苏云金芽胞杆菌大质粒pBMB28的克隆

苏云金芽胞杆菌幕虫亚种YBT-020具有典型的晶胞粘连表型。在前期的研究中,通过质粒消除实验,推测晶胞粘连现象与YBT-020内生质粒pBMB28有关。为了定位质粒pBMB28上控制晶胞粘连表型的基因,首先对质粒pBMB28进行克隆。利用穿梭载体pEMB0557,成功构建了苏云金芽胞杆菌YBT-020的基因组人工染色体(BAC)文库。前期的研究表明晶体蛋白基因cry28Aa定位在质粒pBMB28上,根据cry28Aa基因序列设计引物,从文库中筛选到含有cry28Aa的重组质粒pBMB231。镜检和SDS-PAGE证明质粒pBMB231转化无晶体突变株BMB171形成的重组子BMB231可以产生Cry28Aa晶体蛋白,但不能恢复晶胞粘连表型。对重组质粒pBMB231的插入片段末端序列测定并设计引物筛选文库,通过染色体步移方式得到4个可以重叠覆盖质粒pBMB28不同区域的克隆子,从而克隆了该质粒。对这4个克隆子末端测序和酶切分析,测算出该质粒的大小约为140 kb。进一步确定应用基因组BAC文库以及重叠片段筛选的方法,可以快速有效的克隆苏云金芽胞杆菌大质粒。     

苏云金芽胞杆菌拟步行甲亚种质粒复制子oril65的克隆

以苏云金芽胞杆菌拟步行甲亚种菌株（Bacillus thuringiensis subsp.tenebrionis)YBT-1765作为出发菌株,克隆了一个包含复制子的EcoRI酶切片段,大小约为11kb,称为oril65。这是国内外从此亚种中克隆到的第一个复制子,缩小到8kb左右后仍然能够复制。杂交结果显示,此复制子来源于菌株YBT-1765可以检测到的分子量最大的质粒,以此复制子构建的穿梭载体pBMB6071在不同受体菌中的稳定性差异很大,其中在以色列亚种无晶体突变株4Q7中,传40后代,稳定性100%,质粒pBMB6071与含ori1030和ori2062在库斯塔克亚种无晶体突变株BMB171中是相容的。     

消除内生质粒对苏云金芽胞杆菌YBT-1463特性的影响

研究了经完全消除苏云金芽胞杆菌野生菌株YBT-1463的内生质粒对该菌部分形态、遗传及生理生化特性的影响。结果表明,消除内生质粒后的无质粒突变株不形成伴胞晶体,但电转化4种供体质粒,即pBMBl21、pBMB304-1Ab、pBMBLC和pBMB9748的效率显著提高,转化频率最高比出发菌株提高6.8×10 倍,而无质粒突变株对红霉素等10种抗生素的敏感性,对葡萄糖等19种碳源和谷氨酸等12种氮源的利用能力及生长性能与出发菌株无明显差异。     

苏云金芽胞杆菌拟步行甲亚种YBT_1765中稳定质粒pBMB175的克隆和功能分析

从苏云金芽胞杆菌拟步行甲亚种YBT_1765中克隆得到一个大小约152 kb的质粒pBMB175,构建了该质粒的限制性图谱,通过功能验证,将其最小的复制区定位在一个1151bp的片段上。分析了包含有这个复制区的一个大小为4152 bp的核苷酸序列,该片段包含有3个编码框（ORF1、OFR2和ORF3）。氨基酸序列同源性比较发现, ORF1(767AA)与UvrD_旋促酶、重组酶RecD和RecB家族具有20%～30%的相似性;ORF2（149AA）没有发现与任何已知序列具有同源性;ORF3（83AA）与pGI3中一个未知功能的蛋白（ORF7）具有34%的相似性。通过缺失及序列比较分析推测ORF2可能编码一种新的复制蛋白。因此pBMB175的复制类型可能属于一类新的复制家族。利用最小复制区构建的重组质粒在无抗生素选择压力下可稳定遗传40多代,具备构建稳定遗传质粒载体的潜力。     

