白念珠菌翻译起始因子蛋白Ca-tif1的表达和纯化

本文构建了白色念珠菌体内翻译起始因子Ca-tif1的原核表达载体,纯化Ca-tif1蛋白,并测定其ATP酶活性。采用化学合成Ca-tif1序列片段,酶切并与p ET28a载体对应位点连接,连接后载体转化BL21感受态细胞,IPTG诱导Ca-tif1表达,用镍离子亲和层析柱纯化目的蛋白,并采用孔雀绿-磷钼酸分光光度法测定目的蛋白ATP酶活性。结果显示,根据大肠杆菌密码子偏好性进行密码子优化的重组质粒p ET-28a-Ca-tif1顺利表达可溶性的目的蛋白Ca-tif1,每升大肠杆菌表达产物经纯化后得到Ca-tif1 7.0 mg,纯化后的Ca-tif1具有ATP酶活性,1.25×106U/mg。通过成功构建白色念珠菌翻译起始因子Ca-tif1的原核表达载体p ET-28a-Ca-tif1,高效表达并纯化了Ca-tif1,经测定Ca-tif1具有ATP酶活性,为基于白色念珠菌翻译起始因子的一系列研究奠定了基础。     

克隆、表达及纯化核糖体蛋白S6用于体外激酶活性检测

目的:构建40S核糖体蛋白S6的原核表达载体,表达并纯化S6蛋白,将其作为底物用于S6激酶(S6K)的体外活性测定。方法:采用RT-PCR方法从人胚肾细胞HEK293中获取S6 cDNA,将扩增产物克隆至大肠杆菌表达载体中,进行酶切及测序鉴定;IPTG诱导GST-S6融合蛋白在大肠杆菌中表达,用谷胱甘肽亲和层析纯化GST-S6,免疫沉淀法检测该蛋白是否可作为底物用于S6K的体外激酶活性测定。结果:酶切及测序鉴定表明构建了S6原核表达载体,并表达及纯化出GST-S6融合蛋白,相对分子质量为55×103。该蛋白可用于S6K的体外激酶活性测定,特异性强。结论:S6蛋白的克隆、表达与纯化成功,可用于S6K的体外激酶活性测定,为研究S6K的功能奠定了基础。     

异源表达的幽门螺杆菌cag4蛋白有溶菌糖基转移酶活性

摘要【目的】构建融合基因原核表达载体pET-28a- cag4,并表达重组融合蛋白cag4,分析重组融合蛋白的酶活性,为新型抗生素（或是抗菌药物）的研发提供作用靶位。【方法】本研究利用PCR技术从幽门螺杆菌NCTC11637中克隆了cag4基因;经T-A克隆,酶切鉴定,构建了原核表达载体pET-28a- cag4;经测序鉴定正确后,转化进入大肠埃希菌 BL21(DE3)进行异源表达。利用IPTG体外诱导后,经SDS-PAGE和Western Bolt鉴定目的蛋白表达后,采用Ni2＋-NTA柱在变性条件下纯化目的蛋白,并对重组蛋白进行透析复性处理。将SDS煮沸法获得的溶壁微球菌肽聚糖掺入SDS-PAGE作为底物,进行酶谱分析。【结果】在大肠埃希菌 BL21(DE3)中获得高效表达的重组蛋白; 经SDS-PAGE和Western Bolt鉴定表达后,采用Ni2＋-NTA柱在变性条件下纯化,并进行透析复性处理。将SDS煮沸法获得的溶壁微球菌肽聚糖掺入SDS-PAGE作为底物,进行酶谱分析,表明目的蛋白具有明显的肽聚糖水解活性; 通过监测浊度下降速率,比较其在不同pH条件下活性的变化,即?A/（min?mg protein）,结果表明,幽门螺杆菌cag4蛋白具有溶菌糖基转移酶活性。【结论】幽门螺杆菌cag4蛋白具有溶菌糖基转移酶活性。     

