The serine/threonine protein kinase of Streptococcus suis serotype 2 affects the ability of the pathogen to penetrate the blood–brain barrier

Streptococcus suis serotype 2 (SS2) is a zoonotic agent that causes meningitis in humans and pigs. However, the mechanism whereby SS2 crosses the microvasculature endothelium of the brain is not understood. In this study, transposon (TnYLB‐1) mutagenesis was used to identify virulence factors potentially associated with invasive ability in pathogenic SS2. A poorly invasive mutant was identified and was found to contain a TnYLB‐1 insertion in the serine/threonine kinase (stk) gene. Transwell chambers containing hBMECs were used to model the blood–brain barrier (BBB). We observed that the SS2 wild‐type ZY05719 strain crossed the BBB model more readily than the mutant strain. Hence, we speculated that STK is associated with the ability of crossing blood–brain barrier in SS2. In vitro, compared with ZY05719, the ability of the stk‐deficient strain (Δstk) to adhere to and invade both hBMECs and bEnd.3 cells, as well as to cross the BBB, was significantly attenuated. Immunocytochemistry using antibodies against claudin‐5 in bEnd.3 cells showed that infection by ZY05719 disrupted BBB tight junction proteins to a greater extent than in infection by Δstk. The studies revealed that SS2 initially binds at or near intercellular junctions and crosses the BBB via paracellular traversal. Claudin‐5 mRNA levels were indistinguishable in ZY05719‐ and Δstk‐infected cells. This result indicated that the decrease of claudin‐5 was maybe induced by protein degradation. Cells infected by ZY05719 exhibited higher ubiquitination levels than cells infected by Δstk. This result indicated that ubiquitination was involved in the degradation of claudin‐5. Differential proteomic analysis showed that E3 ubiquitin protein ligase HECTD1 decreased by 1.5‐fold in Δstk‐infected bEnd.3 cells relative to ZY05719‐infected cells. Together, the results suggested that STK may affect the expression of E3 ubiquitin ligase HECTD1 and subsequently increase the degradation of claudin‐5, thus enabling SS2 to traverse the BBB.     

Compartment-specific isoforms of TPI and GAPDH are imported into diatom mitochondria as a fusion protein: evidence in favor of a mitochondrial origin of the eukaryotic glycolytic pathway

Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and triosephosphate isomerase (TPI) are essential to glycolysis, the major route of carbohydrate breakdown in eukaryotes. In animals and other heterotrophic eukaryotes, both enzymes are localized in the cytosol; in photosynthetic eukaryotes, GAPDH and TPI exist as isoenzymes that function in the glycolytic pathway of the cytosol and in the Calvin cycle of chloroplasts. Here, we show that diatoms--photosynthetic protists that acquired their plastids through secondary symbiotic engulfment of a eukaryotic rhodophyte--possess an additional isoenzyme each of both GAPDH and TPI. Surprisingly, these new forms are expressed as an TPI-GAPDH fusion protein which is imported into mitochondria prior to its assembly into a tetrameric bifunctional enzyme complex. Homologs of this translational fusion are shown to be conserved and expressed also in nonphotosynthetic, heterokont-flagellated oomycetes. Phylogenetic analyses show that mitochondrial GAPDH and its N-terminal TPI fusion branch deeply within their respective eukaryotic protein phylogenies, suggesting that diatom mitochondria may have retained an ancestral state of glycolytic compartmentation that existed at the onset of mitochondrial symbiosis. These findings strongly support the view that nuclear genes for enzymes of glycolysis in eukaryotes were acquired from mitochondrial genomes and provide new insights into the evolutionary history (host-symbiont relationships) of diatoms and other heterokont-flagellated protists.     

