Overexpression of prefoldin from the hyperthermophilic archaeum Pyrococcus horikoshii OT3 endowed Escherichia coli with organic solvent tolerance

Prefoldin is a jellyfish-shaped hexameric chaperone that captures a protein-folding intermediate and transfers it to the group II chaperonin for correct folding. In this work, we characterized the organic solvent tolerance of Escherichia coli cells that overexpress prefoldin and group II chaperonin from a hyperthermophilic archeaum, Pyrococcus horikoshii OT3. The colony-forming efficiency of E. coli cells overexpressing prefoldin increased by 1,000-fold and decreased the accumulation of intracellular organic solvent. The effect was impaired by deletions of the region responsible for the chaperone function of prefoldin. Therefore, we concluded that prefoldin endows E. coli cells by preventing accumulation of intracellular organic solvent through its molecular chaperone activity.     

A strong exonic splicing enhancer in dystrophin exon 19 achieve proper splicing without an upstream polypyrimidine tract

Proper splicing is known to proceed under the control of conserved cis-elements located at exon-intron boundaries. Recently, it was shown that additional elements, such as exonic splicing enhancers (ESEs), are essential for the proper splicing of certain exons, in addition to the splice donor and acceptor site sequences; however, the relationship between these cis-elements is still unclear. In this report, we utilize dystrophin exon 19 to analyse the relationship between the ESE and its upstream acceptor site sequences. Dystrophin exon 19, which maintains adequate splicing donor and acceptor consensus sequences, encodes exonic splicing enhancer (dys-ESE19) sequences. Splice pattern analysis, using a minigene reporter expressed in HeLa cells, showed that either a strong polypyrimidine tract (PPT) or a fully active dys-ESE19 is sufficient for proper splicing. Each of these two cis-elements has enough activity for proper exon 19 splicing suggesting that the PPT, which is believed to be an essential cis-element for splicing, is dispensable when the downstream exon contains a strong ESE. This compensation was only seen in living cells but not in 'in vitro splicing'. This suggests the possibility that the previous splicing experiments using an in vitro splicing system could underestimate the activity of ESEs.     

Galactinol synthase gene of Coptis japonica is involved in berberine tolerance

Many plant secondary metabolites show strong biological activities and are potentially also toxic to plants, while plants producing such active compounds are usually insensitive to their own metabolites, suggesting that they have species-specific detoxification mechanisms. In order to clarify the detoxification mechanism of alkaloids, we used cultured cells of Coptis japonica, which are capable of producing a yellow benzylisoquinoline alkaloid, berberine, and accumulate it in the vacuole. Unlike other plant cells that do not produce berberine, C. japonica shows strong tolerance to this alkaloid. We established a fission yeast strain that was sensitive to berberine and performed functional screening using a C. japonica cDNA library. One cDNA clone, which conferred clear berberine tolerance, encoded galactinol synthase (CjGolS). The possible role of CjGolS in berberine tolerance is discussed.     

Structure-antibacterial activity relationship for 9-O,9'-O-demethyl (+)-virgatusin

The relationship between the antibacterial activity and structure of 9-O,9'-O-demethyl (+)-virgatusin (Virg 3) was examined. The conversion of hydroxy groups on the 9 and 9' positions to amino groups increased the activity. It was found that the 3'-methoxy group was more important for higher activity than the 4'-methoxy group on the 7'-phenyl group, and that the 3,4-methylenedioxy group on the 7-phenyl group was necessary for activity.     

Cortisol is a suppressor of apoptosis in bovine corpus luteum

Glucocorticoid (GC) acts as a modulator of physiological functions in several organs. In the present study, we examined whether GC suppresses luteolysis in bovine corpus luteum (CL). Cortisol (an active GC) reduced the mRNA expression of caspase 8 (CASP8) and caspase 3 (CASP3) and reduced the enzymatic activity of CASP3 and cell death induced by tumor necrosis factor (TNF) and interferon gamma (IFNG) in cultured bovine luteal cells. mRNAs and proteins of GC receptor (NR3C1), 11beta-hydroxysteroid dehydrogenase type 1 (HSD11B1), and HSD11B2 were expressed in CL throughout the estrous cycle. Moreover, the protein expression and the enzymatic activity of HSD11B1 were high at the early and the midluteal stages compared to the regressed luteal stage. These results suggest that cortisol suppresses TNF-IFNG-induced apoptosis in vitro by reducing apoptosis signals via CASP8 and CASP3 in bovine CL and that the local increase in cortisol production resulting from increased HSD11B1 at the early and midluteal stages helps to maintain CL function by suppressing apoptosis of luteal cells.     

Hemitriakis complicofasciata, a new whitefin topeshark (Carcharhiniformes: Triakidae) from Japan

Hemitriakis complicofasciata sp. nov. is described from 18 specimens from the waters of the Ryukyu Islands, southern Japan. This new species is distinguishable from other congeners by the following characters: higher vertebral counts (46–52 monospondylous vertebrae and 124–131 precaudal total vertebrae), presence of a developed posterior nasal flap, first dorsal fin origin anterior to free rear tips of pectoral fin, shorter snout length (snout tip to oral length less than 1.8 times internarial width), absence of an accessory cartilage at symphysial part of upper jaw, and dark complicated lines and rings on embryos and juveniles.     

