大气压辉光放电低温等离子体诱变选育谷氨酰胺转胺酶高产菌株

以茂源链轮丝菌(Streptoverticillium mobaraense)03-10为出发菌株,采用一种新型的裸露电极大气压辉光放电的冷等离子体技术对链霉菌孢子进行诱变。根据双层平板法菌落显色及诱变处理后菌落形态差异快速筛选谷氨酰胺转胺酶高产突变株。突变率、正突变率分别达到42.8%和20.6%。最后复筛选育出具有较好遗传稳定性和形态稳定性的高产突变株G2-1,酶活达到2.73U/mL,比出发菌株提高了82%。     

基因组重排筛选高产谷氨酰胺转胺酶菌株

谷氨酰胺转胺酶(TGase)的产量不足的问题一直限制其工业化生产规模,故采用基因组重排的方法,筛选高产谷氨酰胺转胺酶菌株。通过对不同制备条件下原生质体纯度和形成率的考量,获得制备原生质体的最优条件为以6mg/ml的溶菌酶浓度进行酶解,酶解时间2h。再优化融合条件,以2min紫外灭活和40min热灭活结合的方法挑选出融合子。通过两轮基因组重排,经过96孔板发酵高通量筛选和摇瓶发酵复筛验证,获得了一株产酶达7.12U/ml的茂源链霉菌,相比最初选用菌株的平均酶活提高65.5%。发酵结果显示,酶活提高的原因可能是在重组后原酶成熟更快、更彻底,且得到的菌株遗传稳定性良好。证明基因组重排能够有效提高菌株的产酶水平,同时为谷氨酰胺转胺酶产量提高提供理论依据。     

基因组重排筛选高产谷氨酰胺转胺酶菌株

谷氨酰胺转胺酶(TGase)的产量不足的问题一直限制其工业化生产规模,故采用基因组重排的方法,筛选高产谷氨酰胺转胺酶菌株。通过对不同制备条件下原生质体纯度和形成率的考量,获得制备原生质体的最优条件为以6mg/ml的溶菌酶浓度进行酶解,酶解时间2h。再优化融合条件,以2min紫外灭活和40min热灭活结合的方法挑选出融合子。通过两轮基因组重排,经过96孔板发酵高通量筛选和摇瓶发酵复筛验证,获得了一株产酶达7.12U/ml的茂源链霉菌,相比最初选用菌株的平均酶活提高65.5%。发酵结果显示,酶活提高的原因可能是在重组后原酶成熟更快、更彻底,且得到的菌株遗传稳定性良好。证明基因组重排能够有效提高菌株的产酶水平,同时为谷氨酰胺转胺酶产量提高提供理论依据。     

产耐高温谷氨酰胺转胺酶菌株的快速筛选方法

目的:采用亚硝基胍(NTG)诱变结合96孔板高通量筛选方法筛选产耐高温谷氨酰胺转胺酶(MTG)的茂原链霉菌(Streptomyces mobaraensis)。方法:通过优化96孔板高通量测定MTG活性的方法、确定筛选温度和时间,建立了产耐高温MTG菌株的快速筛选方法;通过优化NTG诱变条件建立了筛选突变库;通过96孔板高通量初筛、摇瓶复筛获得了产耐高温MTG的突变株12-82,并通过摇瓶发酵对12-82所产MTG进行热稳定性分析。结果:采用2mg/ml NTG、p H8.0、60min的诱变条件获得突变株,将突变株的发酵上清液于70℃水浴7.5min,再在37℃空气浴、反应10min的条件下测定MTG活性,从5 200株突变株中筛选出5株产耐高温MTG的突变株,其中突变株12-82在50℃水浴60min以及70℃水浴1.5min的酶活残留率均比出发株高出近20%,且80℃保温2min仍有11.9%的酶活残留率。结论:利用NTG诱变结合96孔板高通量筛选的方法筛选到5株所产MTG热稳定性相对较高的突变株,其中突变株12-82在50℃、70℃和80℃的酶活残留率均有10%~20%的提高。这为高温食品加工领域所需耐高温MTG生产菌株的高效筛选提供了可行性方案。     

甲壳素促进茂源链霉菌发酵产酶

为了提高茂源链霉菌发酵生产谷氨酰胺转胺酶的产量,研究了甲壳素对茂源链霉菌发酵产酶的影响。结果表明,添加0.5%的甲壳素对茂源链霉菌发酵产酶的促进效果极显著,但甲壳素的添加量达到2%时反而会抑制菌株产酶。从菌株生长代谢过程中p H变化、产酶情况、发酵液中蛋白含量及总氮含量等方面,对甲壳素促进茂源链霉菌发酵产酶的作用机理进行了初步探讨。研究显示,甲壳素在茂源链霉菌发酵过程中对菌体生长产生一定的胁迫,刺激菌体大量分泌次级代谢产物,从而提高茂源链霉菌的产酶。对菌株发酵过程的显微观察则表明,甲壳素也可能通过分散菌体生长,提高菌体向胞外分泌谷氨酰胺转胺酶的量来促进产酶。     

