癫痫基因研究进展

本综述了癫痫基因的定位,癫痫候选基因的筛查和癫痫相关基因的寻找及其进展。     

单基因肥胖的致病基因概述

肥胖是人类体质研究中的重要组成部分,发生率在世界范围内呈快速上升趋势,其预防与控制是当今研究的重要课题。肥胖受遗传与环境因素的共同作用,其中遗传因素对其发生至关重要。截至目前,已有14种单基因肥胖的致病基因被确认,涉及了食欲调控和食物摄取、能量消耗和脂肪细胞分化调控等方面。本文概述了上述基因在单基因肥胖研究中的情况,旨在加深对肥胖病理生理学机制的理解,并为其相关研究的开展提供参考。     

基因重组与基因合成实验设计软件系统的建立

本文报导了用于基因重组与基因合成实验设计的软件系统的建立.此系统由30个功能模块组成,为研究者提供了包括在DNA分子上寻找限制性内切酶位点、核酸分子片段之间同源性比较,基因化学合成的实验设计、特定顺序分析引物及核酸杂交探针的设计、阅读框的查找等功能.此外,本系统可以对外来数据库的资料进行援引和进一步分析,为分子生物学的研究提供有价值的信息.     

Dicer基因

Dicer编码RNaseⅢ家族,是一进化保守基因。它包含四个ORF框架：DExH/DEAH盒解旋酶,PAZ,两个RNaseⅢ催化区与双链RNA结合区DS－RBD。目前发现Dicer在RNA干扰以及异时发育中起重要作用,它可以切割长的双链RNA成长度为22nt左右的小干扰RNA－siRNA,异时基因stRNA的成熟也与需要Dicer的参与。Dicer行使切割功能需要RDE－1或其同源基因ALG1／ALG2的协同。随着研究的深入,Dicer的其它生物功能将进一步被发现。     

Carrier DNA affects the integration of HSV-1 TK gene in the genome of L929TK- cells.

L929TK- cells were cotransfected with DNA mixtures containing tk gene of HSV-1, plasmids carrying LTR of MoMLV or RSV and carrier DNA of salmon sperm or chromosomal DNA of recipient cells. Selection of TK+ transformants was conducted in DMEM supplemented with HAT. Plasmids carrying LTR sequences of MoMLV or RSV retroviruses showed enhancing effect on the frequency of TK+ transformation. Southern blot analysis of chromosomal DNA of TK+ transformants demonstrated in clones deriving from cotransfections of tk gene and carrier DNA of L929TK- cells multiple copies of tk gene integrated into several genomic sites of host. Single copies of tk gene integrated into different sites of host genome occurred in chromosomal DNA of TK+ clones deriving from cotransfections of tk gene and carrier DNA of salmon sperm. Cells cotransfected with tk gene and plasmids carrying LTR sequences of MoMLV or RSV formed three dimensional colonies in semisolid agar medium. No effect of carrier DNA on the morphology of TK+ transformant clones was noticed.     

Adaptation of a retrovirus as a eucaryotic vector transmitting the herpes simplex virus thymidine kinase gene.

We investigated the feasibility of using retroviruses as vectors for transferring DNA sequences into animal cells. The thymidine kinase (tk) gene of herpes simplex virus was chosen as a convenient model. The internal BamHI fragments of a DNA clone of Moloney leukemia virus (MLV) were replaced with a purified BamHI DNA segment containing the tk gene. Chimeric genomes were created carrying the tk insert in both orientations relative to the MLV sequence. Each was transfected into TK- cells along with MLV helper virus, and TK+ colonies were obtained by selection in the presence of hypoxanthine, aminopterin, and thymidine (HAT). Virus collected from TK+-transformed, MLV producer cells passed the TK+ phenotype to TK- cells. Nonproducer cells were isolated, and TK+ transducing virus was subsequently rescued from them. The chimeric virus showed single-hit kinetics in infections. Virion and cellular RNA and cellular DNA from infected cells were all shown to contain sequences which hybridized to both MLV- and tk-specific probes. The sizes of these sequences were consistent with those predicted for the chimeric virus. In all respects studied, the chimeric MLV-tk virus behaved like known replication-defective retroviruses. These experiments suggest great general applicability of retroviruses as eucaryotic vectors.     