Charge-pairing mechanism of phosphorylation effect upon amyloid fibrillation of human tau core peptide

Phosphorylation of a fibrillogenic protein, human tau, is believed to play crucial roles in the pathogenesis of Alzheimer's disease. For elucidating molecular mechanisms of the phosphorylation effect on tau fibrillation, we synthesized a peptide, VQIVY 310K (PHF6) and its phosphorylated derivative (PHF6pY). PHF6 is a partial peptide surrounding a plausible in vivo phosphorylation site Tyr310 and forms amyloid-type fibrils similar to those generated by full-length tau. Fibrillation of PHF6 and PHF6pY were studied by spectroscopic and microscopic methods, and the critical concentration of the fibrillation was determined for comparing the fibril stability. The results showed that the phosphorylation strongly influenced the fibrillation propensity of PHF6 by changing its dependency on pH and ionic strength. On the basis of the observations, we suggested that charged sites on the phosphate group and its electrostatic pairing with the neighboring charged residues were physical origins of the phosphorylation effect. To verify this charge-pairing mechanism, we conducted experiments using a series of PHF6 derivatives with non-native charge distributions. The electrostatic interaction in an intermolecular mode was also demonstrated by the system composed of two different peptide species, which found that fibrillation of nonphosphorylated PHF6 was drastically enhanced when a trace amount of phosphorylated PHF6 molecules coexisted. A simulation analysis utilizing crystal coordinates of the PHF6 fibril was also performed for interpreting the experimental results in a molecular level. The present study using the model peptide system gave us a microscopically insightful view on the roles of tau phosphorylation in amyloid-related diseases.     

Modulation of redox potential and alteration in reactivity via the peroxide shunt pathway by mutation of cytochrome P450 around the proximal heme ligand

In the thermophilic cytochrome P450 from the thermoacidophilic crenarchaeon Sulfolobus tokodaii strain 7 (P450st), a phenylalanine residue at position 310 and an alanine residue at position 320 are located close to the heme thiolate ligand, Cys317. Single site-directed mutants F310A and A320Q and double mutant F310A/A320Q have been constructed. All mutant enzymes as well as wild-type (WT) P450st were expressed at high levels. The substitution of F310 with Ala and of A320 with Gln induced shifts in redox potential and blue shifts in Soret absorption of ferrous-CO forms, while spectral characterization showed that in the resting state, the mutants almost retained the structural integrity of the active site. The redox potential of the heme varied as follows: -481 mV (WT), -477 mV (A320Q), -453 mV (F310A), and -450 mV (F310A/A320Q). The trend in the Soret band of the ferrous-CO form was as follows: 450 nm (WT) < 449 nm (A320Q) < 446 nm (F310A) < 444 nm (F310A/A320Q). These results established that the reduction potential and electron density on the heme iron are modulated by the Phe310 and Ala320 residues in P450st. The electron density on the heme decreases in the following order: WT > A320Q > F310A > F310A/A320Q. The electron density on the heme iron infers an essential role in P450 activity. The decrease in electron density interferes with the formation of a high-valent oxo-ferryl species called Compound I. However, steady-state turnover rates of styrene epoxidation with H2O2 show the following trend: WT approximately equal to A320Q < F310A approximately equal to F310A/A320Q. The shunt pathway which can provide the two electrons and oxygen required for a P450 reaction instead of NAD(P)H and dioxygen can rule out the first and second heme reduction in the catalytic process. Because the electron density on the heme iron might be deeply involved in the k cat values in this system, the intermediate Compound 0 which is the precursor species of Compound I mainly appears to participate dominantly in epoxidation with H2O2.     

Paraoxonase gene Gln192Arg (Q192R) polymorphism is associated with coronary artery spasm

We recently reported that oxidative stress is involved in the pathogenesis of coronary spasm. We hypothesized that oxidative-stress-related genetic factors and certain polymorphisms in the paraoxonase gene (PON1) and platelet-activating factor acetylhydrolase (PAF-AH) might influence the pathogenesis of coronary spasm. We therefore examined the possible association between the PON1 Q192R or PAF-AH V279F polymorphisms and coronary spasm in 214 patients with coronary spasm and 212 control subjects. Genotypes were determined by polymerase chain reaction/restriction fragment length polymorphism analysis. The incidence of the PON1-192R allele was significantly higher in the coronary spasm group than in the control group (65% vs 53%; P=0.0005). The PAF-AH-279F allele was not associated with coronary spasm (15% vs. 16%; P=0.8781). Multiple logistic regression analysis with forward stepwise selection involving the PON1-192R allele and the environmental risk factors revealed that the most predictive independent risk factor for coronary spasm was the PON1-192R allele (significance=0.0016, OR=2.52), followed by cigarette smoking (significance=0.0007, OR=2.01). We also measured plasma levels of TBARS (thiobarbituric acid-reactive substances) as a marker of oxidative stress. TBARS levels were higher in R/R types than in Q/Q types (2.115+/-0.086 nmol/ml [ n=25] vs 1.676+/-0.102 nmol/ml [ n=11], P<0.01). Thus, there is a significant association between the PON1-192R allele and coronary spasm; the PON1-192R allele may play an important role in the genesis of coronary spasm, probably by attenuating the suppression of oxidative stress.