Effect of superoxide dismutase and manganese on superoxide tolerance in Lactobacillus casei strain Shirota and analysis of multiple manganese transporters.

The Lactobacillus casei/paracasei group accumulates a high level of manganese, which works to scavenge superoxide anions produced during aerobic growth. The genome of L. casei strain Shirota, however, also codes the gene for superoxide dismutase (SOD), sodA, which catalyzes the dismutation of superoxide anion into hydrogen peroxide and oxygen. We anticipated that the SOD and/or manganese may contribute to the aerobic growth of L. casei Shirota and tried to clarify how L. casei Shirota can eliminate the toxicity of superoxide anion. When the sodA of L. casei Shirota was cloned and expressed in Escherichia coli as well as in L. casei Shirota, there was no increase in SOD activity detected, meaning that the protein is in an inactive form, even if it is produced in L. casei Shirota. We next focused on the role of the manganese transport system of L. casei Shirota. One ABC-type manganese transporter (mtsCBA cluster) and three NRAMP-type manganese transporters (mntH1, mntH2, and mntH3) are coded in the genome. To clarify the role of these genes, we disrupted one or more of these manganese transporter genes in different combinations and analyzed the intracellular manganese levels. As a result, we found that NRAMP-type manganese transporters coded by mntH1 and mntH2 and ABC-type manganese transporter coded by mtsCBA cluster are complementarily involved in the accumulation of intracellular manganese and are necessary for aerobic growth of L. casei Shirota. These results indicate that intracellular manganese accumulated by multiple complementary manganese transporters, but not SOD, plays a pivotal role in tolerance to superoxide in L. casei Shirota.

Application of lectin microarray to bacteria including Lactobacillus casei/paracasei strains.

Since 2005, lectin microarray technology has emerged as a simple and powerful technique for comprehensive glycan analysis. By using evanescent-field fluorescence detection technique, it has been applied for analysis of not only glycoproteins and glycolipids secreted by eukaryotic cells but also glycoconjugates on the cell surface of live eukaryotic cells. Bacterial cells are known to be decorated with polysaccharides, teichoic acids, and proteins in the peptide glycans of their cell wall and lipoteichoic acids in their phospholipid bilayer. Specific glycan structures are characteristic of many highly pathogenic bacteria, while polysaccharides moiety of lactic acid bacteria are known to play a role as probiotics to modulate the host immune response. However, the method of analysis and knowledge of glycosylation structure of bacteria are limited. Here, we describe the development of a simple and sensitive method based on lectin microarray technology for direct analysis of intact bacterial cell surface glycomes. The method involves labeling bacterial cells with SYTOX Orange before incubation with the lectin microarray. After washing, bound cells are directly detected using an evanescent-field fluorescence scanner in a liquid phase. The entire procedure takes 3 h from putting labeled bacteria on the microarray to profiling its lectin binding affinity. Using this method, we compared the cell surface glycomes from 16 different strains of L. casei/paracasei. The lectin binding profile of most strains was found to be unique. Our technique provides a novel strategy for rapid profiling of bacteria and enables us to differentiate numerous bacterial strains with relevance to the biological functions of surface glycosylation.

Monitoring immune modulation by nutrition in the general population: identifying and substantiating effects on human health.

Optimal functioning of the immune system is crucial to human health, and nutrition is one of the major exogenous factors modulating different aspects of immune function. Currently, no single marker is available to predict the effect of a dietary intervention on different aspects of immune function. To provide further guidance on the assessment and interpretation of the modulation of immune functions due to nutrition in the general population, International Life Sciences Institute Europe commissioned a group of experts from academia, government and the food industry to prepare a guidance document. A draft of this paper was refined at a workshop involving additional experts. First, the expert group defined criteria to evaluate the usefulness of immune function markers. Over seventy-five markers were scored within the context of three distinct immune system functions: defence against pathogens; avoidance or mitigation of allergy; control of low-grade (metabolic) inflammation. The most useful markers were subsequently classified depending on whether they by themselves signify clinical relevance and/or involvement of immune function. Next, five theoretical scenarios were drafted describing potential changes in the values of markers compared with a relevant reference range. Finally, all elements were combined, providing a framework to aid the design and interpretation of studies assessing the effects of nutrition on immune function. This stepwise approach offers a clear rationale for selecting markers for future trials and provides a framework for the interpretation of outcomes. A similar stepwise approach may also be useful to rationalise the selection and interpretation of markers for other physiological processes critical to the maintenance of health and well-being.

Roles of thioredoxin and thioredoxin reductase in the resistance to oxidative stress in Lactobacillus casei.

