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。     

DNA双链断裂与同源重组修复机理研究进展

双链断裂（double strand breaks,DSBs)是细胞染色体复制过程中经常出现的DNA损伤,它的修复过程顺真核生物中以同源重组（homology recombination,HR)修复为主。正常机体中有着一系列的基因和蛋白及时修复复这些损伤,这些蛋白归属于RAD52上位性集团（RAD52epistasis group)。它们对细胞发挥功能和维持生存意义重大,近来国外研究十分活跃。     

幽门螺杆菌VacA重组蛋白表达、纯化及鉴定

目的研究幽门螺杆菌空泡毒素（VacA）编码基因在大肠埃希菌中的表达及纯化重组蛋白的抗原性。方法将PET32a-vacA-E.coli BE21（DE3）工程菌株常规培养,碱裂解法小量提取重组质粒DNA,琼脂糖凝胶电泳进行酶切鉴定,基因测序法进行插入基因序列分析。重组蛋白采用IPTG诱导表达,镍亲和层析原理提纯,ELISA法检测其抗原性。结果经酶切鉴定表明,插入的基因片段全长约2240bp,测序分析及与Genebank比较,可以肯定插入片段为vacA基因,ELISA法检测重组蛋白具有良好的抗原性。结论VacA重组蛋白在大肠埃希菌中成功表达,重组蛋白具有良好的抗原性。     

幽门螺杆菌Cag致病岛hp0523基因的缺失及其对CagA蛋白转运能力的影响

摘要: 【目的】构建幽门螺杆菌Cag致病岛编码的hp0523基因缺失株,为研究hp0523基因的功能奠定基础。【方法】本研究利用同源重组原理,设计并扩增了hp0523基因上下游同源臂片段,构建hp0523基因缺失自杀质粒pBlueKM40-?hp0523,电击转化进入幽门螺杆菌后,通过抗生素筛选后并经PCR验证无误后,获得hp0523基因缺失株H. pylori 11637?hp0523;采用幽门螺杆菌与胃癌上皮细胞BGC-823共培养后,分析该基因缺失前后对细胞毒性蛋白CagA转运能力的影响;并分析比较     

DNA复制、修复与重组

在一些大肠杆菌株系中,RecET是一种噬菌体衍生出的简单而有效的重组系统,它能通过单链退火启动同源重组。一种称作RecE的5’-3’外切核酸酶可以对生成的DNA末端进行再切割,在切口处造成一个3’－单链末端,而重组酶RecT在此末端加载以单链DNA（ssDNA）互补链。     

大肠杆菌细胞DNA复制、修复和重组途径的衔接

以大肠杆菌为例围绕相关领域的研究动态进行分析和总结.DNA复制、损伤修复和重组过程的相互作用关系研究是当今生命科学研究的前沿和热点之一.越来越多的研究表明,在分子水平上,DNA复制、损伤修复和重组过程既彼此独立,又相互依存.上述途径可以通过许多关键蛋白质之间的相互作用加以协调和整合,并籍此使遗传物质DNA得到有效的维护和忠实的传递.需要指出的是,基于许多细胞内关键蛋白及其功能在生物界中普遍保守性的事实,相信来自大肠杆菌有关DNA复制、修复和重组之间的研究成果也会对相关真核生物的研究提供借鉴.     

