[A comparative analysis of regulatory regions of the transthyretin gene in the mouse, human, and chimpanzee genomes]. / Sravnitel'nyi analiz oblastei reguliatsii gena transtiretina v genomakh myshi, cheloveka i shimpanze.

A full genome analysis of differences between the gene expression in the human and chimpanzee brains revealed that the gene for transthyretin, the carrier of thyroid hormones, is differently transcribed in the cerebella of these species. A 7-kbp DNA fragment of chimpanzee was sequenced to identify possible regulatory sequences responsible for the differences in expression. One hundred and thirteen substitutions were found in the chimpanzee sequence in comparison with the human sequence. About 40% of the substitutions were revealed within the repeating elements of the genome; their location and sizes did not differ from those in the corresponding fragments of the human genome, and the nucleotide sequences had a high degree of identity. A comparison of nucleotide sequences of the transthyretin region of human, chimpanzee, and mouse genes revealed substantial differences in the distribution of G + C content along the examined fragment in the human (chimpanzee) and mouse genes and allowed us to localize three sequence tracts with a higher degree of identity in the three species. One of these tracts is located in the promoter region of the gene, and the other two probably determine the specificity of transthyretin gene expression in the liver and brain. One of the conserved tracts of the chimpanzee genome was found to have a single and a triple nucleotide substitution. The triple substitution distinguishes chimpanzees from humans and mice, which have identical sequences of this site. It is likely that these substitutions are responsible for the differences in the expression levels of the transthyretin gene in the human and chimpanzee brains.

[Nucleotide sequences of long terminal repeats of the human endogenous retrovirus (LTR HERV-K) on the short arm of chromosome 7: identification, analysis and evaluation of transcriptional activity]. / Posledovatel'nosti dlinnykh kontsevykh povtorov éndogennogo retrovirusa (LTR HERV-K) korotkogo plecha khromosomy 7 cheloveka: poisk, analiz i opredelenie transkriptsionnoi aktivnosti.

Six clones containing long terminal repeat (LTR) sequences of human endogenous retrovirus of the HERV-K family were found in the YAC library (1200 kb) of the short arm of human chromosome 7. The sequence sizes of the three clones corresponded to the full-length LTR (969 bp). The LTR localization was determined using FISH and verified by comparison with the GenBank database. All three DNA fragments containing solitary LTRs were transcribed in normal germline cells (testicular parenchyma tissue). The differences in the expression of these clones in the germline tumor cells (seminoma) were observed.

Identification of paralogous HERV-K LTRs on human chromosomes 3, 4, 7 and 11 in regions containing clusters of olfactory receptor genes.

A locus harboring a human endogenous retroviral LTR (long terminal repeat) was mapped on the short arm of human chromosome 7 (7p22), and its evolutionary history was investigated. Sequences of two human genome fragments that were homologous to the LTR-flanking sequences were found in human genome databases: (1) an LTR-containing DNA fragment from region 3p13 of the human genome, which includes clusters of olfactory receptor genes and pseudogenes; and (2) a fragment of region 21q22.1 lacking LTR sequences. PCR analysis demonstrated that LTRs with highly homologous flanking sequences could be found in the genomes of human, chimp, gorilla, and orangutan, but were absent from the genomes of gibbon and New World monkeys. A PCR assay with a primer set corresponding to the sequence from human Chr 3 allowed us to detect LTR-containing paralogous sequences on human chromosomes 3, 4, 7, and 11. The divergence times for the LTR-flanking sequences on chromosomes 3 and 7, and the paralogous sequence on chromosome 21, were evaluated and used to reconstruct the order of duplication events and retroviral insertions. (1) An initial duplication event that occurred 14-17 Mya and before LTR insertion - produced two loci, one corresponding to that located on Chr 21, while the second was the ancestor of the loci on chromosomes 3 and 7. (2) Insertion of the LTR (most probably as a provirus) into this ancestral locus took place 13 Mya. (3) Duplication of the LTR-containing ancestral locus occurred 11 Mya, forming the paralogous modern loci on Chr 3 and 7.