分离自江西的一个青霉属新种

新种江西青霉Pencilliumjangxiensesp.nov.分离自江西省的江西虫草Cordycepsjiangxiensis,它类似于无色青霉Penicilliumincoloratum和贵州青霉P.guizhouanum,但前者的帚状枝不分枝,显著单轮生,生长很慢,分生孢子结构发育很慢,分生孢子也很小,这些特征易于与近似种相区分。     

斜卧青霉原生质体制备和再生的研究

研究了斜卧青霉原生质体制备和再生的条件,确定了培养方式、菌龄、渗透压稳定剂、酶的配比、酶解时间等因素对原生质体制备和再生的影响。最佳条件：菌丝体培养12h,用1％溶壁酶＋1％纤维素酶＋1％蜗牛酶的混合酶液酶解,将NaCl作为渗透压稳定剂,酶解时间为1．5h。在此条件下原生质体的形成量达到5．3×10^5个／mL,再生率为19．4％。     

Enzymological properties of endo-(1–4)-β-glucanase Eg12p of <Emphasis Type="Italic">Penicillium canescens</Emphasis> and characteristics of structural gene <Emphasis Type="Italic">egl2</Emphasis>

Gene egl2 of secreted endo-(1–4)-β-glucanase of glycosyl hydrolase family 5 of the mycelial fungus Penicillium canescens was cloned. The gene was expressed in P. canescens under control of a strong promoter of the bgaS gene encoding β-galactosidase of P. canescens, and endoglucanase producing strains were obtained. Chromatographically purified recombinant 48 kDa protein had pH and temperature optima 3.4 and 60°C, respectively, exhibited specific activity of 33 IU, and had K _m and V _max in CM-cellulose hydrolysis of 10.28 g/liter and 0.26 μmol/sec per mg, respectively.     

Structure-Function Relationships in Fungal Large-Subunit Catalases

Neurospora crassa has two large-subunit catalases, CAT-1 and CAT-3. CAT-1 is associated with non-growing cells and accumulates particularly in asexual spores; CAT-3 is associated with growing cells and is induced under different stress conditions. It is our interest to elucidate the structure-function relationships in large-subunit catalases. Here we have determined the CAT-3 crystal structure and compared it with the previously determined CAT-1 structure. Similar to CAT-1, CAT-3 hydrogen peroxide (H₂O₂) saturation kinetics exhibited two components, consistent with the existence of two active sites: one saturated in the millimolar range and the other in the molar range. In the CAT-1 structure, we found three interesting features related to its unusual kinetics: (a) a constriction in the channel that conveys H₂O₂ to the active site; (b) a covalent bond between the tyrosine, which forms the fifth coordination bound to the iron of the heme, and a vicinal cysteine; (c) oxidation of the pyrrole ring III to form a cis-hydroxyl group in C5 and a cis-γ-spirolactone in C6. The site of heme oxidation marks the starts of the central channel that communicates to the central cavity and the shortest way products can exit the active site. CAT-3 has a similar constriction in its major channel, which could function as a gating system regulated by the H₂O₂ concentration before the gate. CAT-3 functional tyrosine is not covalently bonded, but has instead the electron relay mechanism described for the human catalase to divert electrons from it. Pyrrole ring III in CAT-3 is not oxidized as it is in other large-subunit catalases whose structure has been determined. Different in CAT-3 from these enzymes is an occupied central cavity. Results presented here indicate that CAT-3 and CAT-1 enzymes represent a functional group of catalases with distinctive structural characteristics that determine similar kinetics.     

响应面设计法优化单葡萄糖醛酸基甘草次酸（GAMG）发酵转化培养基

以甘草酸（dycyfrhizin,GL）为底物,利用产紫青霉（Penicillium purpurogenum Li-3）液态发酵转化单葡萄糖醛酸甘草次酸（GAMG）,采用响应面设计法对初始发酵培养基进行优化。用部分因子分析法研究原始发酵培养基各成分对响应值的显著程度,发现甘草酸（GL）、NaNO3和K2HPO4的质量浓度对发酵产生GAMG的影响显著（P〈0．01）。用中心组合设计确立甘草酸、NaNO3和K2HPO4的适宜质量浓度分别为2．8、3．0和0．8g／L。在优化条件下进行发酵时,GAMG的转化率从75．49％提高到89．11％,比优化前提高了13．62％。     

Biotransformation of prednisolone to hydroxy derivatives by Penicillium aurantiacum

Prednisolone, a synthetic adrenal corticosteroid drug, is known to have anti-inflammatory and autoimmune activity. Biotransformation of prednisolone was carried out to obtain more bioactive prednisolone derivatives. Among six different fungi, Penicillium aurantiacum proved to be the best prednisolone hydroxylator. As a result of prednisolone biotransformation by P. aurantiacum, whole cells four different prednisolone derivatives were investigated. 20β-Hydroxyprednisolone (1) and 21,21-dimethoxy-11β-hydroxypregn-1,4-dien-3,20-dione (2) were detected as the main metabolites. These metabolites together with other two metabolites, 11β-hydroxyandrost-1,4-dien-3,17-dione (3) and 11β,17β-dihydroxyandrost-1,4-dien-3- one (4), were purified and assigned by an interpretation of their spectral data using mass spectroscopy (MS), proton nuclear magnetic resonance (¹H-NMR), carbon nuclear magnetic resonance (¹³C-NMR) and infrared spectroscopy (IR) analyses. The best fermentation conditions for production of compounds 1–4 were as follows: medium (3) consisting of (g/l): glucose 20; l-asparagine 0.7; MgSO₄.7H₂O 0.5; KH₂PO₄ 1.52; KCl 0.52; Cu (NO₃)₂ traces; ZnSO₄.7H₂O traces, supplemented with prednisolone concentration of 0.3?mg/ml, inoculated by 10% of microorganism and incubated for 72?h. Under these optimized conditions, ～94.8% of the added prednisolone was converted to aforementioned derivatives, which have the potential to be used in industrial production of important pharmaceutical compounds.     

Recombinant glucose oxidase from Penicillium amagasakiense for efficient bioelectrochemical applications in physiological conditions

GOX is the most widely used enzyme for the development of electrochemical glucose biosensors and biofuel cell in physiological conditions. The present work describes the production of a recombinant glucose oxidase from Penicillium amagasakiense (yGOXpenag) displaying a more efficient glucose catalysis (k_cat/K_M(glucose) = 93 μM⁻¹ s⁻¹) than the native GOX from Aspergillus niger (nGOXaspng), which is the most industrially used (k_cat/K_M(glucose) = 27 μM⁻¹ s⁻¹). Expression in Pichia pastoris allowed easy production and purification of the recombinant active enzyme, without overglycosylation. Its biotechnological interest was further evaluated by measuring kinetics of ferrocinium-methanol (FM_ox) reduction, which is commonly used for electron transfer to the electrode surface. Despite their homologies in sequence and structure, pH-dependant FM_ox reduction was different between the two enzymes. At physiological pH and temperature, we observed that electron transfer to the redox mediator is also more efficient for yGOXpenag than for nGOXaspng(k_cat/K_M(FM_ox) = 27 μM⁻¹ s⁻¹ and 17 μM⁻¹ s⁻¹ respectively). In our model system, the catalytic current observed in the presence of blood glucose concentration (5 mM) was two times higher with yGOXpenag than with nGOXaspng. All our results indicated that yGOXpenag is a better candidate for industrial development of efficient bioelectrochemical devices used in physiological conditions.