作为宿主系统的几株乳酸菌的表型特征

目的：研究乳酸菌载体－宿主系统。方法：采用涂片染色和形态特征观察,用鉴别生化实验如过氧化氢酶实验,碳水化合物发酵产酸实验,精氨酸水解实验及抗生素抗性实验等对含有pMG36e质粒的乳酸菌MG1363,乳球菌IL1403和乳杆菌ATCC4356进行研究鉴定。结果：乳酸乳球菌乳脂亚种MG1363,乳酸乳球菌乳酸亚种IL1403含有质粒pMG36e的MG1363致及嗜酸乳杆菌ATCC4356其表型特征分别与伯杰氏手册中相应细菌特征一致,质粒pMG36e含有红霉素抗性基因,结论：此乳酸菌宿主一载体系统可用载体来源的红霉素抗性进行筛选,用于外源基因在乳酸菌中克隆和表达的研究。     

16S rRNA和recA、groEL基因分类鉴定乳酸乳球菌乳酸亚种和乳脂亚种的比较

【目的】比较16S rRNA和recA、groEL基因部分序列用于乳酸乳球菌乳酸亚种和乳脂亚种分类鉴定的效果。【方法】对已鉴定的8株分离自传统发酵乳的乳酸乳球菌, 选取recA和groEL基因片段, 通过PCR扩增、测序, 将测序得到的序列比对后构建系统发育树, 并与16S rRNA基因序列分析技术进行比较。【结果】比较分析不同菌株16S rRNA和recA、groEL基因的亲缘关系, recA、groEL基因可以准确地完成乳酸乳球菌乳酸亚种和乳脂亚种的区分和鉴定。【结论】recA和groEL基因序列分析可以实现乳酸乳球菌乳酸亚种和乳脂亚种的区分, 因其具有快速、准确、稳定的特点, 可适合于乳酸乳球菌乳酸亚种和乳脂亚种间的快速分类鉴定。     

硬脂酰-辅酶A脱氢酶基因在食品级乳酸菌中的表达

为了实现硬脂酰-辅酶A脱氢酶1编码基因在乳酸乳球菌中的表达,采用PCR技术扩增获得人类scd1的编码序列。Nco I和Xba I双酶切后定向插入到食品级表达载体pNZ8149中,构建表达载体pNZ8149-scd1。电转化乳酸乳球菌NZ3900,经菌落PCR和测序鉴定scd1基因成功插入到乳酸乳球菌中。在乳链菌肽诱导下进行scd1的表达,转化株提取脂肪酸,进行脂肪酸含量的气相色谱分析。结果显示,SCD1转化菌株中的C16∶1n-7和C18∶1n-7脂肪酸组分比转化pNZ8149的对照组乳酸菌分别提高了92%~169%和53%~127%。文中以scd1基因为例,尝试并证明了脂肪酸脱氢酶类基因能够在食品级乳酸菌中有效表达,为后续研究奠定了基础。     

一株具有谷胱甘肽合成能力的乳酸乳球菌的分离与初步研究

基于gshB基因同源性分析设计引物,从采集的菜园地土壤中分离到1株具有谷胱甘肽(GSH)合成能力的乳酸乳球菌菌株CCSYU10100。测定了该菌株的16S rDNA序列并根据16S rDNA序列构建了系统发育树,结果显示该菌株与乳酸乳球菌乳脂亚种在进化关系上的地位最近。电镜分析表明,菌株CCSYU10100与乳酸乳球菌的形态特征基本一致。因此认为菌株CCSYU10100属于乳酸乳球菌乳脂亚种,命名为乳酸乳球菌乳脂亚种CCSYU10100。HPLC法鉴定出该菌株胞内除GSH外,还存在半胱氨酸-甘氨酸。乳酸乳球菌CCSYU10100的部分gshB基因与假单胞菌属的gshB基因高度同源,这是gshB基因在乳酸乳球菌中、甚至是革兰氏阳性菌中的首次发现。     