The Lactobacillus casei strain Shirota used in this study has in the genome four putative thioredoxin genes designated trxA1, trxA2, trxA3 and trxA4, and one putative thioredoxin reductase gene designated trxB. To elucidate the roles of the thioredoxins and the thioredoxin reductase against oxidative stress in L. casei, we constructed gene disruption mutants, in which each of the genes trxA1, trxA2 and trxB, or both trxA1 and trxA2 were disrupted, and we characterized their growth and response to oxidative stresses. In aerobic conditions, the trxA1 (MS108) and the trxA2 (MS109) mutants had moderate growth defects, and the trxA1 trxA2 double mutant (MS110) had a severe growth defect, which was characterized by elongation of doubling time and a lower final turbidity level. Furthermore, the trxB mutant (MS111), which is defective in thioredoxin reductase, lost the ability to grow under aerobic conditions, although it grew partially under anaerobic conditions. The growth of these mutants, however, could be substantially restored by the addition of dithiothreitol or reduced glutathione. In addition, MS110 and MS111 were more sensitive to hydrogen peroxide and disulfide stress than the wild-type. In particular, the stress sensitivity of MS111 was significantly increased. On the other hand, transcription of all these genes was only weakly affected by these oxidative stresses. Taken together, these results suggest that the thioredoxin-thioredoxin reductase system is the major thiol/disulfide redox system and is essential to allow the facultative anaerobe L. casei to grow under aerobic conditions.

Lectin microarray reveals binding profiles of Lactobacillus casei strains in a comprehensive analysis of bacterial cell wall polysaccharides.

We previously showed a pivotal role of the polysaccharide (PS) moiety in the cell wall of the Lactobacillus casei strain Shirota (YIT 9029) as a possible immune modulator (E. Yasuda M. Serata, and T. Sako, Appl. Environ. Microbiol. 74:4746-4755, 2008). To distinguish PS structures on the bacterial cell surface of individual strains in relation to their activities, it would be useful to have a rapid and high-throughput methodology. Recently, a new technique called lectin microarray was developed for rapid profiling of glycosylation in eukaryotic polymers and cell surfaces. Here, we report on the development of a simple and sensitive method based on this technology for direct analysis of intact bacterial cell surface glycomes. The method involves labeling bacterial cells with SYTOX Orange before incubation with the lectin microarray. After washing, bound cells are directly detected using an evanescent-field fluorescence scanner in a liquid phase. Using this method, we compared the cell surface glycomes from 16 different strains of L. casei. The patterns of lectin-binding affinity of most strains were found to be unique. There appears to be two types of lectin-binding profiles: the first is characterized by a few lectins, and the other is characterized by multiple lectins with different specificities. We also showed a dramatic change in the lectin-binding profile of a YIT 9029 derivative with a mutation in the cps1C gene, encoding a putative glycosyltransferase. In conclusion, the developed technique provided a novel strategy for rapid profiling and, more importantly, differentiating numerous bacterial strains with relevance to the biological functions of PS.

Suppressive effect on activation of macrophages by Lactobacillus casei strain Shirota genes determining the synthesis of cell wall-associated polysaccharides.

Although many Lactobacillus strains used as probiotics are believed to modulate host immune responses, the molecular natures of the components of such probiotic microorganisms directly involved in immune modulation process are largely unknown. We aimed to assess the function of polysaccharide moiety of the cell wall of Lactobacillus casei strain Shirota as a possible immune modulator which regulates cytokine production by macrophages. A gene survey of the genome sequence of L. casei Shirota hunted down a unique cluster of 10 genes, most of whose predicted amino acid sequences had similarities to various extents to known proteins involved in biosynthesis of extracellular or capsular polysaccharides from other lactic acid bacteria. Gene knockout mutants of eight genes from this cluster resulted in the loss of reactivity to L. casei Shirota-specific monoclonal antibody and extreme reduction of high-molecular-mass polysaccharides in the cell wall fraction, indicating that at least these genes are involved in biosynthesis of high-molecular-mass cell wall polysaccharides. By adding heat-killed mutant cells to mouse macrophage cell lines or to mouse spleen cells, the production of tumor necrosis factor alpha, interleukin-12 (IL-12), IL-10, and IL-6 was more stimulated than by wild-type cells. In addition, these mutants additively enhanced lipopolysaccharide-induced IL-6 production by RAW 264.7 mouse macrophage-like cells, while wild-type cells significantly suppressed the IL-6 production of RAW 264.7. Collectively, these results indicate that this cluster of genes of L. casei Shirota, which have been named cps1A, cps1B, cps1C, cps1D, cps1E, cps1F, cps1G, and cps1J, determine the synthesis of the high-molecular-mass polysaccharide moiety of the L. casei Shirota cell wall and that this polysaccharide moiety is the relevant immune modulator which may function to reduce excessive immune reactions during the activation of macrophages by L. casei Shirota.