苏云金芽胞杆菌拟步行甲亚种YBT-1765中稳定质粒pBMB175的克隆和功能分析

从苏云金芽胞杆菌拟步行甲亚种YBT_1765中克隆得到一个大小约15.2kb的质粒pBMB175,构建了该质粒的限制性图谱,通过功能验证,将其最小的复制区定位在一个1151bp的片段上。分析了包含有这个复制区的一个大小为4152bp的核苷酸序列,该片段包含有3个编码框(ORF1、OFR2和ORF3)。氨基酸序列同源性比较发现,ORF1(767AA)与UvrD_旋促酶、重组酶RecD和RecB家族具有20%～30%的相似性;ORF2(149AA)没有发现与任何已知序列具有同源性;ORF3(83AA)与pGI3中一个未知功能的蛋白(ORF7)具有34%的相似性。通过缺失及序列比较分析推测ORF2可能编码一种新的复制蛋白。因此pBMB175的复制类型可能属于一类新的复制家族。利用最小复制区构建的重组质粒在无抗生素选择压力下可稳定遗传40多代,具备构建稳定遗传质粒载体的潜力。     

含质粒复制起始区ori44的苏云金芽胞杆菌解离载体的构建

将苏云金芽胞杆菌转座子Tn4430的解离酶识别位点res分别插入克隆载体pRSET B和pUC19得到质粒pBMB1201和pBMB1202。这两个质粒分别经BamHI/Hin dⅢ和EcoRI/HindⅢ双酶切回收含res位点的小DNA片段,与穿梭载体pHT3101经EcoRI/HindⅢ双酶切后加收的含大肠杆菌复制起始区、氨苄青霉素抗性基因和红霉素抗性基因的3．3kb片段连接,获得重组质粒pBMB1203。封闭pBMB1203两res位点外的BamHI和EcoRI位点后,得到解离载体pBMB1204。将来源于苏云金芽胞杆菌库斯塔克亚种YBT－1520的质粒复制起始区ori44片段插入pBMB1204的两res位点之间,得到解离穿梭载体pBMB1205。该解离载体插入壮观霉素抗性基因后电转化无晶体突变株,在辅助质粒所提供的解离酶作用下可发生解离消除抗性基因,解离频率为100％,解离后的质粒稳定性为93％。利用解离穿梭载体pBMB1205可在用抗性筛选到转化子后特定消除抗性标记基因和其它非苏云金芽胞杆菌DNA片段。     

含质粒复制起始区ori44的苏云金芽胞杆菌解离载体的构建

将苏云金芽胞杆菌转座子Tn4430的解离酶识别位点res分别插入克隆载体pRSET B和pUC19得到质粒pBMB1201和pBMB1202。这两个质粒分别经BamHI/HindⅢ和EcoRI/HindⅢ双酶切回收含res位点的小DNA片段,与穿梭载体pHT3101经EcoRI/HindⅢ双酶切后回收的含大肠杆菌复制起始区、氨苄青霉素抗性基因和红霉素抗性基因的3.3kb片段连接,获得重组质粒pBMB1203。封闭pBMB1203两res位点外的BamHI和EcoRI位点后,得到解离载体pBMB1204。将来源于苏云金芽胞杆菌库斯塔克亚种YBT-1520的质粒复制起始区ori44片段插入pBMB1204的两res位点之间,得到解离穿梭载体pBMB1205。该解离载体插入壮观霉素抗性基因后电转化无晶体突变株,在辅助质粒所提供的解离酶作用下可发生解离消除抗性基因,解离频率为100%,解离后的质粒稳定性为93%。利用解离穿梭载体pBMB1205可在用抗性筛选到转化子后特定消除抗性标记基因和其它非苏云金芽胞杆菌DNA片段。     

