Piotr Cegłowski

The Toxin-Antitoxin System of the Streptococcal Plasmid pSM19035

pSM19035 of the pathogenic bacterium Streptococcus pyogenes is a low-copy-number plasmid carrying erythromycin resistance, stably maintained in a broad range of gram-positive bacteria. We show here that the omega-epsilon-zeta operon of this plasmid constitutes a novel proteic plasmid addiction system in which the epsilon and zeta genes encode an antitoxin and toxin, respectively, while omega plays an autoregulatory function. Expression of toxin Zeta is bactericidal for the gram-positive Bacillus subtilis and bacteriostatic for the gram-negative Escherichia coli. The toxic effects of zeta gene expression in both bacterial species are counteracted by proper expression of epsilon. The epsilon-zeta toxin-antitoxin cassette stabilizes plasmids in E. coli less efficiently than in B. subtilis.

The complete nucleotide sequence and environmental distribution of the cryptic, conjugative, broad-host-range plasmid pIPO2 isolated from bacteria of the wheat rhizosphere

Plasmid pIPO2 is a cryptic, conjugative, broad-host-range plasmid isolated from the wheat rhizosphere. It efficiently self-transfers between alpha, beta and gamma Proteobacteria and has a mobilizing/retromobilizing capacity for IncQ plasmids. The complete nucleotide sequence of pIPO2 is presented on the basis of its mini-Tn5::luxABtet-tagged derivative, pIPO2T. The pIPO2 sequence is 39815 bp long and contains at least 43 complete ORFs. Apart from a suite of ORFs with unknown function, all of the genes carried on pIPO2 are predicted to be involved in plasmid replication, maintenance and conjugative transfer. The overall organization of these genes is different from previously described plasmids, but is similar to the genetic organization seen in pSB102, a conjugative plasmid recently isolated from the bacterial community of the alfalfa rhizosphere. The putative conjugative transfer region of pIPO2 covers 23 kb and contains the genes required for DNA processing (Dtr) and mating pair formation (Mpf). The organization of these transfer genes in pIPO2 is highly similar to the genetic organization seen in the environmental plasmid pSB102 and in pXF51 from the plant pathogen Xylella fastidiosa. Plasmids pSB102 and pXF51 have recently been proposed to form a new family of environmental broad-host-range plasmids. Here it is suggested that pIPO2 is a new member of this family. The proposed Mpf system of pIPO2 shares high amino acid sequence similarity with equivalent VirB proteins from the type IV secretion system of Brucella spp. Sequence information was used to design primers specific for the detection of pIPO2. Environmental DNA from a range of diverse habitats was screened by PCR with these primers. Consistently positive signals for the presence of pIPO2 were obtained from a range of soil-related habitats, including the rhizospheres of young wheat plants, of field-grown oats and of grass (all gramineous plants), as well as from the rhizosphere of tomato plants. These data add to the growing evidence that plasmids carry advantageous genes with as yet undefined functions in plant-associated communities.

Characterization of the effectors required for stable inheritance of Streptococcus pyogenes pSM19035-derived plasmids in Bacillus subtilis.

The low-copy-number and broad-host-range pSM19035-derived plasmid pBT233 is stably inherited in Bacillus subtilis cells. Two distinct regions, segA and segB, enhance the segregational stability of the plasmid. Both regions function in a replicon-independent manner. The maximization of random plasmid segregation is accomplished by the recombination proficiency of the host or the presence of the pBT233 segA region. The segA region contains two open reading frames (orϕ) [α and β]. Inactivation or deletion of orϕβ results in SegA− plasmids. Better than random segregation requires an active segB region. The segB region contains two orϕs (orϕɛ and orϕζ). Inactivation of either of the orfs does not lead to an increase in cell death, but orϕζ− plasmids are randomly segregated. These results suggest that pBT233 stabilization relies on a complex system involving resolution of plasmid oligomers (segA) and on the function(s) encoded by the segB region.

Gene organization of the Streptococcus pyogenes plasmid pDB101: sequence analysis of the orfη-copS region

The gene organization of the broad-host-range low-copy-number pSM19035-derived plasmid pDB101 is presented. Analysis of the 19,202-bp sequence revealed thirteen different open reading frames (orfs). Nine of these orfs (repS-orf-orf beta-orf gamma-orf delta-orf epsilon-orf zeta-erm2-erm1 have been previously identified [Cegłowski et al., Gene 136 (1993) 1-12]. The extraordinarily long inverted repeated sequence, which includes orf alpha-orf beta-orf gamma-orf delta-orf epsilon-orf zeta, comprises 76% of the pDB101 molecule. The gene order in pDB101 is repS-orf alpha-orf beta-orf gamma-orf delta-orf epsilon-orf zeta-erm2-erm1-orf zeta-orf epsilon-orf delta-orf gamma-orf beta-orf alpha-orf eta-orf theta-orf1-copS. The organization of genes of the orf eta-orf gamma region resembles the organization of genes in the orfA-orfI region of pAM beta 1. Except for Orf1, bands of radioactive proteins corresponding to the molecular mass of the deduced reading frames (26.7, 14.3 and 10.3 kDa) were detected using the T7 promoter-expression system. The orf1 encoded a product (deduced molecular mass 28.3 kDa) which shows anomalous electrophoretical mobility corresponding to 60 kDa. The copS- and orf1-encoded proteins share homology to plasmid copy number control systems and Gram+ cocci surface proteins, respectively. The orf eta and orf theta encode proteins with unknown activity.

