A type II toxin-antitoxin system is responsible for the cell death at low temperature in Pseudomonas syringae Lz4W lacking RNase R.

RNase R (encoded by the rnr gene) is a highly processive 3' → 5' exoribonuclease essential for the growth of the psychrotrophic bacterium Pseudomonas syringae Lz4W at low temperature. The cell death of a rnr deletion mutant at low temperature has been previously attributed to processing defects in 16S rRNA, defective ribosomal assembly, and inefficient protein synthesis. We recently showed that RNase R is required to protect P. syringae Lz4W from DNA damage and oxidative stress, independent of its exoribonuclease activity. Here, we show that the processing defect in 16S rRNA does not cause cell death of the rnr mutant of P. syringae at low temperature. Our results demonstrate that the rnr mutant of P. syringae Lz4W, complemented with a RNase R deficient in exoribonuclease function (RNase RD284A), is defective in 16S rRNA processing but can grow at 4 °C. This suggested that the processing defect in ribosomal RNAs is not a cause of the cold sensitivity of the rnr mutant. We further show that the rnr mutant accumulates copies of the indigenous plasmid pLz4W that bears a type II toxin-antitoxin (TA) system (P. syringae antitoxin-P. syringae toxin). This phenotype was rescued by overexpressing antitoxin psA in the rnr mutant, suggesting that activation of the type II TA system leads to cold sensitivity of the rnr mutant of P. syringae Lz4W. Here, we report a previously unknown functional relationship between the cold sensitivity of the rnr mutant and a type II TA system in P. syringae Lz4W.

Comparative analysis of genes expression involved in type II toxin-antitoxin system in Staphylococcus aureus following persister cell formation.

BACKGROUND: The formation of persister cells is the main reason for persistent infections. They are associated with antibiotic treatment failure and subsequently chronic infection. The study aimed to assess the expression of type II toxin/antitoxin (TA) system genes in persister cells of Staphylococcus aureus in the presence of the following antibiotics vancomycin, ciprofloxacin, and gentamicin in exponential and stationary phases. METHODS AND RESULTS: The colony count was used to evaluate the effect of different types of antibiotics on S. aureus persister cell formation during exponential and stationary phases. Moreover, the expression level of TA systems and clpP genes in the persister population in exponential and stationary phases were measured by quantitative reverse transcriptase real-time PCR (qRT-PCR). The results of the study showed the presence of persister phenotype of S. aureus strains in the attendance of bactericidal antibiotics in comparison to the control group during the exponential and stationary phases. Moreover, qRT-PCR resulted in the fact that the role of TA systems involved in the persister cell formation depends on the bacterial growth phase and the type of strain and antibiotic. CONCLUSIONS: In total, the present study provides some data on the persister cell formation and the possible role of TA system genes in this process.

Discovery of Antimicrobial Agents Based on Structural and Functional Study of the Klebsiella pneumoniae MazEF Toxin-Antitoxin System.

Klebsiella pneumoniae causes severe human diseases, but its resistance to current antibiotics is increasing. Therefore, new antibiotics to eradicate K. pneumoniae are urgently needed. Bacterial toxin-antitoxin (TA) systems are strongly correlated with physiological processes in pathogenic bacteria, such as growth arrest, survival, and apoptosis. By using structural information, we could design the peptides and small-molecule compounds that can disrupt the binding between K. pneumoniae MazE and MazF, which release free MazF toxin. Because the MazEF system is closely implicated in programmed cell death, artificial activation of MazF can promote cell death of K. pneumoniae. The effectiveness of a discovered small-molecule compound in bacterial cell killing was confirmed through flow cytometry analysis. Our findings can contribute to understanding the bacterial MazEF TA system and developing antimicrobial agents for treating drug-resistant K. pneumoniae.

Identification of Genes Encoded Toxin-Antitoxin System in Mycobacterium Tuberculosis Strains from Clinical Sample.

