Establishment of a Cre recombinase based mutagenesis protocol for markerless gene deletion in Streptococcus suis.

The lack of knowledge about pathogenicity mechanisms of Streptococcus (S.) suis is, at least partially, attributed to limited methods for its genetic manipulation. Here, we established a Cre-lox based recombination system for markerless gene deletions in S. suis serotype 2 with high selective pressure and without undesired side effects.

Disruption of srtA gene in Streptococcus suis results in decreased interactions with endothelial cells and extracellular matrix proteins.

Streptococcus suis, a major pathogen of swine, is an emerging zoonotic agent which causes meningitis and septic shock. In this study, we investigated the ability of S. suis mutant strain (SRTDeltaA) lacking the sortase A gene (srtA) to interact with host cells and extracellular matrix (ECM) proteins, as well as its virulence in a mouse infection model. We demonstrated that mutant SRTDeltaA had reduced capacity to adhere to and invade porcine brain microvascular endothelial cells compared to the wild-type strain. In addition, mutant SRTDeltaA also showed significantly less adherence to plasma fibronectin, cellular fibronectin and collagen type I. However, disruption of srtA had little effect on the virulence of S. suis in a mouse intraperitoneal model of infection. These results indicate that surface proteins anchored by sortase A are required for a normal level of bacterial binding. However, other factors may also be important for S. suis virulence and interaction with host tissues.

Thermosensitive suicide vectors for gene replacement in Streptococcus suis.

Three thermosensitive (Ts) suicide vectors, pSET4s, pSET5s, and pSET6s, have been constructed for gene replacement in Streptococcus suis. Each vector contains an antibiotic-resistance gene (spc or cat), a Ts replication origin of pWV01 lineage, multiple cloning sites, lacZ', and the ColE1 replication origin of pUC19. These vectors could be propagated at 37 degrees C in Escherichia coli, but their replication was blocked above 37 degrees C in S. suis. Moreover, the thermosensitivity of the replication origin was confirmed in S. equi ssp. equi, S. equi ssp. zooepidemicus, and S. dysgalactiae by using pSET4s. For inactivation of the sly gene, which encodes a thiol-activated hemolysin of S. suis, pSLYK, in which the sly gene was interrupted by the cat gene, was constructed using pSET4s and introduced into S. suis DAT2. After growth at the nonpermissive temperature under the antibiotic pressure, the chromosomal sly gene was replaced with the sly::cat gene of pSLYK by a double-crossover event at a rate of 2.6% among chloramphenicol-resistant cells. Moreover, complementation of the sly gene by use of the previously reported S. suis-E. coli shuttle vector pSET2 was demonstrated. These results indicate that the Ts suicide vectors described here will facilitate the genetic analysis of S. suis and other streptococci of veterinary importance by means of allelic exchange of the genes of interest via homologous recombination.

Distribution of the SsuDAT1I restriction-modification system among different serotypes of Streptococcus suis.

The SsuDAT1I restriction-modification (R-M) system, which contains two methyltransferases and two restriction endonucleases with recognition sequence 5'-GATC-3', was first found in a field isolate of Streptococcus suis serotype 2. Isoschizomers of the R-M system were found in the same locus between purH and purD in a field isolate of serotype 1/2 and the reference strains of serotypes 3, 7, 23, and 26 among 29 strains of different serotypes examined in this study. The R-M gene sequences in serotypes 1/2, 3, 7, and 23 were very similar to those of SsuDAT1I, whereas those in serotype 26 were less similar. These results indicate intraspecies recombination among them and genetic divergence through their evolution.