添加CTAB促进吸水链霉菌产谷氨酰胺转胺酶

研究了添加十六烷基三甲基溴化铵（CTAB）对吸水链霉菌（Streptomyces hygroscopicus）合成谷氨酰胺转胺酶的影响。结果表明,添加CTAB可以提高发酵过程中谷氨酰胺转胺酶的酶活,摇瓶培养中,CTAB的最佳添加时间和添加量分别为32h和1%,发酵终了时,谷氨酰胺转胺酶酶活最高达5.04u/mL,比对照提高了21.8%。初步研究表明,CTAB的主要作用是促使谷氨酰胺转胺酶的酶原转化为成熟酶,因此,在发酵过程中添加适当浓度的CTAB,可使酶原快速、完全地转化为成熟的MTG,解除酶原的产物抑制作用,促进了细胞产酶。     

添加胰蛋白酶促进Streptomyces hygroscopicus CCTCC M203062产谷氨酰胺转胺酶

研究了添加胰蛋白酶对Streptomyces hygroscopicus CCTCC M203062合成谷氨酰胺转胺酶的影响。结果表明,添加胰蛋白酶可以提高发酵过程中谷氨酰胺转胺酶的酶活。摇瓶培养中,在发酵起始时添加200U/ml的胰蛋白酶,谷氨酰胺转胺酶的酶活最高达到了6.61U/ml,比对照提高了27.1%。初步研究表明,添加胰蛋白酶可以直接切割发酵过程中产生的酶原,使其被快速地转化为成熟酶,因此推测胰蛋白酶提高谷氨酰胺转胺酶酶活的原因是解除了酶原的产物抑制作用,产生更多的酶原,从而促进了产酶。     

菊粉酶产生菌的筛选及60Co诱变选育简

目的：从新疆石河子盐碱地菊芋生长根际土壤中分离筛选高产菊粉酶活力菌株。方法：通过稀释平板涂布法分离微生物;利用^60Co诱变选育,96孔板筛选突变菌株;采用3,5-二硝基水杨酸比色法测定菊粉酶酶活。结果：分离到12株具有菊粉酶活力的菌株,复筛得到1株高产菊粉酶活力菌株,将其命名为G-60;以此菌株为出发菌株进行^60Co诱变,利用96孔板对诱变菌株进行筛选,经摇瓶发酵酶活测定,得到1株高产菊粉酶酶活的突变株,酶活达46．62U/mL,是未诱变菌株酶活的2．72倍。结论：经诱变得到1株高产菊粉酶活力的突变菌株。     

菊粉酶产生菌的筛选及~(60)Co诱变选育

目的:从新疆石河子盐碱地菊芋生长根际土壤中分离筛选高产菊粉酶活力菌株。方法:通过稀释平板涂布法分离微生物;利用60Co诱变选育,96孔板筛选突变菌株;采用3,5-二硝基水杨酸比色法测定菊粉酶酶活。结果:分离到12株具有菊粉酶活力的菌株,复筛得到1株高产菊粉酶活力菌株,将其命名为G-60;以此菌株为出发菌株进行60Co诱变,利用96孔板对诱变菌株进行筛选,经摇瓶发酵酶活测定,得到1株高产菊粉酶酶活的突变株,酶活达46.62 U/mL,是未诱变菌株酶活的2.72倍。结论:经诱变得到1株高产菊粉酶活力的突变菌株。     

添加CTAB促进吸水链霉菌产谷氨酰胺转胺酶

研究了添加十六烷基三甲基溴化铵(CTAB)对吸水链霉菌(Streptomyces hygroscopicus)合成谷氨酰胺转胺酶的影响。结果表明,添加CTAB可以提高发酵过程中谷氨酰胺转胺酶的酶活,摇瓶培养中,CTAB的最佳添加时间和添加量分别为32h和1%,发酵终了时,谷氨酰胺转胺酶酶活最高达5.04u/mL,比对照提高了21.8%。初步研究表明,CTAB的主要作用是促使谷氨酰胺转胺酶的酶原转化为成熟酶,因此,在发酵过程中添加适当浓度的CTAB,可使酶原快速、完全地转化为成熟的MTG,解除酶原的产物抑制作用,促进了细胞产酶。     