猪链球菌2型新的感染相关因子自溶素的鉴定与分析

根据Sanger研究所公布的猪链球菌2型(SS2)P1/7株的自溶素序列,设计检测引物,取SS2我国2次流行株、其它临床分离株和参考株,及猪链球菌1型、1/2型、7型和9型,共33株,分别以其DNA为模板,PCR扩增.结果表明,SS2除无毒株T15阴性外,其他临床分离株27株(含人源2株)均阳性;其它猪链球菌为,SS7阳性,SS1、SS1/2和SS9均阴性.同时设计引物向两侧扩增,以四川流行株ZY05719和江苏流行株HA9801的DNA为模板,扩增自溶素ORF完整的编码基因,软件分析结果显示,该基因含有6个重复的"GBS_Bsp-like"域和1个"N-乙酰胞壁酰-L-丙氨酸酰胺酶"域,与SS2欧洲株有较高同源性(99.8%),但与SS2加拿大株差异较大.在DNASTAR分析所编码蛋白的抗原性的基础上,另设计引物,以ZY05719株DNA为模板,PCR扩增具有良好免疫原性的片段基因,并定向克隆至表达载体pET30a( )中,进行重组表达,SDS-PAGE和Western blot表明,所获得重组自溶素具有良好反应原性.     

Comparative genomic analysis shows that Streptococcus suis meningitis isolate SC070731 contains a unique 105 K genomic island

Streptococcus suis (SS) is an important swine pathogen worldwide that occasionally causes serious infections in humans. SS infection may result in meningitis in pigs and humans. The pathogenic mechanisms of SS are poorly understood. Here, we provide the complete genome sequence of S. suis serotype 2 (SS2) strain SC070731 isolated from a pig with meningitis. The chromosome is 2,138,568 bp in length. There are 1933 predicted protein coding sequences and 96.7% (57/59) of the known virulence-associated genes are present in the genome. Strain SC070731 showed similar virulence with SS2 virulent strains HA9801 and ZY05719, but was more virulent than SS2 virulent strain P1/7 in the zebrafish infection model. Comparative genomic analysis revealed a unique 105 K genomic island in strain SC070731 that is absent in seven other sequenced SS2 strains. Further analysis of the 105 K genomic island indicated that it contained a complete nisin locus similar to the nisin U locus in S. uberis strain 42, a prophage similar to S. oralis phage PH10 and several antibiotic resistance genes. Several proteins in the 105 K genomic island, including nisin and RelBE toxin–antitoxin system, contribute to the bacterial fitness and virulence in other pathogenic bacteria. Further investigation of newly identified gene products, including four putative new virulence-associated surface proteins, will improve our understanding of SS pathogenesis.     

Entamoeba histolytica: ADP-ribosylation of secreted glyceraldehyde-3-phosphate dehydrogenase

In addition to its classic glycolytic role, glyceraldehyde-3-phosphate dehydrogenase (GAPDH) has been implicated in many activities unrelated to glycolysis, such as membrane fusion, binding to host proteins and signal transduction. GAPDH can be the target of several modifications that allow incorporation to membranes and possible regulation of its activity; among these modifications is mono-ADP-ribosylation. This post-translational modification is important for the regulation of many cellular processes and is the mechanism of action of several bacterial toxins. In a previous study, we observed the extracellular ADP-ribosylation of a 37-kDa ameba protein. We report here that GAPDH and cysteine synthase A are the main ADP-ribosylated proteins in Entamoeba histolytica extracellular medium, GAPDH is secreted from ameba at 37 degrees C in a time-dependent manner, and its enzymatic activity is not inhibited by ADP-ribosylation. Extracellular GAPDH from ameba may play an important role in the survival of this human pathogen or in interaction with host molecules, as occurs in other organisms.     

猪链球菌2型Dbp缺失株的构建及特性分析

【目的】通过构建DNA结合膜蛋白(DNA-binding membrance protein,Dbp)基因的缺失株,探究Dbp基因对猪链球菌2型强毒株毒力的影响。【方法】通过PCR检测Dbp基因的分布。利用同源重组原理构建Dbp基因上下游片段的重组质粒,将构建好的质粒电转入ZY05719感受态细胞中,筛选Dbp缺失突变株,通过PCR及测序分析对其进行验证。生物学特性分析比较缺失株?Dbp和野毒株ZY05719在生长速率、形态特征、毒力等方面的差异。【结果】Dbp基因为猪链球菌2型强毒株中相对保守基因,构建了Dbp基因缺失株?Dbp。体外实验结果显示Dbp基因缺失株的生长速率在对数期减慢,并且缺失株?Dbp的荚膜同野毒株存在显著差异,斑马鱼实验结果表明缺失株?Dbp毒力下降。【结论】Dbp与猪链球菌2型的毒力相关,在猪链球菌2型的致病过程中起一定的作用,这丰富了对该菌致病机理的认识。     

