黑曲霉电转化条件的研究

研究避免了繁琐的原生体制备过程,直接使用萌发的黑曲霉孢子进行电转化,以潮霉素B作为筛选标记,从孢子萌发时间、电场强度及质粒浓度等方面考察了电转化效率的影响因素。研究表明,针对A.nigerMGG029-ΔaamA,其理想的电转化条件:孢子龄为4d,孢子萌发时间为2h,电场强度为5kV/cm。在上述条件下分别使用1μg环状或线状pBC-Hygro质粒DNA进行转化,平均可以得到34个和51个转化子,而在同样条件下使用质粒pRS303H平均可以获得163个和258个转化子。     

原生质体介导马尔尼菲青霉基因转化体系的优化

目的优化原生质体介导的马尔尼菲青霉转化体系,为其基因功能研究提供良好的平台。方法通过原生质体介导将构巢曲霉(Aspergillus nidulans)pyrG基因插入马尔尼菲青霉尿嘧啶缺陷株ligD(pyrG-,ligD-)中,在不含尿嘧啶的培养基中筛选阳性转化子,运用PCR验证重组子,通过改变影响转化效率的酶解时间、培养基浓度、质粒浓度、不同配方的原生质体洗涤液STC和不同配方的原生质体助融剂PTC 5个条件对体系进行优化。结果 PCR验证A.nidulans pyrG基因成功的插入ligD中,转化子可稳定传代。最适合ligD原生质体转化效率的条件为:酶解时间6h,PTC(60%PEG-4000,100mmol/L Tris-HCl pH8.0,100mmol/L CaCl2),每100μL原生质体(106~107/mL)加入2.5μg质粒,0.6 mol/L蔗糖SD/SDU筛选/再生培养基,每1μg质粒转化子可达68个左右。结论成功优化了原生质体介导马尔尼菲青霉转化体系的条件,优化后该方法转化效率高,为基因功能研究提供良好平台。     

农杆菌介导的马尔尼菲青霉基因转化技术的建立及优化

目的建立农杆菌介导的马尔尼菲青霉(PM)基因转化技术,并对该技术条件进行优化。方法以二元质粒p DHt/SK为载体,通过农杆菌介导将pyr G基因插入马尔尼菲青霉尿嘧啶缺陷株SPM4(pyr G-,nia D-)中,在不含尿嘧啶的培养基中筛选阳性转化子。运用PCR验证重组子。进一步对影响转化效率的农杆菌类型、共培养浓度、转化媒介、共培养温度、共培养时间、乙酰丁香酮(AS)等六个条件进行优化。结果 PCR验证pyr G基因成功的插入SPM4中,所得到转化子可稳定传代,通过条件优化,得到转化子约300个/106个细胞。选用AGL-1,以农杆菌共培养浓度为OD600=0.8,AS浓度为200μmol/L,无膜IM固体共培养基为介质,25℃共培养48 h为最适转化条件。结论成功建立了农杆菌介导PM基因转化技术,简化并优化了转化条件,该方法可用于PM基因功能研究。     

潮霉素B抗性为选择标记的整合型表达载体的构建及在米根霉中的遗传转化

为了建立适合米根霉的遗传转化体系,应用重叠延伸PCR的方法构建了以潮霉素B抗性为选择标记的单交换整合型表达载体p BS-hygro-ldh A;分别采用PEG/Ca Cl2介导的原生质体转化、原生质体电转化及萌发孢子电转化的方法将表达载体p BS-hygro-ldh A转化入米根霉AS 3.819菌株中,并研究了菌丝酶解时间、孢子萌发时间以及电转化电场强度对于转化效率的影响;通过荧光定量PCR(q PCR)对米根霉转化子基因组中质粒整合拷贝数进行了检测,并研究了其对米根霉转化子抗性稳定性的影响。实验结果表明成功获得整合了表达载体p BS-hygro-ldh A的米根霉转化子。菌丝酶解140 min产生的原生质体其再生率和转化率最高,原生质体电转化最佳电场强度为13 k V/cm,孢子萌发2.5 h转化率最高,萌发孢子电转化最佳电场强度为14 k V/cm。萌发孢子电转化方法转化率要高于原生质体转化的方法。荧光定量PCR检测结果表明,在一定范围内,高质粒整合拷贝数的米根霉转化子比较稳定。研究建立了用于工业米根霉菌株的遗传转化体系,为米根霉代谢调控研究以及菌种改造工作提供了基础与支持。     