Construction and characterization of Streptococcus suis-Escherichia coli shuttle cloning vectors.

pSSU1, a native plasmid of Streptococcus suis DAT1, was used to construct pSET-series shuttle vectors. In addition to the replication function of pSSU1, these vectors contain the multiple cloning sites and lacZ' gene from pUC19, which means that X-gal screening can be used to select recombinants in Escherichia coli. pSET1, pSET2, and pSET3 carry cat, spc, and both of these genes, respectively, as selectable markers. These vectors could be introduced into S. suis, E. coli, Salmonella typhimurium, S. pneumoniae, and S. equi ssp. equi by electrotransformation. The recA gene was cloned from S. suis and sequenced, and this information was used in the construction of a recA mutant of S. suis. Transformation frequencies and/or plasmid stability of all pSET vectors tested were decreased in both S. suis and E. coli recA mutants compared with the parental strains. These results suggested that functional RecA protein improved the maintenance of pSET vectors in both S. suis and E. coli. Moreover, cloning of the functional S. suis recA gene into pSET2 and complementation analysis of the recA mutant were successful in S. suis but not in E. coli. These results showed that pSET vectors are useful tools for cloning and analyzing S. suis genes in S. suis strains directly.

The roles of Nramp1 and Tnfa genes in nitric oxide production and their effect on the growth of Salmonella typhimurium in macrophages from Nramp1 congenic and tumor necrosis factor-alpha-/- mice.

The macrophages from Nramp1 congenic mice and tumor necrosis factor (TNF)-alpha(-/-) mice were used to examine the functions of Nramp1 and Tnfa genes in nitric oxide (NO) production and Salmonella typhimurium infection. It was confirmed that the level of inducible NO synthase (iNOS)-mediated NO production in Nramp1(r) peritoneal macrophages was generally higher than that of Nramp1(s) macrophages after stimulation by interferon-gamma (IFN-gamma), lipopolysaccharide (LPS), and tumor necrosis factor-alpha (TNF-alpha) alone or in combination. Nramp1 mRNA expression in both Nramp1 congenic macrophages was constitutive notwithstanding cytokine stimulation. During infection with S. typhimurium strain 6203, Nramp1(r) macrophages produced a lower amount of NO because of an initial strong reaction and unsustained iNOS gene expression as compared with Nramp1(s) macrophages. An inhibitory effect of the Nramp1(r) gene on bacterial replication was also observed during the early stage of S. typhimurium infection, whereas the effect of TNF-alpha occurred later. NO production and iNOS expression in TNF-alpha(-/-) macrophages were not detected from the start of the bacterial infection or at 24 h after infection. We also observed that S. typhimurium strain 6203 grew more profoundly without TNF-alpha, especially in Nramp1(s) macrophages. These data, therefore, demonstrate that there is cooperation of the Nramp1 and Tnfa genes in NO production and a growth inhibitory effect in response to S. typhimurium infection.

Evidence for horizontal transfer of SsuDAT1I restriction-modification genes to the Streptococcus suis genome.

Different strains of Streptococcus suis serotypes 1 and 2 isolated from pigs either contained a restriction-modification (R-M) system or lacked it. The R-M system was an isoschizomer of Streptococcus pneumoniae DpnII, which recognizes nucleotide sequence 5'-GATC-3'. The nucleotide sequencing of the genes encoding the R-M system in S. suis DAT1, designated SsuDAT1I, showed that the SsuDAT1I gene region contained two methyltransferase genes, designated ssuMA and ssuMB, as does the DpnII system. The deduced amino acid sequences of M. SsuMA and M.SsuMB showed 70 and 90% identity to M.DpnII and M.DpnA, respectively. However, the SsuDAT1I system contained two isoschizomeric restriction endonuclease genes, designated ssuRA and ssuRB. The deduced amino acid sequence of R.SsuRA was 49% identical to that of R.DpnII, and R.SsuRB was 72% identical to R.LlaDCHI of Lactococcus lactis subsp. cremoris DCH-4. The four SsuDAT1I genes overlapped and were bounded by purine biosynthetic gene clusters in the following gene order: purF-purM-purN-purH-ssuMA-ssuMB-ssuRA++ +-ssuRB-purD-purE. The G+C content of the SsuDAT1I gene region (34.1%) was lower than that of the pur region (48.9%), suggesting horizontal transfer of the SsuDAT1I system. No transposable element or long-repeat sequence was found in the flanking regions. The SsuDAT1I genes were functional by themselves, as they were individually expressed in Escherichia coli. Comparison of the sequences between strains with and without the R-M system showed that only the region from 53 bp upstream of ssuMA to 5 bp downstream of ssuRB was inserted in the intergenic sequence between purH and purD and that the insertion target site was not the recognition site of SsuDAT1I. No notable substitutions or insertions could be found, and the structures were conserved among all the strains. These results suggest that the SsuDAT1I system could have been integrated into the S. suis chromosome by an illegitimate recombination mechanism.