Immunoproteomics of extracellular proteins of Chinese virulent strains of Streptococcus suis type 2

Streptococcus suis type 2 (SS2) is a porcine zoonotic pathogen with worldwide distribution, and lacking suitable vaccine and virulent maker were bottleneck to control this infection. An immunoproteomic assay was used to identify antigenic proteins from the total extracellular proteins of the virulent Chinese SS2 strain ZY05719. The convalescent serum of a specific pathogen free (SPF) mini-pig recognized nine protein spots on PVDF membrane. Antigenic proteins on a duplicate gel, as well as those with a similar placement of extracellular proteins from another virulent strain (HA9801) and an avirulent strain (T15) on 2-D gels, were excised and identified by MALDI-TOF-MS. PMF of the protein spots were performed using the MASCOT server. Two proteins were found in all three strains. Comparative proteomic analysis between the two virulent strains and the avirulent strain revealed nine differential proteins, eight of which were successfully identified. Genes for six of the differentially expressed proteins were found in both virulent strains, and of those were present in the avirulent stain.     

Anchorless surface associated glycolytic enzymes from Lactobacillus plantarum 299v bind to epithelial cells and extracellular matrix proteins

An important criterion for the selection of a probiotic bacterial strain is its ability to adhere to the mucosal surface. Adhesion is usually mediated by proteins or other components located on the outer cell surface of the bacterium. In the present study we characterized the adhesive properties of two classical intracellular enzymes glyceraldehyde 3-phosphate dehydrogenase (GAPDH) and enolase (ENO) isolated from the outer cell surface of the probiotic bacterium Lactobacillus plantarum 299v. None of the genes encoded signal peptides or cell surface anchoring motifs that could explain their extracellular location on the bacterial surface. The presence of the glycolytic enzymes on the outer surface was verified by western blotting using polyclonal antibodies raised against the specific enzymes. GAPDH and ENO showed a highly specific binding to plasminogen and fibronectin whereas GAPDH but not ENO showed weak binding to mucin. Furthermore, a pH dependent and specific binding of GAPDH and ENO to intestinal epithelial Caco-2 cells at pH 5 but not at pH 7 was demonstrated. The results showed that these glycolytic enzymes could play a role in the adhesion of the probiotic bacterium L. plantarum 299v to the gastrointestinal tract of the host. Finally, a number of probiotic as well non-probiotic Lactobacillus strains were analyzed for the presence of GAPDH and ENO on the outer surface, but no correlation between the extracellular location of these enzymes and the probiotic status of the applied strains was demonstrated.     

Biochemical and genetic characterization of the three metabolic routes in Thermococcus kodakarensis linking glyceraldehyde 3-phosphate and 3-phosphoglycerate

In the classical Embden-Meyerhof (EM) pathway for glycolysis, the conversion between glyceraldehyde 3-phosphate (GAP) and 3-phosphoglycerate (3-PGA) is reversibly catalysed by phosphorylating GAP dehydrogenase (GAPDH) and phosphoglycerate kinase (PGK). In the Euryarchaeota Thermococcus kodakarensis and Pyrococcus furiosus, an additional gene encoding GAP:ferredoxin oxidoreductase (GAPOR) and a gene similar to non-phosphorylating GAP dehydrogenase (GAPN) are present. In order to determine the physiological roles of the three routes that link GAP and 3-PGA, we individually disrupted the GAPOR, GAPN, GAPDH and PGK genes (gor, gapN, gapDH and pgk respectively) of T. kodakarensis. The Δgor strain displayed no growth under glycolytic conditions, confirming its proposed function to generate reduced ferredoxin for energy generation in glycolysis. Surprisingly, ΔgapN cells also did not grow under glycolytic conditions, suggesting that GAPN plays a key role in providing NADPH under these conditions. Disruption of gor and gapN had no effect on gluconeogenic growth. Growth experiments with the ΔgapDH and Δpgk strains indicated that, unlike their counterparts in the classical EM pathway, GAPDH/PGK play a major role only in gluconeogenesis. Biochemical analyses indicated that T. kodakarensis GAPN did not recognize aldehyde substrates other than d-GAP, preferred NADP(+) as cofactor and was dramatically activated with glucose 1-phosphate.     