利用电穿孔技术实现质粒向酵母原生质体的转化

本实验的主要目的旨在摸索电场对基因转化的最佳条件.已得到初步结果为:用酿酒酵母S.cerevisiae DBY 746作为穿梭质粒(YRp类)的受体菌.经过对最适电场条件与基因转化率之间关系的研究,我们发现在1个400μS的宽时程脉冲、电场强度为4KV/cm时有最高转化率,达273个转化子/μgDNA.本实验所用的电穿孔装置是自组装的,它简便、快速、实用.     

电穿孔法转化完整酵母的研究

本文用酿酒酵母（Ｓａｃｃｈａｒｏｍｙｃｅｓ ｃｅｒｅｖｉｓｉａｅ）作材料,探讨了电穿孔转化完整酵母的几个条件。其中电场强度及脉冲时间是两个最重要的参数。在２ｋｖ／ｃｍ,９ｍｓ时获得１０＾４转化子／ｕｇＤＮＡ的转化率。转化率还与所采用的菌株与质粒等条件有关。此技术简便迅速。     

辣椒枯萎病拮抗细菌Ljb002菌株发酵条件的优化

从辣椒根际分离筛选到1株具有较强促生能力但拮抗能力一般的细菌菌株Ljb002,为提高抑制辣椒枯萎病病原菌孢子的萌发能力,采用响应面分析方法（Response Surface Methodology,RSM）对该菌株的液体发酵条件进行优化。在单因素的基础上利用Plackett-Burman设计方法对8种影响因素进行了重要性评价。结果表明,初始pH、蛋白胨和MgSO₄加入量对菌株Ljb002发酵液抑制孢子萌发的能力有显著影响。采用响应面分析方法对这3个主要因素进行优化,优化的最佳条件组成为初始pH 7.72、蛋白胨12.93 g/L、硫酸镁1.98 g/L、葡萄糖20 g/L、接种量3%、种龄10 h、100 mL三角瓶装液量为14 mL、培养温度28 ℃,此时相对孢子萌发抑制率最大为96.73%。在验证试验中相对孢子萌发抑制率达到了95.18%,与优化前相对孢子萌发抑制率64.37%相比提高了32.37%。     

农杆菌介导生防棘孢木霉菌转化体系的优化

目的:实现棘孢木霉菌T4的遗传转化并优化其转化体系.方法:以潮霉素抗性为选择标记,利用农杆菌转化法介导转化棘孢木霉菌.结果:潮霉素基因成功整合到受体菌基因组中,转化子抗性基因可稳定遗传.结论:最优的转化体系和条件为:IM和CM培养基中AS浓度为200 μg/mL,棘孢木霉T4孢子浓度为106/mL,农杆菌浓度为200 μL( OD600约0.8),共培养时间为48 h,转化效率约为50个转化子/106个孢子.     

链霉菌质粒pSET152电转化稀有放线菌小单孢菌的研究

利用链霉菌(Streptomyces)噬菌体ΦC31所构建的整合型载体pSET152作为供体质粒,分别以小单孢菌(Micromonospora)40027菌株的萌发孢子和新鲜菌丝体作为受体菌,在不同的电场强度下进行电转化实验,结果表明:以小单孢菌40027菌株萌发孢子为受体菌,未获得电转化子;以小单孢菌40027菌株新鲜菌丝体为受体菌,获得了电转化子。电场强度为13kV/cm时可获得最高转化效率。Southern杂交结果表明:质粒pSET152可通过菌丝体电转化法导入小单孢菌40027菌株,并整合到小单孢菌40027菌株的染色体上,暗示链霉菌噬菌体ΦC31的整合酶基因和整合位点在异源宿主小单孢菌40027菌株中仍具有相同的功能。质粒稳定性检测实验表明:质粒pSET152可稳定地存在于小单孢菌40027菌株中。     

粗茎鳞毛蕨孢子萌发研究

以经过3年低温储藏的粗茎鳞毛蕨孢子为实验材料,从孢子离心、孢子消毒、培养基种类、光质等4方面对孢子萌发进行研究,结果表明:在离心转数≤14 000 r.min-1、离心时间≤30 min条件下,离心处理对孢子萌发基本无影响;对孢子进行1%NaClO水溶液浸泡处理20～30 min为最佳消毒条件;改良Knop’s培养基为最佳孢子萌发培养基;黑暗条件下孢子不能萌发,但是黑暗处理能够明显提高孢子萌发整齐性;红光比白光能促进孢子提早萌发1 d左右,但对提高萌发率效果不显著。     

Properties of Bacillus megaterium and Bacillus subtilis mutants which lack the protease that degrades small, acid-soluble proteins during spore germination.

