E. D. Sverdlov

Retroviruses and primate evolution

Human endogenous retroviruses (HERVs), probably representing footprints of ancient germ-cell retroviral infections, occupy about 1% of the human genome. HERVs can influence genome regulation through expression of retroviral genes, either via genomic rearrangements following HERV integrations or through the involvement of HERV LTRs in the regulation of gene expression. Some HERVs emerged in the genome over 30 MYr ago, while others have appeared rather recently, at about the time of hominid and ape lineages divergence. HERVs might have conferred antiviral resistance on early human ancestors, thus helping them to survive. Furthermore, newly integrated HERVs could have changed the pattern of gene expression and therefore played a significant role in the evolution and divergence of Hominoidea superfamily. Comparative analysis of HERVs, HERV LTRs, neighboring genes, and their regulatory interplay in the human and ape genomes will help us to understand the possible impact of HERVs on evolution and genome regulation in the primates. BioEssays 22:161-171, 2000.

Pig kidney Na+,K+-ATPase: Primary structure and spatial organization

(Na+ + K+)‐ATPase α‐Subunit β‐Subunit cDNA nucleotide sequence Primary structure Glycopeptide Transmembrane arrangement

Perpetually mobile footprints of ancient infections in human genome

Up to 1% of the human genome is represented by human endogenous retroviruses (HERVs) and their fragments that are likely footprints of ancient primate germ‐cell infections by retroviruses that occurred 10–60 million years ago. HERV solitary long terminal repeats (LTRs) can be often met in close vicinity to functional genes. The LTRs comprise a set of regulatory sequences like promoters, enhancers, hormone responsive elements and polyadenylation signals that might come out as new regulatory signals to resident genes and thus change their regulation in evolution. Moreover, the LTRs have a potential for chromatin remodeling that can also modulate gene expression. This review describes the integration specificity and distribution of the HERVs and LTRs in the human genome and discusses possible functional consequences of their integration in the vicinity of genes.

Solitary HERV-K LTRs possess bi-directional promoter activity and contain a negative regulatory element in the U5 region

Reporter gene analysis of HERV‐K solitary long terminal repeats (LTRs) showed that they retain detectable activity in human teratocarcinoma cells, and can direct the transcription in both orientations relative to the reporter gene. Deletion analysis demonstrated the possible existence of alternative promoters within the LTR as well as a silencer‐like element in the U5 region. Our results indicate also that all‐trans‐retinoic acid is capable of modulating expression of the reporter gene directed by a HERV‐K LTR in NT2/D1 cells.

At Least 50% of Human-Specific HERV-K (HML-2) Long Terminal Repeats Serve In Vivo as Active Promoters for Host Nonrepetitive DNA Transcription

ABSTRACT We report the first genome-wide comparison of in vivo promoter activities of a group of human-specific endogenous retroviruses in healthy and cancerous germ line tissues. To this end, we employed a recently developed technique termed genomic repeat expression monitoring. We found that at least 50% of human-specific long terminal repeats (LTRs) possessed promoter activity, and many of them were up- or downregulated in a seminoma. Individual LTRs were expressed at markedly different levels, ranging from ∼0.001 to ∼3% of the housekeeping beta-actin gene transcript level. We demonstrated that the main factors affecting the LTR promoter activity were the LTR type (5′-proviral, 3′ proviral, or solitary) and position with regard to genes. The averaged promoter strengths of solitary and 3′-proviral LTRs were almost identical in both tissues, whereas 5′-proviral LTRs displayed two- to fivefold higher promoter activities. The relative content of promoter-active LTRs in gene-rich regions was significantly higher than that in gene-poor loci. This content was maximal in those regions where LTRs “overlapped” readthrough transcripts. Although many promoter-active LTRs were mapped near known genes, no clear-cut correlation was observed between transcriptional activities of genes and neighboring LTRs. Our data also suggest a selective suppression of transcription for LTRs located in gene introns.

