Wasabi leaf extracts attenuate adipocyte hypertrophy through PPARγ and AMPK.

Hypertrophy of adipocytes in obese adipose tissues causes metabolic abnormality by adipocytokine dysregulation, which promotes type 2 diabetes mellitus, hypertension, and dyslipidemia. We investigated the effects of wasabi (Wasabia japonica Matsum) leaf extracts on metabolic abnormalities in SHRSP.Z-Leprfa/IzmDmcr rats (SHRSP/ZF), which are a model of metabolic syndrome. Male SHRSP/ZF rats aged 7 weeks were divided into two groups: control and wasabi leaf extract (WLE) groups, which received water or oral treatment with 4 g/kg/day WLE for 6 weeks. WLE improved the body weight gain and high blood pressure in SHRSP/ZF rats, and the plasma triglyceride levels were significantly lower in the WLE group. Adipocyte hypertrophy was markedly prevented in adipose tissue. The expression of PPARγ and subsequent downstream genes was suppressed in the WLE group adipose tissues. Our data suggest that WLE inhibits adipose hypertrophy by suppressing PPARγ expression in adipose tissue and stimulating the AMPK activity by increased adiponectin.

Multistep regulation of protein kinase A in its localization, phosphorylation and binding with a regulatory subunit in fission yeast.

The cAMP-PKA is the major glucose-sensing pathway that controls sexual differentiation in Schizosaccharomyces pombe. Sequencing from the pka1 locus of recessive sam mutants, in which cells are highly inclined to sexual differentiation, led to the identification of mutations in the pka1 locus in sam5 (pka1-G441E) and sam7 (pka1-G441R). Rst2 and Ste11 proteins were induced and localized to the nucleus of sam5 and sam7 mutants even under rich glucose conditions, indicating that the function of Pka1 was completely abolished by mutations. Pka1-G441E and Pka1-G441R mutant proteins reside in the cytoplasm, even under glucose-rich conditions, while wild-type Pka1 resides in the nucleus, indicating that the functionality of Pka1 is important for its nuclear localization. This is supported by the observation that the Pka1-T356A mutant, which partially lacks Pka1 function, was localized to both the cytoplasm and the nucleus, but an active phosphomimetic Pka1-T356D mutant prtotein was localized to the nucleus under glucose-rich conditions. In addition to the basal phosphorylation of Pka1 at T356, hyperphosphorylation of Pka1 was observed under glucose-starved conditions, and such hyperphosphorylation was not observed in pka1-G441E, pka1-G441R, pka1-T356A or pka1-T356D mutants. As these mutant proteins failed to interact with a regulatory subunit Cgs1, hyperphosphorylation of Pka1 mutant proteins was considered to be dependent on Cgs1 interaction. Consistent with a role for Cgs1 in Pka1 phosphorylation, we detected the formation of a Cgs1-Pka1 complex prior to Pka1 hyperphosphorylation. Together, these results indicate that nuclear localization of Pka1 depends on its activity and hyperphosphorylation of Pka1 depends on Cgs1 interaction.

Complex formation, phosphorylation, and localization of protein kinase A of Schizosaccharomyces pombe upon glucose starvation.

Nine sam mutants that undergo sexual differentiation without requiring starvation in Schizosaccharomyces pombe were previously isolated. In this study, we identified a nonsense mutation on the pka1 locus in the sam6 mutant. pka1 encodes a catalytic subunit of protein kinase A (PKA). Replacement and overexpression of pka1 suppressed the KCl sensitivity and hyper-mating phenotype of sam6, confirming that sam6 is an allele of pka1. To characterize further the regulation of Pka1, we tested the physical interaction between Pka1 and Cgs1 (a regulatory subunit of PKA). Pka1 and Cgs1 physically interacted under glucose-limited conditions but not under glucose-rich conditions. In addition, the formation of a Pka1-Cgs1 complex was detected under glucose-limited conditions by Blue Native PAGE. Furthermore, the Pka1 protein was found to be phosphorylated under glucose-starved conditions, and at the same time its localization shifted from the nucleus towards the cytoplasm (mainly the vacuoles), suggesting a strong relationship among phosphorylation, complex formation, and the cytoplasmic distribution of Pka1.