BACKGROUND: The toxin-antitoxin system is a genetic element that is highly present in Mycobacterium tuberculosis (MTB), the causative agent of tuberculosis. The toxin-antitoxin sys-tem comprises toxin protein and antitoxin protein or non-encoded RNA interacting with each other and inhibiting toxin activity. M. Tuberculosis has more classes of TA loci than non-tubercle bacilli and other microbes, including VapBC, HigBA, MazEF, ParDE, RelBE, MbcTA, PemIK, DarTG, MenTA, one tripartite type II TAC chaperone system, and hypothetical proteins. AIMS: The study aims to demonstrate the genes encoded toxin-antitoxin system in mycobacterium tuberculosis strains from clinical samples. MATERIALS AND METHODS: The pulmonary and extra-pulmonary tuberculosis clinical samples were collected, and smear microscopy (Ziehl-Neelsen staining) was performed for the detection of high bacilli (3+) count, followed by nucleic acid amplification assay. Bacterial culture and growth assay, genomic DNA extraction, and polymerase chain reaction were also carried out. RESULTS: The positive PTB and EPTB samples were determined by 3+ in microscopy smear [20], and the total count of tubercle bacilli determined by NAAT assay was 8.0×1005 in sputum and 1.3×1004 CFU/ml in tissue abscess. Moreover, the genomic DNA was extracted from culture, and the amplification of Rv1044 and Rv1045 genes in 624 and 412 base pairs (between 600-700 and 400-500 in ladder), respectively, in the H37Rv and clinical samples was observed. CONCLUSION: It has been found that Rv1044 and Rv1045 are hypothetical proteins with 624 and 882 base pairs belonging to the AbiEi/AbiEii family of toxin-antitoxin loci. Moreover, the signifi-cant identification of TA-encoded loci genes may allow for the investigation of multidrug-resistant and extensively drug-resistant tuberculosis.

RES-Xre toxin-antitoxin locus knaAT maintains the stability of the virulence plasmid in Klebsiella pneumoniae.

Hypervirulent Klebsiella pneumoniae isolates have been increasingly reported worldwide, especially hypervirulent drug-resistant variants owing to the acquisition of a mobilizable virulence plasmid by a carbapenem-resistant strain. This pLVPK-like mobilizable plasmid encodes various virulence factors; however, information about its genetic stability is lacking. This study aimed to investigate the type II toxin-antitoxin (TA) modules that facilitate the virulence plasmid to remain stable in K. pneumoniae. More than 3,000 TA loci in 2,000 K. pneumoniae plasmids were examined for their relationship with plasmid cargo genes. TA loci from the RES-Xre family were highly correlated with virulence plasmids of hypervirulent K. pneumoniae. Overexpression of the RES toxin KnaT, encoded by the virulence plasmid-carrying RES-Xre locus knaAT, halts the cell growth of K. pneumoniae and E. coli, whereas co-expression of the cognate Xre antitoxin KnaA neutralizes the toxicity of KnaT. knaA and knaT were co-transcribed, representing the characteristics of a type II TA module. The knaAT deletion mutation gradually lost its virulence plasmid in K. pneumoniae, whereas the stability of the plasmid in E. coli was enhanced by adding knaAT, which revealed that the knaAT operon maintained the genetic stability of the large virulence plasmid in K. pneumoniae. String tests and mouse lethality assays subsequently confirmed that a loss of the virulence plasmid resulted in reduced pathogenicity of K. pneumoniae. These findings provide important insights into the role of the RES-Xre TA pair in stabilizing virulence plasmids and disseminating virulence genes in K. pneumoniae.

Toxin-antitoxin system gene mutations driving Mycobacterium tuberculosis transmission revealed by whole genome sequencing.

Background: The toxin-antitoxin (TA) system plays a vital role in the virulence and pathogenicity of Mycobacterium tuberculosis (M. tuberculosis). However, the regulatory mechanisms and the impact of gene mutations on M. tuberculosis transmission remain poorly understood. Objective: To investigate the influence of gene mutations in the toxin-antitoxin system on M. tuberculosis transmission dynamics. Method: We performed whole-genome sequencing on the analyzed strains of M. tuberculosis. The genes associated with the toxin-antitoxin system were obtained from the National Center for Biotechnology Information (NCBI) Gene database. Mutations correlating with enhanced transmission within the genes were identified by using random forest, gradient boosting decision tree, and generalized linear mixed models. Results: A total of 13,518 M. tuberculosis isolates were analyzed, with 42.29% (n = 5,717) found to be part of genomic clusters. Lineage 4 accounted for the majority of isolates (n = 6488, 48%), followed by lineage 2 (n = 5133, 37.97%). 23 single nucleotide polymorphisms (SNPs) showed a positive correlation with clustering, including vapB1 G34A, vapB24 A76C, vapB2 T171C, mazF2 C85T, mazE2 G104A, vapB31 T112C, relB T226A, vapB11 C54T, mazE5 T344C, vapB14 A29G, parE1 (C103T, C88T), and parD1 C134T. Six SNPs, including vapB6 A29C, vapB31 T112C, parD1 C134T, vapB37 G205C, Rv2653c A80C, and vapB22 C167T, were associated with transmission clades across different countries. Notably, our findings highlighted the positive association of vapB6 A29C, vapB31 T112C, parD1 C134T, vapB37 G205C, vapB19 C188T, and Rv2653c A80C with transmission clades across diverse regions. Furthermore, our analysis identified 32 SNPs that exhibited significant associations with clade size. Conclusion: Our study presents potential associations between mutations in genes related to the toxin-antitoxin system and the transmission dynamics of M. tuberculosis. However, it is important to acknowledge the presence of confounding factors and limitations in our study. Further research is required to establish causation and assess the functional significance of these mutations. These findings provide a foundation for future investigations and the formulation of strategies aimed at controlling TB transmission.