依托泊苷影响HEK293细胞同源重组修复体系

抗肿瘤药物疗效的研究多集中在肿瘤细胞,目前针对正常细胞的研究颇少,有必要建立能进行定量分析的同源重组定量修复体系。我们已建立的模型可以探讨肿瘤药物化疗后对HEK293细胞DSBs修复的继发性后果。通过构建含有带I-SceⅠ酶切位点的同源介导的重组修复底物（homologous direct recombination, HDR）,或单链退火修复（single strand annealing, SSA）底物的细胞株,定量检测依托泊苷 (etoposide,VP-l6)对同源性重组修复(homologous recombination, HR)通路的影响。成功构建了可用于定量检测DNA双链断裂(double-strand break, DSBs)诱导的SSA和HDR修复的正常人HEK293细胞应用模型。细胞毒结果证实,与SSA/293对照组对比,VP-16给药组 16 μmol/L（0.475±0.029 vs 1.000±0.000, P<0.001)细胞活力明显降低;与HDR/293对照组相比,VP-16 给药组16 μmol/L（0.458±0.188 vs 1.000±0.000, P<0.05)细胞活力降低。此外,本研究证实,VP-16抑制SSA修复,VP-16给药组 2 μmol/L与SSA/293对照组相比（0.575%±0.177% vs 1.352%±0.195%, P<0.05）,修复效率降低;VP-16抑制HDR修复,VP-16给药组1 μmol/L与HDR/293对照组修复效率相比（0.305%±0.078% vs. 0.635%± 0.049%,P<0.05),修复效率降低。VP-16诱导DNA损伤的同时,抑制HDR修复和SSA修复,修复效率呈现剂量依赖性。本研究结果可为抗肿瘤药物的临床应用提供某些指导。     

幽门螺杆菌STM文库重组质粒的构建

目的:应用信号标签突变技术(Signature tagged mutagenesis,STM)构建幽门螺杆菌突变体文库重组质粒。方法:采用平末端内切酶随机酶切幽门螺杆菌基因组DNA,并回收300～500bp片段(记作Fr),基因重组技术构建重组质粒pID700-Fr,电转化E.coliDH5α筛选阳性克隆,提取重组质粒酶切鉴定。结果:成功构建了1200个幽门螺杆菌STM文库重组质粒。结论:STM技术可用于幽门螺杆菌致病以及耐药相关基因的筛选,为幽门螺杆菌致病及耐药机理的研究奠定了基础。也将为幽门螺杆菌的治疗提供新的药物靶点。     

幽门螺杆菌相关胃癌发生不同阶段miRNAs表达与临床研究

目的 观察幽门螺杆菌（Helicobacter pylori, H. pylori）感染的慢性非萎缩性胃炎（no-atrophic gastritis,NAG）→萎缩性胃炎（chronic atrophic gastritis,CAG）→肠上皮化生（intestinal metaplasia,IM）→非典型增生（dysplasia,DYS）→胃癌（gastric cancer,GC）五个不同阶段miR-1、miR-20a、miR-34a、miR-423-5p表达变化规律及其与临床的关系。方法 收集胃镜及病理证实的上述胃癌发生五个不同阶段且H. pylori感染的患者（依次为44、47、43、50、45例）,胃癌无H. pylori感染者46例,胃黏膜正常（normal gastric mucose,NGM）63例的血清标本,采用Real-time PCR法检测无H. pylori感染者miR-1、miR-20a、miR-34a、miR-423-5p表达。结果 H. pylori感染NAG→GC不同阶段,miR-1、miR-20a、miR-34a、miR-423-5p表达逐渐升高（P<0.05）,GC阶段最高,miR-1、miR-20a CAG→GC阶段均高于NGM（P<0.05）,与NGM比较差异有统计学意义（P<0.05）;其表达程度与GC发生阶段呈正相关（P<0.001）;GC组H. pylori感染者较无H. pylori感染者miR-1、miR-20a、miR-34a、miR-423-5p表达升高（P<0.05）。结论 H. pylori感染CAG→GC阶段miR-1、miR-20a、miR-34a、miR-423-5p表达升高,向胃癌演进中呈逐渐升高趋势,miR-1、miR-20a、miR-34a、miR-423-5p高表达可能是H. pylori感染后导致胃癌发生发展的重要机制,miR-1、miR-20a、miR-34a可作为诊断早期胃癌的标记物。     

DNA双链断裂损伤修复系统研究进展

多种内源或外源因素都能造成细胞基因组DNA损伤,细胞内建立了复杂的修复系统来应对不同形式的损伤。其中DNA双链断裂(DNA double-strand breaks,DSBs)作为最严重的损伤形式,主要激活同源重组修复(Homologous recombination repair)和非同源末端连接(Non-homologous end joining)通路。这两条通路都是由多个修复元件参与、经过多步反应的复杂过程。两者各具特点、协同作用,共同维护细胞基因组的稳定性。对其分子机制的阐明为肿瘤放化疗的辅助治疗提供了潜在的作用靶点。     

