung cancer cell line, and 313 L1ASP loci were detected to have transcriptional activity but differed in the number of mapped reads by four orders of magnitude. This indicates that transcriptional activities of the individual L1ASPs can vary greatly and that only a small population of L1ASP loci is active within individual nuclei. LATRAP is the first experimental method for ranking L1ASPs according to their transcriptional activity and will thus open a new avenue to unveiling the locus-specific biology of L1ASPs.

Polymorphic L1 retrotransposons are frequently in strong linkage disequilibrium with neighboring SNPs.

L1 retrotransposons have been the major driver of structural variation of the human genome. L1 insertion polymorphism (LIP)-mediated genomic variation can alter the transcriptome and contribute to the divergence of human phenotypes. To assess this possibility, a genome-wide association study (GWAS) including LIPs is required. Toward this ultimate goal, the present study examined linkage disequilibrium between six LIPs and their neighboring single nucleotide polymorphisms (SNPs). Genomic PCR and sequencing of L1-plus and -minus alleles from different donors revealed that all six LIPs were in strong linkage disequilibrium with at least one SNP. In addition, comparison of syntenic regions containing the identified SNP nucleotides was performed among modern humans (L1-plus and -minus alleles), archaic humans and non-human primates, revealing two different evolutionary schemes that might have resulted in the observed strong SNP-LIP linkage disequilibria. This study provides an experimental framework and guidance for a future SNP-LIP integrative GWAS.

The bonobo genome compared with the chimpanzee and human genomes.

Two African apes are the closest living relatives of humans: the chimpanzee (Pan troglodytes) and the bonobo (Pan paniscus). Although they are similar in many respects, bonobos and chimpanzees differ strikingly in key social and sexual behaviours, and for some of these traits they show more similarity with humans than with each other. Here we report the sequencing and assembly of the bonobo genome to study its evolutionary relationship with the chimpanzee and human genomes. We find that more than three per cent of the human genome is more closely related to either the bonobo or the chimpanzee genome than these are to each other. These regions allow various aspects of the ancestry of the two ape species to be reconstructed. In addition, many of the regions that overlap genes may eventually help us understand the genetic basis of phenotypes that humans share with one of the two apes to the exclusion of the other.