Effect of Divalent Metal Ions on the Ribonuclease Activity of the Toxin Molecule HP0894 from Helicobacter pylori.

Bacteria and archaea respond and adapt to environmental stress conditions by modulating the toxin-antitoxin (TA) system for survival. Within the bacterium Helicobacter pylori, the protein HP0894 is a key player in the HP0894-HP0895 TA system, in which HP0894 serves as a toxin and HP0895 as an antitoxin. HP0894 has intrinsic ribonuclease (RNase) activity that regulates gene expression and translation, significantly influencing bacterial physiology and survival. This activity is influenced by the presence of metal ions such as Mg2+. In this study, we explore the metal-dependent RNase activity of HP0894. Surprisingly, all tested metal ions lead to a reduction in RNase activity, with zinc ions (Zn2+) causing the most significant decrease. The secondary structure of HP0894 remained largely unaffected by Zn2+ binding, whereas structural rigidity was notably increased, as revealed using CD analysis. NMR characterized the Zn2+ binding, implicating numerous His, Asp, and Glu residues in HP0894. In summary, these results suggest that metal ions play a regulatory role in the RNase activity of HP0894, contributing to maintaining the toxin molecule in an inactive state under normal conditions.

PemK's Arg24 is a crucial residue for PemIK toxin-antitoxin system to induce the persistence of Weissella cibaria against ciprofloxacin stress.

The toxin-antitoxin (TA) system plays a key role in bacteria escaping antibiotic stress with persistence, however, the mechanisms by which persistence is controlled remain poorly understood. Weissella cibaria, a novel probiotic, can enters a persistent state upon encountering ciprofloxacin stress. Conversely, it resumes from the persistence when ciprofloxacin stress is relieved or removed. Here, it was found that PemIK TA system played a role in transitioning between these two states. And the PemIK was consisted of PemK, an endonuclease toxic to mRNA, and antitoxin PemI which neutralized its toxicity. The PemK specifically cleaved the U↓AUU in mRNA encoding enzymes involved in glycolysis, TCA cycle and respiratory chain pathways. This cleavage event subsequently disrupted the crucial cellular processes such as hydrogen transfer, electron transfer, NADH and FADH2 synthesis, ultimately leading to a decrease in ATP levels and an increase in membrane depolarization and persister frequency. Notably, Arg24 was a critical active residue for PemK, its mutation significantly reduced the mRNA cleavage activity and the adverse effects on metabolism. These insights provided a clue to comprehensively understand the mechanism by which PemIK induced the persistence of W. cibaria to escape ciprofloxacin stress, thereby highlighting another novel aspect PemIK respond for antibiotic stress.

Specificity of DNA ADP-Ribosylation Reversal by NADARs.

Recent discoveries establish DNA and RNA as bona fide substrates for ADP-ribosylation. NADAR ("NAD- and ADP-ribose"-associated) enzymes reverse guanine ADP-ribosylation and serve as antitoxins in the DarT-NADAR operon. Although NADARs are widespread across prokaryotes, eukaryotes, and viruses, their specificity and broader physiological roles remain poorly understood. Using phylogenetic and biochemical analyses, we further explore de-ADP-ribosylation activity and antitoxin functions of NADAR domains. We demonstrate that different subfamilies of NADAR proteins from representative E. coli strains and an E. coli-infecting phage retain biochemical activity while displaying specificity in providing protection from toxic guanine ADP-ribosylation in cells. Furthermore, we identify a myxobacterial enzyme within the YbiA subfamily that functions as an antitoxin for its associated DarT-unrelated ART toxin, which we termed YarT, thus presenting a hitherto uncharacterised ART-YbiA toxin-antitoxin pair. Our studies contribute to the burgeoning field of DNA ADP-ribosylation, supporting its physiological relevance within and beyond bacterial toxin-antitoxin systems. Notably, the specificity and confinement of NADARs to non-mammals infer their potential as highly specific targets for antimicrobial drugs with minimal off-target effects.

