Phage Trojan horses: a conditional expression system for lethal genes

The EcoRI restriction enzyme (ENase) cleaves DNA molecules within the sequence GAATTC. Cells expressing this lethal activity normally make a second enzyme, the M.EcoRI methyltransferase (MTase), which protects their chromosomal DNA by modifying the EcoRI recognition sites. To isolate mutants of the EcoRI ENase, its gene was cloned into a filamentous phage vector (M13mp18) under control of the lac promoter. Normally, filamentous phages (M13, f1 and their derivatives) form turbid plaques by impairing the growth of their host cell without killing it. In contrast, phages expressing the EcoRI ENase kill the host cell, but survive long enough to produce plaques which are very clear. Expression of the M.EcoRI MTase rescues the host and restores turbid plaque formation. EcoRI ENase mutants were isolated by screening for mutants that make turbid, instead of clear, plaques on an M- host. This conditional expression system may be useful for cloning and mutating genes for other toxic proteins.     

A versatile vector system for multiple gene expression in plants

Today, cloning vectors that have been specifically designed to facilitate the fusion, overexpression or down-regulation of a variety of genes in plant cells are available from various sources. In most cases, their basic design allows the cloning of a single target gene, typically under a specific promoter, in parallel with the expression of selection and/or marker genes from the same vector. However, new and versatile systems now exist that expand the user's choice to a large number of promoters and terminators, and various autofluorescent tags confer the ability to express multiple genes from a single transformation vector.     

pPSY: a vector for the stable cloning and expression of streptomycete single gene phenotypes in Escherichia coli

pPSY is a 12kb cloning vector derived from the IncW plasmid R388, which provides a rapid and easy way to stably clone phenotypes encoded in DNA segments <10kb. In the present study three different genes were amplified by PCR, cloned into pGEM-T Easy and sub-cloned into the EcoRI site of pPSY. The first gene, vioA, is a FAD-dependent l-tryptophan amino acid oxygenase from the high G+C Gram-negative bacterium Chromobacterium violaceum. VioA is involved in the synthesis of the indolocarbazole antitumour antibiotic violacein. It was found that vioA was strongly expressed in Escherichia coli from its native promoter. Two other genes encoding recombinase A (recA) and an amylase (amyA), derived from the high G+C Gram-positive streptomycete, Streptomyces lividans, were also tested. Despite recA lacking its native promoter sequence, it was strongly expressed in E. coli using the lac promoter of pGEM-T Easy. Similar to vioA, S. lividansamyA was strongly expressed in E. coli from its native promoter. Unlike pGEM-T Easy, pPSY stably maintained all three genes without the requirement for antibiotic selection. These results demonstrate the applicability of pPSY as a stable amplicon cloning vector for the expression of heterologous genes in E. coli.     

An expression vector system providing plasmid stability and conditional suicide of plasmid-containing cells

Summary A cloning vector system was constructed on the basis of the pBR322 derivative pEG1 by introducing the whole parB locus of plasmid R1 cloned behind the promoter of the alkaline phosphatase gene (phoA) of Escherichia coli. The parB locus in combination with the phoA promoter ensures both (i) plasmid stabilization due to the post-segregational killing of plasmid-free cells during growth and (ii) killing of the cells induced by the potential environmental signal phosphate limitation. This vector, therefore, appears to be a model system for increasing the stability of recombinant plasmids and for decreasing the potential risks in the application of recombinant bacteria in industrial fermentations.Correspondence to: T. Schweder     

New vector system for induction of gene expression in dicotyledonous plants

A system of two vectors, pEnLox and pCre, was developed. The pEnLox vector is used to induce insertional mutations, while pCre is used to obtain transgenic plants expressing the Cre recombinase gene. The T-DNA enhancer is flanked by the loxP sites in the pEnLox vector. As an Arabidopsis thaliana insertional mutant obtained by transformation with pEnLox is crossed with another transgenic line carrying the cre gene, the enhancer sequence is eliminated. The vector system makes it possible to induce insertional mutations and to determine whether the mutant phenotype is caused by the loss-of-function insertional mutation or by overespression of nearby genes in response to the enhancer contained in the insert.     

New vector system for induction of gene expression in dicotyledonous plants

A system of two vectors, pEnLox and pCre. was developed. The pEnLox vector is used to induce insertional mutations, while pCre is used to obtain transgenic plants expressing the Cre recombinase gene. The T-DNA enhancer is flanked by the loxP sites in the pEnLox vector. As an Arahidopsis thaliana insertional mutant obtained by transformation with pEnLox is crossed with another transgenic line carrying the cre gene. the enhancer sequence is eliminated. The vector system makes it possible to induce insertional mutations and to determine whether the mutant phenotype is caused by the loss-of-function insertional mutation or by overespression of nearby genes in response to the enhancer contained in the insert.     

