Protective mechanism of Lactobacillus casei ATCC393 against multiple stresses by proteomics analysis

为考察干酪乳杆菌典型株ATCC 393在交互胁迫环境下的生理应答机制,应用二维电泳和iTRAQ技术在蛋白水平上比较了交互胁迫前后干酪乳杆菌蛋白质组的变化情况.在对不同处理条件下细胞全蛋白的二维电泳分析中发现,干酪乳杆菌的主要蛋白分布在等电点pI 4～7的范围,经酸预适应处理后细胞的蛋白表达产生了较大的变化.通过iTRAQ技术对细胞在酸适应前后以及相应致死条件下蛋白表达的定性及相对定量分析得知,酸诱导所产生的热胁迫应激蛋白( dna K,dna J等)、氧胁迫应激蛋白(mut S,rec O)以及与代谢相关的酶类上调可能是提高细胞对交互胁迫耐受能力的主要原因,而酸适应后GTP环化水解酶Ⅰ和GMP合成酶的高表达可能与这一过程的诱导有关.上述研究结果为提高工业生产菌株在发酵生产及加工过程中对外界不利环境的抵御能力,进而通过调控与微生物生理应答机制密切相关的功能元器件实现生产菌株的性能强化提供了重要的生物信息和可借鉴的研究思路.     

应用双向荧光差异凝胶技术解析干酪乳杆菌Lactobacillus casei Zhang驯化菌株耐酸胁迫机制

以干酪乳杆菌Lactobacillus casei Zhang为出发菌株,通过适应性进化获得了干酪乳杆菌酸胁迫抗性驯化菌株.对细胞内微环境的检测发现,驯化菌株在酸胁迫过程中能够维持较高的磷酸烯醇式丙酮酸-糖转移酶系统活力,并具有较高的H+ -ATPase活性以及胞内ATP浓度.蛋白质组学分析结果表明,酸胁迫引发了细胞蛋白表达的变化,与原始菌株相比,驯化菌株保持了更高的代谢活性;同时,驯化菌株通过大量诱导应激蛋白如分子伴侣GroEL、GrpE,冷/热应激蛋白CspC、DnaK等维持了细胞的生理活性,有效提高了细胞对酸胁迫的抵御能力.本研究为进一步揭示酸胁迫下乳酸菌细胞的生理应答机制,探寻促进乳酸菌酸胁迫性能提升的最优策略,进而改善其在生产中的应用性能提供了可借鉴的思路.     

交互保护对干酪乳杆菌ATCC 393~(TM)存活的影响

【目的】以干酪乳杆菌典型株ATCC 393TM(Lactobacillus casei ATCC 393TM)为实验菌株,研究其在多重胁迫环境下的交互保护应答机制。【方法】比较不同亚适应条件(热、H2O2、酸、胆盐)处理后菌体细胞在热致死条件(60℃)及氧致死条件H2O2(5mmol/L)下的存活率变化,并集中考察了最佳亚适应条件-酸适应的不同处理方式对细胞交互保护存活率、胞内pH以及脂肪酸含量的影响。【结果】交互保护对干酪乳杆菌ATCC393生理活性的影响因亚适应及致死条件而异:酸胁迫预适应能够显著提高细胞的交互胁迫抗性,其中,盐酸预适应的交互保护效果优于乳酸,其预适应引发的生理应答效应使细胞在应对热致死和氧致死胁迫时存活率分别提高了305倍和173倍;进一步的研究表明,酸预适应提高细胞存活率的作用机制可能与其能够显著改善胁迫环境下的胞内pH和细胞膜脂肪酸不饱和度相关。【结论】盐酸预适应对干酪乳杆菌典型株ATCC393的交互保护作用最为显著,并能够维持胁迫条件下细胞生理状态的相对稳定,本研究将有助于进一步解析干酪乳杆菌在对抗不同胁迫环境的过程中生理应答机制间的相互作用关系。     