Genomic Characterization of a Plasmid-Free and Highly Drug-Resistant Salmonella enterica Serovar Indiana Isolate in China.

The emergence of multi-drug resistant (MDR) Salmonella enterica serovar Indiana (S. Indiana) strains in China is commonly associated with the presence of one or more resistance plasmids harboring integrons pivotal in acquiring antimicrobial resistance (AMR). This study aims to elucidate the genetic makeup of this plasmid-free, highly drug-resistant S. Indiana S1467 strain. Genomic sequencing was performed using Illumina HiSeq 2500 sequencer and PacBio RS II System. Prodigal software predicted putative protein-coding sequences while BLASTP analysis was conducted. The S1467 genome comprises a circular 4,998,300 bp chromosome with an average GC content of 51.81%, encompassing 4709 open reading frames (ORFs). Fifty-four AMR genes were identified, conferring resistance across 16 AMR categories, aligning closely with the strain's antibiotic susceptibility profile. Genomic island prediction unveiled an approximately 51 kb genomic island housing a unique YeeVU toxin-antitoxin system (TAS), a rarity in Salmonella species. This suggests that the AMR gene cluster on the S1467 genomic island may stem from the integration of plasmids originating from other Enterobacteriaceae. This study contributes not only to the understanding of the genomic characteristics of a plasmid-free, highly drug-resistant S. Indiana strain but also sheds light on the intricate mechanisms underlying antimicrobial resistance. The implications of our findings extend to the broader context of horizontal gene transfer between bacterial species, emphasizing the need for continued surveillance and research to address the evolving challenges posed by drug-resistant pathogens.

Functions of bacterial Toxin-Antitoxin systems / 生物工程学报

TA (Toxin-Antitoxin) systems are widely spread in chromosomes and plasmids of bacteria and archaea. These systems consist of two co-expression genes, encoding stable toxin and sensitive antitoxin, respectively. The toxicity of toxins usually inhibits bacterial growth and antitoxins can neutralize the toxins. Interaction between them would regulate the growth state of bacteria precisely. According to the composition of TA and nature of antitoxin, six types of TA have been found. The role of these TA systems in bacteria has been a hot research topic in recent years. Now, the research status on functions of bacterial TA is reviewed.

Function of four pairs of genes in toxin-antitoxin system of Mycobacterium tuberculosis / 中国人兽共患病学报

We discussed the function of four pairs of genes in the toxin-antitoxin system of Mycobacterium tuberculosis,providing theoretical foundation and scientific basis for studying the transmission mechanism of Mycobacterium tuberculosis.Four pairs of genes which belong to VapBC family,including four VapC genes (Rv1720c,Rv2103c,Rv2494,Rv3408) and four VapB genes (Rv1721c,Rv2104c,Rv2493,Rv3407) were chosen.We constructed a serial of arabinose-induced hybrid plasmid system in Escherichia coli and a serial of acetamide-induced hybrid plasmid system in Mycobacterium smegmatis respectively,in order to observe the potential inhibition effect of VapC and the release inhibition of homologous VapB.Results showed that only one toxin gene(Rv2103c) showed the function of bacteriostasis in both E.coli and M.smegmatis and the homologous antitoxin gene(Rv2104c) could release the inhibition of growth.We built the inducible systems of VapBC family in both E.coli and M.smegmatis respectively and found only a pair of toxin and antitoxin genes(Rv2103c,Rv2104c) had the function of inhibition and release for the growth of bacteria.And two pairs of toxin genes(Rv1720c,Rv2494) did not have the function of inhibition for the growth of both E.coli and M.smegmatis.Whereas,another toxin gene VapC47(Rv3408) also did not have the bacteriostastic activity,only this result was not consistent with the existing literature.We speculated that the reason for this kind of difference may be the different inducible systems we used.Cause the other three results were consistent with all existing literature and the doubtful result also appeared in other reports,so our protocol could be confirmed as reliable,and we would use it to build inducible systems and make further functional identification of certain toxin and antitoxin genes that we are interested in.