DNA sequence and comparison of virulence plasmids from Rhodococcus equi ATCC 33701 and 103.

The virulence plasmids of the equine virulent strains Rhodococcus equi ATCC 33701 and 103 were sequenced, and their genetic structure was analyzed. p33701 was 80,610 bp in length, and p103 was 1 bp shorter; their sequences were virtually identical. The plasmids contained 64 open reading frames (ORFs), 22 of which were homologous with genes of known function and 3 of which were homologous with putative genes of unknown function in other species. Putative functions were assigned to five ORFs based on protein family characteristics. The most striking feature of the virulence plasmids was the presence of a 27,536-bp pathogenicity island containing seven virulence-associated protein (vap) genes, including vapA. These vap genes have extensive homology to vapA, which encodes a thermoregulated and surface-expressed protein. The pathogenicity island contained a LysR family transcriptional regulator and a two-component response regulator upstream of six of the vap genes. The vap genes were present as a cluster of three (vapA, vapC, and vapD), as a pair (vapE and vapF), or individually (vapG; vapH). A region of extensive direct repeats of unknown function, possibly associated with thermoregulation, was present immediately upstream of the clustered and the paired genes but not the individual vap genes. There was extensive homology among the C-terminal halves of all vap genes but not generally among the N-terminal halves. The remainder of the plasmid consisted of a large region which appears to be associated with conjugation functions and a large region which appears to be associated with replication and partitioning functions.

Sequence analysis of a small cryptic plasmid isolated from Streptococcus suis serotype 2.

A small cryptic plasmid designated pSSU1 was isolated from Streptococcus suis serotype 2 strain DAT1. The complete sequence of pSSU1 was 4975 bp and contained six major open reading frames (ORFs). ORF1 and ORF2 encode for proteins highly homologous to CopG and RepB of the pMV158 family, respectively. ORF5 encodes for a protein highly homologous to Mob of pMV158. ORF4 encodes for a protein highly homologous to orf3 of pVA380-1 of S. ferus, but its function is unknown. There was no similarity between ORF3 and ORF6 and other protein sequences. In this plasmid, the ORF1 (CopG protein) was preceded by two multiples of direct repeat and the conserved nucleotides that could be the double-strand origin (DSO) of rolling circle replication (RCR) mechanism. The ORF5 (Mob protein) was followed by a potential hairpin loop that could be the single-strand origin (SSO) of RCR mechanism. The sequence, which was complementary to the leader region of Rep mRNA, was homologous to the countertranscribed RNA (ctRNA) of pLS1. Moreover, a 5-amino acid conserved sequence was found in C terminal of Rep and putative Rep proteins of several pMV158 family plasmids. These observations suggest that this plasmid replicates by use of the rolling circle mechanism.

Cloning and characterization of the gene encoding O-acetylserine lyase from Streptococcus suis.

We have cloned and sequenced a gene encoding O-acetylserine lyase from Streptococcus suis. The gene encodes a protein of 309 amino acids with a calculated molecular mass of 32,038 Da. The deduced amino acid sequence showed more extensive similarities to the CysK proteins than to the CysM proteins of other bacteria. The cloned gene was inserted into a pTrcHisB histidine hexamer expression vector. A 38-kDa fusion protein was expressed in a cysMK auxotrophic mutant of Salmonella typhimurium and complemented the auxotrophic properties of the mutant. Furthermore, the transformants could grow in minimal defined media supplemented with not only sulfide but also thiosulfate as a sole sulfur source. These data indicated that the cloned gene encodes a protein that was a functional homolog of the CysM in S. typhimurium.