核酶在大肠杆菌内对烟草花叶病毒靶RNA的切割作用

把一段取自TMV RNA的靶cDNA序列连接在一个体内表达转录载体内的报道基因CAT起译密码子ATG的下游组成了读码框不改变的CAT融合基因,通过测定载体在大肠杆菌内表达的CAT活力变化,观察了与CAT同时表达的核酶在体内对靶序列的作用。当专一核酶RZ1、RZ1A或RZ1表达时,CAT的酶活力下降了30%,但非专一核酶RZ3的表达并不改变CAT活力。凝胶电泳和引物延伸结果表明CAT活力的下降是由于这些核酶对融合CAT mRNA在5’靶序列区发生了专一切割从而影响了蛋白的合成所致。     

Activity identification of chimeric anti-caspase-3 mRNA hammerhead ribozyme in vitro and in vivo

To study the expression activity of various vectors containing anti-caspase-3 ribozyme cassettes in vivo, and to further study the role of caspas-3 in the apoptotic pathway, we constructed anti-caspase-3 hammerhead ribozyme embedded into the human snRNA U6, and detected the activity of the ribozyme in vitro and in vivo. Meanwhile we compared it with the self-cleaving hammerhead ribozymes that we previously studied, and with the general ribozyme, cloned into RNA polymerase II expression systems. The results showed that the three ribozymes, p1.5RZ107, pRZ107 and pU6RZ107 had the correct structure, and that they could cleave cas-pase-3 mRNA exactly to produce two fragments: 143nt/553nt. p1.5RZ107 has the highest cleavage efficiency in vitro, almost 80%. However, the U6 chimeric ribozyme, pU6RZ107, has the highest cleavage activity in vivo, almost to 65%, though it has lower cleavage activity in vitro. The cleavage results demonstrated that the pU6RZ107, the U6 chimeric ribozyme, could more efficiently expre     

Expression of a chimeric ribozyme gene results in endonucleolytic cleavage of target mRNA and a concomitant reduction of gene expression in vivo.

The subclass of catalytic RNAs termed ribozymes cleave specific target RNA sequences in vitro. Only circumstantial evidence supports the idea that ribozymes may also act in vivo. In this study, ribozymes with a hammerhead motif directed against a target sequence within the mRNA of the neomycin phosphotransferase gene (npt) were embedded into a functional chimeric gene. Two genes, one containing the ribozyme and the other producing the target, were cotransfected into plant protoplasts. Following in vivo expression, a predefined cleavage product of the target mRNA was detected by ribonuclease protection. Expression of both the ribozyme gene and the target gene was driven by the CaMV 35S promoter. Concomitant with the endonucleolytic cleavage of the target mRNA, a complete reduction of NPT activity was observed. An A to G substitution within the ribozyme domain completely inactivates ribozyme-mediated hydrolysis but still shows a reduction in NPT activity, albeit less pronounced. Therefore, the reduction of NPT activity produced by the active ribozyme is best explained by both hydrolytic cleavage and an antisense effect. However, the mutant ribozyme--target complex was more stable than the wildtype ribozyme--target complex. This may result in an overestimation of the antisense effect contributing to the overall reduction of gene expression.     

Activity identification of chimeric anti-caspase-3 mRNA hammerhead ribozyme in vitro and in vivo

To study the expression activity of various vectors containing anti-caspase-3 ribozyme cassettesin vivo, and to further study the role of caspas-3 in the apoptotic pathway, we constructed anti-caspase-3 hammerhead ribozyme embedded into the human snRNA U6, and detected the activity of the ribozymein vitro andin vivo. Meanwhile we compared it with the self-cleaving hammerhead ribozymes that we previously studied, and with the general ribozyme, cloned into RNA polymerase II expression systems. The results showed that the three ribozymes, p1.5RZ107, pRZ107 and pU6RZ107 had the correct structure, and that they could cleave caspase-3 mRNA exactly to produce two fragments: 143nt/553nt. p1.5RZ107 has the highest cleavage efficiencyin vitro, almost 80%. However, the U6 chimeric ribozyme, pU6RZ107, has the highest cleavage activityin vivo, almost to 65%, though it has lower cleavage activityin vitro. The cleavage results demonstrated that the pU6RZ107, the U6 chimeric ribozyme, could more efficiently express and downregulate the level of caspase-3in vivo, and the ribozyme could provide an alternative approach to the research into the mechanism of apoptosis and human gene therapy also.     

