Protein preparation, crystallization and preliminary X-ray crystallographic studies of Smu.1392c from Streptococcus mutans

Smu.1392c is a protein with 158 residues of uncharacterized function. Bioinformatics studies predict it is a putative acetyltransferase. In order to identify its exact function via structural studies, Smu.1392c gene was amplified from Streptococcus mutans genomic DNA and cloned into expression vector PET28a. Smu.1392c was crystallized and diffracted to a resolution of 3 A in-house. The crystal belongs to R32 space group, with unit cell parameters a=b=229.10, c=63.49 A. There are 2 or 3 molecules in the asymmetric unit.     

Structure of the bifunctional methyltransferase YcbY (RlmKL) that adds the m7G2069 and m2G2445 modifications in Escherichia coli 23S rRNA

The 23S rRNA nucleotide m(2)G2445 is highly conserved in bacteria, and in Escherichia coli this modification is added by the enzyme YcbY. With lengths of around 700 amino acids, YcbY orthologs are the largest rRNA methyltransferases identified in Gram-negative bacteria, and they appear to be fusions from two separate proteins found in Gram-positives. The crystal structures described here show that both the N- and C-terminal halves of E. coli YcbY have a methyltransferase active site and their folding patterns respectively resemble the Streptococcus mutans proteins Smu472 and Smu776. Mass spectrometric analyses of 23S rRNAs showed that the N-terminal region of YcbY and Smu472 are functionally equivalent and add the m(2)G2445 modification, while the C-terminal region of YcbY is responsible for the m(7)G2069 methylation on the opposite side of the same helix (H74). Smu776 does not target G2069, and this nucleotide remains unmodified in Gram-positive rRNAs. The E.coli YcbY enzyme is the first example of a methyltransferase catalyzing two mechanistically different types of RNA modification, and has been renamed as the Ribosomal large subunit methyltransferase, RlmKL. Our structural and functional data provide insights into how this bifunctional enzyme evolved.     

LuxS-mediated signaling in Streptococcus mutans is involved in regulation of acid and oxidative stress tolerance and biofilm formation

LuxS-mediated quorum sensing has recently been shown to regulate important physiologic functions and virulence in a variety of bacteria. In this study, the role of luxS of Streptococcus mutans in the regulation of traits crucial to pathogenesis was investigated. Reporter gene fusions showed that inactivation of luxS resulted in a down-regulation of fructanase, a demonstrated virulence determinant, by more than 50%. The LuxS-deficient strain (TW26) showed increased sensitivity to acid killing but could still undergo acid adaptation. Northern hybridization revealed that the expression of RecA, SmnA (AP endonuclease), and Nth (endonuclease) were down-regulated in TW26, especially in early-exponential-phase cells. Other down-regulated genes included ffh (a signal recognition particle subunit) and brpA (biofilm regulatory protein A). Interestingly, the luxS mutant showed an increase in survival rate in the presence of hydrogen peroxide (58.8 mM). The luxS mutant formed less biofilm on hydroxylapatite disks, especially when grown in biofilm medium with sucrose, and the mutant biofilms appeared loose and hive-like, whereas the biofilms of the wild type were smooth and confluent. The mutant phenotypes were complemented by exposure to supernatants from wild-type cultures. Two loci, smu486 and smu487, were identified and predicted to encode a histidine kinase and a response regulator. The phenotypes of the smu486 smu487 mutant were, in almost all cases, similar to those of the luxS mutant, although our results suggest that this is not due to AI-2 signal transduction via Smu486 and Smu487. This study demonstrates that luxS-dependent signaling plays critical roles in modulating key virulence properties of S. mutans.     

口腔致病菌变形链球菌Smu.776蛋白的制备、结晶及初级晶体学分析

变形链球菌smu.776基因编码一段含有385个氨基酸的蛋白质,其功能可能为依赖于腺苷甲硫氨酸的甲基转移酶.smu.776的DNA片段被克隆到表达载体pET28a后,在大肠杆菌BL21(DE3)菌株中过量表达得到很好的产量.产物Smu.776蛋白通过Ni2 亲和柱和分子筛柱层析两步得到纯化.采用悬滴气象扩散法得到了Smu.776蛋白的晶体.X射线衍射分辨率达到2.0!,晶体属单斜空间群C2,晶格参数为a=168.47",b=50.66#,c=53.96$,β=104.22°.每个最小不对称单元内含有一个蛋白质分子,溶剂含量为51.3%.     