利用乳酸乳球菌AcmA表面展示b-1, 3-1, 4-葡聚糖酶

采用PCR扩增乳酸乳球菌(Lactococcus lactis)MB191菌株的全长肽聚糖水解酶基因acmA, 通过C-末端融合构建了与绿色荧光基因gfp的融合基因acmA-gfp, 再连接于表达载体pMG36k上后得到可组成型表达AcmA-GFP融合蛋白的重组质粒pMB137, 然后将该质粒电转化导入到乳酸乳球菌AS1.2829中获得重组菌MB137。经SDS-PAGE检测, 重组菌MB137可表达预期的分子量约74 kD的蛋白质。Western blotting、细胞分级分离组分的荧光活性测定和特异GFP二抗标记的流式细胞仪检测证实GFP被成功锚定在重组菌细胞表面, 被锚定蛋白约占总表达融合蛋白的35%。进一步通过从枯草芽胞杆菌BF7658基因组中扩增去信号肽序列的b-1, 3-1, 4葡聚糖酶基因gls, 来取代pMB137中的gfp, 得到携带融合基因acmA-gls的重组质粒pMB138, 经导入到乳酸乳球菌AS1.2829后得到重组菌MB138, 其全细胞b-1, 3-1, 4-葡聚糖水解酶的活性约为12 U/mL菌液, 明显高于对照菌株。     

表达猪传染性胃肠炎病毒S基因的重组乳酸乳球菌的构建及免疫原性分析

根据猪传染性胃肠炎病毒纤突(S)蛋白的全基因序列及表达载体质粒的基因融合特点,设计一对引物,进行PCR扩增,获得含有TGEVS基因4个主要抗原位点的约2000bp的目的片段,将其与分泌表达的载体质粒pNZ8112进行连接,通过电击转化进入宿主菌乳酸乳球菌NZ9000细胞内,在乳链菌肽(Nisin)的诱导下进行表达,通过SDS-PAGE和Western blot分析,表明TGEVS蛋白在乳酸乳球菌中获得表达,所表达的TGEVS蛋白具有与TGE病毒一样的抗原特异性。间接免疫荧光试验表明重组菌表达蛋白定位于菌体表面。将表达TGEVS蛋白的重组乳酸乳球菌及空质粒菌株分别口服免疫BALB/c小鼠,收集粪便样品进行抗体检测,结果表明分泌型的重组菌pNZ8112-Sa/NZ9000免疫小鼠能够产生明显的抗TGEVsIgA抗体。     

南极假丝酵母脂肪酶B(CALB)基因在乳酸乳球菌MG1363中的整合及表达

根据南极假丝酵母脂肪酶B (CALB)的基因序列将CALB基因进行TA克隆、酶切鉴定及测序后,亚克隆至大肠杆菌-乳酸乳球菌穿梭表达栽体pMG36e-Nisl中,构建重组表达栽体pMG36e-Nisl-CALB.设计特异性引物P3和P4,对重组质粒pMG36e-NisI-CALB进行红霉素抗性基因的敲除,以构建食品级表达载体pMG36N-CALB,后再将两种重组质粒分别电转化入乳酸乳球菌MG1363,以Nisin为选择压力,考察CALB在MG1363中的表达情况.结果显示,成功构建了表达载体pMG36e-NisI-CALB及pMG36N-CALB,两株重组菌在含有20 IU Nisir/mL的培养基中均生长情况良好,遗传性能稳定,且经水解圈鉴定,CALB能够进行活性表达.进一步研究发现,CALB基因整合到乳酸乳球菌MG1363染色体中.     

