嗜麦芽寡养单胞菌D2株smp基因缺失株的构建及鉴定

为深入研究smp基因的功能,需构建嗜麦芽寡养单胞菌D2株smp基因缺失株。首先,PCR扩增D2株smp基因上游、下游片段作为上下游同源臂,同时扩增获得氯霉素抗性(cat)基因,采用SOE-PCR方法将各片段连接,然后双酶切后克隆入自杀质粒pEX18Tc,构建获得重组自杀质粒pEX18Tc-Δsmp/cat,并转化入大肠埃希菌SM10λpir。通过接合将重组自杀质粒转入嗜麦芽寡养单胞菌D2野生株,经同源重组以cat基因替换野生株的smp基因,链霉素和氯霉素双抗培养基筛选接合子,15%蔗糖选择培养基筛选smp基因缺失株。PCR、酶切和测序验证重组自杀质粒pEX18Tc-Δsmp/cat构建正确,缺失株的分泌蛋白经12%SDS-PAGE证实嗜麦芽寡养单胞菌D2株smp基因缺失株失去表达SMP蛋白的能力。结果显示成功获得smp基因缺失的嗜麦芽寡养单胞菌D2株,为进一步研究其功能和胞外分泌途径奠定基础。     

68株北极产蛋白酶菌株的筛选、鉴定以及部分酶学性质

【目的】从北极海水样品中分离产蛋白酶细菌,并对其进行初步的分类鉴定,为低温蛋白酶的低温适应性及其应用研究奠定基础。【方法】通过酪蛋白筛选培养基低温培养的方法从北极水样中分离出68株产蛋白酶细菌,采用16S rRNA基因PCR-RFLP(限制性酶切多态性)方法及传统的表型特性分析对所分离纯化的菌株进行分类,每种细菌类型各取1株代表菌株进行16S rRNA基因序列测定、GenBank数据库blast分析以及通过DNAMAN软件进行系统进化树分析。对代表菌株的蛋白酶酶学性质进行初步研究。【结果】68个菌株可归为3种类型(54.41%、42.65%和2.94%),分别以菌株6、11和52为代表菌株。16S rRNA基因序列分析结果表明,菌株11与比目鱼黄杆菌(Chryseobacterium scophthalmum)具有98.24%的同源性;菌株52与嗜根寡养单胞菌(Stenotrophomonas rhizophila)具有98.55%的同源性;菌株6与Stenotrophomonas rhizophila具有96.50%的同源性,可能为该属的新物种。对3种类型代表菌株进行表型性状研究显示,菌株6、11和52为革兰氏阴性、直杆状、不产胞外脂肪酶和淀粉酶,具有强的蛋白酶活性。菌株6的蛋白酶最适酶活温度为55℃,最适宜pH为6.7;菌株11的蛋白酶最适酶活温度为40℃,属于低温酶,最适酶活pH约为8.5;菌株52的蛋白酶最适酶活温度为65℃,最适酶活pH为7.4。【结论】本文首次报道了Stenotrophomonas和Chryseobacterium的菌株在北极海水样品中的分布,充实了极地产蛋白酶菌的种属分布多样性,为后续低温蛋白酶的研究和应用奠定了基础。     

一株产高温蛋白酶嗜热菌A-2的筛选鉴定及酶学特性分析

本研究为从云南腾冲热泉中分离纯化得到一株产高温蛋白酶的菌株并对其进行驯化培养,用以探究该菌株的生长条件及酶学特性,通过选择培养基筛选能够分解脱脂奶粉产蛋白酶的菌株,应用常规方法液体培养菌体,探究温度、pH、碳源、氮源对菌株生长情况的影响,并采用福林酚法测蛋白酶活性。并提取蛋白酶液对酶的最适pH、温度以及热稳定性、pH稳定性进行研究。结果发现通过含脱脂奶粉的固体培养基筛选得到一株产蛋白酶菌株A-2,经过生理生化试验和16S rDNA鉴定知该菌种属于Aneurinibacillus属。酵母粉、葡萄糖、55℃、pH值7.5分别为菌株生长的最适氮源、碳源、温度和pH。此外该菌株所产的蛋白酶最适温度为60℃,在pH值7~9具有较好的酶活性。因此,该菌株为嗜热芽孢杆菌,所产的碱性蛋白酶具有较高的耐受温度和pH稳定性,为进一步开发利用提供参考的价值。     