AtMMS21 regulates DNA damage response and homologous recombination repair in Arabidopsis

DNA damage is a significant problem in living organisms and DNA repair pathways have been evolved in different species to maintain genomic stability. Here we demonstrated the molecular function of AtMMS21, a component of SMC5/6 complex, in plant DNA damage response. Compared with wild type, the AtMMS21 mutant plants show hypersensitivity in the DNA damaging treatments by MMS, cisplatin and gamma radiation. However, mms21-1 is not sensitive to replication blocking agents hydroxyurea and aphidicolin. The expression of a DNA damage response gene PARP2 is upregulated in mms21-1 under normal condition, suggesting that this signaling pathway is constitutively activated in the mutant. Depletion of ATAXIA-TELANGIECTASIA MUTATED (ATM) in mms21-1 enhances its root growth defect phenotype, indicating that ATM and AtMMS21 may play additive roles in DNA damage pathway. The analysis of homologous recombination frequency showed that the number of recombination events is reduced in mms21-1 mutant. Conclusively, we provided evidence that AtMMS21 plays an important role in homologous recombination for DNA damage repair.     

Evaluation of the homologous recombination in Helicobacter pylori

BACKGROUND: Most strategies for direct mutagenesis of Helicobacter pylori primarily involve genomic DNA cloning which is a time-consuming and expensive technique. METHODS: To make a gene replacement, we propose a strategy using polymerase chain reaction (PCR) amplicons to allow a double homologous recombination in the genome of H. pylori. Different strains were used to validate this strategy and we describe how the amplicon insertion was made with accuracy. Moreover, we looked for the shortest homologous sequence needed to allow a specific gene replacement in H. pylori without any deletion, insertion or mutation at the recombination site. All of the experiments were performed at the flaA locus, whose gene encodes the major flagellin. RESULTS: Amplicons bearing 500 or 150 bp flanking regions of flaA on each side (depending on the strain) were sufficient to allow the specific insertion of a 1173 bp chloramphenicol cassette into the genome of H. pylori. The insertion was accurate with no substitutions at the insertion locus. CONCLUSIONS: This information opens the door to other strategies for mutagenesis used for the identification of virulence factors without deleting genes, which would not be based on a negative screening system. For example, they could be useful in performing protein fusion for a better understanding of the virulence factor's mechanism.     

Inhibition of homologous recombination with vorinostat synergistically enhances ganciclovir cytotoxicity

The nucleoside analog ganciclovir (GCV) elicits cytotoxicity in tumor cells via a novel mechanism in which drug incorporation into DNA produces minimal disruption of replication, but numerous DNA double strand breaks occur during the second S-phase after drug exposure. We propose that homologous recombination (HR), a major repair pathway for DNA double strand breaks, can prevent GCV-induced DNA damage, and that inhibition of HR will enhance cytotoxicity with GCV. Survival after GCV treatment in cells expressing a herpes simplex virus thymidine kinase was strongly dependent on HR (>14-fold decrease in IC₅₀ in HR-deficient vs. HR-proficient CHO cells). In a homologous recombination reporter assay, the histone deacetylase inhibitor, suberoylanilide hydroxamic acid (SAHA; vorinostat), decreased HR repair events up to 85%. SAHA plus GCV produced synergistic cytotoxicity in U251tk human glioblastoma cells. Elucidation of the synergistic mechanism demonstrated that SAHA produced a concentration-dependent decrease in the HR proteins Rad51 and CtIP. GCV alone produced numerous Rad51 foci, demonstrating activation of HR. However, the addition of SAHA blocked GCV-induced Rad51 foci formation completely and increased γH2AX, a marker of DNA double strand breaks. SAHA plus GCV also produced synergistic cytotoxicity in HR-proficient CHO cells, but the combination was antagonistic or additive in HR-deficient CHO cells. Collectively, these data demonstrate that HR promotes survival with GCV and compromise of HR by SAHA results in synergistic cytotoxicity, revealing a new mechanism for enhancing anticancer activity with GCV.     

