Kazuko Okamoto-Shibayama

The malQ gene is essential for starch metabolism in Streptococcus mutans

Background The malQ and glgP genes, respectively, annotated as putative 4-α-glucanotransferase and putative glycogen phosphorylase are located with a 29 nucleotide overlap on the Streptococcus mutans genome. We found that the glgP gene of this organism was induced with maltose, and the gene likely constituted an operon with the upstream gene malQ. This putative operon was negatively regulated with the malR gene located upstream from the malQ gene and a MalR-binding consensus sequence was found upstream of the malQ gene. S. mutans is not able to catabolize starch. However, this organism utilizes maltose degraded from starch in the presence of saliva amylase. Therefore, we hypothesized that the MalQ/GlgP system may participate in the metabolism of starch-degradation products. Methods A DNA fragment amplified from the malQ or glgP gene overexpressed His-tagged proteins with the plasmid pBAD/HisA. S. mutans malQ and/or glgP mutants were also constructed. Purified proteins were assayed for glucose-releasing and phosphorylase activities with appropriate buffers containing maltose, maltotriose, maltodextrin, or amylodextrin as a substrate, and were photometrically assayed with a glucose-6-phosphate dehydrogenase–NADP system. Results Purified MalQ protein released glucose from maltose and maltotriose but did not from either maltodextrin or amylodextrin. The purified GlgP protein did not exhibit a phosphorylase reaction with maltose or maltotriose but generated glucose-1-phosphate from maltodextrin and amylodextrin. However, the GlgP protein released glucose-1-phosphate from maltose and maltotriose in the presence of the MalQ protein. In addition, the MalQ enzyme activity with maltose released not only glucose but also produced maltooligosaccharides as substrates for the GlgP protein. Conclusion These results suggest that the malQ gene encodes 4-α-glucanotransferase but not α-1,4-glucosidase activity. The malQ mutant could not grow in the presence of maltose as a carbon source, which suggests that the malQ gene is essential for the utilization of starch-degradation products.

Glucose-PTS Involvement in Maltose Metabolism by Streptococcus mutans.

Streptococcus mutans grows with starch-derived maltose in the presence of saliva. Maltose transported into the cells is mediated by the MalQ protein (4-alpha-glucanotransferase) to produce glucose and maltooligosaccharides. Glucose can be phosphorylated to glucose 6-phosphate, which can enter the glycolysis pathway. The MalQ enzyme is essential in the catabolism of maltose when it is the sole carbon source, suggesting the presence of a downstream glucokinase of the MalQ enzyme reaction. However, a glucokinase gene-inactivated mutant (glk mutant) grew with maltose as the sole carbon source, with no residual glucokinase activity. This left a phosphoenolpyruvate-dependent phosphotransferase system (PTS) as the only candidate pathway for the phosphorylation of glucose in its transport as a substrate. Our hypothesis was that intracellular glucose derived from maltose mediated by the MalQ protein was released into the extracellular environment, and that such glucose was transported back into the cells by a PTS. The mannose PTS encoded by the manL, manM, and manN genes transports glucose into cells as a high affinity system with concomitant phosphorylation. The purpose of this study was to investigate extracellular glucose by using an enzyme-linked photometrical method, monitoring absorbance changes at 340 nm in supernatant of S. mutans cells. A significant amount of glucose was detected in the extracellular fluid of a glk, manLM double mutant. These results suggest that the glk and manLMN genes participate in maltose catabolism in this organism. The significance of multiple metabolic pathways for important energy sources, including maltose, in the oral environment is discussed.

Genes responsible for dextran-dependent aggregation of Streptococcus sobrinus strain 6715

INTRODUCTION Streptococcus sobrinus exhibits more significant dextran-dependent aggregation mediated by glucan-binding proteins than Streptococcus mutans. We have identified four glucan-binding protein C gene (gbpC) homologues designated as gbpC1, gbpC2, dblA and dblB in S. sobrinus in contrast to the single gene gbpC in S. mutans. We attempted to determine which gene is most responsible for the dextran-dependent aggregation of S. sobrinus. METHODS We introduced mutation with a chemical mutagen, 1-methyl-3-nitro-1-nitrosoguanidine, into S. sobrinus strain 6715 and analysed the four gbpC homologous gene sequences in the parental strain 6715 and an obtained aggregation-negative mutant NUM-Ssg99. We also examined the localization of proteins encoded by these genes in the mutant NUM-Ssg99. RESULTS The nucleotide sequences of the gbpC1, gbpC2 and dblA genes in NUM-Ssg99 were 100% identical to the homologous genes in parental strain 6715. In contrast, a truncated mutation was detected in the dblB gene and the mutant protein devoid of the LPXTG motif was confirmed by Western blot analysis to be released into the extracellular milieu. CONCLUSION We conclude that the dblB gene among the four GbpC homologous protein genes is most responsible for aggregation in strain 6715.

