Isolation of Bacillus and Paenibacillus bacterial strains that produce large molecules of cyclic isomaltooligosaccharides.

Cyclic isomaltooligosaccharides (CIs) usually consist of 7 to 12 glucose units, although only CI-10 has strong inclusion complex-forming ability. Four Bacillus strains and two Paenibacillus strains were isolated as novel CI-producing bacteria. Among these, five strains produced small amounts of CI-7 to CI-9, but mainly produced CI-10 to CI-12. Larger CIs, up to CI-17, were also identified.

A novel cyclic isomaltooligosaccharide (cycloisomaltodecaose, CI-10) produced by Bacillus circulans T-3040 displays remarkable inclusion ability compared with cyclodextrins.

Cyclodextrans (CIs) are cyclic isomaltooligosaccharides and only CI-7, CI-8, and CI-9 were known. CI-7, CI-8, and CI-9, consisting of seven, eight, and nine glucoses, respectively, bound by alpha-(1-->6) linkages, are known to be produced by T-3040 strain of Bacillus circulans. However, we have found, using 13C NMR and mass spectrometry, that this strain also produces CI-10, CI-11 and CI-12. These large CIs are very soluble in water and inhibit the glucan synthesis of glucansucrases to the same degree as do the smaller CIs. The CIs were thought to be poor at forming inclusion complexes with chemical compounds, due to their flexible alpha-(1-->6)-glucosidic structure. Among these six CIs, CI-10 was much better at forming an inclusion complex, and it ability to do so was as good as cyclodextrins, as determined by its ability to stabilize the color of Victoria blue B. Therefore, CI-10 may be the most commercially useful CI.

Identification of genes whose expressions are enhanced or reduced in baker's yeast during fed-batch culture process using molasses medium by DNA microarray analysis.

Genes whose expression levels are enhanced or reduced during the cultivation process that uses cane molasses in baker's yeast production were identified in this study. The results showed that baker's yeast grown in molasses medium had higher fermentation ability and stress tolerance compared with baker's yeast grown in synthetic medium. Molasses apparently provided not only sugar as a carbon source but also provided functional components that enhanced or reduced expression of genes involved in fermentation ability and stress tolerance. To identify the genes whose expression is enhanced or reduced during cultivation in molasses medium, DNA microarray analysis was then used to compare the gene expression profile of cells grown in molasses with that of cells grown in synthetic medium. To simulate the commercial baker's yeast production process, cells were cultivated using a fed-batch culture system. In molasses medium, genes involved in the synthesis or uptake of vitamins (e.g., biotin, pyridoxine and thiamine) showed enhanced expression, suggesting that vitamin concentrations in molasses medium were lower than those in synthetic medium. Genes involved in formate dehydrogenase and maltose assimilation showed enhanced expression in molasses medium. In contrast, genes involved in iron utilization (e.g., siderophore, iron transporter and ferroxidase) showed enhanced expression in synthetic medium, suggesting that iron starvation occurred. The genes involved in the metabolism of amino acids also showed enhanced expression in synthetic medium. This identification of genes provides information that will help improve the baker's yeast production process.