Single-stranded oligonucleotide-mediated gene repair in mammalian cells has a mechanism distinct from homologous recombination repair

Single-stranded DNA oligonucleotide (SSO)-mediated gene repair has great potentials for gene therapy and functional genomic studies. However, its underlying mechanism remains unclear. Previous studies from other groups have suggested that DNA damage response via the ATM/ATR pathway may be involved in this process. In this study, we measured the effect of two ATM/ATR inhibitors caffeine and pentoxifylline on the correction efficiency in SSO-mediated gene repair. We also checked their effect on double-stranded break (DSB)-induced homologous recombination repair (HRR) as a control, which is well known to be dependent on the ATM/ATR pathway. We found these inhibitors could completely inhibit DSB-induced HRR, but could only partially inhibit SSO-mediated process, indicating SSO-mediated gene repair is not dependent on the ATM/ATR pathway. Furthermore, we found that thymidine treatment promotes SSO-mediated gene repair, but inhibits DSB-induced HRR. Collectively, our results demonstrate that SSO-mediated and DSB-induced gene repairs have distinct mechanisms.     

The effect of Helicobacter pylori infection on levels of DNA damage in gastric epithelial cells

Background. Helicobacter pylori infection leads to an increased risk of developing gastric cancer. The mechanism through which this occurs is not known. We aimed to determine the effect of H. pylori and gastritis on levels of DNA damage in gastric epithelial cells. Methods. Epithelial cells were isolated from antral biopsies from 111 patients. DNA damage was determined using single cell gel electrophoresis and the proportion of cells with damage calculated before and 6 weeks after eradication of H. pylori. Cell suspensions generated by sequential digestions of the same biopsies were assayed to determine the effect of cell position within the gastric pit on DNA damage. Results. DNA damage was significantly higher in normal gastric mucosa than in H. pylori gastritis [median (interquartile range) 65% (58.5–75.8), n = 18 and 21% (11.9–29.8), n = 65, respectively, p < .001]. Intermediate levels were found in reactive gastritis [55.5% (41.3–71.7), n = 13] and H. pylori negative chronic gastritis [50.5% (36.3–60.0), n = 15]. DNA damage rose 6 weeks after successful eradication of H. pylori[to 39.5% (26.3–51.0), p = .007] but was still lower than in normal mucosa. Chronic inflammation was the most important histological factor that determined DNA damage. DNA damage fell with increasing digestion times (r = –.92 and –.88 for normal mucosa and H. pylori gastritis, respectively). Conclusions. Lower levels of DNA damage in cells isolated from H. pylori infected gastric biopsies may be a reflection of increased cell turnover in H. pylori gastritis. The investigation of mature gastric epithelial cells for DNA damage is unlikely to elucidate the mechanisms underlying gastric carcinogenesis.     

胃息肉与幽门螺杆菌感染关系研究

目的探讨胃息肉与幽门螺杆菌（Helicobacter pylori,H.pylori）感染关系。方法对1218例胃息肉同时进行H．pylori检查患者进行回顾性分析,分析胃息肉患者H.pylori感染率、胃息肉部位与H.pylori感染关系、胃息肉病理类型与H.pylori感染关系。结果发现胃息肉Hpylori感染患者532例,Hpylori感染率为43．7％。男性胃息肉患者H.pylori感染率为47．5％（216／455）,女性Hpriori感染率感染率为41．4％（316／763）（P〉0．05）,年龄〈20岁、20～39岁、40—59岁和≥60岁胃息肉H.priori感染率分别为41．7％、44．7％、41．6％和47．2％（P〉0．05）;胃窦胃角息肉H.pylori感染率高于其他部位（胃体、胃底和贲门）（P〈0．05）;炎性和增生性胃息肉H.priori感染率高于胃底腺和腺瘤性息肉（P〈0．05）。结论H.pylori感染可能与部分胃息肉发生有一定关系,需要进一步深入研究胃息肉的发生机制。     