幽门螺杆菌CagA蛋白N端片段的表达、纯化及其与磷脂酰丝氨酸的亲和力检测

目的:表达和纯化幽门螺杆菌不同菌株的CagA蛋白N端片段,检测其与磷脂酰丝氨酸(PS)的相互作用及亲和力。方法:用PCR方法从幽门螺杆菌3个菌株中扩增出CagA蛋白N端基因,并连接到表达载体pET-28a上;转化大肠杆菌BL21,经IPTG诱导可溶性表达CagA蛋白N端880残基片段;经镍柱亲和纯化后,利用PLOA法检测CagA蛋白与PS的相互作用。结果:构建了3种幽门螺杆菌菌株cagA基因的原核表达质粒pET-28a/cagAJ99、pET-28a/cagA11637及pET-28a/cagASS1,并在大肠杆菌中获得可溶性表达,SDS-PAGE和Western印迹证实得到目标融合蛋白,亲和纯化得到高纯度CagA蛋白。PLOA结果表明,CagA蛋白与PS有明显的相互作用。结论:3种幽门螺杆菌菌株CagA蛋白与PS之间存在相互作用,且不同的CagA与PS有不同的亲和力。     

幽门螺杆菌cagA克隆表达

克隆表达4株幽门螺杆菌的cagA基因,以方便地获得大鼠CagA蛋白和重组表达质粒,为临床诊断CagA阳性幽门螺杆菌感染,以及进一步研究不同类型CagA功能及其与疾病关系提供材料。PCR扩增幽门螺杆菌的cagA基因,克隆至PinPoint^TMXa-1T载体,酶切鉴定连接方向,IPTG诱导正向连接克隆表达CagA融合蛋白并进行SDS－PAGE和Western blots鉴定。结果显示PCR扩增得到3.5-3.8kb的CagA基因,PCR及酶切鉴定得到正向连接的重组克隆,SDS－PAGE及Western blots证实正向连接的重组克隆表达CagA融合蛋白。构建了4种cagA的重组表达质粒,通过转化同一宿主菌可研究不同CagA的功能和致病性差异;通过亲和层析纯化融合蛋白可获大量CagA蛋白,用于血清学诊断CagA阳性幽门螺杆菌感染,及不同抗原性CagA与疾病之间的关系。     

高效表达幽门螺杆菌UreB重组蛋白工程菌的构建

克隆表达幽门螺杆菌(Hp)的尿素酶B亚单位(UreB)重组蛋白,可为Hp疫苗开发和快速诊断试剂盒的研究奠定基础。用PCR方法由幽门螺杆菌染色体DNA扩增UreB基因片段,将其融合插入原核表达载体pQE30中,并在M15大肠杆菌表达。经酶切、测序分析,包括部分融合载体基因在内的重组UreB基因片段由1773bp组成。为编码591个氨基酸残基的多肽。SDS-PAGE分析显示重组表达的目的蛋白相对分子量约为66kD,表达量点菌体总蛋白的23．5％,并经免疫印迹分析证实被幽门螺杆菌感染的阳性血清可与纯化UreB重组蛋白发生特异性的结合反应。UreB重组蛋白具有良好的抗原性,将有可能成为一种有效蛋白质疫苗以及快速诊断试剂盒用于Hp感染的防治和检测。     

人GST-14-3-3σ融合蛋白的原核表达、纯化及活性检测

目的:构建人14-3-3σ基因的原核表达载体,获得其原核表达产物,并对融合蛋白进行纯化及活性检测。方法:采用PCR技术从人乳腺文库中扩增14-3-3σ基因编码序列,将其克隆到pGEX-KG载体中,重组质粒转化大肠杆菌Rossate后表达重组蛋白,利用GST-Sepharose 4B亲和珠对原核表达产物进行纯化,并通过SDS-PAGE和Western印迹检测融合蛋白的表达,采用GST pull-down技术检测已纯化的蛋白与已知体外相互作用蛋白AKT之间的相互作用。结果:从人乳腺文库中扩增获得约750 bp的DNA片段,并成功克隆至pGEX-KG载体上,经双酶切鉴定得到与预期片段大小相符的外源基因插入片段,测序与目的基因序列完全一致;在Rossate菌株中诱导表达出相对分子质量约52 000的目的蛋白,SDS-PAGE和Western印迹结果表明融合蛋白表达成功,并纯化得到GST-14-3-3σ融合蛋白;通过GST pull-down技术检测证实GST-14-3-3σ融合蛋白可以和AKT在体外结合,并证实其具有生物学活性。结论:获得了原核表达的活性较好的GST-14-3-3σ蛋白,为后续研究细胞周期蛋白调控机制奠定了实验基础。     