苏云金芽胞杆菌拟步行甲亚种质粒复制子ori165的克隆

以苏云金芽胞杆菌拟步行甲亚种菌株 (Bacillusthuringiensissubsp.tenebrionis)YBT 1 76 5作为出发菌株 ,克隆了一个包含复制子的EcoRI酶切片段 ,大小约为 1 1kb ,称为ori1 6 5。这是国内外从此亚种中克隆到的第一个复制子。缩小到 8kb左右后仍然能够复制。杂交结果显示 ,此复制子来源于菌株YBT 1 76 5可以检测到的分子量最大的质粒。以此复制子构建的穿梭载体pBMB6 0 71在不同受体菌中的稳定性差异很大 ,其中在以色列亚种无晶体突变株 4Q7中 ,传 40后代 ,稳定性 1 0 0 %。质粒pBMB6 0 71与含ori1 0 3 0和ori2 0 6 2在库斯塔克亚种无晶体突变株BMB1 71中是相容的     

苏云金芽胞杆菌内生质粒提取方法的改进

改进了苏云金芽胞杆菌（Bacillus thuringiensis,Bt）内生质粒提取技术,提取了Bt库斯塔克亚种、以色利亚种和一株对鳞翅目害虫有活性的野生菌株的质粒,利用琼脂糖凝胶电泳分析了质粒图谱,进一步检测了质粒的浓度与纯度。实验结果表明,该方法与传统技术相比,操作简单、耗时短,提取的质粒纯度高、条带清晰,染色体DNA污染较少。为Bt杀虫基因克隆、质粒特性分析等研究创造了有利条件。     

类似S-层蛋白的苏云金芽胞杆菌伴胞晶体蛋白基因的克隆

芽胞杆菌CTC菌被鉴定为苏云金芽胞杆菌,鞭毛血清型H2,幕虫亚种;产生卵圆形伴胞晶体,伴胞晶体蛋白为100kD;测定了该蛋白 N－末端序列,该序列与炭疽芽胞杆菌的细胞表面S－层蛋白具92－93％相似性,根据Southern杂交制作了该晶体蛋白基因ctc所在位置的限制性酶切图谱,分别克隆了该基因5’和3’端所在2．9kb XbaI片段和3．1kb Cla I DNA片段,彼此间具0．6kb重叠,通过拼接获得含完整ctc基因的克隆,含该基因的大肠杆菌与表达S－层蛋白的大肠杆菌具相似生长特征,初步表明CTC菌株的伴胞晶体由细胞表面S－层蛋白组成,苏云金芽胞杆菌区别于蜡状芽胞杆菌和炭疽芽胞杆菌的唯一标准是能形成伴胞晶体,由于S－层是细胞表面的结构成分,本文对CTC菌株鉴定为苏云金芽胞杆菌以及伴胞晶体作为苏云金芽胞杆菌鉴别的唯一标准提出了质疑。     

Bacterial artificial chromosome library of Finegoldia magna ATCC 29328 for genetic mapping and comparative genomics

We constructed a bacterial artificial chromosome (BAC) library of Finegoldia magna ATCC 29328 DNA to facilitate further genome analysis of F. magna. The BAC library contained 385 clones with an average insert size of 55 kb, representing a 10.1-fold genomic coverage. Repeated DNA hybridization using primer sets designed on the basis of BAC-end sequences yielded nine contigs covering 95% of the chromosome and two contigs covering 98% of the plasmid. The contigs were localized on the physical map of F. magna ATCC 29328 DNA. A total of 121 BAC-end sequences revealed 103 unique genes, which had not been previously reported for F. magna. The homolog ORF of albumin-binding protein (urPAB), one of the known virulence factors from F. magna, was sequenced and localized on the physical map. Homology analysis of 121 BAC-end sequences revealed that F. magna is most closely related to clostridia, particularly Clostridium tetani. This close relationship is consistent with the recent classification of peptostreptococci based on 16S rRNA sequence analysis. The BAC library constructed here will be useful for the whole genome sequencing project and other postgenomic applications.     