幽门螺杆菌感染对过敏性紫癜患儿的影响

目的 探讨幽门螺杆菌(H.pylori)感染对过敏性紫癜(henochschonlein purpura,HSP)患儿肠道菌群、疗效及疾病复发情况的影响。 方法 选取2017年1月至2018年6月我院收治的100例HSP患儿作为观察组,同时随机选取同时段于我院体检的100例健康儿童作为对照组。采用13C同位素呼吸试验法检测H.pylori感染情况,根据H.pylori感染情况进一步将观察组患儿分为感染组和非感染组。收集观察组患儿粪便样本,采用Illumina MiSeq平台对患儿肠道菌群的16S rRNA V4序列进行测序,分析肠道菌群组成,同时分析患儿疗效及疾病复发情况与H.pylori感染的关系。 结果 观察组患儿H.pylori感染率显著高于对照组(47.00% vs 30.00%,χ2=6.100,P=0.015)。治疗后非感染组患儿有效率明显高于感染组(92.45% vs 78.72%,χ2=3.900,P=0.048),复发率显著低于感染组(24.53% vs 44.68%,χ2=4.510,P=0.034)。感染组和非感染组患儿肠道菌群多样性差异无统计学意义,但在门、科水平上肠道菌群结构相对丰度差异有统计学意义。非感染组患儿肠道厚壁菌门、放线菌门相对丰度显著高于感染组,同时其拟杆菌科、瘤胃菌科、链球菌科、双歧杆菌科、巴斯德菌科相对丰度也显著高于感染组(均P结论 H.pylori感染与儿童HSP的发生存在一定相关性。H.pylori感染可影响HSP患儿肠道菌群组成,同时降低疾病治疗效果以及增加复发风险。     

Role of RAD51AP1 in homologous recombination DNA repair and carcinogenesis

Homologous recombination (HR) serves to repair DNA double-strand breaks and damaged replication forks and is essential for maintaining genome stability and tumor suppression. HR capacity also determines the efficacy of anticancer therapy. Hence, there is an urgent need to better understand all HR proteins and sub-pathways. An emerging protein that is critical for RAD51-mediated HR is RAD51-associated protein 1 (RAD51AP1). Although much has been learned about its biochemical attributes, the precise molecular role of RAD51AP1 in the HR reaction is not yet fully understood. The available literature also suggests that RAD51AP1 expression may be relevant for cancer development and progression. Here, we review the efforts that led to the discovery of RAD51AP1 and elaborate on our current understanding of its biochemical profile and biological function. We also discuss how RAD51AP1 may help to promote cancer development and why it could potentially represent a promising new target for therapeutic intervention.     

幽门螺杆菌相关miRNA与胃癌关系的研究进展

微小核糖核酸(microRNA,miRNA)是一种由内源基因编码长度约为22个核苷酸的非编码RNA,其能抑制靶基因蛋白质表达,有多种生物学功能。越来越多的研究表明,miRNA在多种肿瘤中异常表达,参与肿瘤发生、发展过程。幽门螺杆菌(Helicobacter pylori,Hp)作为胃癌的主要致病因素,可通过调节miRNA的表达,在胃癌中起促进或抑制作用。现就Hp相关miRNA在胃癌中的作用作一概述。     

Role of PCNA and TLS polymerases in D-loop extension during homologous recombination in humans

Homologous recombination (HR) is essential for maintaining genomic integrity, which is challenged by a wide variety of potentially lethal DNA lesions. Regardless of the damage type, recombination is known to proceed by RAD51-mediated D-loop formation, followed by DNA repair synthesis. Nevertheless, the participating polymerases and extension mechanism are not well characterized. Here, we present a reconstitution of this step using purified human proteins. In addition to Pol δ, TLS polymerases, including Pol η and Pol κ, also can extend D-loops. In vivo characterization reveals that Pol η and Pol κ are involved in redundant pathways for HR. In addition, the presence of PCNA on the D-loop regulates the length of the extension tracks by recruiting various polymerases and might present a regulatory point for the various recombination outcomes.