Characterization of a Novel Partition System Encoded by the δ and ω Genes from the Streptococcal Plasmid pSM19035

High segregational stability of the streptococcal plasmid pSM19035 is achieved by the concerted action of systems involved in plasmid copy number control, multimer resolution, and postsegregational killing. In this study, we demonstrate the role of two genes, δ and ω, in plasmid stabilization by a partition mechanism. We show that these two genes can stabilize the native pSM19035 replicon as well as other θ- and σ-type plasmids in Bacillus subtilis. In contrast to other known partition systems, in this case the two genes are transcribed separately; however, they are coregulated by the product of the parB-like gene ω. Analysis of mutants of the parA-like gene δ showed that the Walker A ATPase motif is necessary for plasmid stabilization. The ParB-like product of the ω gene binds to three regions containing repeated WATCACW heptamers, localized in the copS (regulation of plasmid copy number), δ, and ω promoter regions. We demonstrate that all three of these regions can cause partition-mediated incompatibility. Moreover, our data suggest that each of these could play the role of a centromere-like sequence. We conclude that δ and ω constitute a novel type of plasmid stabilization system.

In Vivo Interactions between Toxin-Antitoxin Proteins Epsilon and Zeta of Streptococcal Plasmid pSM19035 in Saccharomyces cerevisiae

The widespread prokaryotic toxin-antitoxin (TA) systems involve conditional interaction between two TA proteins. The interaction between the Epsilon and Zeta proteins, constituting the TA system of plasmid pSM19035 from Streptococcus pyogenes, was detected in vivo using a yeast two-hybrid system. As we showed using Saccharomyces cerevisiae, the Zeta toxin hybrid gene also exerts its toxic effects in a dose-dependent manner in eukaryotic cells. Analysis of mutant proteins in the two-hybrid system demonstrated that the N-terminal part of Zeta and the N-terminal region of Epsilon are involved in the interaction. The N-terminal region of the Zeta protein and its ATP/GTP binding motif were found to be responsible for the toxicity.

Isolation, sequence and expression in Escherichia coli, Bacillus subtilis and Lactococcus lactis of the DNase (streptodornase)-encoding gene from Streptococcus equisimilis H46A

A partial library of BclI-generated chromosomal DNA fragments from Streptococcus equisimilis H64A (Lancefield Group C) was constructed in Escherichia coli. Clones displaying either streptokinase or deoxyribonuclease (streptodornase; SDC) activities were isolated. The gene (sdc) expressing the SDC activity was allocated on the 1.1-kb AccI DNA subfragment. Sequence analysis of this DNA fragment revealed the presence of one open reading frame, which could encode a protein of 36.8 kDa. The N-terminal portion of the deduced protein exhibited features characteristic of prokaryotic signal peptides. The sdc gene was expressed in E. coli, Bacillus subtilis and Lactococcus lactis. As observed for S. equisimilis, in the heterologous Gram + hosts, at least part of the SDC protein was secreted into the medium.

M.(phi)BssHII, a novel cytosine-C5-DNA-methyltransferase with target-recognizing domains at separated locations of the enzyme.

In all cytosine‐C5‐DNA‐methyltransferases (MTases) from prokaryotes and eukaryotes, remarkably conserved amino acid sequence elements responsible for general enzymatic functions are arranged in the same canonical order. In addition, one variable region, which includes the target‐recognizing domain(s) (TRDs) characteristic for each enzyme, has been localized in one region between the same blocks of these conserved elements. This conservation in the order of conserved and variable sequences suggests stringent structural constraints in the primary structure to obtain the correct folding of the enzymes. Here we report the characterization of a new type of a multispecific MTase, M.(φ)BssHII, which is expressed as two isoforms. Isoform I is an entirely novel type of MTase which has, in addition to the TRDs at the conventional location, one TRD located at a non‐canonical position at its N‐terminus. Isoform II is represented by the same MTase, but without the N‐terminal TRD. The N‐terminal TRD provides HaeII methylation specificity to isoform I. The TRD is fully functional when engineered into either the conventional variable region of M.(φ)BssHII or the related monospecific M.φ3TII MTase. The implications of this structural plasticity with respect to the evolution of MTases are discussed.

Tandem multiplication of the IS26‐flanked amplicon with the blaSHV‐5 gene within plasmid p1658/97

The IncF plasmid p1658/97 (c. 125 kb) from Escherichia coli isolates recovered during a clonal outbreak in a hospital in Warsaw, Poland, in 1997 contains the extended-spectrum β-lactamase (ESBL) gene bla(SHV-5), originated from the Klebsiella pneumoniae chromosome. A region containing the bla(SHV-5) gene is flanked by two IS26 copies and its copy number multiplies spontaneously within p1658/97 and RecA-deficient E. coli strains. Here, we demonstrate that the amplified IS26-bla(SHV-5) units were arranged in tandems, containing up to more than 10 units, which could raise ceftazidime MICs for host strains from 4 μg mL(-1) to more than 128 μg mL(-1). Successive deletions within p1658/97, located outside the amplifiable module and encompassing even as little as c. 15% of the plasmid, blocked the amplification. Moreover, the complementing re-introduction of the deleted fragments in trans did not restore the process. Similarly, insertions of a 1-kb DNA fragment into the amplicon inhibited its self-multiplication ability. The module was able to transmit into another IS26-containing plasmid by recombination. The results prompted us to speculate that local DNA structure, especially favorable in p1658/97, might have been responsible for the IS26-bla(SHV-5) multiplication ability.