嗜麦芽寡养单胞菌角蛋白酶基因在毕赤酵母中的表达

将嗜麦芽寡养单胞菌BBE11-1来源的角蛋白酶基因kerD进行毕赤酵母密码子优化,构建重组载体pPIC9k-ker D;整合该重组载体到毕赤酵母SMD1168基因组,筛选到Mut~+型重组子;对利用G418抗性筛选到的重组子进行甲醇诱导,筛选到产酶效果最好的重组菌株。纯化和SDS-PAGE检测表达的重组酶,研究重组酶的部分酶学性质,结果表明,重组酶的最适反应pH为10,最适反应温度为60℃。为进一步提高目的蛋白的产量,采用甲醇与山梨醇和甘露醇混合流加的策略,优化重组菌产角蛋白酶的发酵过程。结果表明,甲醇与甘露醇以20∶0.5比例混合流加,发酵168 h,角蛋白酶的产量2 048 U/m L,比单流加甲醇提高了87.2%。     

产几丁质酶菌株SWCH-6的筛选、鉴定及其产酶条件的优化研究

从汕头海湾养殖区域的海底沉积物中分离到1株几丁质酶活性较高的菌株, 命名为SWCH-6, 根据菌株的形态特征、生理生化特征和16S rDNA 序列, 确定该菌株为嗜水气单胞菌(Aeromonas hydrophlilla)。采用单因素优化方法结合正交实验, 得到菌株SWCH-6产几丁质酶的最佳发酵条件：胶体几丁质25.0 g/L, 胰蛋白胨10.0 g/L, 陈海水1.0 L, pH 8.5, 32℃, 150 r/min培养72 h; 在该条件下酶活力达0.39 U/mL。此外, 菌株所产几丁质酶的最适催化pH 5.0; 最适催化温度为40℃; Cu2+、Fe3+及表面活性剂Tween-80能增强该酶的催化活性; Zn2+、Mn2+及表面活性剂SDS、洗衣粉对该酶的催化活性有抑制作用, 与其它几丁质酶存在着一些不同。     

红树林微生物DH-2胞外蛋白酶的性质及产酶条件优化

从大亚湾红树林土壤样品中分离得到产蛋白酶菌株,鉴定所产胞外蛋白酶的酶学性质以及菌株的最佳发酵培养条件。采用平板透明圈法筛选菌株,福林酚显色法测定蛋白酶的酶活,通过单因素和正交试验确定其最佳发酵培养基以及发酵条件。从壤样品中分离得到一株产蛋白酶的枯草芽孢杆菌DH-2,该菌株分泌的蛋白酶最适反应pH和温度分别为8.0和65℃,50℃保温处理60 min后,剩余酶活仍保留80%以上。该蛋白酶对多种金属离子、有机溶剂及表面活性剂均有较好的耐受性。确定该菌株产蛋白酶的最适条件:1%(m/V,下同)可溶性淀粉,1%胰蛋白胨、1%NaCl,初始pH 5.5及7%的接种量,40℃培养36 h。在最适条件下测得其发酵液的酶活为236.30 U/mL,约为初筛时的酶活的8倍。该蛋白酶具有较为广阔的作用温度和pH范围,金属离子、有机溶剂及表面活性剂耐受性好,酶的性质比较稳定。     

高温蛋白酶产生菌的筛选及其产酶条件和酶学性质分析

从徂徕山温泉附近土样中分离到9株产高温蛋白酶菌株,选取一株碱性蛋白酶高产菌株L7为出发菌株,进行显微形态、16S rRNA基因序列分析,将其初步鉴定为短芽孢杆菌(Brevibacillus sp.)。研究该菌株发酵条件,确定产酶的最佳培养基组成为葡萄糖40 g/L,蛋白胨20 g/L,磷酸氢二钠1.4 g/L,氯化钙0.6 g/L,硫酸镁0.4 g/L,通过培养基优化,酶活达到103.08 U/mL。最佳培养条件为250 mL三角烧瓶中装液量50 mL、pH8.0、培养温度为55℃、培养时间为24 h。对该菌株酶学性质研究,L7菌株所产高温蛋白酶的最适温度为55℃,最适pH为10,并且具有良好的温度稳定性和pH稳定性,酶活性受PMSF强烈抑制。     

四株冰川雪细菌产酶能力的初步研究

目的:从青藏高原冰川雪中筛选出一菌多酶的菌株.方法:对恢复出的4个细菌,通过平板透明法研究其产淀粉酶、脂肪酶和蛋白酶的特性.结果:LHG-C-9为惟一可以产淀粉酶的菌株,所产脂肪酶活性最高.4个菌株均不产蛋白酶.结论:LHG-C-9最适生长温度为15℃,属于耐冷菌.对该菌所产淀粉酶和脂肪酶的性质进行了初步研究,其随产淀粉酶的最适作用温度为50℃;最佳产酶pH值为7.0,该pH值所产酶活为83.9U/mL;在60℃的高温下温浴10min后酶活为0%.该菌株所产脂肪酶的最适作用温度为20℃;最佳产酶pH值为7.0,该pH值所产酶活为9.2U/mL;50℃温浴1h后酶活力不足34%.     