Regulation and role of an RNA-binding protein Msa2 in controlling the sexual differentiation of fission yeast.

The msa2/nrd1 gene encodes an RNA-binding protein that negatively regulates sexual differentiation of fission yeast Schizosaccharomyces pombe by repressing the Ste11-regulated genes. However, it is not known how Msa2 regulates sexual differentiation, and to characterize its role, we altered the msa2 gene by inducing point mutations and tested the resulting mutants for their ability to inhibit sexual differentiation and their suppressive effect on a temperature sensitive pat1 mutant. Several amino acids were found to be important, including three phenylalanine residues (F153, F245 and F453) in the three consensus RNA recognition motifs (RRMs) and a threonine residue (T126) that normally functions as a phosphorylation site. Results indicated that Msa2 was negatively regulated by phosphorylation that arose from Spk1-mediated pheromone signaling. Msa2 also regulated the Ste11 protein level coordinating with Cpc2, a ribosomal-associated protein. In addition, Msa2 was detected in stress granules that co-localized with Pabp in the cytosol under conditions of glucose starvation. Msa2 may regulate the translation of Ste11, be a component of stress granules that form in response to glucose starvation, and regulate the sexual differentiation of S. pombe.

A large complex mediated by Moc1, Moc2 and Cpc2 regulates sexual differentiation in fission yeast.

Sexual differentiation in Schizosaccharomyces pombe is triggered by nutrient starvation and is downregulated by cAMP. Screening programs have identified the moc1/sds23, moc2/ded1, moc3 and moc4/zfs1 genes as inducers of sexual differentiation, even in the presence of elevated levels of cAMP. To investigate possible interactions among Moc1, Moc2, Moc3 and Moc4 proteins, we first screened for individual Moc-interacting proteins using the yeast two-hybrid system and verified the interactions with other Moc proteins. Using this screening process, Cpc2 and Rpl32-2 were highlighted as factors involved in interactions with multiple Moc proteins. Cpc2 interacted with Moc1, Moc2 and Moc3, whereas the ribosomal protein Rpl32-2 interacted with all Moc proteins in the two-hybrid system. Physical interactions of Cpc2 with Moc1, Moc2 and Rpl32-2, and of Rpl32-2 with Moc2 were confirmed by coimmunoprecipitation. In addition, using Blue Native/PAGE, we revealed that each Moc protein exists as a large complex. Overexpression of Moc1, Moc2, Moc3, Moc4 and Rpl32-2 resulted in the efficient induction of a key transcription factor Ste11, suggesting that all proteins tested are positive regulators of Ste11. Considering that Moc2/Ded1 is a general translation factor and that Cpc2 associates with many ribosomal proteins, including Rpl32-2, it is possible that a large Moc-mediated complex, detected in this study, may act as a translational regulator involved in the control of sexual differentiation in S. pombe through the induction of Ste11.

Identification of sam4 as a rad24 allele in Schizosaccharomyces pombe.

Fission yeast requires nutritional starvation to switch the mitotic cell cycle to sexual differentiation, but sam mutants, of which we had isolated nine alleles, mate without the starvation condition. These mutants are useful for understanding the mechanism underlying the way cells sense nutritional starvation and change the cell cycle. To identify the sam allele, we first sought phenotypes other than the original sam phenotype. We found that all nine sam mutants were sensitive to 1 M KCl, that sam2, sam3, sam4 and sam9 were sensitive to 0.1 M CaCl(2), and that only the sam4 mutant was sensitive to 150 J/m(2) UV. This peculiar phenotype of sam4 suggested to us that sam4 might be an allele of rad24, which encodes a 14-3-3 protein. In fact, the Rad24 protein disappeared in sam4 and the rad24 mRNA was not transcribed in sam4. In addition, the mutation that changed Gln to a stop codon was found in the rad24 locus of sam4. Hence we concluded that sam4 is an allele of rad24. We also found that over-expression of rad24 or rad25 (a paralog of rad24) has a suppressive effect on sam1, and that sam1 was not an allele of rad24 nor rad25. Thus 14-3-3 proteins are deeply involved in the switching of the mitotic cell cycle to the sexual differentiation of fission yeast.