BCR3/ABL2核酶的设计、构建及对K562细胞增殖与集落形成的抑制作用和凋亡诱导作用

利用计算机模拟设计合成了针对 K5 62细胞致癌融合 bcr3/abl2 m RNA的锤头状核酶 .该核酶以融合点附近 UUC为识别切割三联体 ,在核酶的 3′端增加一段 T7噬菌体终止子序列 .用基因克隆结合体外转录的方法 ,肯定了核酶的体外切割活性 .进而将核酶基因克隆到 p CEP4真核细胞高效表达载体上 ,利用脂质体 Lipofectin AMINE介导的转染技术将核酶与核酶基因导入靶细胞 ,从抑制靶细胞 K5 62的增殖与集落形成及引起靶细胞凋亡等方面验证了核酶在细胞水平上对融合基因 bcr3/abl2 m RNA的特异切割作用 ,并观察到了 T7噬菌体终止子序列对核酶切割效率的增强影响 .     

Activity identification of chimeric anti-caspase-3 mRNA hammerhead ribozymein vitro andin vivo

To study the expression activity of various vectors containing anti-caspase-3 ribozyme cassettesin vivo, and to further study the role of caspas-3 in the apoptotic pathway, we constructed anti-caspase-3 hammerhead ribozyme embedded into the human snRNA U6, and detected the activity of the ribozymein vitro andin vivo. Meanwhile we compared it with the self-cleaving hammerhead ribozymes that we previously studied, and with the general ribozyme, cloned into RNA polymerase II expression systems. The results showed that the three ribozymes, p1.5RZ107, pRZ107 and pU6RZ107 had the correct structure, and that they could cleave caspase-3 mRNA exactly to produce two fragments: 143nt/553nt. p1.5RZ107 has the highest cleavage efficiencyin vitro, almost 80%. However, the U6 chimeric ribozyme, pU6RZ107, has the highest cleavage activityin vivo, almost to 65%, though it has lower cleavage activityin vitro. The cleavage results demonstrated that the pU6RZ107, the U6 chimeric ribozyme, could more efficiently express and downregulate the level of caspase-3in vivo, and the ribozyme could provide an alternative approach to the research into the mechanism of apoptosis and human gene therapy also.     

Suppression of BCR-ABL mRNA by various ribozymes in HeLa cells.

Ribozymes are RNA molecules with enzymatic activity that can cleave target RNA molecules in a sequence specific manner. To date, various types of ribozyme have been constructed to cleave other RNAs and such trans-acting ribozymes include hammerhead, hairpin and HDV ribozymes. External guide sequence (EGS) can also induce the suppression of a gene-expression by taking advantage of cellular RNase P. Here we compared the activities of various functional RNA cleavers both in vitro and in vivo. The first purpose of this comparison was intended to determine the best ribozyme motif with the highest activity in cells. The second purpose is to know the correlation between the activities of ribozymes in vitro and in vivo. Our results indicated that the intrinsic cleavage activity of ribozymes is not the sole determinant that is responsible for the activity of a ribozyme in cultured cells.     

抗HPV11E2核酸的计算机设计

借助计算机软件分析,设计出能特异性切割HPV11型644nt型644ntE2mNA的核酶。遵循Symons锤头状核酶结构和GUX剪切位点原则,靶序列存在32个剪切位点,通过计算机软件分析核酶的最佳剪切位点,并对底物及核酶的二级结构进行预测及进行相应基因生物学功能和基因同源性分析,筛选出2个锤头结构核酶。针对这两位点设计的核酶分别命名为RZ277和RZ3281。计算机分析显示,两核酶与底物切点两翼碱基形成锤头状结构,切点所在基因序列具有相对松驰的二级结构,位于该基因重要生物功能区内,是核酶的理想攻击区域,通过基因库检索,在已知人类基因中排除了与上述两核酶切点两翼碱基有基因同源性序列的可能性。并非所有的GUX位点（X：C、U、A）或CUX均可作为核酶的最佳剪切切割反应,为下一步将核酶用于细胞内和体内试验打下基础。