酸胁迫下琥珀酸放线杆菌的生理及转录应答

【目的】通过琥珀酸放线杆菌Actinobacillus succinogenes CGMCC1593对酸胁迫的生理应答和转录组学分析,探究琥珀酸放线杆菌酸胁迫的机制。【方法】测定不同pH对细胞生长、H+-ATPase、细胞内pH的影响;测定酸胁迫前后细胞膜和谷氨酸脱氢酶的变化、谷氨酸对琥珀酸放线杆菌生长的影响;通过RNA-seq测序分析酸胁迫条件下的差异表达基因。【结果】随pH值的降低,细胞生长受抑制,H+-ATPase的活性下降。pH 4.7酸胁迫后,细胞膜受到严重损伤,谷氨酸对酸胁迫后的细胞有保护作用,GDH酶活响应酸胁迫后略有增加。酸胁迫后,39个基因差异表达较为显著,其中49%基因属于应激蛋白、转运蛋白,小部分基因与代谢相关。【结论】本文探究了琥珀酸放线杆菌酸胁迫下的生理及转录应答,研究结果可为寻找增强琥珀酸放线杆菌耐酸性策略提供参考。     

表面表达猪流行性腹泻病毒核蛋白蛋白的重组干酪乳杆菌诱导产生的免疫应答

为探讨表达猪流行性腹泻病毒(PEDV)核蛋白(N)基因的重组干酪乳杆菌口服免疫小鼠后诱导特异性免疫应答,本研究制备表达流行性腹泻病毒核蛋白的重组干酪乳杆菌,应用Western blotting、间接免疫荧光和全细胞ELISA鉴定目的蛋白的表达。然后用该重组干酪乳杆菌口服免疫BALB/c小鼠,分别测定了免疫后不同时间血清中特异性IgG、粪便中特异性的sIgA水平以及血清的中和活性;并测定免疫小鼠脾淋巴细胞增殖情况和细胞因子水平。结果显示,目的蛋白表达在细胞表面,可被阳性血清所识别。免疫小鼠后,可分别在血清中和粪便中检测到较高水平特异性IgG、sIgA(P<0.01),但血清并没有中和活性;淋巴细胞增殖试验和细胞因子测定结果显示,免疫组可产生明显的细胞免疫应答。结果表明,该重组干酪乳杆菌表达系统可诱导小鼠产生黏膜免疫应答和系统免疫应答,具有作为口服疫苗潜在的应用价值。     

重组粪肠球菌gshF基因对副干酪乳杆菌(Lactobacillus paracasei)L14抗逆性能的影响

乳酸菌作为重要的食品工业微生物,其在工业生产应用过程中会受到多种非生物胁迫。已有研究表明部分乳酸菌可以吸收培养基中或是自身合成谷胱甘肽(Glutathione,GSH),提高对各种胁迫的抵抗作用。克隆了粪肠球菌(Enterococcus faecalis)中的谷胱甘肽合成酶基因gshF,通过构建乳杆菌重组表达质粒,实现了gshF在副干酪乳杆菌(Lactobacillus paracasei)L14菌株中的异源表达。通过对重组gshF-副干酪乳杆菌阳性菌株的抗逆性性测定,结果表明在过氧化氢、酸、冻干脱水和渗透等胁迫条件下,gshF重组菌株的存活率与对照菌株相比均有显著提高。     

酸适应对一株乳酸乳球菌膜脂肪酸组成和膜蛋白表达的影响

[目的]筛选具有较强酸适应能力的菌株,研究酸适应对其膜脂肪酸组成和膜蛋白表达的影响.[方法]从20株菌中筛选出一株具有较强酸适应能力的乳酸乳球菌KLDS4.0312,以GC-MS法测定该菌酸适应前后膜脂肪酸组成变化;对酸适应前后该菌膜蛋白的差异表达进行双向电泳分析.[结果]酸适应后,该菌膜不饱和脂肪酸含量从30.77%上升到42.93%,饱和脂肪酸含量从69.23%下降到57.07%,且有一种新的长链单不饱和脂肪酸C<,19:1>-n6被诱导产生.酸适应过程中至少有65个蛋白质点表达出现显著差异,其中上调的蛋白质点有43个,减弱表达的蛋白质点有22个.而添加氯霉素后,菌株的酸适应能力消除,可能与氯霉素抑制新蛋白的合成有关.[结论]说明细胞膜脂肪酸组成的适应性改变和应激蛋白的诱导产生是该菌主要的酸适应机制.     

