Yeast MIG1 repressor is related to the mammalian early growth response and Wilms'' tumour finger proteins.

We have cloned a yeast gene, MIG1, which encodes a C2H2 zinc finger protein involved in glucose repression. The fingers of MIG1 are very similar to those present in the mammalian Egr finger proteins, which are induced during the early growth response, and also to the finger protein encoded by a human gene that is deleted in Wilms' tumour cells. MIG1 protein binds to two sites in the upstream region of SUC2, a yeast gene that is repressed by glucose. The MIG1 sites closely resemble the sequence recognized by the Egr proteins. Thus, finger proteins that are similar in both amino acid sequence and DNA specificity are involved in the response of yeast to glucose, and in the mammalian early growth response.     

Analysis of the creA gene, a regulator of carbon catabolite repression in Aspergillus nidulans.

The complete nucleotide sequence derived from a genomic clone and two cDNA clones of the creA gene of Aspergillus nidulans is presented. The gene contains no introns. The derived polypeptide of 415 amino acids contains two zinc fingers of the C2H2 class, frequent S(T)PXX motifs, and an alanine-rich region indicative of a DNA-binding repressor protein. The amino acid sequence of the zinc finger region has 84% similarity to the zinc finger region of Mig1, a protein involved in carbon catabolite repression in yeast cells, and it is related both to the mammalian Egr1 and Egr2 proteins and to the Wilms' tumor protein. A deletion removing the creA gene was obtained, by using in vitro techniques, in both a heterokaryon and a diploid strain but was unobtainable in a pure haploid condition. Evidence is presented suggesting that the phenotype of such a deletion, when not complemented by another creA allele, is leaky lethality allowing limited germination of the spore but not colony formation. This phenotype is far more extreme than that of any of the in vivo-generated mutations, and thus either the gene product may have an activator activity as well as a repressor function or some residual repressor function may be required for full viability.     

ZNF300, a recently identified human transcription factor,activates the human IL-2Rβ promoter through the overlapping ZNF300/EGR1 binding site

ZNF300 was recently identified as a member of the human KRAB/C₂H₂ zinc finger protein family. Little is known about the role of ZNF300 in human gene regulation networks. In this study, the DNA-binding property of ZNF300 was further analyzed. We found that the recombinant ZNF300 could bind to the binding site 5′-GCGGGGGCG-3′ of Egr1, another member of the KRAB/C₂H₂ zinc finger protein family. Similarly, recombinant Egr1 also showed a similar binding affinity to the ZNF300 binding site 5′-CTGGGGGCG-3′. Bioinformatics analysis revealed that there is an overlapping ZNF300/Egr1 binding site in the human IL-2Rβ promoter region, which was previously known to be recognized by endogenous Egr1. Electrophoretic mobility shift assays showed that endogenous ZNF300 could also bind to this site. A transient transfection assay revealed that both ZNF300 and Egr1 could transactivate the IL-2Rβ promoter, and that the activation was abrogated by a mutation of residues in the overlapping ZNF300/Egr1 binding site. Co-expression of ZNF300 and Egr1 led to enhanced IL-2Rβ promoter activity. Thus, ZNF300 is likely to be another regulator of the human IL-2Rβ promoter.     

真核生物中锌指蛋白的结构与功能

真核生物中的许多蛋白质分子包含锌指结构区,这类蛋白称为锌指蛋白.锌指蛋白因其包含特殊的指状结构,在对DNA、蛋白质和RNA的识别和结合中起重要作用.许多锌指蛋白的锌指结构域包含能与DNA特异结合的区域,并与某些效应结构域（如KRAB、SCAN、BTB/POZ、SNAG、SANT和PLAG等）相连,这类锌指蛋白常作为转录因子起作用,可调控靶基因的转录.一些锌指蛋白包含蛋白质识别结构域（如LIM锌指、MYND锌指、PHD锌指和RING锌指等）,它们能够特异地介导蛋白质之间的相互作用,因此被称作蛋白适配器.此外,某些锌指蛋白还可以结合RNA,起转录后调控作用.本文就锌指蛋白与DNA、RNA以及蛋白质分子间的相互作用作一综述.     

人工锌指核酸酶的设计与表达纯化

设计表达了四个锌指核酸酶,用于切断人基因组中的rRNA基因家族的内部转录间隔序列,造成双链断裂,以此提高针对多位点基因打靶的效率,为后续基因打靶应用于基因治疗研究奠定基础。首先,在人rRNA基因家族ITS1序列中找到两个合适的9 bp长的序列(中间间隔6 bp)为锌指蛋白识别位点,根据识别位点序列每个位点分别设计两个三锌指蛋白。通过设计引物进行重叠延伸PCR得到全长编码锌指蛋白的DNA,分别克隆到表达载体pET-28a（+）,构建重组质粒pET28a-ZFP,转化大肠杆菌RossettaTM（DE3）,实现带组氨酸标签的锌指融合蛋白的表达与纯化。同时,将限制性内切酶Fok I的切割结构域分别与四个锌指蛋白序列采用PCR拼接后克隆到表达载体pET-28a（+）,构建重组质粒pET28a-ZFN,转化到大肠杆菌RossettaTM（DE3）,实现带组氨酸标签的锌指核酸酶融合蛋白的表达并纯化。