Vadim Nikiforov

Unified two-metal mechanism of RNA synthesis and degradation by RNA polymerase.

In DNA‐dependent RNA polymerases, reactions of RNA synthesis and degradation are performed by the same active center (in contrast to DNA polymerases in which they are separate). We propose a unified catalytic mechanism for multisubunit RNA polymerases based on the analysis of its 3′–5′ exonuclease reaction in the context of crystal structure. The active center involves a symmetrical pair of Mg2+ ions that switch roles in synthesis and degradation. One ion is retained permanently and the other is recruited ad hoc for each act of catalysis. The weakly bound Mg2+ is stabilized in the active center in different modes depending on the type of reaction: during synthesis by the β,γ‐phosphates of the incoming substrate; and during hydrolysis by the phosphates of a non‐base‐paired nucleoside triphosphate. The latter mode defines a transient, non‐specific nucleoside triphosphate‐binding site adjacent to the active center, which may serve as a gateway for polymerization of substrates.

Four genes, two ends, and a res region are involved in transposition of Tn5053: a paradigm for a novel family of transposons carrying either a mer operon or an integron

The complete nucleotide sequence of an 8447 bp‐long mercury‐resistance transposon (Tn5053) has been determined. Tn5053 is composed of two modules: (i) the mercury‐resistance module and (ii) the transposition module. The mercury‐resistance module carries a mer operon, merRTPFAD, and appears to be a single‐ended relic of a transposon closely related to the classical mercury‐resistance transposons Tn21 and Tn501. The transposition module of Tn5053 is bounded by 25 bp terminal inverted repeats and contains four genes involved in transposition, i.e. tniA, tniB, tniQ, and tniR. Transposition of Tn5053 occurs via cointegrate formation mediated by the products of the tniABQ genes, followed by site‐specific cointegrate resolution. This is catalysed by the product of the tniR gene at the res region, which is located upstream of tniR. The same pathway of transposition is used by Tn402 (Tn5090) which carries the integron of R751. Transposition genes of Tn5053 and Tn402 are interchangeable. Sequence analysis suggests that Tn5053 and Tn402 are representatives of a new family of transposable elements, which fall into a recently recognized superfamily of transposons including retroviruses, insertion sequences of the IS3 family, and transposons Tn552 and Tn7. We suggest that the tni genes were involved in the dissemination of integrons.

Coupling between transcription termination and RNA polymerase inchworming

Advancement of RNA polymerase of E. coli occurs in alternating laps of monotonic and inchworm-like movement. Cycles of inchworming are encoded in DNA and involve straining and relaxation of the ternary complex accompanied by characteristic leaping of DNA and RNA footprints. We demonstrate that the oligo(T) tract that constitutes a normal part of transcription terminators acts as an inchworming signal so that the leap coincides with the termination event. Prevention of leaping with a roadblock of cleavage-defective EcoRI protein results in suppression of RNA chain release at a termination site. The results indicate that straining and relaxation of RNA polymerase are steps in the termination mechanism.

Donation of catalytic residues to RNA polymerase active center by transcription factor Gre

During transcription elongation, RNA polymerase (RNAP) occasionally loses its grip on the growing RNA end and backtracks on the DNA template. Prokaryotic Gre factors rescue the backtracked ternary elongating complex through stimulation of an intrinsic endonuclease activity, which removes the disengaged 3′ RNA segment. By using RNA-protein crosslinking in defined ternary elongating complexes, site-directed mutagenesis, discriminative biochemical assays, and docking of the two protein structures, we show that Gre acts by providing two carboxylate residues for coordination of catalytic Mg2+ ion in the RNAP active center. A similar mechanism is suggested for the functionally analogous eukaryotic SII factor. The results expand the general two-metal model of RNAP catalytic mechanism whereby one of the Mg2+ ions is permanently retained, whereas the other is recruited ad hoc by an auxiliary factor.

Tn5053 family transposons are res site hunters sensing plasmidal res sites occupied by cognate resolvases.