Gene clusters located on two large plasmids determine spore crystal association (SCA) in Bacillus thuringiensis subsp. finitimus strain YBT-020

Crystals in Bacillus thuringiensis are usually formed in the mother cell compartment during sporulation and are separated from the spores after mother cell lysis. In a few strains, crystals are produced inside the exosporium and are associated with the spores after sporulation. This special phenotype, named 'spore crystal association' (SCA), typically occurs in B. thuringiensis subsp. finitimus. Our aim was to identify genes determining the SCA phenotype in B. thuringiensis subsp. finitimus strain YBT-020. Plasmid conjugation experiments indicated that the SCA phenotype in this strain was tightly linked with two large plasmids (pBMB26 and pBMB28). A shuttle bacterial artificial chromosome (BAC) library of strain YBT-020 was constructed. Six fragments from BAC clones were screened from this library and discovered to cover the full length of pBMB26; four others were found to cover pBMB28. Using fragment complementation testing, two fragments, each of approximately 35 kb and located on pBMB26 and pBMB28, were observed to recover the SCA phenotype in an acrystalliferous mutant, B. thuringiensis strain BMB171. Furthermore, deletion analysis indicated that the crystal protein gene cry26Aa from pBMB26, along with five genes from pBMB28, were indispensable to the SCA phenotype. Gene disruption and frame-shift mutation analyses revealed that two of the five genes from pBMB28, which showed low similarity to crystal proteins, determined the location of crystals inside the exosporium. Gene disruption revealed that the three remaining genes, similar to spore germination genes, contributed to the stability of the SCA phenotype in strain YBT-020. Our results thus identified the genes determining the SCA phenotype in B. thuringiensis subsp. finitimus.     

One large-insert plant-transformation-competent BIBAC library and three BAC libraries of Japonica rice for genome research in rice and other grasses

We report one large-insert BIBAC library and three BAC libraries for japonica rice cv Nipponbare. The BIBAC library was constructed in the HindIII site of a plant-transformation-competent binary vector (pCLD04541) and the three BAC libraries were constructed in the BamHI, HindIII and EcoRI sites of a BAC vector (pECBAC1), respectively. Each library contains 23,040 clones, has an average insert size of 130 kb, 170 kb, 150 kb and 156 kb, and covers 6.7x, 8.7x, 7.7x and 8.0 x rice haploid genomes, respectively. The combined libraries contain 92,160 clones in total, covering 31.1 x rice haploid genomes. To demonstrate their utility, we screened the libraries with 55 DNA markers mapped to chromosome 8 of the rice genetic maps and analyzed a number of clones by the restriction fingerprinting and contig assembly method. The results indicate that the libraries completely cover the rice genome and, thus, are well-suited for genome research in rice and other gramineous crops. The BIBAC library represents the first plant-transformation-competent large-insert DNA library for rice, which will streamline map-based cloning, functional analysis of the rice genome sequence and molecular breeding in rice and other grass species. These libraries are being used in the development of a whole-genome, BAC/BIBAC-based, integrated physical, genetic and sequence map of rice and in the research of genome-wide comparative genomics of grass species.     

Construction and Identification of Bacterial Artificial Chromosome Library for 0-613-2R in Upland Cotton

A bacterial artificial chromosome （BAC） library containing a large genomlc DNA insert is an important tool for genome physical mapping, map-based cloning, and genome sequencing. To Isolate genes via a map-based cloning strategy and to perform physical mapping of the cotton genome, a high-quality BAC library containing large cotton DNA Inserts Is needed. We have developed a BAC library of the restoring line 0-613-2R for Isolating the fertility restorer （Rf1） gene and genomic research in cotton （Gossypium hirsutum L.）. The BAC library contains 97 825 clones stored In 255 pieces of a 384-well mlcrotiter plate. Random samples of BACs digested with the Notl enzyme Indicated that the average Insert size Is approximately 130 kb, with a range of 80-275 kb, and 95.7% of the BAC clones in the library have an average insert size larger than 100 kb. Based on a cotton genome size of 2 250 Mb, library coverage is 5.7 × haploid genome equivalents. Four clones were selected randomly from the library to determine the stability of the BAC clones. There were no different fingerprints for 0 and 100 generations of each clone digested with Notl and Hlndiii enzymes. Thus, the atabiiity of a single BAC clone can be sustained at iesat for 100 generations. Eight simple sequence repeat （SSR） markers flanking the Rf; gene were chosen to screen the BAC library by pool using PCR method and 25 positive clones were identified with 3.1 positive clones per SSR marker.     