吸水链霉菌发酵生产谷氨酰胺转胺酶的补料研究

在吸水链霉菌(Streptomyces hygroscopicus)分批发酵研究的基础上,通过在菌体生长阶段指数流加葡萄糖,进行高细胞密度培养,获得了较高的菌体量;待菌体生长进入产酶期后,通过补加氮源,为产酶提供充足的氮源,其中通过流加蛋白质氮源,可以减少蛋白酶对成熟MTG的分解,促进产酶。结果表明,8~16 h采用较高的的比生长速率(0.15 h-1),后期降低比生长速率(0.10 h-1),此时得到的菌体量较高,可达到36 g/L,比分批发酵下的菌体量提高了80%。同时在培养基中添加50g/L的豆饼粉,最终酶活可达到5.79U/ml,提高了83%。     

微生物转谷氨酰胺酶的生产菌种诱变和发酵生产分析

对本研究室从土壤分离得到的使霉菌(Streptomyces sp.)WZFF．W-12菌株的斜面孢子预培养处于初萌发状态后,以亚硝基胍(NTG)进行诱变育种试验,并根据诱变处理后菌落的某些形态变化状况与产酶能力相结合的特征,初步判断产酶性能,挑选高酶活菌株,再经过初筛和复筛,获得一性能良好的产酶突变菌株WZFF.W-12.var MN-35,转谷氨酰酶活达0．53U／mL,比原始菌株提高了1．2倍。然后在摇瓶条件下,对其发酵过程中的主要培养基组成及各种培养条件对菌体生长和产酶的影响作用进行了研究,结果表明该菌株发酵生产转谷氨酰酶的适宜破源为可溶性淀粉 葡萄糖,氮源是多价胨外加少量的酵母膏,优化工艺条件为种龄时间24h、接种量10％、初始以值6．5、温度30℃和搅拌速度200r／min,产酶能力显著提高,用小型生化反应器可以稳定生产2.0U／mL以上的酶产品。     

产纤溶酶少根根霉菌株的诱变筛选

目的:通过对自南方小酒药中筛选得到的1株产纤溶酶的少根根霉Or株的诱变筛选,提高原有菌株的产酶能力。方法:以Or为出发菌株,进行亚硝基胍、紫外线、Co60诱变,以血纤维蛋白平板法为检测方法,筛选高产酶突变株。结果:经诱变传代后得到高产突变株8B,其产酶活性稳定为291.05U/mL,为原菌株产酶活力的6.34倍。该菌在血琼脂平板上不产生溶圈,诱变后孢子成熟提前8h。结论:物理诱变和化学诱变交替应用,能显著提高少根根霉Or株单位体积发酵液的产酶量,并能缩短孢子的成熟周期。该菌不具有溶血性,与已有报道的产纤溶酶的菌株不同。     

纤维素分解菌的选育及酶活测定

纤维素是地球上最丰富的有机物质,这些丰富的宝贵资源大部分被浪费了,而且由于部分地区焚烧秸杆造成了严重的环境污染。为了充分利用纤维素,纤维素分解菌的筛选研究逐步展开。通过新华滤纸为唯一碳源的杜氏培养基和刚果红纤维素培养基,从堆肥、污泥、马粪和土壤中分离得到7株纤维素分解菌。以5号菌株为出发菌株,经过紫外线诱变,用刚果红纤维素平板透明圈选育法得到8号菌株。为了评价筛选工作,对8株纤维素分解菌进行酶活测定。结果表明,8号菌株具有最高的CMC酶活和FPA酶活。     

Efficacy assessment of Candida oleophila (strain O) and Pichia anomala (strain K) against major postharvest diseases of citrus fruits in Morocco

Two yeasts, Candida oleophila (strain O) and Pichia anomala (strain K), were previously selected for their antagonistic activity against postharvest diseases on apples and pears. The objective of the study was to determine the efficacy of both antagonistic yeast's against wound postharvest pathogens of citrus fruits. The efficacy of both strains (applied at 10(5), 10(6) and 10(8) CFU/ml) was assessed against Penicillium digitatum and P. italicum inoculated after one hour (at a concentration of 10(5), 10(6) and 10(7) spores/ml) on citrus varieties 'clementine' and 'valencia-late'. Fruits were incubated for one week at 24 degrees C before measurement of lesion diameter. The protective levels were positively correlated with high concentration of antagonist and low concentration of pathogen. Highest protective levels (from 73 to 100%) were detected with the application of strain O or strain K at 10(8) CFU/ml whatever the pathogen (applied at 10(5) spores/ml) and the citrus variety. The antagonistic activity of both strains was also dependent on the incubation period before pathogen Inoculation. The protective level increased with time between application of the antagonist and inoculation of fungal spores. Whatever the yeast strain (10(8) CFU/ml). the protective level exceed 70% when wounded oranges were inoculated with P. digitatum or P. italicum (both at 10(6) spores/ml) 12 hours after yeast treatment. These protective levels reached 100% when the incubation period separating the antagonist application and the pathogenic inoculation was 24 hours. On the other hand, high protective levels (< 80%) were also observed against the sour rot decay on citrus variety 'clementine' caused by Geotrichum candidum inoculated at concentration of 10(6) spores/ml when strain O or strain K were applied at 10(8) CFU/ml 24 hours before pathogen. All these results support the potential practical application of both strains against major postharvest pathogens on citrus.     