Detection on expression levels of mazE F toxin-antitoxin system in Mycobacterium tuberculosis by qRT-PCR / 中国人兽共患病学报

We investigate the different expression of toxin gene mazF3,6,9 and antitoxin gene mazE3,6,9 in the drug-resistance Mycobacterium tuberculosis,we used quantitative real-time polymerase chin reaction method to detect the expression level of toxin gene mazF3,6,9 and antitoxin gene mazE3,6,9 in M.tuberculosis (20 mono-resistance strains,20 multidrug resistance strains and standard strain H37Rv).The differences of gene expression levels between groups were analyzed by oneway ANOVA.Contrasting with control group,toxin genes mazF6,9 were up-regulated expression levels both in mono-resistance (11.1519±22.31721;8.4306±17.97897) and multidrug resistance (4.6016±1.29018;6.9627±6.92948),had statistical significance (P＜0.01),mazF3 expression levels had statistical significance neither in mono-resistance nor in multidrug resistance (P＞0.05);antitoxin genes mazE3 was in down-expression level,and had statistical significance both in mono-resistance (0.3606±0.12527) and multidrug resistance (0.2016±0.16542) (P＜0.01),mazE6 had no statistical significance (P＞0.05)either in mono-resistance or multi drug resistance,mazE9 only in multidrug resistance(0.3989±0.37679) was in downexpression level,and has statistical significance (P＜0.001).The toxin gene mazF6,9 and antitoxin gene mazE3,9 may participate in the drug-resistance formation of M.tuberculosis.

Análise do sistema toxina-antitoxina tipo II na fisiologia bacteriana de uma cepa híbrida: Escherichia coli enteropatogênica atípica e E. coli extraintestinal

The toxin-antitoxin (TA) systems are genetic modules associated with some bacterial processes, such as cell formation persistence, biofilm formation, protection against bacteriophages and responses to stressful environments. In these systems, the toxin is related to the inhibition of physiological processes and the antitoxin provides protection to the cell against the toxin. Five TA type II systems present in the genome of the hybrid strain BA1250 (atypical enteropathogenic E. coli and extraintestinal E. coli strain) were analyzed. The hybrid strain BA1250 can colonize different host niches and can face different stress environments, therefore, through transcription analysis under stress conditions such as nutritional, oxidative, osmotic and acid, the CcdB-CcdA, YhaV-PrlF, MazF-MazE, YoeB-YefM and PasI-PasT were evaluated both in the log and stationary phases of BA1250 strain. We observed significant differences in the expression levels of the CcdB-CcdA, YhaV-PrlF, YoeB-YefM and PasT-PasI systems in the presence of nutritional stress in the stationary phase. In acid stress, an increase in the gene expression of YhaV, YefM and PasT toxins in stationary phase was observed. In contrast, the analysis of the MazF-MazE system did not show any change in expression levels under the stress conditions evaluated. These data indicate that these four TA systems seem to be involved in the stress response of the BA1250 strain, therefore involved in the physiological processes of BA1250.

Os sistemas toxina-antitoxina (TA) são módulos genéticos que estão associados a alguns processos das bactérias, como formação de células persistentes, formação de biofilme, proteção contra bacteriófagos e respostas a ambientes estressantes. Nesses sistemas, a toxina está relacionada à inibição de processos fisiológicos e a antitoxina fornece proteção à célula contra a toxina. Cinco sistemas TA tipo II presentes no genoma da cepa híbrida BA1250 (E. coli enteropatogênica atípica e cepa de E. coli extraintestinal) foram analisados. A cepa híbrida BA1250 pode colonizar diferentes nichos do hospedeiro e pode enfrentar diferentes ambientes de estresse, por tanto, por meio de análises de transcrição sob condições de estresse como nutricional, oxidativo, osmótico e ácido, os sistemas CcdB-CcdA, YhaV-PrlF, MazF-MazE, YoeB-YefM e PasI-PasT foram avaliados tanto na fase log quanto estacionária do cultivo da cepa BA1250. Observamos diferenças significativas nos níveis de expressão dos sistemas CcdB-CcdA, YhaV-PrlF, YoeB-YefM e PasT-PasI na presença de estresse nutricional na fase estacionária. No estresse ácido foi observado um aumento de expressão gênica das toxinas YhaV, YefM e PasT em fase estacionária. Em contraste, a análise do sistema MazF-MazE não apresentou nenhuma alteração nos níveis de expressão nas condições de estresse avaliadas. Esses dados indicam que esses quatro sistemas TA parecem estar envolvidos na resposta ao estresse da cepa BA1250, portanto envolvidos em processos fisiológicos da BA1250.

