A Simple Colorimetrie Assay for Aspartate Aminotransferase

γ-Glutamylmethylamide (γ-GMA) synthetase was detected in crude extracts of Methylophaga sp. AA-30, but neither methylamine dehydrogenase nor N-methylglutamate dehydrogenase was observed. A large amount of γ-GMA was accumulated in the cells when the growth on methanol-methylamine was inhibited with iodoacetate, but the accumulation was not observed in the cells grown on methanol-(NH₄)₂SO₄. It is thought that γ-GMA is a metabolic intermediate of the methylamine-dissimilating pathway in the bacterium. In addition, γ-GMA-dissimilating enzymes were found in methylamine-grown cells. The enzymes, which consisted of H protein and L protein, required α-ketoglutaric acid, Mg²⁺ or Mn²⁺, and ammonia as a cofactor. Although the enzyme catalyzed the formation of glutamate from γ-GMA, it did not catalyze the formation of N-methylglutamate. Consequently, in this bacterium, methylamine seems to be metabolized through a different pathway from the N-methylglutamate pathway.     

Extra tyrosine in the carbohydrate-binding module of Irpex lacteus Xyn10B enhances its cellulose-binding ability

The xylanase (Xyn10B) that strongly adsorbs on microcrystalline cellulose was isolated from Driselase. The Xyn10B contains a Carbohydrate-binding module family 1 (CBM1) (IrpCBM_Xyn10B) at N-terminus. The canonical essential aromatic residues required for cellulose binding were conserved in IrpCBM_Xyn10B; however, its adsorption ability was markedly higher than that typically observed for the CBM1 of an endoglucanase from Trametes hirsuta (ThCBM_EG1). An analysis of the CBM-GFP fusion proteins revealed that the binding capacity to cellulose (7.8 μmol/g) and distribution coefficient (2.0 L/μmol) of IrpCBM_Xyn10B-GFP were twofold higher than those of ThCBM_EG1-GFP (3.4 μmol/g and 1.2 L/μmol, respectively), used as a reference structure. Besides the canonical aromatic residues (W24-Y50-Y51) of typical CBM1-containing proteins, IrpCBM_Xyn10B had an additional aromatic residue (Y52). The mutation of Y52 to Ser (IrpCBM_Y52S-GFP) reduced these adsorption parameters to 4.4 μmol/g and 1.5 L/μmol, which were similar to those of ThCBM_EG1-GFP. These results indicate that Y52 plays a crucial role in strong cellulose binding.     

Are there two forms of beta 2-N-acetylglucosaminyltransferase I in rat testicular and epididymal fluids?

The activity of alpha 3-D-mannoside-beta-1,2-N-acetylglucosaminyltransferase I (GnT I; EC 2.4.1.101), which catalyzes the first step in the conversion of oligomannose to complex or hybrid N-glycans of glycoproteins, was detected in rat testicular and cauda epididymal fluids. The GnT I activity of testicular fluid had a pH optimum of 6.0, whereas that of the cauda epididymal fluid was optimal at pH 7.0. The enzyme in testicular fluid had an absolute requirement for either Co2+, or Mn2+, Mg2+ and Ca2+, the activity being stimulated by these cations in the above order, whereas that of cauda epididymal fluid had an absolute requirement for Mn2+ or Ca2+, with Co2+ and Mg2+ being ineffective. The specific activity of GnT I in cauda epididymal fluid was somewhat higher than in testicular fluid. The apparent Km value for alpha 1-3 alpha 1-6mannopentaose of GnT I in the testicular and epididymal fluids was 0.57 and 0.38 mM, respectively. The substrate specificity for both GnT I activities decreased in the following order: alpha1-3 alpha 1-6mannopentaose>alpha1-3 alpha 1-6mannotriose>alpha 1-3mannobiose>alpha 1-6mannobiose. These data suggest that two forms of GnT I exist in the testicular and epididymal fluids.     