猪细小病毒VP2蛋白在干酪乳杆菌表面的表达

将编码猪细小病毒主要免疫保护性抗原VP2基因插入干酪乳杆菌细胞表面表达载体pPG中,构建了重组表达载体pPG-VP2,将其电转化干酪乳杆菌Lactobacillus casei 393,获得了表达猪细小病毒VP2蛋白的重组干酪乳杆菌系统,经2%乳糖在MRS培养基中的诱导表达,SDS-PAGE检测表明,有约74kD蛋白得到了表达,表达蛋白的大小与理论值相符。Western-blot结果分析表明,表达的蛋白可被鼠源PPV抗血清所识别,间接免疫荧光实验结果表明,所表达的蛋白能够在干酪乳杆菌菌体表面检测到。     

酸胁迫下短乳杆菌NCL912蛋白质的差异表达及其作用

【目的】本文从蛋白质组水平,对本实验室分离的一株高产γ-氨基丁酸的短乳杆菌NCL912(Lactobacillus brevis)在酸胁迫下蛋白质的差异表达及其应激机理进行探讨。【方法】利用双向凝胶电泳技术对pH 5.0和pH 4.0条件下,不含L-谷氨酸钠的培养物的蛋白质组电泳图谱进行了分析,并对酸胁迫下差异表达的蛋白进行了比较。利用质谱检测技术和生物信息学技术对这些差异表达的蛋白进行了鉴定、功能分类和代谢途径分析等。【结果】通过双向凝胶电泳技术,可以得到均匀、背景清晰、分辨率高、重复性好的Lb.brevis NCL912的双向凝胶电泳图谱。对pH 5.0和pH 4.0条件下培养的该菌总蛋白质电泳图谱进行比较,发现有25个差异表达的蛋白点。对这25个差异表达的蛋白进行了质谱鉴定。由于缺乏短乳杆菌NCL912的全基因组,所以其中只有8个蛋白点被质谱鉴定和分析得到。它们分别参与了蛋白质的合成、核苷酸的合成、糖酵解代谢、细胞能量水平的调节等。【结论】酸应激下这些表达蛋白质可通过其相应的功能来保护细胞耐受酸胁迫,从而使菌能够在酸性环境下生存增值。这可能就是Lb.brevis NCL912的酸胁迫应激机理之一。     

乳酸菌表面蛋白对免疫细胞的诱导增殖及粘附抑制效应

目的研究表面蛋白在乳酸菌体外粘附和激活免疫细胞中的作用。方法应用5mol/L氯化锂结合盐酸胍提取植物乳杆菌LpYZU09、干酪乳杆菌LcYZU02、鼠李糖乳杆菌LrGG、发酵乳杆菌LfYZU15及戊糖片球菌PpYZU32的表面蛋白,并分析提取物对乳酸菌粘附鼠肠上皮细胞、巨噬细胞和脾细胞的抑制作用及诱导增殖效应。结果表面蛋白对3种细胞粘附菌体均具有显著抑制效应,抑制作用具有细胞和菌株差异性,其中菌株LrGG表面蛋白对巨噬细胞粘附5种菌体普遍显示了较强的抑制作用,抑制率为38.7%~76.0%。不同菌株表面蛋白对肠上皮细胞的诱导增殖指数为0.05~0.35,对巨噬细胞为0.05~0.42,对脾细胞为0.02~0.40,诱导效应具有菌株和剂量依赖性,菌株LrGG的诱导增殖指数显著高于其他四种。结论乳酸菌表面的蛋白类因子在粘附和激活免疫细胞中发挥了重要作用。     

Rapid PCR-based procedure to identify lactic acid bacteria: application to six common Lactobacillus species

The goal of this study was to develop a method allowing rapid identification of the lactic acid bacteria strains in use in the laboratory (Lactobacillus plantarum NCIMB8826; L. fermentum KLD; L. reuteri 100-23; L. salivarius UCC43321; L. paracasei LbTGS1.4; L. casei ATCC393), based on PCR amplification of 16S RNA coding sequences. First, specific forward oligonucleotides were designed in the variable regions of 16S RNA coding sequences of six Lactobacillus strains. The reverse oligonucleotide was designed in the region where the sequences were homologous for the six strains. The expected size of the amplification product was +/-1000 bp. The specificity of the method was tested on total chromosomal DNA. For five out of the six strains, the amplification of the fragment was strain-specific and the method was directly applicable to colonies. For the strain L. casei ATCC393, an additional argument to the classification of this bacteria in the paracasei group could be proposed. Validation of the developed method was performed by applying it to six Lactobacillus reference strains and to various species of bacteria.     