Smad2条件基因剔除载体的构建及LoxP位点有效性鉴定

Smads家族是最新发现的TGF－β信号转导途径中一个重要的新基因家族,SMAD2属于受体激活的SMADs。Smad2在某些肿瘤中发生突变,是一种可能的肿瘤抑制基因。Smad2基因完全剔除小鼠在胚胎期E6．5天死亡,为了研究Smad2在成体各组织器官及肿瘤发生中的可能作用,构建了Smad2条件基因剔除载体,将LoxP置于Smad2基因组序列C末端功能域两侧,并在组成型表达Cre重组酶的大肠杆菌中检测了LoxP位点的功能,该载体的构建为进行Smad2组织特异性基因剔除研究了奠定了基础。     

A versatile tool for conditional gene expression and knockdown

Drug-inducible systems allowing the control of gene expression in mammalian cells are invaluable tools for genetic research, and could also fulfill essential roles in gene- and cell-based therapy. Currently available systems, however, often have limited in vivo functionality because of leakiness, insufficient levels of induction, lack of tissue specificity or prohibitively complicated designs. Here we describe a lentiviral vector-based, conditional gene expression system for drug-controllable expression of polymerase (Pol) II promoter-driven transgenes or Pol III promoter-controlled sequences encoding small inhibitory hairpin RNAs (shRNAs). This system has great robustness and versatility, governing tightly controlled gene expression in cell lines, in embryonic or hematopoietic stem cells, in human tumors xenotransplanted into nude mice, in the brain of rats injected intraparenchymally with the vector, and in transgenic mice generated by infection of fertilized oocytes. These results open up promising perspectives for basic or translational research and for the development of gene-based therapeutics.     

Potential of adenovirus as a vector for sustained gene expression

Inder Verma received his Ph.D. in biochemistry from the Weizmann Institute of Science, Rehovot, Israel, in 1971, and was a postdoctoral fellow (with David Baltimore) in the Department of Biology, Massachussetts Institute of Technology. He is currently American Cancer Society Professor of Molecular Biology, Chair of the Laboratory of Genetics at the Salk Institute for Biological Studies, and Adjunct Professor in the Department of Biology, University of California at San Diego. Inder Verma is a member of the National Academy of Sciences (USA). He is a member of the editorial boards of The Journal of Gene Medicine, Journal of Virology and Gene, and serves on several other scientific advisory boards. His major fields of interest are molecular analysis of oncoproteins, and suppressor genes, gene therapy involving retroviral, adenoviral, AAV vectors, and generation of novel lentiviral vectors. Copyright © 1999 John Wiley & Sons, Ltd.     

Cauliflower mosaic virus as a gene expression vector for plants

It is possible to replace the CaMV (cauliflower mosaic virus) ORF (open reading frame) II with foreign sequences without interfering with virus viability. Such recom-binants can induce the synthesis of substantial amounts of a foreign protein in infected plants and confer new properties to these plants. However, so far only three genes have been successfully cloned and expressed in this way. The expression mechanism of CaMV demands precise replacement of ORF II and probably certain structural features of the viral 35S RNA, which should not be disturbed by inserted sequences. Since these features are largely unknown, it cannot at present be pre-dicted whether an insert will be tolerated. It is more likely that larger inserts will disturb the viral gene expression mechanism than smaller ones.     

Strict regulation of gene expression from a high-copy plasmid utilizing a dual vector system

High-copy plasmids are useful for producing large quantities of plasmid DNA, but are generally inadequate for tightly regulating gene expression. Attempts to suppress expression of genes on high-copy plasmids often results in residual or “leaky” production of protein. For stringent regulation of gene expression, it is often necessary to excise the gene of interest and subclone it into a low-copy plasmid. Here, we report a dual plasmid technique that enables tight regulation of gene expression driven by the lac promoter in a high-copy vector. A series of plasmids with varying copies of the lacI^q gene have been constructed to permit titration of the LacI protein. When a high-copy plasmid is transformed along with the appropriate lacI^q-containing plasmid, tight gene regulation is achieved, thus eliminating the need to subclone genes into low-copy plasmids. In addition, we show that this dual plasmid technique enables high-copy gene expression of a protein lethal to Escherichia coli, the ccdB protein. In principle, this technique can be applied to any high-copy plasmid containing the popular pUC replication of origin and provides an easier means of obtaining rigid control over gene expression.