嗜水气单胞菌J-1株弹性蛋白酶的表达、纯化及特性分析

摘要：【目的】表达、纯化嗜水气单胞菌J-1株弹性蛋白酶,并对弹性蛋白酶的性质进行分析。【方法】以pET-32a为表达载体将弹性蛋白酶基因ahyB转化至大肠杆菌BL21菌株中进行诱导表达,表达重组酶用His TaqNi2+亲和层析柱纯化并用6 mol/L盐酸胍进行复性;利用硫酸铵分级沉淀、阴离子交换层析和分子筛层析对嗜水气单胞菌培养上清液中的弹性蛋白酶进行纯化。将【结果】从嗜水气单胞菌培养上清液中获得的弹性蛋白酶原酶的最适pH 为8.5,而表达重组酶为 10.0;对热的稳定性,原酶高于表达酶。两种形式酶的性     

β-甘露聚糖酶产生菌的分离、鉴定及产β-甘露聚糖酶最适条件的研究

以采集的土壤样品为试验材料,经过富集培养及分离纯化,筛选出2株产β-甘露聚糖酶的菌株.采用摇瓶培养分别测定其酶活力,其中1株菌株酶活力较高,酶活力达50.36 U/ml.生理生化性质鉴定及16S rDNA序列相似性结果表明该菌为假单孢菌(Pseudomonas sp.).产酶的最适条件研究发现,1 g/100 ml玉米粉,2 g/100 ml魔芋粉,pH6.0,32℃为最优产酶条件,酶活力达185.37 U/ml,是优化前的3.68倍.该菌产酶迅速,培养12 h后已达产酶高峰.粗酶的性质研究发现,该酶是一种酸性的甘露聚糖酶,作用的最适pH为4.0,最适反应温度为55℃;该酶的稳定性较好,在pH4.0～6.0、温度为40～55℃保持较好的稳定性.     

一株东祁连山耐低温纤维素降解菌株的分离、鉴定及产酶特性

从东祁连山高寒草甸土壤中分离得到一株纤维素酶高产菌株【3-2。根据菌体形态观察、革兰氏染色反应及16S rDNA序列测定以及序列同源性比较,确定鉴定该菌为芽孢杆菌属的成员(Bacillus sp.)。对该菌的产纤维素酶条件研究结果表明:该菌在5℃~45℃、初始pH 4.0~9.0的环境下均能产纤维素酶。在初始pH为8.0、盐浓度为2.0%~3.0%之间、培养温度为20℃培养条件下最适产酶。在5℃时,相对酶活仍能保持60%。     

家蚕肠道枯草杆菌产蛋白酶的发酵条件与酶学性质

肠道微生物分泌的蛋白酶可促进家蚕对桑叶养分的消化吸收,枯草芽孢杆菌是家蚕肠道内一种重要的产蛋白酶菌株。为提高枯草芽孢杆菌蛋白酶的高效利用,对该菌株适宜发酵条件及酶学性质进行了研究。结果表明：各因素对枯草芽孢杆菌产酶活性影响的大小顺序依次为：pH值〉培养温度〉培养时间〉装液量;最适的产酶条件为：pH=7,培养温度：30 ℃,培养时间：36 h;对枯草芽孢杆菌产蛋白酶进行初步提纯后并研究得出该酶反应的最适pH 10.0,最适反应温度为：60 ℃;该酶为碱性蛋白酶、不耐高温、不耐酸,但在35 ℃条件下热稳定性较好。     