Ribotyping ofLactobacillus casei group strains isolated from dairy products

A series of lactobacilli isolated from dairy products were characterized using biotyping and ribotyping with EcoRI and HindIII restriction enzymes. Biotyping assigned 14 strains as Lactobacillus casei, 6 strains as Lactobacillus paracasei subsp. paracasei and 12 as Lactobacillus rhamnosus. The obtained ribotype patterns separated all analyzed strains into two clearly distinguished groups corresponding to L. rhamnosus and L. casei/L. paracasei subsp. paracasei. The HindIII ribotypes of individual strains representing these two groups were visually very similar. In contrast, EcoRI ribotyping revealed high intraspecies variability. All ribotypes of L. casei and L. paracasei subsp. paracasei dairy strains were very close and some strains even shared identical ribotype profiles. The type strains L. casei CCM 7088T (= ATCC 393T) and Lactobacillus zeae CCM 7069T revealing similar ribopatterns formed a separate subcluster using both restriction enzymes. In contrast, the ribotype profile of L. casei CCM 7089 (= ATCC 334) was very close to ribopatterns obtained from the dairy strains. These results support synonymy of L. casei and L. paracasei species revealed by other studies as well as reclassification of the type strain L. casei CCM 7088T as L. zeae and designation of L. casei CCM 7089 as the neotype strain.     

Effect of probiotic-fermented milk administration on gastrointestinal survival of Lactobacillus casei ATCC 393 and modulation of intestinal microbial flora

The aim of the present study was to assess the survival of free and immobilized Lactobacillus casei ATCC 393 on apple pieces, contained in probiotic-fermented milk, after gastrointestinal (GI) transit and to investigate the potential regulation of intestinal microbial flora in a rat model. In in vitro GI stress tolerance tests, immobilized L. casei ATCC 393 exhibited significantly higher survival rates compared to free cells. At a second stage, probiotic-fermented milk produced by either free or immobilized cells was administered orally at a single dose or daily for 9 days in Wistar rats. By 12 h after single-dose administration, both free and immobilized cells were detected by microbiological and molecular analysis at levels ≥6 logCFU/g of feces. Moreover, daily administration led to significant reduction of staphylococci, enterobacteria, coliforms and streptococci counts. In conclusion, L. casei ATCC 393 contained in fermented milk survived GI transit and modulated intestinal microbiota.     

Taxonomic and strain-specific identification of the probiotic strain Lactobacillus rhamnosus 35 within the Lactobacillus casei group

Lactobacilli are lactic acid bacteria that are widespread in the environment, including the human diet and gastrointestinal tract. Some Lactobacillus strains are regarded as probiotics because they exhibit beneficial health effects on their host. In this study, the long-used probiotic strain Lactobacillus rhamnosus 35 was characterized at a molecular level and compared with seven reference strains from the Lactobacillus casei group. Analysis of rrn operon sequences confirmed that L. rhamnosus 35 indeed belongs to the L. rhamnosus species, and both temporal temperature gradient gel electrophoresis and ribotyping showed that it is closer to the probiotic strain L. rhamnosus ATCC 53103 (also known as L. rhamnosus GG) than to the species type strain. In addition, L. casei ATCC 334 gathered in a coherent cluster with L. paracasei type strains, unlike L. casei ATCC 393, which was closer to L. zeae; this is evidence of the lack of relatedness between the two L. casei strains. Further characterization of the eight strains by pulsed-field gel electrophoresis repetitive DNA element-based PCR identified distinct patterns for each strain, whereas two isolates of L. rhamnosus 35 sampled 40 years apart could not be distinguished. By subtractive hybridization using the L. rhamnosus GG genome as a driver, we were able to isolate five L. rhamnosus 35-specific sequences, including two phage-related ones. The primer pairs designed to amplify these five regions allowed us to develop rapid and highly specific PCR-based identification methods for the probiotic strain L. rhamnosus 35.     

Production of a heterologous nonheme catalase by Lactobacillus casei: an efficient tool for removal of H2O2 and protection of Lactobacillus bulgaricus from oxidative stress in milk

Lactic acid bacteria (LAB) are generally sensitive to H2O2, a compound that they can paradoxically produce themselves, as is the case for Lactobacillus bulgaricus. Lactobacillus plantarum ATCC 14431 is one of the very few LAB strains able to degrade H2O2 through the action of a nonheme, manganese-dependent catalase (hereafter called MnKat). The MnKat gene was expressed in three catalase-deficient LAB species: L. bulgaricus ATCC 11842, Lactobacillus casei BL23, and Lactococcus lactis MG1363. While the protein could be detected in all heterologous hosts, enzyme activity was observed only in L. casei. This is probably due to the differences in the Mn contents of the cells, which are reportedly similar in L. plantarum and L. casei but at least 10- and 100-fold lower in Lactococcus lactis and L. bulgaricus, respectively. The expression of the MnKat gene in L. casei conferred enhanced oxidative stress resistance, as measured by an increase in the survival rate after exposure to H2O2, and improved long-term survival in aerated cultures. In mixtures of L. casei producing MnKat and L. bulgaricus, L. casei can eliminate H2O2 from the culture medium, thereby protecting both L. casei and L. bulgaricus from its deleterious effects.     