Ionic strength dependence of F-actin and glycolytic enzyme associations: a Brownian dynamics simulations approach

The association of glycolytic enzymes with F-actin is proposed to be one mechanism by which these enzymes are compartmentalized, and, as a result, may possibly play important roles for: regulation of the glycolytic pathway, potential substrate channeling, and increasing glycolytic flux. Historically, in vitro experiments have shown that many enzyme/actin interactions are dependent on ionic strength. Herein, Brownian dynamics (BD) examines how ionic strength impacts the energetics of the association of F-actin with the glycolytic enzymes: lactate dehydrogenase (LDH), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), fructose-1,6-bisphosphate aldolase (aldolase), and triose phosphate isomerase (TPI). The BD simulations are steered by electrostatics calculated by Poisson-Boltzmann theory. The BD results confirm experimental observations that the degree of association diminishes as ionic strength increases but also suggest that these interactions are significant, at physiological ionic strengths. Furthermore, BD agrees with experiments that muscle LDH, aldolase, and GAPDH interact significantly with F-actin whereas TPI does not. BD indicates similarities in binding regions for aldolase and LDH among the different species investigated. Furthermore, the residues responsible for salt bridge formation in stable complexes persist as ionic strength increases. This suggests the importance of the residues determined for these binary complexes and specificity of the interactions. That these interactions are conserved across species, and there appears to be a general trend among the enzymes, support the importance of these enzyme-F-actin interactions in creating initial complexes critical for compartmentation.     

Identification and proteome analysis of the two-component VirR/VirS system in epidemic Streptococcus suis serotype 2

Streptococcus suis serotype 2 (SS2) is an important zoonotic pathogen that infects pigs and sporadically causes serious infections in humans. Two recent large-scale outbreaks of human streptococcal toxic-shock-like syndrome with high mortality occurred in China, posing new challenges for global public health. However, the global regulation of the virulence of epidemic SS2 isolates lacks a systematic understanding. In this study, we performed a mutational and functional analysis of an SS2 two-component system that is orthologous to the VirR/VirS regulatory system of Clostridium perfringens. An isogenic knockout mutant of VirR/VirS (ΔvirRS) was found to exhibit marked phenotypic changes, including the formation of shorter chains and thinner capsular walls, more easily cleared in whole blood, and decreased oxidative stress tolerance. Furthermore, the ΔvirRS mutant was greatly attenuated in a mouse model. Comparative proteome analysis of the expression profiles of the wild-type strain with the ΔvirRS mutant allowed us to identify 72 proteins that are differentially expressed in the absence of the VirR/VirS system and that are directly responsible for the pleiotropic phenotype of the ΔvirRS mutant.     

Overexpression of the phosphofructokinase encoding gene is crucial for achieving high production of <Emphasis Type="SmallCaps">D</Emphasis>-lactate in <Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis> under oxygen deprivation

We previously reported on the impacts of the overexpression of individual genes of the glycolytic pathway encoding glucokinase (GLK), glyceraldehyde phosphate dehydrogenase (GAPDH), phosphofructokinase (PFK), triosephosphate isomerase (TPI), and bisphosphate aldolase (FBA) on D-lactate productivity in Corynebacterium glutamicum under oxygen-deprived conditions. Searching for synergies, in the current study, we simultaneously overexpressed the five glycolytic genes in a stepwise fashion to evaluate the effect of the cumulative overexpression of glycolytic genes on D-lactate production. Interestingly, the final D-lactate concentration markedly differed depending on whether or not the PFK encoding gene was overexpressed when combined with overexpressing other glycolytic genes. The simultaneous overexpression of the GLK, GAPDH, TPI, and FBA encoding genes led to the highest initial D-lactate concentration at 10 h. However, this particular recombinant strain dramatically slowed producing D-lactate when a concentration of 1300 mM was reached, typically after 32 h. In contrast, the strain overexpressing the PFK encoding gene together with the GLK, GAPDH, TPI, and FBA encoding genes showed 12.7 % lower initial D-lactate concentration at 10 h than that observed with the strain overexpressing the genes coding for GLK, GAPDH, TPI, and FBA. However, this recombinant strain continued to produce D-lactate after 32 h, reaching 2169 mM after a mineral salts medium bioprocess incubation period of 80 h. These results suggest that overexpression of the PFK encoding gene is essential for achieving high production of D-lactate. Our findings provide interesting options to explore for using C. glutamicum for cost-efficient production of D-lactate at the industrial scale.     