Construction and isolation of a transmissible retrovirus containing the src gene of Harvey murine sarcoma virus and the thymidine kinase gene of herpes simplex virus type 1

We constructed lambda recombinants containing the Harvey murine sarcoma virus genome and the thymidine kinase (tk) gene of herpes simplex virus type 1 linked to each other. The tk gene was located in a position downstream from both the long terminal repeat and the src gene of Harvey murine sarcoma virus. The DNAs of the lambda recombinants were used to transfect NIH3T3 mouse fibroblasts in order to obtain Harvey murine sarcoma virus DNA-induced foci of transformed cells. The transformed foci were superinfected with a helper-independent retrovirus, and new individual retrovirus were isolated from the superinfected foci. The new viruses could induce focus formation on NIH3T3 cells and could convert NIH3T3(TK-) cells into TK+ cells by carrying the herpes simplex virus type 1 tk gene into the TK- cells. From virus-infected cells, we isolated nonproducer foci on NIH3T3 cells and TK+ transformants on NIH3T3(TK-) cells containing one such new viral genome coding for the dual properties. The new retroviral sequence in the nonproducer cells could be rescued into virus particles at high titers by superinfection with a helper-independent retrovirus. A hybridization analysis indicated that the recombinant virus contained both the Harvey murine sarcoma virus src sequence and the tk gene sequence in a single RNA species approximately 4.9 kilobases long. We concluded that retroviruses can be used as true vectors for genes other than genes that lead to oncogenesis.     

Studying DNA mutations in human cells with the use of an integrated HSV thymidine kinase target gene

A shuttle vector carrying the origin of SV40 replication, the thymidine kinase (tk) gene of herpes simplex virus and the E. coli xanthine guanine phosphoribosyl transferase (gpt) gene has been introduced into human TK- cells. A transformed cell line containing only one stably integrated copy of the shuttle vector was used to study mutations in the introduced tk gene at the molecular level. Without selection for gpt expression, spontaneous TK- mutants arose at a frequency of approximately 10(-4)/generation, and were caused by deletion of plasmid sequences. However, when selection for expression of the gpt gene was applied, the background level of mutations at the tk gene was below 4.10(-6). From this cell line, TK- mutants were obtained after treatment with N-ethyl-N-nitrosourea (ENU). COS fusion appeared to be an efficient method for rescue and amplification of the integrated shuttle vector from the human chromosome. After further amplification and analysis in E. coli, rescued tk genes were easily identified and were shown to be physically unaltered by the rescue procedure. In contrast to rescued tk genes from TK+ cells, those obtained from the ENU-induced TK- mutants were unable to complement thymidine kinase-negative E. coli cells. Two such tk mutations were mapped in E. coli by marker rescue analysis. A GC----AT transition was the cause of both mutations. We show here that plasmid rescue by COS fusion is a reliable system for studying gene mutations in human cells, since no sequence changes occurred in rescued DNA except for the 2 ENU-induced sequence changes.     

Phenotypic switching in cells transformed with the herpes simplex virus thymidine kinase gene

Biochemical transformation of Ltk- cells with the herpes simplex virus thymidine kinase (tk) gene resulted in numerous TK+ colonies that survived selection in hypoxanthine-aminopterin-thymidine medium. Many of these TK+ cell lines switched phenotypes and reverted to the TK- state. In this report, we describe the biological and biochemical characteristics of three TK- revertant lines. One (K1B5) transiently expressed TK in the presence of bromodeoxyuridine, which selects for the TK- phenotype. Another TK- sibling (K1B6n) expressed TK only after removal from bromodeoxyuridine-containing medium. The last variant (K1B6me) lost the ability to switch to the TK+ phenotype, although it maintained the herpes simplex virus sequences coding for TK. Loss of the ability of K1B6me cells to express TK was correlated with extensive methylation of the sequence recognized by the restriction endonuclease HpaII (pCpCpGpG). After these cells were treated with 5-azacytidine, they regained the ability to clone in hypoxanthine-aminopterin-thymidine medium and reexpressed virus tk mRNA and enzyme. In addition, the HpaII sites that were previously shown to be refractile to enzyme digestion were converted to a sensitive state, demonstrating that they were no longer methylated.     

Evidence for allelic exclusion in Chinese hamster ovary cells.

Earlier results suggested that the functional hemizygosity of genes in pseudodiploid Chinese hamster ovary (CHO) cells is due to the silencing of one allele by DNA methylation. From this one could make a strong prediction that we have now been able to confirm by genetic experiments, using thymidine kinase (TK) alleles. TK- mutants induced by ethylmethane sulphonate (EMS) were all revertible to TK+ at high frequency by the demethylating agent 5-azacytidine (5-aza-CR). This revertibility was due to reactivation of a silent nonmutant TK allele. Further mutagenesis by EMS yielded TK- derivatives that were no longer revertible by 5-aza-CR; these are assumed to have mutations in both alleles. TK- cells were also transfected with equine herpes virus TK+ DNA, and the TK+ derivatives were shown to be markedly less stable than cells with the normal TK+ gene. CHO cells lack metallothionein activity (sensitive to cadmium), and also require proline for growth, because genes have become silenced during the establishment of the cell line. In both cases 5-aza-CR reactivates these genes to give the cadmium resistant and proline independent phenotypes. Long-term experiments with reactivants in the absence of selection showed that the genes become silent, presumably as a result of de novo methylation. A strain resistant to cytosine arabinoside (araCR) was also resistant to 5-azadeoxycytidine (5-aza-CdR), but not to 5-aza-CR, which would be expected if the araCR strain lacked deoxycytidine kinase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic transformation of somatic cells. VIII. The effect of the DNA methylation inhibitor 5-azacytidine on the stability of thymidine kinase-negative and -positive phenotypes of transformant clone cells