DNA sequence database search revealed that most of Tn5053/Tn402 family transposons inserted into natural plasmids were located in putative res regions upstream of genes encoding various resolvase‐like proteins. Some of these resolvase genes belonged to Tn3 family transposons and were closely related to the tnpR genes of Tn1721 and a recently detected Tn5044. Using recombinant plasmids containing fragments of Tn1721 or Tn5044 as targets in transposition experiments, we have demonstrated that Tn5053 displays striking insertional preference for the res regions of these transposons: more than 70% of Tn5053 insertion events occur in clusters inside the target res regions, while most remaining insertion events occur no further than 200 base pairs away from both sides of the res regions. We demonstrate that Tn5053 insertions (both into and outside a res region of the target plasmid) require the presence of a functional cognate resolvase gene either in cis or in trans. To our knowledge, this is the first case when a site‐specific recombination system outside a transposon has been shown to be involved in transposition.

Mercury resistance transposons of gram-negative environmental bacteria and their classification.

A total of 29 mercury resistance transposons were isolated from mercury-resistant environmental strains of proteobacteria collected in different parts of Eurasia and the USA and tested for hybridization with probes specific for transposase genes of known mercury resistance transposons. 9 were related to Tn21 in this test, 12 were related to Tn5053, 4 to Tn5041 and 1 to Tn5044; three transposons were negative in this test. Restriction mapping and DNA sequencing revealed that 12 transposons were identical or nearly identical to their corresponding relatives while the rest showed varying divergence from their closest relatives. Most of these previously unknown transposons apparently arose as a result of homologous or site-specific recombination. One of these, Tn5046, was completely sequenced, and shown to be a chimera with the mer operon and the transposition module derived from the transposons related to Tn5041 and to Tn5044, respectively. Transposon Tn5070, showing no hybridization with the specific probes used in this study, was also completely sequenced. The transposition module of Tn5070 was most closely related to that of Tn3 while the mer operon was most closely related to that of plasmid pMERPH. The merR of Tn5070 is transcribed in the same direction as the mer structural genes, which is typical for mer operons of gram-positive bacteria. Our data suggest that environmental bacteria may harbor many not yet recognized mercury resistance transposons and warrant their further inventory.

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.

Intercontinental spread of promiscuous mercury- resistance transposons in environmental bacteria

We demonstrate that horizontal spread of mer operons similar to worldwide spread of antibiotic‐resistance genes in medically important bacteria occurred in bacteria found in ores, soils and waters. The spread was mediated by different transposons and plasmids. Some of the spreading transposons were damaged in different ways but this did not prevent their further spread. Certain transposons are mosaics composed of segments belonging to distinct sequence types. These mosaics arose as a result of homologous and site‐specific recombination. Our data suggest that the mercury‐resistance operons of Gram‐negative environmental bacteria can be considered as a worldwide population composed of a relatively small number of distinct recombining clones shared, at least partially, by environmental and clinical bacteria.

Horizontal spread of mer operons among gram-positive bacteria in natural environments.

Horizontal dissemination of the genes responsible for resistance to toxic pollutants may play a key role in the adaptation of bacterial populations to environmental contaminants. However, the frequency and extent of gene dissemination in natural environments is not known. A natural horizontal spread of two distinct mercury resistance (mer) operon variants, which occurred amongst diverse Bacillus and related species over wide geographical areas, is reported. One mer variant encodes a mercuric reductase with a single N-terminal domain, whilst the other encodes a reductase with a duplicated N-terminal domain. The strains containing the former mer operon types are sensitive to organomercurials, and are most common in the terrestrial mercury-resistant Bacillus populations studied in this work. The strains containing the latter operon types are resistant to organomercurials, and dominate in a Minamata Bay mercury-resistant Bacillus population, previously described in the literature. At least three distinct transposons (related to a class II vancomycin-resistance transposon, Tn1546, from a clinical Enterococcus strain) and conjugative plasmids are implicated as mediators of the spread of these mer operons.

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.