人谷胱甘肽硫转移酶A1在乳酸乳球菌中的表达及活性研究

用RTPCR技术从人肝总RNA中分离扩增了人谷胱甘肽硫转移酶A1基因的cDNA序列,克隆至大肠杆菌表达质粒pET23b,采用蛋白表达筛查法及DNA测序证明该cDNA序列完全正确。重组质粒pET23bhgst转化大肠杆菌BL21(DE3),经IPTG诱导获得高效表达的可溶性hGSTA1产物,其表达量约为大肠杆菌可溶性总蛋白的40%。将hGSTA1cDNA亚克隆至乳酸乳球菌表达载体pMG36e,电穿孔法转化乳酸乳球菌MG1363获得hGSTA1乳酸乳球菌表达株。SDSPAGE及Western杂交分析表明该菌株表达预期大小的hGSTA1融合蛋白,经谷胱甘肽琼脂糖亲和层析纯化获得的hGSTA1蛋白具有较高的谷胱甘肽硫转移酶活性。具hGSTA1酶活性的乳酸乳球菌工程菌可望应用于研制防癌保健乳制品。     

乳酸乳球菌乳脂亚种W56中质粒pJW566的生物学特性

从丹麦乳酪发酵启子乳酸乳球菌乳脂亚种 (Lactococcuslactissubsp .cremoris)W56中 ,分离到一个 2 2 4kb的质粒pJW566,将该质粒转化到无质粒且噬菌体敏感的L .lactisMG1 61 4、SMQ86菌株中 ,所得转化子对常见 963、c2和P335属的噬菌体具有一定抗性。经测定噬菌体以及含有pJW566的菌株所繁育的噬菌体效价 ,发现该质粒对外源DNA具有限制和修饰 (Re strictionandModification ,R M)作用。将pJW566转化到一株噬菌体敏感的乳酪工业生产菌株L .lactisCHCC2 2 81 ,在牛奶发酵中 ,表现出较强的噬菌体抗性。体外内切酶活性测定表明 ,该质粒具有的限制性内切酶需要Mg2 +和ATP ,而AdoMet(S adenosylmethionine,AdoMet)对酶活有促进作用     

ptsH基因过表达对乳酸乳球菌N8自身免疫耐受性及其生理代谢的影响

目的:通过基因工程方法提高HPr蛋白编码基因ptsH在乳链菌肽(nisin)高产野生乳酸乳球菌株N8中的表达,揭示ptsH基因与乳酸乳球菌乳链菌肽耐受性等相关生物学功能的关系。方法:构建ptsH过表达质粒pLEV16-ptsH并转化至N8,使其ptsH基因过量表达,进而对比分析ptsH过表达菌株与野生菌株在生长曲线、乳链菌肽耐受性、效价、Biolog等方面的差异。结果:N8-ptsH过表达菌株与N8菌株在菌落形态、大小、表面湿滑程度及生长曲线等方面没有明显差异;ptsH基因过表达使N8菌株的乳链菌肽耐受性提高了8.3%,2个乳链菌肽耐受性相关基因nisI和nisF的表达量分别提高了15.45倍和近45倍;ptsH基因过表达略微减缓了N8菌株中乳链菌肽的产生,但乳链菌肽的最终产量略有提高;ptsH基因过表达菌株中PTS系统糖苷和磷酸化糖类的利用率比原始菌株显著提高。结论:ptsH基因主要与乳酸乳球菌的乳链菌肽耐受性有关。     

Isolation of a replication region of a large lactococcal plasmid and use in cloning of a nisin resistance determinant

The replication region of a 28-kilobase-pair (kbp) cryptic plasmid from Lactococcus lactis subsp. lactis biovar diacetylactis SSD207 was cloned in L. lactis subsp. lactis MG1614 by using the chloramphenicol resistance gene from the streptococcal plasmid pGB301 as a selectable marker. The resulting 8.1-kbp plasmid, designated pVS34, was characterized further with respect to host range, potential cloning sites, and location of replication gene(s). In addition to lactococci, pVS34 transformed Lactobacillus plantarum and, at a very low frequency, Staphylococcus aureus but not Escherichia coli or Bacillus subtilis. The 4.1-kbp ClaI fragment representing lactococcal DNA in pVS34 contained unique restriction sites for HindIII, EcoRI, XhoII, and HpaII, of which the last three could be used for molecular cloning. A region necessary for replication was located within a 2.5-kbp fragment flanked by the EcoRI and ClaI restriction sites. A 3.8-kbp EcoRI fragment derived from a nisin resistance plasmid, pSF01, was cloned into the EcoRI site of pVS34 to obtain a nisin-chloramphenicol double-resistance plasmid, pVS39. From this plasmid, the streptococcal chloramphenicol resistance region was subsequently eliminated. The resulting plasmid, pVS40, contains only lactococcal DNA. Potential uses for this type of a nisin resistance plasmid are discussed.     