A mechanism for extremely weak SpaP-expression in Streptococcus mutans strain Z1

Abstract Background: Streptococcus mutans surface-protein antigen (SpaP, PAc, or antigen I/II) has been well known to play an important role in initial attachment to tooth surfaces. However, strains with weak SpaP-expression were recently reported to be found in natural populations of S. mutans. The S. mutans gbpC-negative strain Z1, which we previously isolated from saliva and plaque samples, apparently expresses relatively low levels of SpaP protein compared to S. mutans strains MT8148 or UA159. Objective: To elucidate the mechanism for weak SpaP-expression in this strain, the spaP gene region in strain Z1 was amplified by polymerase chain reaction (PCR) and analyzed. Methods: Allelic exchange mutants between strains Z1 and UA159 involving the spaP gene region were constructed. The SpaP protein expressed in the mutants was detected with Coomasie Brilliant Blue (CBB)-staining and Western blot analysis following SDS-PAGE. Results: The 4689 bp spaP gene coding sequence for Z1 appeared to be intact. In contrast, a 20 bp nucleotide sequence appeared to be deleted from the region immediately upstream from the Z1 spaP gene when compared to the same region in UA159. The 216 bp and 237 bp intergenic fragments upstream from the spaP gene, respectively, from Z1 and UA159 were isolated, modified, and transformed into the other strain by allelic replacement. The resultant UA159-promoter region-mutant exhibited extremely weak SpaP-expression similar to that of strain Z1 and the Z1 complemented mutant expressed Spa protein levels like that of strain UA159. Conclusion: These results suggest that weak SpaP-expression in strain Z1 resulted from a 20 bp-deletion in the spaP gene promoter region.

Four gbpC Gene Homologues in Streptococcus sobrinus

We previously identified the glucan-binding protein C gene, gbpC, solely involved in dextran-dependent aggregation (ddag) of Streptococcus mutans. Recently, we identified two gbpC gene homologues, gbpC and dbl, in Streptococcus sobrinus, and suggested that the dbl gene was very likely responsible for ddag of this species. However, homology searches with the gbpC or dbl genes against the incomplete TIGR S. sobrinus 6715 database suggested that this strain may have other gbpC homologues. PCR-based chromosomal walking from the gbpC and dbl genes revealed two additional homologous genes designated as gbpC2 and dblB. Proteins encoded by these genes exhibited alpha-1,6 glucan-binding activities. Therefore, gbpC2 and dblB are also logical candidates responsible for the ddag phenotype.

Involvement of luxS in Biofilm Formation by Capnocytophaga ochracea

Capnocytophaga ochracea is present in the dental plaque biofilm of patients with periodontitis. Biofilm cells change their phenotype through quorum sensing in response to fluctuations in cell-population density. Quorum sensing is mediated by auto-inducers (AIs). AI-2 is involved in intercellular signaling, and production of its distant precursor is catalyzed by LuxS, an enzyme involved in the activated methyl cycle. Our aim was to clarify the role of LuxS in biofilm formation by C. ochracea. Two luxS-deficient mutants, TmAI2 and LKT7, were constructed from C. ochracea ATCC 27872 by homologous recombination. The mutants produced significantly less AI-2 than the wild type. The growth rates of these mutants were similar to that of the wild-type in both undiluted Tryptic soy broth and 0.5 × Tryptic soy broth. However, according to crystal violet staining, they produced significantly less biofilm than the wild type. Confocal laser scanning microscopy and scanning electron microscopy showed that the biofilm of the TmAI2 strain had a rougher structure than that of the wild type. Complementation of TmAI-2 with extrinsic AI-2 from the culture supernatant of wild-type strain did not restore biofilm formation by the TmAI2 strain, but complementation of LKT7 strain with luxS partially restored biofilm formation. These results indicate that LuxS is involved in biofilm formation by C. ochracea, and that the attenuation of biofilm formation by the mutants is likely caused by a defect in the activated methyl cycle rather than by a loss of AI-2.

Additional Glucose-PTS Induction in Streptococcus mutans Mutant Deficient in Mannose- and Cellobiose-PTS

Streptococcus mutans utilizes maltooligosaccharides, including maltose derived from human dietary starch. We recently reported that the glucose-phosphotransferase system (Glc-PTS) was also involved in the metabolism of glucose derived from intracellular maltooligosaccharides in S. mutans. The activity of the Glc-PTS was mediated by the mannose-(manLMN) and cellobiose-PTSs (celABRCD) in this organism. The purpose of this study was to identify which kind of glucose transporter was involved in this process. A celD, manLM, and glk triple mutant, cm6vU1, was constructed and its growth in maltose or glucose broth measured. When cm6vU1 cells were inoculated into a fresh glucose broth following prolonged incubation with glucose, their growth rate was greater than that in the initial inoculum. This suggested that an additional Glc-PTS was induced in these cells. To investigate this possibility, permeabilized S. mutans cells were constructed and Glc-PTS activity examined by photometrical assay method. Activity in the cells was higher in the secondary inocula than in the initial inocula. These results suggest that S. mutans possesses an additional as yet uncharacterized PTS transporter for glucose in addition to the mannose- and cellobiose-PTSs.