Effects of Lactobacillus strains on cancer cell proliferation and oxidative stress in vitro

AIMS: The objective of this study was to assess in vitro, whether heat-killed (HK) lactic acid bacteria cells and fractionations of HK cells could suppress the viability of human cancer cells and inhibit the cytotoxicity associated with oxidative stress. METHODS AND RESULTS: Among the strains, the HK cells of Lactobacillus acidophilus 606 and Lactobacillus casei ATCC 393 exhibited the most profound inhibitory activity in all of the tested cell lines. HK cells of L. acidophilus 606 were determined to be less toxic to healthy human embryo fibroblasts (hEF cells) than were HK cells of L. casei ATCC 393. The soluble polysaccharides from L. acidophilus 606 evidenced the most effective anticancer activity, but inhibited hEF cell growth by only 20%. The soluble polysaccharides from L. acidophilus 606 were partly observed to induce apoptosis in the HT-29 cells by DNA fragmentation and propidium iodine staining. Both the HK cells of L. acidophilus 606 and the soluble polysaccharide components of this strain also exhibited potent antioxidative activity. CONCLUSIONS: Our findings suggest that the soluble polysaccharide fraction from L. acidophilus 606 may constitute a novel anticancer agent, which manifests a high degree of selectivity for human cancer cells and antioxidative agent in the food industry. SIGNIFICANCE AND IMPACT OF THE STUDY: These soluble polysaccharide components from Lactobacillus may be applied to various foods, and used as adjuncts for cancer therapy and prevention.     

Generation of food-grade recombinant lactic acid bacterium strains by site-specific recombination

The construction of a delivery and clearing system for the generation of food-grade recombinant lactic acid bacterium strains, based on the use of an integrase (Int) and a resolvo-invertase (beta-recombinase) and their respective target sites (attP-attB and six, respectively) is reported. The delivery system contains a heterologous replication origin and antibiotic resistance markers surrounded by two directly oriented six sites, a multiple cloning site where passenger DNA could be inserted (e.g., the cI gene of bacteriophage A2), the int gene, and the attP site of phage A2. The clearing system provides a plasmid-borne gene encoding beta-recombinase. The nonreplicative vector-borne delivery system was transformed into Lactobacillus casei ATCC 393 and, by site-specific recombination, integrated as a single copy in an orientation- and Int-dependent manner into the attB site present in the genome of the host strain. The transfer of the clearing system into this strain, with the subsequent expression of the beta-recombinase, led to site-specific DNA resolution of the non-food-grade DNA. These methods were validated by the construction of a stable food-grade L. casei ATCC 393-derived strain completely immune to phage A2 infection during milk fermentation.     

Lactobacillus casei, Lactobacillus rhamnosus, and Lactobacillus zeae isolates identified by sequence signature and immunoblot phenotype

Species taxonomy within the Lactobacillus casei group of bacteria has been unsettled. With the goal of helping clarify the taxonomy of these bacteria, we investigated the first 3 variable regions of the 16S rRNA gene, the 16S-23S rRNA interspacer region, and one third of the chaperonin 60 gene for Lactobacillus isolates originally designated as L. casei, L. paracasei, L. rhamnosus, and L. zeae. For each genetic region, a phylogenetic tree was created and signature sequence analysis was done. As well, phenotypic analysis of the various strains was performed by immunoblotting. Both sequence signature analysis and immunoblotting gave immediate identification of L. casei, L. rhamnosus, and L. zeae isolates. These results corroborate and extend previous findings concerning these lactobacilli; therefore, we strongly endorse recent proposals for revised nomenclature. Specifically, isolate ATCC 393 is appropriately rejected as the L. casei type strain because of grouping with isolates identified as L. zeae. As well, because all other L. casei isolates, including the proposed neotype isolate ATCC 334, grouped together with isolates designated L. paracasei, we support the use of the single species L. casei and rejection of the name L. paracasei.