极地适冷菌Pseudoalteromonas sp. QI-1产适冷蛋白酶发酵条件的优化

对极地适冷菌Pseudoalteromonas sp. QI-1产适冷蛋白酶的发酵条件进行优化。结果表明:菌株QI-1的最适生长和产酶温度均为5℃;最佳接种量为1%;发酵培养基的最适初始pH和最佳装样量分别为5和10%;盐度为2%时对菌株的生长和产酶最为有利;麸皮和醋酸钠分别为最佳N源和C源;添加0.75%酪蛋白时菌株QI-1胞外蛋白酶的活性最高;10 mmol/L Mg2+和0.5%Tween-80有利于产酶。正交试验结果表明:菌株Pseudoalteromonassp. QI-1产蛋白酶较佳培养基配方(g/L)为麸皮5,酵母粉2.5,酪蛋白3,MgCl2.6H2O 3,KCl 1.5;发酵液比酶活为166.20 U/mL,较优化前提高了约56%。     

交替假单胞菌LP621菌株产右旋糖苷酶的培养条件优化

从江苏连云港海域分离和筛选到1株产右旋糖苷酶的海洋细菌交替假单胞菌Pseudoalteromonas tetraodonis LP621,通过单因素试验和正交试验对该菌株产右旋糖苷酶培养条件进行优化。单因素试验结果表明,最佳培养时间为24 h,最适产酶温度为25℃;产酶pH范围为5.0~11.0,最适产酶pH为6.0;产酶NaCl浓度范围为1%~10%,NaCl浓度为4%时产酶较高;装液量在25%。麦芽糖、胰蛋白胨和酵母膏促进产酶。利用响应面方法对LP621产右旋糖苷酶的发酵条件进行优化。选择培养基pH、时间、麦芽糖浓度和装液量4因素进行优化,结果为pH 7.07,发酵时间21.94 h,麦芽糖浓度0.42%,装液量为21.88%,酶活为270.1U/mL。     

产脂肪酶细菌RYXP的诱变选育及突变株产酶条件优化

以"凤丹"牡丹根际土壤中分离筛选到的产脂肪酶菌株Pseudomonas sp. RYXP作为出发菌株,对其进行了紫外线诱变选育,并采用单因素试验和正交试验方法对活性最强正突变株的产脂肪酶基本特性进行了测定。结果表明,出发菌株Pseudomonas sp. RYXP的紫外线诱变最佳条件为:15 W紫外灯30 cm距离照射1 min;将产脂肪酶活性最强的正突变菌株编号为RYXP-3,单因素试验表明RYXP-3产脂肪酶适宜的碳源为玉米淀粉,适宜氮源为豆饼粉,适宜的磷酸二氢钾含量是0.3%,适宜的初始pH值为7;正交试验表明RYXP-3的最佳的产酶培养基成分组成是:玉米淀粉7%,豆饼粉3%,磷酸二氢钾0.3%,初始pH值为8。在优化方案A1B2C2D3产酶条件下,突变株RYXP-3最高的产酶活性达到56.1 U/mL。突变菌株RYXP-3可作为产油牡丹"凤丹"专用促生菌肥开发的备选资源菌株。     

Identification of a New Marine Bacterial Strain SD8 and Optimization of Its Culture Conditions for Producing Alkaline Protease

While much attention has been given to marine microorganisms for production of enzymes, which in general are relatively more stable and active compared to those from plants and animals, studies on alkaline protease production from marine microorganisms have been very limited. In the present study, the alkaline protease producing marine bacterial strain SD8 isolated from sea muds in the Geziwo Qinhuangdao sea area of China was characterized and its optimal culture conditions were investigated. Strain SD8 was initially classified to belong to genus Pseudomonas by morphological, physiological and biochemical characterizations, and then through 16S rDNA sequence it was identified to be likely Pseudomonas hibiscicola. In addition, the culture mediums, carbon sources and culture conditions of strain SD8 were optimized for maximum production of alkaline protease. Optimum enzyme production (236U/mL when cultured bacteria being at 0.75 mg dry weight/mL fermentation broth) was obtained when the isolate at a 3% inoculum size was grown in LB medium at 20 mL medium/100mL Erlenmeyer flask for 48h culture at 30°C with an initial of pH 7.5. This was the first report of strain Pseudomonas hibiscicola secreting alkaline protease, and the data for its optimal cultural conditions for alkaline protease production has laid a foundation for future exploration for the potential use of SD8 strain for alkaline protease production.     