Construction of a BAC Library for a Defoliating Insect-Resistant Soybean and Identification of Candidate Clones Using a Novel Approach

Positional cloning of an insect-resistance quantitative trait locus (QTL) requires the construction of a large-insert genomic DNA library from insect-resistant genotypes. To facilitate cloning of a major defoliating insect-resistance QTL on linkage group M of the soybean genetic map, a bacterial artificial chromosome (BAC) library for PI 229358 was constructed and characterized. The HindIII BAC library contains 55,296 clones with an average insert size 131 kb. This library represents a 6-fold soybean haploid genome equivalents, allowing a 99.8% probability of recovering any specific sequence of interest in soybean. BAC filters were screened with a genomic DNA probe Sat_258sc2 obtained through genome walking from flanking sequences of a simple sequence repeat (SSR) marker, Sat_258, which links to the insect-resistance QTL. Thirteen BAC clones were identified positive for Sat_258sc2, and two of them were confirmed to carry Sat_258. The results suggest that this library is useful in positional cloning of the major insect-resistance QTL, and the approach presented here can be used to screen a BAC library for a SSR marker without requiring the creation of BAC pools.     

A sunflower BAC library suitable for PCR screening and physical mapping of targeted genomic regions

A sunflower BAC library consisting of 147,456 clones with an average size of 118 kb has been constructed and characterized. It represents approximately 5× sunflower haploid genome equivalents. The BAC library has been arranged in pools and superpools of DNA allowing screening with various PCR-based markers. Each of the 32 superpools contains 4,608 clones and corresponds to a 36 matrix pools. Thus, the screening of the entire library could be accomplished in less than 80 PCR reactions including positive and negative controls. As a demonstration of the feasibility of the concept, a set of 24 SSR markers covering about 36 cM in the sunflower SSR map (Tang et al. in Theor Appl Genet 105:1124–1136, 2002) have been used to screen the BAC library. About 125 BAC clones have been identified and then organized in 23 contigs by HindIII digestion. The contigs are anchored on the SSR map and thus constitutes a first-generation physical map of this region. The utility of this BAC library as a genomic resource for physical mapping and map-based cloning in sunflower is discussed.     

Construction and characterization of a BAC library from the Coffea arabica genotype Timor Hybrid CIFC 832/2

Most of the world’s coffee production originates from Coffea arabica, an allotetraploid species with low genetic diversity and for which few genomic resources are available. Genomic libraries with large DNA fragment inserts are useful tools for the study of plant genomes, including the production of physical maps, integration studies of physical and genetic maps, genome structure analysis and gene isolation by positional cloning. Here, we report the construction and characterization of a Bacterial Artificial Chromosome (BAC) library from C. arabica Timor Hybrid CIFC 832/2, a parental genotype for several modern coffee cultivars. The BAC library consists of 56,832 clones with an average insert size of 118 kb, which represents a dihaploid genome coverage of five to sixfold. The content of organellar DNA was estimated at 1.04 and 0.5 % for chloroplast and mitochondrial DNA, respectively. The BAC library was screened for the NADPH-dependent mannose-6-phosphate reductase gene (CaM6PR) with markers positioned on four linkage groups of a partial C. arabica genetic map. A mixed approach using PCR and membrane hybridization of BAC pools allowed for the discovery of nine BAC clones with the CaM6PR gene and 53 BAC clones that were anchored to the genetic map with simple sequence repeat markers. This library will be a useful tool for future studies on comparative genomics and the identification of genes and regulatory elements controlling major traits in this economically important crop species.