HCV丝氨酸蛋白酶小分子底物构建及GST融合表达

丝氨酸蛋白酶是丙型肝炎病毒重要的功能蛋白和药物作用靶点,其通过分子内（cis）和分子间（trans）方式催化水解前体蛋白,释放病毒功能蛋白。目的：为深入研究病毒蛋白酶活性和抑制剂鉴定需要,实验研究参照丙型肝炎病毒1a亚型菌株蛋白酶天然底物的氨基酸序列特点,设计了一段包含两个天然底物酶切位点的小分子多肽2S,并进行了原核表达。方法：利用PCR方法,合成2S小分子多肽基因,目的基因两端引入BamH I和EcoR I两个限制性酶切位点,双酶切后将基因与表达载体pGEX-4T-2重组,转化大肠杆菌DH5α,经化学诱导进行GST融合蛋白表达,通过亲和层析柱纯化目的蛋白。纯化的GST 2S融合蛋白在体外反应系统进行酶切鉴定,SDS-PAGE和ELISA鉴定酶切结果。结果：PCR合成的小分子底物多肽2S基因,经与表达载体重组后测序,证实基因序列正确。采用0.5mmol/L浓度的IPTG诱导工程菌过夜,获得表达的目的蛋白,经分离纯化得到融合蛋白GST-2S。GST-2S在体外磷酸盐缓冲系统中与丝氨酸蛋白酶反应,15%SDS-PAGE鉴定酶切产物,证实融合蛋白底物条带明显消失,ELISA结果同样说明融合蛋白的底物活性。结论：含有两个天然底物酶切位点的小分子多肽可以替代病毒天然底物,实验结果为丙型肝炎病毒丝氨酸蛋白酶活性研究和酶抑制剂研究奠定了方法学基础。     

靶向抗肿瘤蛋白iRGD-CDD的原核表达及生物活性鉴定

目的: 原核表达并纯化具有特异性成纤维细胞激活蛋白(FAPα)酶切位点的靶向抗肿瘤GP-CDD-iRGD融合蛋白,利用FAPα的酶切功能切除融合标签,检测其对FAPα阳性肿瘤细胞株的毒性。方法: 设计并合成GP-CDD-iRGD基因,插入pGEX-4T3 载体,构建重组表达质粒,转化至BL21大肠杆菌感受态细胞中,IPTG诱导表达,SDS-PAGE分析重组融合蛋白的表达,Western blot检测融合蛋白的表达,经GST亲和柱纯化融合蛋白后,通过体外细胞毒性试验(MTT法)和细胞凋亡实验评价该融合蛋白的靶向抗肿瘤活性。结果: 成功构建重组原核表达质粒pGEX-GP-CDD-iRGD,可溶性表达相对分子量约为36 kDa的融合蛋白GST-GP-CDD-iRGD,纯化后蛋白纯度约为90%,经MTT实验测定其对FAPα阳性4T1细胞株的ED50约为18.5μmol/L,流式细胞术检测到其对FAPα阳性4T1细胞株具有选择性毒性作用,早期凋亡比例达到约28%。结论: 原核表达的重组融合蛋白GP-CDD-iRGD对FAPα阴性4T1细胞株未显示毒性,而对FAPα阳性4T1细胞株具有显著的促凋亡作用,为进一步研究其在体内的靶向抗肿瘤活性提供了依据。     

人类肠道病毒68型3A蛋白可溶区的表达及其结构初步研究

为了解人类肠道病毒68型3A蛋白可溶区的结构,本研究构建了EV-D68 3A蛋白可溶区的原核表达载体,在大肠杆菌中表达、纯化并对其结构进行了初步研究。首先,采用PCR的方法扩增EV-D68 3A(1~61)基因片段,克隆至原核表达载体pET-28a-His-SUMO中,转化进入BL21(DE3)感受态细胞,诱导表达出His-SUMO-3A(1~61)融合蛋白。经Ni-NTA树脂亲和层析初步纯化后得到大量融合蛋白,利用ULP酶酶切去除His-SUMO标签,通过Ni-NTA树脂亲和层析、阴离子交换层析柱、分子筛层析等方法分离标签并进一步纯化目的蛋白。最后通过化学交联反应检测目的蛋白的多聚化状态。结果显示,利用pET28a-His-SUMO-3A(1~61)原核表达载体能够在大肠杆菌中成功表达出大量可溶性的融合蛋白;经过多步纯化方法得到了大量高纯度的目的蛋白,平均每升大肠杆菌可得到约5mg目的蛋白,纯度达95%以上;通过化学交联反应证明了该蛋白的多聚化存在形式。本研究成功建立了EV-D68 3A蛋白可溶区的表达和纯化系统,为进一步获得3A蛋白晶体、研究3A蛋白功能以及设计以3A为靶点的抗病毒药物奠定了基础。     