During germination of spores of Bacillus species the degradation of the spore's pool of small, acid-soluble proteins (SASP) is initiated by a protease termed GPR, the product of the gpr gene. Bacillus megaterium and B. subtilis mutants with an inactivated gpr gene grew, sporulated, and triggered spore germination as did gpr+ strains. However, SASP degradation was very slow during germination of gpr mutant spores, and in rich media the time taken for spores to return to vegetative growth (defined as outgrowth) was much longer in gpr than in gpr+ spores. Not surprisingly, gpr spores had much lower rates of RNA and protein synthesis during outgrowth than did gpr+ spores, although both types of spores had similar levels of ATP. The rapid decrease in the number of negative supertwists in plasmid DNA seen during germination of gpr+ spores was also much slower in gpr spores. Additionally, UV irradiation of gpr B. subtilis spores early in germination generated significant amounts of spore photoproduct and only small amounts of thymine dimers (TT); in contrast UV irradiation of germinated gpr+ spores generated almost no spore photoproduct and three to four times more TT. Consequently, germinated gpr spores were more UV resistant than germinated gpr+ spores. Strikingly, the slow outgrowth phenotype of B. subtilis gpr spores was suppressed by the absence of major alpha/beta-type SASP. These data suggest that (i) alpha/beta-type SASP remain bound to much, although not all, of the chromosome in germinated gpr spores; (ii) the alpha/beta-type SASP bound to the chromosome in gpr spores alter this DNA's topology and UV photochemistry; and (iii) the presence of alpha/beta-type SASP on the chromosome is detrimental to normal spore outgrowth.     

Germination of spores of Bacillus subtilis with dodecylamine

AIMS: To determine the properties of Bacillus subtilis spores germinated with the alkylamine dodecylamine, and the mechanism of dodecylamine-induced spore germination. METHODS AND RESULTS: Spores of B. subtilis prepared in liquid medium were germinated efficiently by dodecylamine, while spores prepared on solid medium germinated more poorly with this agent. Dodecylamine germination of spores was accompanied by release of almost all spore dipicolinic acid (DPA), degradation of the spore's peptidoglycan cortex, release of the spore's pool of free adenine nucleotides and the killing of the spores. The dodecylamine-germinated spores did not initiate metabolism, did not degrade their pool of small, acid-soluble spore proteins efficiently and had a significantly lower level of core water than did spores germinated by nutrients. As measured by DPA release, dodecylamine readily induced germination of B. subtilis spores that: (a) were decoated, (b) lacked all the receptors for nutrient germinants, (c) lacked both the lytic enzymes either of which is essential for cortex degradation, or (d) had a cortex that could not be attacked by the spore's cortex-lytic enzymes. The DNA in dodecylamine-germinated wild-type spores was readily stained, while the DNA in dodecylamine-germinated spores of strains that were incapable of spore cortex degradation was not. These latter germinated spores also did not release their pool of free adenine nucleotides. CONCLUSIONS: These results indicate that: (a) the spore preparation method is very important in determining the rate of spore germination with dodecylamine, (b) wild-type spores germinated by dodecylamine progress only part way through the germination process, (c) dodecylamine may trigger spore germination by a novel mechanism involving the activation of neither the spore's nutrient germinant receptors nor the cortex-lytic enzymes, and (d) dodecylamine may trigger spore germination by directly or indirectly activating release of DPA from the spore core, through the opening of channels for DPA in the spore's inner membrane. SIGNIFICANCE AND IMPACT OF THE STUDY: These results provide new insight into the mechanism of spore germination with the cationic surfactant dodecylamine, and also into the mechanism of spore germination in general. New knowledge of mechanisms to stimulate spore germination may have applied utility, as germinated spores are much more sensitive to processing treatments than are dormant spores.     