Structure and physicochemical properties of starches from kidney bean seeds at immature,premature and mature stages of development

Starches from kidney bean (Phaseolus vulgaris L. cv. Toramame) seeds at the immature, premature, mature stages of development were examined. The starch content increased from 94, 219 to 265 mg per seed. Starches showed the C(a)-crystalline type composed of small (<5 micrometer) and large (10-35 micrometer) granules, with the large granules largely increasing with maturity. The amylose content increased from 21, 26 to 27%, and rapid viscograms and DSC thermograms suggested that the mature-stage starch was gelatinized with ease. The amylose increased in size from DPn 820, 1000 to 1080 and a number of chains per molecule (NC) from 3.3, 4.2 to 4.5. The branched amylose was a minor component (11-18% by mole) with NC 20-22. The amylopectin was similar in CL (23), beta-amylolysis limit (59%), and chain-length distribution, but reduced in size (DPn 17,100-5270) and increased in content of phosphorus (114-174 ppm) with an increase in the amount of phosphorus linked to C-6 of the glucose residue (8-66%).     

Genotype/age interactions on aggressive behavior in gonadally intact estrogen receptor beta knockout (betaERKO) male mice

Estrogen, as an aromatized metabolite of testosterone, has a facilitatory effect on male aggressive behavior in mice. Two subtypes of estrogen receptors, alpha (ER-alpha) and beta (ER-beta), in the brain are known to bind estrogen. Previous studies revealed that the lack of ER-alpha gene severely reduced the induction of male aggressive behavior. In contrast, mice that lacked the ER-beta gene tended to be more aggressive than wild type (WT) control mice, although the behavioral effects of ER-beta gene disruption were dependent on their social experience. These findings lead us to hypothesize that estrogen may facilitate aggression via ER-alpha whereas it may inhibit aggression via ER-beta. In the present study, we further investigated the role of ER-beta in the regulation of aggressive behavior by examining developmental changes starting at the time of first onset, around the age of puberty. Aggressive behaviors of ER-beta gene knockout (betaERKO) mice were examined in three different age groups, puberty, young-adult, and adult. Each mouse was tested every other day for three times in a resident-intruder paradigm against olfactory bulbectomized intruder mice and their trunk blood was collected for measurements of serum testosterone after the completion of the study. Overall, betaERKO mice were significantly more aggressive than WT. These genotype differences were more pronounced in puberty and young adult age groups, but not apparent in the adult age group, in which betaERKO mice were less aggressive than those in two younger age groups. Serum testosterone levels of betaERKO mice were significantly higher than those of WT mice only in the pubertal age group, but not in young adult (when betaERKO mice were still significantly more aggressive than WT mice) and adult (when no genotype differences in aggression were found) age groups. These results suggest that ER-beta mediated actions of gonadal steroids may more profoundly be involved in the inhibitory regulation of aggressive behavior in pubertal and young adult mice.     

Production of transgenic chimera rabbit fetuses using somatic cell nuclear transfer

We produced aggregate chimeric embryos between blastomeres from the somatic cell nuclear transfer (SCNT) embryos and blastomeres from normal embryos. The SCNT embryos were produced by fusing enucleated oocytes with GFP gene introduced fibroblast cells, which were derived from a day 16 fetus. GFP gene-introduced fibroblast cells were cultured and passaged four to 12 times over a period of 45-79 days before SCNT. After transferring them into pseudopregnant recipient rabbits, the 15-day postcoitus fetuses were collected. We examined the existence of the cells derived from SCNT embryos in the fetus stage of pregnancy to detect the GFP gene. Fetuses that were not collected continued to develop into newborn rabbits. Two hundred and thirty-six chimeric embryos were produced using 39 SCNT morula stage embryos, and these embryos were transferred to 11 recipient rabbits. As a result, 27 normally developed and 16 degenerated concepti were obtained. The GFP gene-positive signals were detected in one of the fetuses, two of the placentae, and two of the degenerated concepti. In this study, we found that the rabbit SCNT embryos have the ability to develop and differentiate in vivo. We also demonstrated a novel method of producing a transgenic rabbit using SCNT.