Protein preparation, crystallization and preliminary X-ray crystallographic analysis of Smu.1475c from caries pathogen Streptococcus mutans

The gene smu.1475c encodes a putative protein of 211 residues in Streptococcus mutans, a primary pathogen for human dental caries. In this work, smu.1475c was cloned into pET28a and expressed in good amount from the E. coli strain BL21 (DE3). Smu.1475c protein was purified to homogeneity in a two-step procedure of Ni2+ chelating and size exclusion chromatography. Crystals were obtained by hanging-drop vapor-diffusion method and diffracted to 2.7 angstroms resolution. The crystal belongs to orthorhombic space group P2(1)2(1)2(1) with cell dimension of a = 68.3 angstroms, b = 105.9 angstroms, c = 136.2 angstroms. The asymmetric unit is expected to contain four molecules with solvent content of 49.4%.     

Analysis of immunoglobulin Sgamma3 recombination breakpoints by PCR: implications for the mechanism of isotype switching.

The molecular mechanism of immunoglobulin switch recombination is poorly understood. Switch recombination occurs between pairs of switch regions located upstream of the constant heavy chain genes. Previously we showed that switch recombination breakpoints cluster to a defined subregion in the Sgamma3, Sgamma1 and Sgamma2b tandem repeats. We have developed a strategy for direct amplification of Smu/Sgamma3 composite fragments as well as Smu and Sgamma3 regions by PCR. This assay has been used to analyze the organization of Smu, Sgamma3 and a series of Smu/Sgamma3 recombination breakpoints from hybridomas and normal mitogen-activated splenic B cells. DNA sequence analysis of the switch fragments showed direct joining of Smu and Sgamma3 without deletions or duplications. Mutations were found in two switch junctions on both sides of the crossover point, suggesting that template switching is the most likely model for the mechanism of switch recombination. Statistical analysis of the positions of the recombination breakpoints in the Sgamma3 tandem repeat indicates the presence of two sub-clusters, suggesting non-random usage of DNA substrate in the recombination reaction.     

Immunoglobulin heavy chain switch region recombination within a retroviral vector in murine pre-B cells.

We have employed a retroviral vector, ZN(Smu/S gamma 2b)tk1, as a substrate for detecting the presence of immunoglobulin heavy chain constant region (CH) gene switch (S) recombination activity in murine pre-B cells. ZN(Smu/S gamma 2b)tk1 contains a neomycin (neo) resistance gene in addition to the herpes simplex virus thymidine kinase (Htk) gene which is positioned between murine Smu and S gamma 2b sequences. Stable acquisition of the ZN(Smu/S gamma 2b)tk1 vector was selected in G-418 and switch region recombination within these proviruses was selected by resistance to the drug bromodeoxyuridine (BUdR). Fluctuation analyses of ZN(Smu/S gamma 2b)tk1 infected 18-8tk- and 38B9tk- pre-B lines revealed Htk gene inactivations with apparent frequencies of 5 X 10(-5) and 1 X 10(-5) events/cell/generation, respectively, while G-418 resistant Ltk- fibroblasts lost the HTK phenotype at an apparent rate of 4 X 10(-8). Southern blot analysis demonstrated that switch recombination caused the deletion of the Htk gene in all pre-B clones examined while the loss of Htk in Ltk- clones was not mediated by S region recombination. In 21 out of 24 pre-B clones, the recombinations involved the tandemly repetitive portions of the Smu and S gamma 2b sequences. These results demonstrate that the CH gene S region segments inserted into ZN(Smu/S gamma 2b)tk1 are sufficient for B-cell-specific recombination/deletion within the S region tandem repeats.     

Structural and functional characterization of a novel α/β hydrolase from cariogenic pathogen Streptococcus mutans

The protein Smu.1393c from Streptococcus mutans is annotated as a putative α/β hydrolase, but it has low sequence identity to the structure‐known α/β hydrolases. Here we present the crystal structure of Smu.1393c at 2.0 Å resolution. Smu.1393c has a fully open alkaline substrate pocket, whose conformation is unique among other similar hydrolase structures. Three residues, Ser101, His251, and Glu125, were identified as the active center of Smu.1393c. By screening a series of artificial hydrolase substrates, we demonstrated Smu.1393c had low carboxylesterase activity towards short‐chain carboxyl esters, which provided a clue for exploring the in vivo function of Smu.1393c. Proteins 2014; 82:695–700. © 2013 Wiley Periodicals, Inc.     