Effect of bongkrekic acid on growth and metabolism of filamentous fungi

The antifungal activity of bongkrekic acid against 17 tested molds was determined. Bongkrekic acid prevented spore germination and mycelial proliferation of Aspergillus niger, Rhizopus oryzae and Penicillium italicum. The action of bongkrekic acid was fungicidal. Under these conditions, the incorporation of ¹⁴C-leucine and ¹⁴C-uracil into the perchloric acid insoluble material of germinating A. niger conidia was significantly reduced by bongkrekic acid. Respiratory activity of resting spores was not affected by bongkrekic acid. Respiratory activity of germinated spores was inhibited by bongkrekic acid to the extent of 30 to 60% of controls for A. niger, R. oryzae and P. italicum. It has been concluded that operation of adenine nucleotide translocation in mitochondria of tested fungi is obligatory both for normal spore germination and fungal growth.     

Clostridium perfringens spore germination: characterization of germinants and their receptors

Clostridium perfringens food poisoning is caused by type A isolates carrying a chromosomal enterotoxin (cpe) gene (C-cpe), while C. perfringens-associated non-food-borne gastrointestinal (GI) diseases are caused by isolates carrying a plasmid-borne cpe gene (P-cpe). C. perfringens spores are thought to be the important infectious cell morphotype, and after inoculation into a suitable host, these spores must germinate and return to active growth to cause GI disease. We have found differences in the germination of spores of C-cpe and P-cpe isolates in that (i) while a mixture of L-asparagine and KCl was a good germinant for spores of C-cpe and P-cpe isolates, KCl and, to a lesser extent, L-asparagine triggered spore germination in C-cpe isolates only; and (ii) L-alanine or L-valine induced significant germination of spores of P-cpe but not C-cpe isolates. Spores of a gerK mutant of a C-cpe isolate in which two of the proteins of a spore nutrient germinant receptor were absent germinated slower than wild-type spores with KCl, did not germinate with L-asparagine, and germinated poorly compared to wild-type spores with the nonnutrient germinants dodecylamine and a 1:1 chelate of Ca2+ and dipicolinic acid. In contrast, spores of a gerAA mutant of a C-cpe isolate that lacked another component of a nutrient germinant receptor germinated at the same rate as that of wild-type spores with high concentrations of KCl, although they germinated slightly slower with a lower KCl concentration, suggesting an auxiliary role for GerAA in C. perfringens spore germination. In sum, this study identified nutrient germinants for spores of both C-cpe and P-cpe isolates of C. perfringens and provided evidence that proteins encoded by the gerK operon are required for both nutrient-induced and non-nutrient-induced spore germination.     

Identification of germination gene of Bacillus megaterium

Glucose, KNO3, proline and leucine initiate the spore germination of B. megaterium ATCC 12872, but not of B. megaterium ATCC 19213. In order to isolate the gene concerning germination of B. megaterium ATCC 12872, we constructed its gene library in plasmid vector, and introduced into B. megaterium ATCC 19213. We obtained a transformant whose spores differed from those of the wild type strain with respect to germinability. Spores of this transformant could be germinated by glucose, proline or leucine. The recombinant plasmid prepared from this transformant was found to carry 2 kilobase pairs fragment of B. megaterium ATCC 12872 DNA. This fragment may contain the gene encoding the protein which plays an important role in germination.     

Transitory germinative excision repair in Bacillus subtilis.

Bacillus subtilis strains UVSSP-42-1 (hcr42 ssp1) and UVSSP-1-1 (hcr1 ssp1) are ultraviolet (UV) radiation sensitive both as dormant spores and as vegetative cells. These strains are unable to excise cyclobutane-type dimers from the deoxyribonucleic acid (DNA) of irradiated vegetative cells and fail to remove spore photoproduct from the DNA of irradiated spores either by excision (controlled by gene hcr) or by spore repair (controlled by gene ssp1). When irradiated soon after spore germination, these strains excise dimers, but not spore photoproduct, from their DNA. This process, termed germinative excision repair, functions only transiently in the germination phase and is responsible for the high UV resistance of germinated spores and for their temporary capacity to host cell reactivate irradiated phages infecting them. The recA1 mutation confers higher UV sensitivity to the germinated spores, but does not interfere with dimer removal by germinative excision repair.