Preliminary report on the biological effects of space flight on the producing strain of a new immunosuppressant, Kanglemycin C

Kanglemycin C (K-C) is a new immunosuppressant isolated from the culture broth of Nocardia mediterranei var. kanglensis 1747-64. To improve the productivity of K-C and to study the biological effects of space flight on its producing strain, spores from five K-C producing strains (U-10, U-15, U-7, M-13, γ-33) mutated from the wild strain N. mediterranei var. kanglensis 1747-64 were carried into space by an unmanned spaceship, “Shenzhou III” (Divine Vessel III) on March 25, 2002. Comparatively, the strain U-7 was the highest K-C producing strain among the above five starting strains when cultivated in 500-ml Erlenmeyer flasks. After a 6 day and 18 h flight, the treated spores went through serial screening processes to screen for high-yield K-C mutant strains, using thin layer chromatography and high performance liquid chromatography (HPLC). The K-C yield produced by one mutant strain, designated as F-16, derived from the starting strain U-7 was increased by up to 200% when compared to that produced by the starting strain U-7 in 500-ml Erlenmeyer flasks after careful postflight HPLC analysis. Another mutant strain, designated as F-210, derived from the starting strain M-13 showed reduced productivity of K-C as well as exhibited changes in some morphological and physiological characteristics. For example, the broth color of the strain F-210 changed from yellow to purple after 96 h of culture, but that of the ground control strain M-13 remained yellow. Similarly, the mycelium morphological change from filamentous to coccoid of F-210 occurred later than that of ground control M-13. Examination of the survivability of postflight spores indicated that exposure to radiation, during the 162 h of space flight, plays a critical role in the survival rates of spores such that spores exposed to strong radiation exhibited lower survival rates than spores exposed to weak radiation.Jianqin Zhou and Chenghang Sun have contributed equally to this work.     

豆豉纤溶酶产生菌的筛选及诱变

从广泛收集的豆豉成品及半成品中筛选到数株菌落形态各异且具有纤溶酶活性的菌株.分别采用亚硝酸和紫外线对豆豉纤溶酶产生菌DC-12进行诱变育种,成功筛选到了3株突变株,其纤溶酶产量较出发菌株分别提高了3.6、3.7和4.75倍.     

嗜碱芽孢杆菌NTT33产碱性β-甘露聚糖酶发酵条件的研究及高产菌株选育

研究了嗜碱芽孢杆菌（ａｌｋａｌｏｐｈｉｌｉｃＢａｃｌｕｓｓｐ．）ＮＴＴ３３发酵产生胞外碱性β－甘露聚糖酶的条件,其最佳碳源为１％槐豆角,最佳氮源为１％蛋白胨＋０．２％酵母膏,发酵培养３６ｈ产酶量最高（达６１．３υ／ｍＬ）。甘油,葡萄糖,甘露糖等对产酶有强的阻遏作用。该菌株经紫外诱变处理后,采用透明圈法初步筛选出在含葡萄糖和不含葡萄糖的槐豆胶培养基上同时产生透明圈的菌株,进一步测定其产酶进程曲线,最后筛选到一株（ＮＴＴ３３－ｒ６）部分消除葡萄糖代谢阻遏高产β－甘露聚糖酶的菌株,其酶活力比出发菌株提高５０％,,达到９６．３Ｕ／ｍｌ;。     

ENHANCED β-GALACTOSIDASE PRODUCTION OF Aspergillus oryzae MUTATED BY UV AND LiCl

In order to breed a high-yield β-galactosidase-producing strain, Aspergillus oryzae was used as the parent strain and mutagenized with ultraviolet (UV) and UV plus lithium chloride (LiCl), respectively. After being mutagenized by UV, the β-galactosidase activity of mutant UV-15-20 reached 114.08 U/mL, which revealed a 49.22% increase compared with the original strain. A mutant UV-LiCl-38 with high β-galactosidase activity (121.42U/mL) was obtained after compound mutagenesis of UV and LiCl; the β-galactosidase activity of this mutant was 58.82% higher than that of the parent strain. Subculture testing indicated that UV-15-20 and UV-LiCl-38 had good hereditary stability and may be ideal strains for the production of β-galactosidase. Additionally, it was demonstrated that compound mutagenesis with UV and LiCl is an effective mutation method for breeding industrially interesting strains.