Different chain length specificity among three polyphosphate quantification methods

Polyphosphate is ubiquitous among living organisms and has a variety of biochemical functions. Arbuscular mycorrhizal fungi have been known to accumulate polyphosphate as a key compound for their function. However, an enzymatic assay using polyphosphate kinase (PPK) reverse reaction, in which polyphosphate is converted to adenosine triphosphate (ATP) and quantified by luciferase assay, failed to detect accumulation of polyphosphate in some mycorrhizal root. When yeast exopolyphosphatase (PPX) was applied to these samples, a much higher polyphosphate level was detected than when the PPK assay was applied. Detailed analysis of substrate chain length specificity of these methods using polyphosphate chain length standards revealed that the PPX method was the most appropriate to detect short-chain polyphosphate. The average chain length of the shortest polyphosphate fraction that could be quantified with more than 50% efficiency was 3 for the PPX method and 38 for the PPK method. It was also suggested that the ratio of the PPK value to the PPX value may be useful as a simple and relative index to compare polyphosphate chain length distribution in different samples.     

利用ATP扩增反应与生物发光法结合检测微量微生物

摘要:【目的】腺苷酸激酶（adenylate kinase, ADK）和多聚磷酸盐激酶（polyphosphate kinase, PPK）偶联催化的ATP扩增反应结合生物发光检测法能够对微量微生物进行检测。但是PPK当中结合的内源性的ADP会产生背景干扰,影响测定。本文旨在融合表达ADK和PPK,并建立一种方便有效的内源性ADP的去除方法,降低背景,使之与传统生物发光法结合,实现高灵敏生物发光法检测微量ATP及微生物。【方法】PCR扩增得到PPK、ADK基因,插入表达载体pET28a (+)中构建重组表达质粒pET28a (+)-PPKADK,表达PPK-ADK融合蛋白。利用表面包裹聚胺醇（Polyurethane）的磁珠（magnetic beads）,通过化学反应将腺苷酸双磷酸酶（apyrase）固定于磁珠表面,制备固相腺苷酸双磷酸酶（Beads-apyrase）,用于除去与融合蛋白结合的内源性ADP,降低ATP扩增反应的背景,从而使之与生物发光反应相结合,测定微量外源ATP及细菌菌落数。【结果】表达的融合蛋白具有PPK和ADK的活性,利用Beads-apyrase可以方便而有效的去除内源性ADP,显著地降低反应背景,从而实现了利用ATP扩增反应与传统生物发光反应结合,测定了小于1 fmol的外源微量ATP,使生物发光法检测ATP及微生物的灵敏度提高至少100倍。【结论】利用Beads-apyrase能够方便、有效地降低PPK-ADK中的ADP背景,从而使PPK-ADK催化的ATP扩增反应能够与传统生物发光法相结合,极大地提高了生物发光法的灵敏度。     

Crystallization and characterization of polyphosphate kinase from Escherichia coli

Linear polyphosphate chains have been found to play a key role in bacterial responses to stresses and nutritional depletion, and are necessary for host infection of various pathogens. Polyphosphate kinase (PPK) is a critical enzyme responsible for polyphosphate synthesis in bacteria. PPK knockout mutations in several Gram-negative pathogens identify PPK as an ideal drug target for the development of a new class of antibacterial drugs. To reveal the catalytic mechanism and provide a structural basis for drug discovery, we have purified and crystallized full-length Escherichia coli PPK and its complex with AMP-PNP. The crystals diffract to a resolution of 2.5A and belong to the space group P4(2)2(1)2 with unit-cell parameters a=152.0, b=152.0, and c=150.0 A. Crystal structure of PPK is being determined by the Se-Met MAD experiment.     

Bacterial microcompartment‐directed polyphosphate kinase promotes stable polyphosphate accumulation in E. coli