Glutamyl tRNA synthetases and glutamic acid induce sexual differentiation of Schizosaccharomyces pombe.

The moc3 gene was screened out as an inducer of sexual differentiation in fission yeast Schizosaccharomyces pombe. We isolated a novel gene, named ers2, encoding mitochondrial glutamyl tRNA synthetase (mGluRS) as a Moc3 interacting element by the yeast two-hybrid system. Cytoplasmic glutamyl tRNA synthetase (cGluRS) also interacted with Moc3 in a yeast two-hybrid system. Disruption of ers1 (cGluRS) and of ers2 (mGluRS) indicated that these genes are both essential for the cell growth of S. pombe. We found that ers2 severely affected cell growth and decreased viability, but induced sexual differentiation of S. pombe when it was over-expressed. Over-expression of ers1 also stimulated sexual differentiation in S. pombe. These observations led us to test the effects of various amino acids on sexual differentiation. We found that glutamic acid, as well as other specific amino acids, such as tryptophan, methionine, and threonine, efficiently induced sexual differentiation in S. pombe. Our findings suggest a new regulatory mechanism where GluRSs and glutamic acid are involved in sexual differentiation in S. pombe.

Analysis of expressed sequence tags (ESTs) from Lentinula edodes.

The 1,031 expressed sequence tags (ESTs) from the basidiomycete Lentinula edodes were generated as a pilot experiment to see distribution of genes expressed in L. edodes. Among them, genes for hydrophobin, which are specifically found in filamentous fungi, were the most frequently obtained ESTs (33 times), suggesting that they are highly expressed in L. edodes. In addition to known hydrophobin 1 and 2 types, our analysis revealed the existence of novel types of hydrophobin, which we named hydrophobin 3, 4, and 5. The second and the third most highly obtained ESTs were phosphatidylserine decarboxylase and formate dehydrogenase, which were obtained eight and seven times, respectively. It should be noted that two important genes (argonaute and RNA-dependent RNA polymerase) involved in the RNAi pathway were found, suggesting a future application for gene knock-down by RNA interference. The 53 ESTs were identical with the sequences already reported in L. edodes. The 433 ESTs were found to show significant sequence similarity (E value <1 x 10(-5)) with the proteins reported (or predicted) in other species. In total, 387,952 bp were sequenced and registered in DDBJ/GenBank (accession number BJ998097-BJ999127).

Interaction between a negative regulator (Msa2/Nrd1) and a positive regulator (Cpc2) of sexual differentiation in Schizosaccharomyces pombe.

The sexual differentiation of Schizosaccharomyces pombe is controlled by many cellular components which have not been fully characterized. We isolated a gene called msa2 as a multi-copy suppressor of a sporulation abnormal mutant (sam1). Msa2p is identical with Nrd1p which has been characterized as a factor that blocks the onset of sexual differentiation. The yeast two-hybrid system was used to identify Cpc2p, a fission yeast homolog of the RACK1 protein, that interacted with Msa2p/Nrd1p. We confirmed that Msa2p/Nrd1p interacted with Cpc2p in S. pombe cells. An epistatic analysis of msa2/nrd1 and cpc2 suggests that Msa2p/Nrd1p was an upstream regulator for Cpc2p. A localization analysis of Cpc2p and Msa2p/Nrd1p indicates that both proteins were predominantly localized in the cytoplasm. The interaction of negative regulator Msa2p/Nrd1p with positive regulator Cpc2p suggests a new regulatory circuit in the sexual differentiation of S. pombe.