A study was made of the effect of an DNA methylation inhibitor 5-azacytidine (azaC) on the frequency of reversion to a thymidine kinase-positive (TK+) phenotype in 5-bromodeoxy-uridine (BrdU)-resistant subclones obtained from clones of Chinese hamster cells transformed by thymidine kinase gene (tk-gene) of Herpes simplex virus type 1 (HSV1). It is shown that in 8 of 15 BrdU-resistant subclones azaC increases 2-1000-fold the frequency of reversion to TK+ phenotype. Variations in the inducibility of reversions to TK+ phenotype indicate that the DNA methylation associated with TK- phenotype affects but differently tk gene of HSV1. Cultivation of TK+ cells of transformant clones in the presence of azaC may lead to stabilization (or decrease in the rate of the loss) of TK+ phenotype, or may not influence the stability of transformant phenotype. The reaction of TK+ cells of transformant clones depends both on genetically determined rate of the loss of TK+ phenotype, and on the structure of transforming DNA introduced to cells. A conclusion is drawn that the TK- phenotype of transformant clone cells arises due to processes which are not associated with methylation of tk gene of HSV1 in spite of the fact that such a methylation may later stabilize significantly the TK- phenotype.     

Biochemical transformation of thymidine kinase (TK)-deficient mouse cells by herpes simplex virus type 1 DNA fragments purified from hybrid plasmids.

The thymidine kinase (TK) gene of HSV-1 has been cloned in Escherichia coli K12 plasmids, pMH1, pMH1A, and pMH4. These plasmids contain a 1,92Obp HSV-1 TK DNA sequence, which replaces a 2,067 bp EcoR I to Pvu II sequence of plasmid pBR322 DNA. Superhelical DNAs of plasmids pMH1, pMH1A, and pMH4 as well as plasmid DNAs cleaved by EcoR I, Hinc II, Bg1 II, Sma I, and Pvu II transformed TK-deficient LM(TK-) cells to the TK+ phenotype. A 1,230bp EcoR I-Sma I fragment purified from pMH1 DNA (and from plasmid pAGO, DNA, the parent of pMH1) also transformed LM(TK-) cells. Serological and disc PAGE studies demonstrated that the TK activity expressed in biochemically transformed cells were HSV-1-specific. The experiments suggest that the HSV-1 TK coding region may be contained within a l.1kbp DNA sequence extending from about the Hinc II (or Bgl II) cleavage site to the Sma I site. 35S-methionine labeling experiments carried out on cell lines transformed by Hinc II-cleaved pMH1 DNA and by the EcoR I-Sma I fragment showed that the TKs purified from the transformed cells consisted of about 39-40,000 dalton polypeptides.     

Hybrid plasmids containing an active thymidine kinase gene of Herpes simplex virus 1.

The gene for the thymidine kinase (TK) of Herpes simplex virus type 1 (HSV-1) is located in the KpnI m and BamHI p fragments of the genome (Wigler et al., Cell 11, 223-232 (1977)). These fragments have been inserted into the EcoRI and BamHI sites, respectively, of plasmid pBR322, and propagated in E.coli. The TK gene contained in the recombinant plasmids was shown to be biologically active when introduced into TK- mouse L cells. Detailed restriction site maps of the BamHI p fragment have been constructed and the approximate location of the TK gene has been determined. Mouse cells transformed with cloned HSV-1 tk+ DNA produced HSV-1-specific thymidine kinase; superinfection with HSV-1 tk- virus increased the level of TK activity tenfold, suggesting that the BamHI p sequences present in transformed cells respond to virus-encoded regulatory gene product(s).     

Lack of site specific recombination of exogenous DNA in mouse L cells

Plasmids were constructed containing the HSV thymidine kinase gene and two copies of X. borealis 5S rDNA. Mouse L TK- cells were transformed with these DNAs, with selection for the TK+ gene. Transformed cells were then analyzed by Southern blot hybridization and hybridization in situ to determine whether integration of the exogenous DNA occurred at regions of chromosomal homology i.e., at the 5S rDNA regions. Four cell lines were analyzed by Southern blots. Differences in restriction endonuclease specificity strongly suggested that integration was at a different site in each cell line. Two cell lines were further analyzed by hybridization in situ; each showed a single integration site, both different from each other and different from the mouse L cell 5S rDNA sites. Therefore, the presence of two copies of the 5S rDNA gene in the DNA introduced by gene transfer and approximately 300-350 copies of the mouse 5S rDNA gene was not sufficient in these experiments to produce homologous integration into a specific site.