Processes for the biological removal of phosphate from wastewater rely on temporary manipulation of bacterial polyphosphate levels by phased environmental stimuli. In E. coli polyphosphate levels are controlled via the polyphosphate‐synthesizing enzyme polyphosphate kinase (PPK1) and exopolyphosphatases (PPX and GPPA), and are temporarily enhanced by PPK1 overexpression and reduced by PPX overexpression. We hypothesised that partitioning PPK1 from cytoplasmic exopolyphosphatases would increase and stabilise E. coli polyphosphate levels. Partitioning was achieved by co‐expression of E. coli PPK1 fused with a microcompartment‐targeting sequence and an artificial operon of Citrobacter freundii bacterial microcompartment genes. Encapsulation of targeted PPK1 resulted in persistent phosphate uptake and stably increased cellular polyphosphate levels throughout cell growth and into the stationary phase, while PPK1 overexpression alone produced temporary polyphosphate increase and phosphate uptake. Targeted PPK1 increased polyphosphate in microcompartments 8‐fold compared with non‐targeted PPK1. Co‐expression of PPX polyphosphatase with targeted PPK1 had little effect on elevated cellular polyphosphate levels because microcompartments retained polyphosphate. Co‐expression of PPX with non‐targeted PPK1 reduced cellular polyphosphate levels. Thus, subcellular compartmentalisation of a polymerising enzyme sequesters metabolic products from competing catabolism by preventing catabolic enzyme access. Specific application of this process to polyphosphate is of potential application for biological phosphate removal.     

Quantification of polyphosphate: different sensitivities to short-chain polyphosphate using enzymatic and colorimetric methods as revealed by ion chromatography

Polyphosphate is ubiquitous and has a variety of biochemical functions. Among polyphosphate quantification methods, an enzymatic assay using Escherichia coli polyphosphate kinase (PPK), in which polyphosphate is converted to adenosine 5'-triphosphate and quantified by luciferase assay, is the most specific and most sensitive. However, chain-length specificity of the assay has not been analyzed in detail so far. Ion chromatography equipped with an on-line hydroxide eluent generator enabled us to analyze polyphosphate up to 50 inorganic phosphate (P(i)) residues, and we employed this method to investigate the chain-length specificity of PPK in this study. Several fractions of short-chain polyphosphate were prepared by electrophoresis, and the chain-length distribution was analyzed before and after 1-6 h PPK reaction by ion chromatography. Polyphosphates longer than 23 P(i) residues were processed by PPK completely after 1 h incubation, but complete processing of those between 11 and 22 P(i) residues required 6h incubation. Limited processing of polyphosphates of 10 P(i) residues or shorter were observed even after 6h incubation. Metachromasy of Toluidine blue O, an alternative method for polyphosphate quantification, showed broader chain-length specificity although it was not as sensitive as the enzymatic assay. Combination of these two methods would be practically applicable to analysis of polyphosphate dynamics in living organisms.     

Amino acids involved in polyphosphate synthesis and its mobilization are distinct in polyphosphate kinase-1 from Mycobacterium tuberculosis

Background

In bacteria polyphosphates (poly-P) are involved in cellular metabolism and development especially during stress. The enzyme, principally involved in polyphosphate biosynthesis and its mobilization leading to generation of NTPs, is known as polyphosphate kinase (PPK).

Principal Findings

Among two genes of polyphosphate kinases present in Mycobacterium tuberculosis, we cloned and expressed PPK1 in Escherichia coli as histidine-tagged protein. This ∼86 kDa protein is capable of autophosphorylation and synthesis of poly-P as well as NTP. Among 22 conserved histidine residues, we found only His-491 is autophosphorylated and crucial for any enzymatic activity. Substitution of His-510 caused mPPK1 protein deficient but not defective in autophosphorylation, thereby contrary to earlier reports negating any role of this residue in the process. However, mutation of His-510 with either Ala or Gln affected ATP or poly-P synthesis depending on the substitution; while such effects were severe with H510A but mild with H510Q. Furthermore, mPPK1 also renders auxiliary nucleotide diphosphate kinase function by synthesizing virtually all NTPs/dNTPs from their cognate NDPs/dNDPs by utilizing poly-P as the phosphate donor albeit with varied efficiency. To assess the influence of other catalytic domain residues of mPPK1 towards its functionality, we designed mutations based on E. coli PPK1 crystal structure since it owes 68% amino acid sequence similarity with mPPK1. Interestingly, our results revealed that mutations in mPPK1 affecting poly-P synthesis always affected its ATP synthesizing ability; however, the reverse may not be true.

Conclusions/Significance

We conclude that amino acid residues involved in poly-P and ATP synthesizing activities of mPPK1 are distinct. Considering conserved nature of PPK1, it seems our observations have broader implications and not solely restricted to M. tuberculosis only.     