Análise do sistema toxina-antitoxina HipA/B na indução da persistência bacteriana de cepas de Escherichia coli extraintestinal / The importance of HipA/B Toxin-Antitoxin system in extraintestinal Escherichia Coli persistence

Os sistemas toxina-antitoxinas (TA) compreendem um conjunto de genes que são amplamente difundidos em procariotos. No cromossomo, os sistemas podem estar envolvidos na indução de morte celular em resposta a condições estressantes, indução de persistência, formação de biofilme, colonização de novos nichos, manutenção da mobilidade bacteriana e virulência de bactérias patogênicas. Em E. coli K12, 36 sistemas TA foram descritos, dos quais o do tipo II é o mais abundante e estudado. Dentre as oito toxinas pesquisadas nesse trabalho, o gene da toxina HipA está presente em 76 das 100 cepas de ExPEC estudadas. Apesar da abundância de hipA em ExPEC e em diversos genomas bacterianos, a participação dos sistemas hipA/B na indução da persistência ainda não é clara. Portanto, o sistema hipA/B de duas cepas ExPEC isoladas de infecção sanguínea foi deletado, e estas foram avaliadas quando a indução da persistência bacteriana na presença de antibióticos, formação de biofilme, resistência ao soro e sobrevivência em macrófagos. O sistema TA hipA/B não influenciou no fenótipo de resistência ao soro humano e na sobrevivência intracelular em macrófagos, no entanto, participou da indução da persistência por ciprofloxacino em um isolado (EC182); e da formação de biofilme em superfície de vidro do isolado (EC273)

Toxin-antitoxin (TA) systems comprise a set of genes that are widespread in prokaryotes. On the chromosome, the systems may be involved in the induction of cell death in response to stressful conditions, persistence induction, biofilm formation, colonization of new niches, maintenance of bacterial mobility and virulence. In E. coli K12, 36 TA systems have been described, of which type II is the most abundant. Among the eight toxins searched in this work, hipA is present in 76 bacteria of the 100 ExPEC strains studied. Despite the abundance of hipA in ExPEC and in several bacterial genomes, the participation of hipA/B modules in the persistence is still unclear. Therefore, hipA/B system of two ExPEC strains isolated from blood infection was deleted and consequently evaluated in bacterial persistence induced by antibiotics, serum resistance and macrophage survival. Despite the fact that, the TA hipA/B system did not influence the phenotype of resistance to human serum and intracellular survival in macrophages. Herein, we described that hipA/B was important for persistence induction in one isolate (EC182); and may participate in the biofilm formation on the glass surface in the other studied strain (EC273)

Nuclease activity and cytotoxicity to host cells of toxic protein VapC produced by Leptospira species / 中华微生物学和免疫学杂志

Objective To determine the function of toxic protein VapC in toxin/antitoxin system of Leptospira species and the cytotoxicity to host cells of the toxic protein.Methods Using genomic DNA of pathogenic L.interrogans serogroup Icterohaemorrhagiae serovar Lai strain Lai as the template,several PCRs were performed to amplify entire vapB,vapC and vapBC genes.Subsequently,the prokaryotic expression systems of vapB,vapC and vapBC genes were constructed.Expression of the target recombinant proteins rVapB and rVapC was detected by SDS-PAGE and the expressed rVapB and rVapC were extracted by NiNTA affinity chromatography.Activity of rVapB and rVapC to lyse the DNAs or RNAs from L.interrogans strain Lai and THP-1 cells were then determined.The changes of transcription and expression of vapB and vapC genes of L.interrogans strain Lai before and after infection of THP-1 cells were detected by real-time fluorescent quantitative RT-PCR and Western blot assay.The eukaryotic expression vectors of the vapB and vapC genes were generated for transfection of host cells and CCK-8 agent was used to detect the effect of leptospiral VapB and VapC proteins on activity of host cells.Results The nucleotide and putative amino acid sequences of the cloned vapB and vapC genes were completely identical with the reported corresponding genes.The constructed prokaryotic expression systems could express rVapB and rVapC,respectively.rVapC displayed RNase avtivity but did not lyse DNA.When L.interrogans strain Lai infected THP-1 cells,the transcription and expression of vapB and vapC genes were upregulated and partial VapC protein was secreted from the leptospiral cells.The mass mortality was observed in HEK293 human renal tubular epithelial ceils containing the vapC gene through transfection.Conclusion VapC protein of L.interrogans strain Lai is a RNase and is secreted during infection of host cells with obvious cytotoxicity.