Isolation of a replication region of a large lactococcal plasmid and use in cloning of a nisin resistance determinant.

The replication region of a 28-kilobase-pair (kbp) cryptic plasmid from Lactococcus lactis subsp. lactis biovar diacetylactis SSD207 was cloned in L. lactis subsp. lactis MG1614 by using the chloramphenicol resistance gene from the streptococcal plasmid pGB301 as a selectable marker. The resulting 8.1-kbp plasmid, designated pVS34, was characterized further with respect to host range, potential cloning sites, and location of replication gene(s). In addition to lactococci, pVS34 transformed Lactobacillus plantarum and, at a very low frequency, Staphylococcus aureus but not Escherichia coli or Bacillus subtilis. The 4.1-kbp ClaI fragment representing lactococcal DNA in pVS34 contained unique restriction sites for HindIII, EcoRI, XhoII, and HpaII, of which the last three could be used for molecular cloning. A region necessary for replication was located within a 2.5-kbp fragment flanked by the EcoRI and ClaI restriction sites. A 3.8-kbp EcoRI fragment derived from a nisin resistance plasmid, pSF01, was cloned into the EcoRI site of pVS34 to obtain a nisin-chloramphenicol double-resistance plasmid, pVS39. From this plasmid, the streptococcal chloramphenicol resistance region was subsequently eliminated. The resulting plasmid, pVS40, contains only lactococcal DNA. Potential uses for this type of a nisin resistance plasmid are discussed.     

Characterization of two nisin-producing Lactococcus lactis subsp. lactis strains isolated from a commercial sauerkraut fermentation.

Two Lactococcus lactis subsp. lactis strains, NCK400 and LJH80, isolated from a commercial sauerkraut fermentation were shown to produce nisin. LJH80 was morphologically unstable and gave rise to two stable, nisin-producing (Nip+) derivatives, NCK318-2 and NCK318-3. NCK400 and derivatives of LJH80 exhibited identical morphological and metabolic characteristics, but could be distinguished on the basis of plasmid profiles and genomic hybridization patterns to a DNA probe specific for the iso-ISS1 element, IS946. NCK318-2 and NCK318-3 harbored two and three plasmids, respectively, which hybridized with IS946. Plasmid DNA was not detected in NCK400, and DNA from this strain failed to hybridize with IS946. Despite the absence of detectable plasmid DNA in NCK400, nisin-negative derivatives (NCK402 and NCK403) were isolated after repeated transfer in broth at 37 degrees C. Nisin-negative derivatives concurrently lost the ability to ferment sucrose and became sensitive to nisin. A 4-kbp HindIII fragment containing the structural gene for nisin (spaN), cloned from L. lactis subsp. lactis ATCC 11454, was used to probe genomic DNA of NCK318-2, NCK318-3, NCK400, and NCK402 digested with EcoRI or HindIII. The spaN probe hybridized to an 8.8-kbp EcoRI fragment and a 10-kbp HindIII fragment in the Nip+ sauerkraut isolates, but did not hybridize to the Nip- derivative, NCK402. A different hybridization pattern was observed when the same probe was used against Nip+ L. lactis subsp. lactis ATCC 11454 and ATCC 7962. These phenotypic and genetic data confirmed that unique Nip+ L. lactis subsp. lactis strains were isolated from fermenting sauerkraut.     

Characterization of two nisin-producing Lactococcus lactis subsp. lactis strains isolated from a commercial sauerkraut fermentation.