A temperature-sensitive mutation in the WD repeat-containing protein Smu1 is related to maintenance of chromosome integrity

Temperature-sensitive CHO-K1 mutant cell line tsTM18 exhibits chromosomal instability and cell cycle arrest at S and G2 phases with decreased DNA synthesis at the nonpermissive temperature, 39 degrees C. To identify the causative mutation, we fused tsTM18 cells with normal human cells to generate hybrids carrying fragments of human chromosomes. Analysis of chromosome content of temperature-resistant transformants and introduction of a bacterial artificial chromosome containing part of human chromosome 9 led to isolation of the human SMU1 gene. Comparison of sequences of the Smu1 gene from wild-type and mutant cells revealed that the mutant phenotype is caused by a G-to-A transition that yields a gly-to-arg substitution at position 489 in hamster Smu1. The substituted glycine is located in the WD-repeat domain of Smu1. Single-stranded DNA accumulated in the nuclei of mutant cells at 39 degrees C. Furthermore, cdc2 kinase was not activated during G2 phase, and there was no chromosome segregation due to incomplete assembly of the spindle during M phase. Thus, Smu1 appears to be involved directly or indirectly in DNA replication, activation of cdc2 kinase, spindle assembly, and maintenance of chromosome integrity, reflecting the important roles of Smu1 in cellular function.     

Involvement of sensor kinases in the stress tolerance response of Streptococcus mutans

The gram-positive bacterium Streptococcus mutans is the primary causative agent in the formation of dental caries in humans. The ability of S. mutans to adapt and to thrive in the hostile environment of the oral cavity suggests that this cariogenic pathogen is capable of sensing and responding to different environmental stimuli. This prompted us to investigate the role of two-component signal transduction systems (TCS), particularly the sensor kinases, in response to environmental stresses. Analysis of the annotated genome sequence of S. mutans indicates the presence of 13 putative TCS. Further bioinformatics analysis in our laboratory has identified an additional TCS in the genome of S. mutans. We verified the presence of the 14 sensor kinases by using PCR and Southern hybridization in 13 different S. mutans strains and found that not all of the sensor kinases are encoded by each strain. To determine the potential role of each TCS in the stress tolerance of S. mutans UA159, insertion mutations were introduced into the genes encoding the individual sensor kinases. We were successful in inactivating all of the sensor kinases, indicating that none of the TCS are essential for the viability of S. mutans. The mutant S. mutans strains were assessed for their ability to withstand various stresses, including osmotic, thermal, oxidative, and antibiotic stress, as well as the capacity to produce mutacin. We identified three sensor kinases, Smu486, Smu1128, and Smu1516, which play significant roles in stress tolerance of S. mutans strain UA159.     

Sequence dependence of chromosomal R-loops at the immunoglobulin heavy-chain Smu class switch region

The mechanism by which the cytidine deaminase activation-induced deaminase (AID) acts at immunoglobulin heavy-chain class switch regions during mammalian class switch recombination (CSR) remains unclear. R-loops have been proposed as a basis for this targeting. Here, we show that the difference between various forms of the Smu locus that can or cannot undergo CSR correlates well with the locations and detectability of R-loops. The Smu R-loops can initiate hundreds of base pairs upstream of the core repeat switch regions, and the area where the R-loops initiate corresponds to the zone where the AID mutation frequency begins to rise, despite a constant density of WRC sites in this region. The frequency of R-loops is 1 in 25 alleles, regardless of the presence of the core Smu repeats, again consistent with the initiation of most R-loops upstream of the core repeats. These findings explain the surprisingly high levels of residual CSR in B cells from mice lacking the core Smu repeats but the marked reduction in CSR in mice with deletions of the region upstream of the core Smu repeats. These studies also provide the first analysis of how R-loop formation in the eukaryotic chromosome depends on the DNA sequence.     

