Enhanced production of isoamyl alcohol and isoamyl acetate by ubiquitination-deficient Saccharomyces cerevisiae mutants

Aromatic compounds are an important element in the flavor of yeast-fermented alcohol. We isolated mutants of Saccharomyces cerevisiae capable of growth at high levels of hydrostatic pressure. Among them, the HPG1 mutants, with a defect in their Rsp5 ubiquitin ligase, were found to produce high amounts of aromatics due to enhanced leucine uptake, with isoamyl alcohol production 2- to 3-fold and isoamyl acetate production 4- to 8-fold that of the wild-type strain. The result suggests that the HPG1/RSP5 mutant alleles could be new resources for producing these flavoring compounds for yeast-fermented alcoholic beverages.     

Cell structure degradation in Escherichia coli and Thermococcus sp. strain Tc-1-95 associated with thermal death resulting from brief heat treatment

The thermal death mechanism of microorganisms when heated at lethally high temperatures is still not fully understood. In this study, we examined the relationship between thermal death and degradation of the cell structure in the mesophilic bacterium Escherichia coli strain W3110 and the hyperthermophilic archaeon Thermococcus sp. strain Tc-1-95. By heating the microorganisms at lethally high temperatures only briefly (1.5 s duration) in a flow-type apparatus, we studied the microbial cells at very early and critical stages of the thermal death process. For E. coli, it was found that the loss of viability was not associated with thermal damage to the cell envelope. Deformation of the nucleoid was observed. These results suggest that the thermal death of E. coli is attributed to thermal denaturation or degradation of cytoplasmic molecules. On the other hand, the thermal death of Thermococcus sp. strain Tc-1-95 was strongly associated with rupture of the cell envelope. Furthermore, massive deformation of the S-layer with lethal thermal stress was observed. These results demonstrate that the thermal deaths of the two microorganisms investigated proceed via very different mechanisms. The contrast can be attributed to the difference in their cell envelope structures.     

Quantification of mcrA by quantitative fluorescent PCR in sediments from methane seep of the Nankai Trough

A quantitative fluorogenic PCR method for group-specific methyl coenzyme M reductase subunit A genes (mcrA) from methanotrophic archaea was established and applied to the characterization of microbial communities in anoxic methane seep sediments at the accretionary prism of the Nankai Trough. All of the previously identified subgroups of anaerobic methanotroph (ANME) mcrA genes were detected in the cores up to 25 cm below the seafloor, but distributional patterns of mcrA genes were found to differ according to depth. These findings suggest a distinct distribution of phylogenetically and physiologically diverse methanotrophic archaea that mediate methane oxidation in the anoxic sediments. This quantification method will contribute to future investigations of methanotrophic microbial ecosystems in anoxic marine sediments.     

Establishment of a reverse genetics system for rotavirus

The rotavirus genome is composed of 11 segments of double-stranded RNA (dsRNA). Rotavirus is the leading etiological agent of severe gastroenteritis in infants and young children worldwide. Reverse genetics is the powerful and ideal methodology for the molecular study of virus replication, which enables the virus genome to be artificially manipulated. Very recently, we developed the first reverse genetics system for rotavirus, which enables one to generate an infectious rotavirus containing a novel gene segment derived from cDNA. In this review, we describe each steps of rotavirus replication to understand the background to the establishment of a reverse genetics system for rotavirus, and summarize the reverse genetics systems for segmented dsRNA viruses including rotavirus.     

An engineered sorbitol cycle alters sugar composition, not growth, in transformed tobacco

Many efforts have been made to engineer stress tolerance by accumulating polyols. Transformants that accumulate polyols often show growth inhibition, because polyols are synthesized as a dead-end product in plants that do not naturally accumulate polyols. Here, we show a novel strategy in which a sorbitol cycle was engineered by introducing apple cDNA encoding NAD-dependent sorbitol dehydrogenase (SDH) in addition to sorbitol-6-phosphate dehydrogenase (S6PDH). Tobacco plants transformed only with S6PDH showed growth inhibition, and very few transformants were obtained. In contrast, many transgenic plants with both S6PDH and SDH were easily obtained, and their growth was normal despite their accumulation of sorbitol. Interestingly, the engineered sorbitol cycle enhanced the accumulation of sucrose instead of fructose that was expected to be increased. Sucrose, rather than fructose, was also increased in the immature fruit of tomato plants transformed with an antisense fructokinase gene in which the phosphorylation of fructose was inhibited. A common phenomenon was observed in the metabolic engineering of two different pathways, showing the presence of homeostatic regulation of fructose levels.     

Functional involvement of membrane-embedded and conserved acidic residues in the ShaA subunit of the multigene-encoded Na+/H+ antiporter in Bacillus subtilis

ShaA, a member of a multigene-encoded Na+/H+ antiporter in B. subtilis, is a large integral membrane protein consisting of 20 transmembrane helices (TM). Conservation of ShaA-like protein subunits in several cation-coupled enzymes, including the NuoL (ND5) subunit of the H+-translocating complex I, suggests the involvement of ShaA in cation transport. Bacillus subtilis ShaA contains six acidic residues that are conserved in ShaA homologues and are located in putative transmembrane helices. We examined the functional involvement of the six transmembrane acidic residues of ShaA by site-directed mutagenesis. Mutation in glutamate (Glu)-113 in TM-4, Glu-657 in TM-18, aspartate (Asp)-734 and Glu-747 in TM-20 abolished the antiport activity, suggesting that these residues play important roles in the ion transport of Sha. The acidic group was necessary and sufficient in Glu-657 and Asp-743, while it was not true of Glu-113 and Glu-747. Mutation in Asp-103 in TM-3, which is conserved in ShaA-types but not in ShaAB-types, partially affected on the antiport activity. Mutation in Asp-50 in TM-2 resulted in a unexpected phenotype: mutants retained the wild type level of ability to confer NaCl resistance to the Na+/H+ antiporter-deficient E. coli KNabc, but showed a very low antiport activity. The acidic group of Asp-50 and Asp-103 was not essential for the function. Our results suggested that these acidic residues are functionally involved in the ion transport of Sha, and some of them probably in cation binding and/or translocation.     

Skin and hair pigmentation variation in Island Melanesia

Skin and hair pigmentation are two of the most easily visible examples of human phenotypic variation. Selection-based explanations for pigmentation variation in humans have focused on the relationship between melanin and ultraviolet radiation, which is largely dependent on latitude. In this study, skin and hair pigmentation were measured as the melanin (M) index, using narrow-band reflectance spectroscopy for 1,135 individuals from Island Melanesia. Overall, the results show remarkable pigmentation variation, given the small geographic region surveyed. This variation is discussed in terms of differences between males and females, among islands, and among neighborhoods within those islands. The relationship of pigmentation to age, latitude, and longitude is also examined. We found that male skin pigmentation was significantly darker than females in 5 of 6 islands examined. Hair pigmentation showed a negative, but weak, correlation with age, while skin pigmentation showed a positive, but also weak, correlation with age. Skin and hair pigmentation varied significantly between islands as well as between neighborhoods within those islands. Bougainvilleans showed significantly darker skin than individuals from any other island considered, and are darker than a previously described African-American population. These findings are discussed in relation to prevailing hypotheses about the role of natural selection in shaping pigmentation variation in the human species, as well as the role of demographic processes such as admixture and drift in Island Melanesia.