A nonradioactive method for the assay of polyphosphate kinase activity and its application in the study of polyphosphate metabolism in Burkholderia cepacia

Studies of polyphosphate (polyP) metabolism in microorganisms have been hampered by the lack of a convenient method for the assay in cell extracts of the activity of polyphosphate kinase (PPK), the enzyme principally responsible for microbial polyP biosynthesis. We report the development of such an assay, based on the well-established metachromatic reaction, with toluidine blue, of the polyP formed during the PPK-catalyzed reaction. The method was successfully used in the characterization of PPK activity in crude extracts of an environmental Burkholderia cepacia isolate. The development of a protocol for the physical recovery of polyP from solution is also reported.     

ATP amplification for ultrasensitive bioluminescence assay: detection of a single bacterial cell

We developed an ultrasensitive bioluminescence assay of ATP by employing (i) adenylate kinase (ADK) for converting AMP + ATP to two molecules of ADP, (ii) polyphosphate (polyP) kinase (PPK) for converting ADP back to ATP (ATP amplification), and (iii) a commercially available firefly luciferase. A highly purified PPK-ADK fusion protein efficiently amplified ATP, resulting in high levels of bioluminescence in the firefly luciferase reaction. The present method, which was approximately 10,000-fold more sensitive to ATP than the conventional bioluminescence assay, allowed us to detect bacterial contamination as low as one colony-forming unit (CFU) of Escherichia coli per assay.     

幽门螺杆菌napA基因在乳酸菌中的表达及免疫原性分析

为在乳酸菌中表达幽门螺杆菌（Helicobacter pylori,H.pylori）中性粒细胞激活蛋白(NAP),口服免疫小鼠后检测其免疫原性。在实验中利用了分子克隆技术构建携带nap基因的重组原核表达质粒pNICE:secnap,将重组质粒转化乳酸菌NZ9000株,筛选鉴定阳性菌落,诱导表达的NAP蛋白用SDSPAGE和Western blot进行鉴定。将雌性ICR（CV级）小鼠随机分为4组,分别用PBS、携带空质粒的乳酸菌、携带pNICE:secnap的乳酸菌、灭活的H.pylori 灌胃。免疫7次后检测其特异性IgG和IgA的产生。成功扩增了nap基因并构建了重组原核表达质粒pNICE:secnap,转化乳酸菌NZ9000后经nisin诱导可表达Mr约17kDa的重组蛋白,表达量约占菌体总蛋白量的9.5%,表达的蛋白能与兔抗H.pylori 血清特异性反应,具有良好的免疫原性。携带pNICE:secnap质粒的乳酸菌刺激产生的IgG水平明显高于携带空质粒组,与灭活H.pylori组没有明显的差异,但其刺激产生的IgA水平明显高于其他组。以上结果说明表达NAP蛋白的乳酸菌口服免疫小鼠后,能够刺激小鼠产生特异的IgG和IgA,对幽门螺杆菌疫苗的研究开发具有理论意义。为乳酸菌作为抗原递送载体的研究和H.pylori口服疫苗的开发提供了一定的实验基础。     

幽门螺杆菌napA基因在乳酸菌中的表达及免疫原性分析

本实验目的是在乳酸菌中表达幽门螺杆菌（Helicobacter pylori,H.pylori） 中性粒细胞激活蛋白(NAP),口服免疫小鼠后检测其免疫原性。在实验中利用了分子克隆技术构建携带nap基因的重组原核表达质粒pNICE:sec-nap,将重组质粒转化乳酸菌NZ9000株,筛选鉴定阳性菌落,诱导表达的NAP蛋白用SDS-PAGE和Western blot进行鉴定。将雌性ICR（CV级）小鼠随机分为4组,分别用PBS、携带空质粒的乳酸菌、携带pNICE:sec-nap的乳酸菌、灭活的H.pylori 灌胃。免疫7次后检测其特异性IgG和IgA的产生。成功扩增了nap基因并构建了重组原核表达质粒pNICE:sec-nap,转化乳酸菌NZ9000后经nisin诱导可表达Mr约17kDa的重组蛋白,表达量约占菌体总蛋白量的9.5%,表达的蛋白能与兔抗H.pylori 血清特异性反应,具有良好的免疫原性。携带pNICE:sec-nap质粒的乳酸菌刺激产生的IgG水平明显高于携带空质粒组,与灭活H.pylori组没有明显的差异,但其刺激产生的IgA水平明显高于其他组。以上结果说明表达NAP蛋白的乳酸菌口服免疫小鼠后,能够刺激小鼠产生特异的IgG和IgA,对幽门螺杆菌疫苗的研究开发具有理论的意义。为乳酸菌作为抗原递送载体的研究和H.pylori口服疫苗的开发提供一定的实验基础。