The Truncated Major Pilin Subunit Sbp2 of the srtBCD Pilus Cluster Still Contributes to Streptococcus suis Pathogenesis in the Absence of Pilus Shaft

Streptococcus suis serotype 2 (SS2) is an emerging zoonotic agent responsible for a number of infections in pigs and humans. Pili have been proposed as virulence factors in Gram-positive bacteria. However, due to the abolition of pili production, the function of the srtBCD pilus cluster, especially the truncated major pilin subunit Sbp2 (Sbp2′, Sbp2″), has not been explored. In this study, isogenic mutants (Δsbp2′, Δsbp2″) were constructed by homologous replacement in SS2 strain P1/7. Deletion of sbp2′ attenuated the virulence in a zebrafish model as shown by more than an eightfold increase in the LD₅₀ of Δsbp2′, compared with that of the parent strain. In addition, the adhesion of Δsbp2′ to HEp-2 cell monolayers decreased significantly. Compared with the parent strain, no obvious differences in virulence and adherence efficiency were observed for Δsbp2″. Our data suggest that Sbp2′ could be involved in SS2 pathogenesis despite absence of its pilus shaft.     

溶原性噬菌体在猪链球菌2型分离株中的检出和鉴定

[目的]为了研究噬菌体整合酶基因在猪链球菌2型(Streptococcus suis type 2,SS2)中的分布情况.[方法]根据噬菌体整合酶基因设计引物,建立了PCR方法,并对扩增产物进行测序.[结果]结果显示,25株SS2致病菌株均扩增出目的片段,非毒力株T15、5株其它血清型猪链球菌及兰氏C群猪源链球菌未扩增出目的片段.经丝裂霉素C诱导后,SS2致病菌株出现完全的细胞溶解,而非毒力株T15未出现溶解.SS2致病株HA9801和ZY05719诱导均产生溶原性噬菌体,分别命名为SS2-HA和SS2-ZY,电镜观察,二者均头部呈正六边形,无尾部,其核酸类型为dsDNA,可鉴定为复层噬菌体科(Tectiviridae)的成员.噬菌体SS2-HA和SS2-ZY整合酶基因序列与已报道的SS2噬菌体整合酶基因序列高度同源,显示SS2噬菌体整合酶具有较高的特异性.[结论]从SS2致病株中检出溶原性噬菌体和噬菌体整合酶基因,且噬菌体整合酶基因与SS2溶菌酶释放蛋白(mrp)等7种毒力相关基因有相关性,表明SS2的溶原性噬菌体可能与其致病性有关.     

A transcriptional fusion of genes encoding glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and enolase in dinoflagellates

Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and enolase are enzymes essential for glycolysis and gluconeogenesis. Dinoflagellates possess several types of both GAPDH and enolase genes. Here, we identify a novel cytosolic GAPDH-enolase fusion protein in several dinoflagellate species. Phylogenetic analyses revealed that the GAPDH moiety of this fusion is weakly related to a cytosolic GAPDH previously reported in dinoflagellates, ciliates, and an apicomplexan. The enolase moiety has phylogenetic affinity with sequences from ciliates and apicomplexans, as expected for dinoflagellate genes. Furthermore, the enolase moiety has two insertions in a highly conserved region of the gene that are shared with ciliate and apicomplexan homologues, as well as with land plants, stramenopiles, haptophytes, and a chlorarachniophyte. Another glycolytic gene fusion in eukaryotes is the mitochondrion-targeted triose-phosphate isomerase (TPI) and GAPDH fusion in stramenopiles (i.e. diatoms and oomycetes). However, unlike the mitochondrial TPI-GAPDH fusion, the GAPDH-enolase fusion protein appears to exist in the same compartment as stand-alone homologues of each protein, and the metabolic reactions they catalyze in glycolysis and gluconeogenesis are not directly sequential. It is possible that the fusion is post-translationally processed to give separate GAPDH and enolase products, or that the fusion protein may function as a single bifunctional polypeptide in glycolysis, gluconeogenesis, or perhaps more likely in some previously unrecognized metabolic capacity.