Two Lactococcus lactis subsp. lactis strains, NCK400 and LJH80, isolated from a commercial sauerkraut fermentation were shown to produce nisin. LJH80 was morphologically unstable and gave rise to two stable, nisin-producing (Nip+) derivatives, NCK318-2 and NCK318-3. NCK400 and derivatives of LJH80 exhibited identical morphological and metabolic characteristics, but could be distinguished on the basis of plasmid profiles and genomic hybridization patterns to a DNA probe specific for the iso-ISS1 element, IS946. NCK318-2 and NCK318-3 harbored two and three plasmids, respectively, which hybridized with IS946. Plasmid DNA was not detected in NCK400, and DNA from this strain failed to hybridize with IS946. Despite the absence of detectable plasmid DNA in NCK400, nisin-negative derivatives (NCK402 and NCK403) were isolated after repeated transfer in broth at 37 degrees C. Nisin-negative derivatives concurrently lost the ability to ferment sucrose and became sensitive to nisin. A 4-kbp HindIII fragment containing the structural gene for nisin (spaN), cloned from L. lactis subsp. lactis ATCC 11454, was used to probe genomic DNA of NCK318-2, NCK318-3, NCK400, and NCK402 digested with EcoRI or HindIII. The spaN probe hybridized to an 8.8-kbp EcoRI fragment and a 10-kbp HindIII fragment in the Nip+ sauerkraut isolates, but did not hybridize to the Nip- derivative, NCK402. A different hybridization pattern was observed when the same probe was used against Nip+ L. lactis subsp. lactis ATCC 11454 and ATCC 7962. These phenotypic and genetic data confirmed that unique Nip+ L. lactis subsp. lactis strains were isolated from fermenting sauerkraut.     

Genetic construction of nisin-producing Lactococcus lactis subsp. cremoris and analysis of a rapid method for conjugation.

Conjugation was used to construct nisin-producing Lactococcus lactis subsp. cremoris strains. Recipients were obtained by electroporation of L. lactis subsp. cremoris strains with the drug resistance plasmid pGK13 or pGB301. A method, direct-plate conjugation, was developed in which donor and recipient cells were concentrated and then combined directly on selective media. This method facilitated transfer of the nisin-sucrose (Nip+ Suc+) phenotype from the donor strain, L. lactis subsp. lactis 11454, to three L. lactis subsp. cremoris recipient strains. Nip+ Suc+ L. lactis subsp. cremoris transconjugants were obtained at frequencies which ranged from 10(-7) to 10(-8) per donor CFU. DNA-DNA hybridization to transconjugant DNAs, performed with an oligonucleotide probe synthesized to detect the nisin precursor gene, showed that this gene was transferred during conjugation but was not associated with detectable plasmid DNA. Further investigation indicated that L. lactis subsp. cremoris Nip+ Suc+ transconjugants retained the recipient strain phenotype with respect to bacteriophage resistance and acid production in milk. Results suggested that it would be feasible to construct nisin-producing L. lactis subsp. cremoris strains for application as mixed and multiple starter systems. Additionally, the direct-plate conjugation method required less time than filter or milk agar matings and may also be useful for investigations of conjugal mechanisms in these organisms.     

Genetic construction of nisin-producing Lactococcus lactis subsp. cremoris and analysis of a rapid method for conjugation

Conjugation was used to construct nisin-producing Lactococcus lactis subsp. cremoris strains. Recipients were obtained by electroporation of L. lactis subsp. cremoris strains with the drug resistance plasmid pGK13 or pGB301. A method, direct-plate conjugation, was developed in which donor and recipient cells were concentrated and then combined directly on selective media. This method facilitated transfer of the nisin-sucrose (Nip+ Suc+) phenotype from the donor strain, L. lactis subsp. lactis 11454, to three L. lactis subsp. cremoris recipient strains. Nip+ Suc+ L. lactis subsp. cremoris transconjugants were obtained at frequencies which ranged from 10(-7) to 10(-8) per donor CFU. DNA-DNA hybridization to transconjugant DNAs, performed with an oligonucleotide probe synthesized to detect the nisin precursor gene, showed that this gene was transferred during conjugation but was not associated with detectable plasmid DNA. Further investigation indicated that L. lactis subsp. cremoris Nip+ Suc+ transconjugants retained the recipient strain phenotype with respect to bacteriophage resistance and acid production in milk. Results suggested that it would be feasible to construct nisin-producing L. lactis subsp. cremoris strains for application as mixed and multiple starter systems. Additionally, the direct-plate conjugation method required less time than filter or milk agar matings and may also be useful for investigations of conjugal mechanisms in these organisms.     