Screening and genetic identification of acidic and neutral protease-producing yeasts strains by 26S rRNA gene sequencing

Protease enzymes (proteases), particularly those produced by microorganisms, play very important roles in industry, due to their diverse applications. Considering the richness of microbial diversity in nature, a good chance always exists that proteases more suitable, with better properties for commercial application, may be discovered while screening novel microorganisms from local environments. In this study, 94 yeasts were isolated from different natural sources collected from the Abha region, Kingdom of Saudi Arabia, to determine extracellular protease production and activity. Among them, 23 isolates (24.46%) showed protease activity using a casein hydrolysis test. Of these, five isolates (21.74%) were selected and identified as the best protease producers by exhibiting the largest clearance zones around colonies. A 26S rRNA gene D1/D2 domain sequence alignment, comparison, and phylogenetic analysis of our study yeasts to published D1/D2 domain rRNA gene sequences from GenBank, identifies the isolates as Rhodotorula mucilaginosa KKU-M12c, Cryptococcus albidus KKU-M13c, Pichia membranifaciens KKU-M18c, Hanseniaspora uvarum KKU-M19c, and Candida californica KKU-M20c. The influence of varying pH (4.0–9.0) on the yield and activity of the proteases was investigated using 0.5% (w/v) casein as a substrate, to detect optimum pH values for yeast extracellular protease production. Enzyme activity was measured using qualitative and quantitative assays. Results show all of the study yeasts secreting protease enzyme at all tested pH levels, with the exception of pH 9.0. This indicates that none of the five yeasts are alkaline protease producers. Maximum protease activity (187 U/mL) was observed in strain H. uvarum KKU-M19c at pH 6.0 (only), indicating that strain KKU-M19c only produces neutral protease. The other four yeast isolates, R. mucilaginosa KKU-M12c, C. albidus KKU-M13c, P. membranifaciens KKU-M18c, and C. californica KKU-M20c, produced both acidic (at pH 4.0) and neutral (at pH 6.0 and 7.0) proteases. Strain C. californica KKU-M20c was found to be the best acidic and neutral protease producer (138 U/mL at pH 4.0, and 185 U/mL at pH 7.0). This is the first report of the discovery and isolation of local, powerful yeasts producing acidic and neutral protease enzymes from the Abha region, Kingdom of Saudi Arabia.     

Production of protease and lipase by solvent tolerant Pseudomonas aeruginosa PseA in solid-state fermentation using Jatropha curcas seed cake as substrate

Deoiled Jatropha seed cake was assessed for its suitability as substrate for enzyme production by solid-state fermentation (SSF). Solvent tolerant Pseudomonas aeruginosa PseA strain previously reported by us was used for fermentation. The seed cake supported good bacterial growth and enzyme production (protease, 1818 U/g of substrate and lipase, 625 U/g of substrate) as evident by its chemical composition. Maximum protease and lipase production was observed at 50% substrate moisture, a growth period of 72 and 120 h, and a substrate pH of 6.0 and 7.0, respectively. Enrichment with maltose as carbon source increased protease and lipase production by 6.3- and 1.6-fold, respectively. Nitrogen supplementation with peptone for protease and NaNO(3) for lipase production also enhanced the enzyme yield reaching 11,376 U protease activity and 1084 U lipase activity per gram of Jatropha seed cake. These results demonstrated viable approach for utilization of this huge biomass by solid-state fermentation for the production of industrial enzymes. This offers significant benefit due to low cost and abundant availability of cake during biodiesel production.     

地衣芽孢杆菌TG116胞外蛋白酶产酶条件与酶学性质

【背景】从独角莲中分离得到的地衣芽孢杆菌TG116是一株对植物病原菌具有广谱抗性作用的生防菌株。【目的】优化TG116的产酶条件并探索其酶学性质,进一步了解其抗菌机制。【方法】采用Folin-Phenol显色法与响应曲面法,优化菌株TG116的产酶条件并研究其蛋白酶的酶学性质。【结果】菌株TG116产酶最适条件为:温度40.83°C,p H 8.01,发酵时间53.74 h,增加通气量可以显著提高酶活力。按照优化后的条件培养48 h后,上清液蛋白酶活力从57.46 U/mL达到了254.07 U/mL。酶学性质研究表明:该酶为碱性蛋白酶,最适反应pH为8.5,最适反应温度为50°C,具有良好的温度和pH稳定性,EDTA对酶活具有强烈的抑制作用,金属离子Mg~(2+)、Ca~(2+)、Na~+、Co~(2+)、K~+等对酶活也具有一定的抑制作用。【结论】菌株TG116具有良好的p H与温度稳定性,在实际应用中蛋白酶不易失活,可以分解真菌的细胞壁蛋白成分,破坏细胞壁结构,从而抑制甚至杀死病原菌,达到抗菌作用。