Genes from the medicinal leech (Hirudo medicinalis) coding for unusual enzymes that specifically cleave endo- epsilon ( gamma -Glu)-Lys isopeptide bonds and help to dissolve blood clots

Abstract We previously detected in salivary gland secretions of the medicinal leech (Hirudo medicinalis) a novel enzymatic activity, endo-ɛ(γ-Glu)-Lys isopeptidase, which cleaves isopeptide bonds formed by transglutaminase (Factor XIIIa) between glutamine γ-carboxamide and the ɛ-amino group of lysine. Such isopeptide bonds, either within or between protein polypeptide chains are formed in many biological processes. However, before we started our work no enzymes were known to be capable of specifically splitting isopeptide bonds in proteins. The isopeptidase activity we detected was specific for isopeptide bonds. The enzyme was termed destabilase. Here we report the first purification of destabilase, part of its amino acid sequence, isolation and sequencing of two related cDNAs derived from the gene family that encodes destabilase proteins, and the detection of isopeptidase activity encoded by one of these cDNAs cloned in a baculovirus expression vector. The deduced mature protein products of these cDNAs contain 115 and 116 amino acid residues, including 14 highly conserved Cys residues, and are formed from precursors containing specific leader peptides. No homologous sequences were found in public databases.

RNA polymerase rifampicin resistance mutations in Escherichia coli: Sequence changes and dominance

SummaryFive recombinant plasmids, pBK2646, pBK611, pRC3, pRC4 and pRC5, carrying rpoB rifampicin-resistant RNA-polymerase genes were obtained.The sequence analysis of these plasmids revealed certain structural changes in the rpoB gene which specify corresponding alterations in the β-subunit of RNA polymerase. Some functional properties of the corresponding mutant strains and their RNA polymerases have been investigated.

Destabilase from the medicinal leech is a representative of a novel family of lysozymes

Intrinsic lysozyme-like activity was demonstrated for destabilase from the medicinal leech supported by (1) high specific lysozyme activity of the highly purified destabilase, (2) specific inhibition of the lysozyme-like activity by anti-destabilase antibodies, and (3) appreciable lysozyme-like activity in insect cells infected with recombinant baculoviruses carrying cDNAs encoding different isoforms of destabilase. Several isoforms of destabilase constitute a protein family at least two members of which are characterized by lysozyme activity. The corresponding gene family implies an ancient evolutionary history of the genes although the function(s) of various lysozymes in the leech remains unclear. Differences in primary structures of the destabilase family members and members of known lysozyme families allow one to assign the former to a new family of lysozymes. New proteins homologous to destabilase were recently described for Caenorhabditis elegans and bivalve mollusks suggesting that the new lysozyme family can be widely distributed among invertebrates. It remains to be investigated whether the two enzymatic activities (isopeptidase and lysozyme-like) are attributes of one and the same protein.

Differences in HERV-K LTR insertions in orthologous loci of humans and great apes

The classification of the long terminal repeats (LTRs) of the human endogenous retrovirus HERV-K (HML-2) family was refined according to diagnostic differences between the LTR sequences. The mutation rate was estimated to be approximately equal for LTRs belonging to different families and branches of human endogenous retroviruses (HERVs). An average mutation rate value was calculated based on differences between LTRs of the same HERV and was found to be 0.13% per million years (Myr). Using this value, the ages of different LTR groups belonging to the LTR HML-2 subfamily were found to vary from 3 to 50Myr. Orthologous potential LTR-containing loci from different primate species were PCR amplified using primers corresponding to the genomic sequences flanking LTR integration sites. This allowed us to calculate the phylogenetic times of LTR integrations in primate lineages in the course of the evolution and to demonstrate that they are in good agreement with the LTR ages calculated from the mutation rates. Human-specific integrations for some very young LTRs were demonstrated. The possibility of LTRs and HERVs involvement in the evolution of primates is discussed.

Mutation to rifampicin resistance at the beginning of the RNA polymerase ? subunit gene in Escherichia coli

SummaryThe unusual recombinant plasmid pRC19 carrying the N-terminal fragment of the Escherichia coli RNA polymerase rpoB gene was found to specify high level rifampicin resistance of E. coli cells. Sequence analysis of this plasmid revealed one substitution only: transversion G→T, leading to amino acid substitution Val146→Phe. This mutational change marks the second domain of the β subunit involved in rifampicin binding.