DnaK expression in response to heat shock of Streptococcus mutans

Abstract The oral pathogen, Streptococcus mutans , persistently colonizes human hosts and initiates oral disease despite extreme variations in environmental conditions. To begin to investigate the role of the stress protein, DnaK (Hsp70), in environmental stress responses by S. mutans , pulse—chase experiments were initially used to establish that a functional heat shock response existed in this organism. A C-terminal fragment of the S. mutans dnaK gene was cloned and engineered to be expressed with a histidine tag. Using the recombinant DnaK protein that had been purified by nickel affinity chromatography, an antibody specific for the S. mutans DnaK protein was generated to analyse DnaK expression under homeostatic and heat shock conditions. Western blot analysis indicated that the anti-recombinant DnaK antibody specifically recognized a protein (molecular mass approx. 68 kDa) which was induced in response to thermal stress. Elucidating the role of DnaK in responses by S. mutans to various environmental Stressors will provide a better understanding of how DnaK is involved in survival of extreme environments and the contribution of the DnaK protein to the virulence of S. mutans .     

Role of Hsl7 in morphology and pathogenicity and its interaction with other signaling components in the plant pathogen Ustilago maydis

The phytopathogenic fungus Ustilago maydis undergoes a dimorphic transition in response to mating pheromone, host, and environmental cues. On a solid medium deficient in ammonium (SLAD [0.17% yeast nitrogen base without ammonium sulfate or amino acids, 2% dextrose, 50 μM ammonium sulfate]), U. maydis produces a filamentous colony morphology, while in liquid SLAD, the cells do not form filaments. The p21-activated protein kinases (PAKs) play a substantial role in regulating the dimorphic transition in fungi. The PAK-like Ste20 homologue Smu1 is required for a normal response to pheromone, via upregulation of pheromone expression, and virulence, and its disruption affects both processes. Our experiments suggest that Smu1 also regulates cell length and the filamentous response on solid SLAD medium. Yeast two-hybrid analysis suggested an Hsl7 homologue as a potential interacting partner of Smu1, and a unique open reading frame for such an arginine methyltransferase was detected in the U. maydis genome sequence. Hsl7 regulates cell length and the filamentous response to solid SLAD in a fashion opposite to that of Smu1, but neither overexpression nor disruption of hsl7 attenuates virulence. Simultaneous disruption of hsl7 and overexpression of smu1 lead to a hyperfilamentous response on solid SLAD. Moreover, only this double mutant strain forms filaments in liquid SLAD. The double mutant strain was also significantly reduced in virulence. A similar filamentous response in both solid and liquid SLAD was observed in strains lacking another PAK-like protein kinase involved in cytokinesis and polar growth, Cla4. Our data suggest that Hsl7 may regulate cell cycle progression, while both Smu1 and Cla4 appear to be involved in the filamentous response in U. maydis.     

Mutation of the NADH oxidase gene (nox) reveals an overlap of the oxygen- and acid-mediated stress responses in Streptococcus mutans

NADH oxidase (Nox) is a flavin-containing enzyme used by Streptococcus mutans to reduce dissolved oxygen encountered during growth in the oral cavity. In this study, we characterized the role of the NADH oxidase in the oxidative and acid stress responses of S. mutans. A nox-defective mutant strain of S. mutans and its parental strain, the genomic type strain UA159, were exposed to various oxygen concentrations at pH values of 5 and 7 to better understand the adaptive mechanisms used by the organism to withstand environmental pressures. With the loss of nox, the activities of oxygen stress response enzymes such as superoxide dismutase and glutathione oxidoreductase were elevated compared to those in controls, resulting in a greater adaptation to oxygen stress. In contrast, the loss of nox led to a decreased ability to grow in a low-pH environment despite an increased resistance to severe acid challenge. Analysis of the membrane fatty acid composition revealed that for both the nox mutant and UA159 parent strain, growth in an oxygen-rich environment resulted in high proportions of unsaturated membrane fatty acids, independent of external pH. The data indicate that S. mutans membrane fatty acid composition is responsive to oxidative stress, as well as changes in environmental pH, as previously reported (E. M. Fozo and R. G. Quivey, Jr., Appl. Environ. Microbiol. 70:929-936, 2004). The heightened ability of the nox strain to survive acidic and oxidative environmental stress suggests a multifaceted response system that is partially dependent on oxygen metabolites.