Characterization of a novel potential peptide import system in Treponema denticola

Treponema denticola is a major etiologic agent of chronic periodontitis. On the outer sheath of T. denticola, several proteins, such as the major outer sheath protein and dentilisin were detected, and among them, a 95 kDa protein which has not yet been characterized. The aim of this study was to characterize the function of this 95 kDa protein containing gene cluster. A gene encoding this 95 kDa protein (TDE_1072) of T. denticola was inactivated by homologous recombination. We compared growth curves between the TDE_1072 mutant and wild-type strains as well as differences in gene expression by DNA microarray analysis. Differential expression of genes identified by microarray analysis was confirmed by quantitative reverse transcription-polymerase chain reaction. The proteins encoded by TDE_1072, TDE_1073, TDE_1074, TDE_1075, and TDE_1076 shared respective similarities to the substrate-binding domain (DppA) of an ABC-type dipeptide/oligopeptide/nickel transport system, and to the permease components (DppB and DppC) and ATPase components (DppD and DppF) of an ABC-type dipeptide/oligopeptide/nickel transport system. Inactivation of dppA attenuated the growth of T. denticola and dppA-dppF were co-transcribed. In contrast, expression of oppB-oppF was up-regulated in the mutant. Our findings indicate that TDE_1072 may be a potential periplasmic solute binding protein encoded by dppA that is involved in the organization of a peptide uptake system with dppB-dppF.

Effect of extracytoplasmic function sigma factors on autoaggregation, hemagglutination, and cell surface properties of Porphyromonas gingivalis

Porphyromonas gingivalis is a bacterium frequently isolated from chronic periodontal lesions and is involved in the development of chronic periodontitis. To colonize the gingival crevice, P. gingivalis has to adapt to environmental stresses. Microbial gene expression is regulated by transcription factors such as those in two-component systems and extracytoplasmic function (ECF) sigma factors. ECF sigma factors are involved in the regulation of environmental stress response genes; however, the roles of individual ECF sigma factors are largely unknown. The purpose of this study was to investigate the functions, including autoaggregation, hemagglutination, gingipain activity, susceptibility to antimicrobial agents, and surface structure formation, of P. gingivalis ECF sigma factors encoded by SigP (PGN_0274), SigCH (PGN_0319), PGN_0450, PGN_0970, and SigH (PGN_1740). Various physiological aspects of the sigP mutant were affected; autoaggregation was significantly decreased at 60 min (p < 0.001), hemagglutination activity was markedly reduced, and enzymatic activities of Kgp and Rgps were significantly decreased (p < 0.001). The other mutants also showed approximately 50% reduction in Rgps activity. Kgp activity was significantly reduced in the sigH mutant (p < 0.001). No significant differences in susceptibilities to tetracycline and ofloxacin were observed in the mutants compared to those of the wild-type strain. However, the sigP mutant displayed an increased susceptibility to ampicillin, whereas the PGN_0450 and sigH mutants showed reduced susceptibility. Transmission electron microscopy images revealed increased levels of outer membrane vesicles formed at the cell surfaces of the sigP mutant. These results indicate that SigP is important for bacterial surface-associated activities, including gingipain activity, autoaggregation, hemagglutination, vesicle formation, and antimicrobial susceptibility.

Possible Involvement of Surface Antigen Protein 2 in the Morphological Transition and Biofilm Formation of Candida albicans

Surface antigen protein 2 (Csa2) is a member of the Candida albicans Common in Fungal Extracellular Membranes (CFEM) protein superfamily. We previously established its role in iron acquisition in C. albicans. However, the other roles of Csa2 remain unknown. Here, we compared growth, morphological transition, and biofilm formation among wild-type, Csa2-mutant, and complemented strains of C. albicans. Deletion of the Csa2 gene resulted in smaller and reduced colony growth, significant attenuation of the dimorphic transition under serum-inducing conditions, and reduced biofilm formation; complementation restored these levels to those of the wild-type. Our findings demonstrated that Csa2 participated in yeast-to-hyphae morphological switching under serum-inducing conditions and contributed to the biofilm formation of C. albicans. This work, therefore, provides novel insights into the potential roles of Csa2 in virulence of C. albicans.