Identification and characterization of a mobilizing plasmid, pND300, in Lactococcus lactis M189 and its encoded nisin resistance determinant

A 60 kb conjugative plasmid, pND300, which encodes nisin resistance, was identified in Lactococcus lactis ssp. lactis (L. lactis ) M189. pND300 was found to mobilize the transfer of some other plasmids as indicated by the mobilization of plasmids encoding lactose utilization. The nisin resistance determinant from pND300 was initially subcloned on a 12 kb DNA fragment and subsequently reduced to 10.4 kb. Restriction analysis, PCR, Southern hybridization and sequencing illustrated that the nisin resistance of pND300 is very similar to that encoded by the transposon involved in nisin production. pND300 encodes nis R. as well as nis K and the recently reported nis F, nis E and nis G, but does not encode nis I. The DNA fragment encoding the nis genes is flanked by IS946 with a copy at each end in reverse orientation. The expression of these nis genes is probably controlled by a putative promoter upstream of nis R, which is composed of the TTGCAA hexanucleotide on the insertion sequence IS 946 and the TATAAT sequence 21 bp downstream.     

Novel paired starter culture system for sauerkraut, consisting of a nisin-resistant Leuconostoc mesenteroides strain and a nisin-producing Lactococcus lactis strain.

Nisin-resistant Leuconostoc mesenteroides NCK293 and nisin-producing Lactococcus lactis subsp. lactis NCK401 were evaluated separately and in combination for growth and nisin production in a model sauerkraut fermentation. Strains were genetically marked and selectively enumerated by using antibiotic-containing media. The growth and survival of L. mesenteroides were similar in the presence and absence of Lactococcus lactis subsp. lactis. The growth of Lactococcus lactis subsp. lactis was not inhibited, although the maximum cell density was reduced and the population decline was more pronounced in the presence of L. mesenteroides. Nisin was detected within 24 h, and levels were relatively constant over the 12-day test period. The maximum cell populations and nisin level achieved could be altered by changing the initial cell ratios of L. mesenteroides and lactococcus lactis subsp. lactis. Isogenic nisin-producing and nisin-negative Lactococcus lactis subsp. lactis derivatives were used in combination with nisin-resistant L. mesenteroides to demonstrate that nisin levels produced in mixed culture were sufficient to retard the onset of the growth of nisin-sensitive, homofermentative Lactobacillus plantarum ATCC 14917.     

Novel paired starter culture system for sauerkraut, consisting of a nisin-resistant Leuconostoc mesenteroides strain and a nisin-producing Lactococcus lactis strain.

Nisin-resistant Leuconostoc mesenteroides NCK293 and nisin-producing Lactococcus lactis subsp. lactis NCK401 were evaluated separately and in combination for growth and nisin production in a model sauerkraut fermentation. Strains were genetically marked and selectively enumerated by using antibiotic-containing media. The growth and survival of L. mesenteroides were similar in the presence and absence of Lactococcus lactis subsp. lactis. The growth of Lactococcus lactis subsp. lactis was not inhibited, although the maximum cell density was reduced and the population decline was more pronounced in the presence of L. mesenteroides. Nisin was detected within 24 h, and levels were relatively constant over the 12-day test period. The maximum cell populations and nisin level achieved could be altered by changing the initial cell ratios of L. mesenteroides and lactococcus lactis subsp. lactis. Isogenic nisin-producing and nisin-negative Lactococcus lactis subsp. lactis derivatives were used in combination with nisin-resistant L. mesenteroides to demonstrate that nisin levels produced in mixed culture were sufficient to retard the onset of the growth of nisin-sensitive, homofermentative Lactobacillus plantarum ATCC 14917.