A retroviral vector for siRNA expression in mammalian cells

Utilization of RNA interference (RNAi) for knockdown of gene expression has become a standard tool for the study of gene function. Short hairpin RNAs (shRNAs) expressed from RNA polymerase III promoters are widely used to achieve stable knockdown of gene expression by RNAi. We have constructed a retroviral-based shRNA expression vector, pSiRPG, as a tool for shRNA-based functional genomic studies. This vector is based on a widely used shRNA expression system and was modified to harbor an enhanced green fluorescent protein (EGFP) and a puromycin selection marker. The functionality of the elements in the pSiRPG vector was validated. The H1(TetO₂) promoter in the vector facilitates doxycycline-inducible shRNA expression, which was demonstrated in cells expressing the Tet repressor (TetR). However, we also demonstrated limited efficiency of the inhibition of shRNA expression in an uninduced TetR-expressing cell line. This observation strongly indicates that the H1(TetO₂) promoter, which is used in a wide range of vectors, is not optimal for tightly regulated shRNA expression. Stable repression of the NDRG1 protein level was observed when introducing pSiRPG constructs expressing shRNAs targeting NDRG1 into two mammary epithelial cell lines by retroviral delivery. This vector should therefore facilitate functional studies in breast cell lines that are hard to transfect with conventional plasmid-based methods.     

A novel BK virus-based episomal vector for expression of foreign genes in mammalian cells.

A composite mammalian cell-E. coli shuttle vector was developed based on the human papova virus BK and pSV-neo. The vector contains a dioxin-responsive enhancer (DRE) controlling a mouse mammary tumor virus (MMTV) promoter for the inducible expression of inserted genes. In human cells the vector replicates episomally, presumably utilizing the BKV rather than the SV40 origin, and expresses the BK T/t antigens. A deletion in the late BK region precludes the expression of the core/capsid proteins VP1, VP2, and VP3, thereby preventing the infectious lytic cycle. HeLa cells which were transfected with this vector and selected for resistance to the antibiotic G418 maintained the construct primarily in episomal form during more than one year of continuous culture, with little or no integration into the host genome. Transformed cells cultured in higher concentrations of G418 contained higher copy numbers of the vector. This permits one to vary the dosage of an inserted gene easily and reversibly without the need of conventional amplification techniques and clonal analysis. Using a chloramphenicol acetyl transferase (CAT) reporter gene inserted downstream of the MMTV promoter, we found that CAT expression was greater in clones with higher vector copy number. CAT expression was inducible with 2,3,7,8-tetrachlorodibenzo-p-dioxin, but inducibility was found to be inversely proportional to the copy number. Transformation of bacteria with plasmid molecules retrieved from the mammalian host was efficient, making this vector well adapted for the screening of cDNA libraries for the ability to express a phenotype in mammalian cells. Moreover, DNA sequences were stable during long-term passage in mammalian cells; vector passaged continuously for more than one year retained fully functional bacterial genes for resistance to chloramphenicol and ampicillin.     

Pharmacological-based translational induction of transgene expression in mammalian cells

In the quest for the development of pharmacological switches that control gene expression, no system has been reported that regulates at the translational level. To permit small-molecule control of transgene translation, we have constructed a farnesyl transferase inhibitor-responsive translation initiation factor. This artificial protein is a three-component chimaera consisting of the ribosome recruitment core of the eIF4G1 eukaryotic translation initiation factor, the RNA-binding domain of the R17 bacteriophage coat protein and the plasma membrane localization CAAX motif of farnesylated H-Ras. This membrane-delocalized translation factor is inactive unless liberated in the cytosol. Farnesyl transferase inhibitor FTI-277 prevents the membrane association of the CAAX motif and thus increases the cytoplasmic levels of the eIF4G fusion protein, which is then capable of inducing translation of the second cistron of a bicistronic messenger RNA containing an R17-binding site in its intercistronic space. Such direct translational control by farnesyl transferase inhibitors provides a system for fast, graded and reversible regulation of transgene expression.     

A baculovirus expression vector system for simultaneous protein expression in insect and mammalian cells

Since the number of potential drug targets identified has significantly increased in the past decade, rapid expression of recombinant proteins in sufficient amounts for structure determination and modern drug discovery is one of the major challenges in pharmaceutical research. As a result of its capacity for insertion of large DNA fragments, its high yield of recombinant protein and its high probability of success compared to protein expression in Escherichia coli, the baculovirus expression vector system (BEVS) is used routinely to produce recombinant proteins in the milligram scale. For some targets, however, expression of the recombinant protein with the BEVS in insect cells fails and mammalian expression systems have to be used to achieve proper post-translational processing of the nascent polypeptide. We now introduce a modified BEVS as a very useful tool for simultaneously testing the expression of target proteins in both insect and mammalian cells by using baculovirus infection of both host systems. The expression yields in insect cells are comparable to those obtained with state-of-the-art baculovirus vectors, such as the Bac-to-Bac system. Using the same virus, we can transduce mammalian cells to quickly assess target gene expression feasibility and optimize expression conditions, eliminating additional cloning steps into mammalian expression vectors. This reduces time and effort for finding appropriate expression conditions in various hosts.     

A bicistronic baculovirus vector for transient and stable protein expression in mammalian cells

Baculoviruses are widely used for protein production in insect cells, and their potential for gene transfer to mammalian cells is increasingly being recognized. Here we describe a baculovirus vector with a bicistronic mammalian expression cassette and demonstrate its suitability for efficient transient and stable protein expression in human glioblastoma cells. Bicistronic baculovirus vectors are safe, cost efficient, and easy to produce; thus, they represent an excellent gene transfer system for mammalian cells.     

Novel promoter/transactivator configurations for macrolide- and streptogramin-responsive transgene expression in mammalian cells

Background

The recently developed heterologous macrolide‐ (E.REX system) and streptogramin‐ (PIP system) responsive gene regulation systems show significant differences in their regulation performance in diverse cell lines.

Methods

In order to provide optimal regulation modalities for a wide variety of mammalian cell lines, we have performed a detailed analysis of E.REX and PIP systems modified in (i) the transactivation domains of the antibiotic‐dependent transactivators, (ii) the type of minimal promoter used, and (iii) the spacing between the operator module and the minimal promoter.

Results

These novel E.REX and PIP regulation components showed not only dramatically improved regulation performance in some cell types, but also enabled their use in cell lines which had previously been inaccessible to regulated transgene expression.

Conclusions

Due to their modular set‐up the novel E.REX and PIP regulation systems presented here are most versatile and ready for future upgrades using different cell‐specific key regulation components. Copyright © 2002 John Wiley & Sons, Ltd.

     

Adeno-associated viral vectors engineered for macrolide-adjustable transgene expression In mammalian cells and mice

Background  

Adjustable gene expression is crucial in a number of applications such as de- or transdifferentiation of cell phenotypes, tissue engineering, various production processes as well as gene-therapy initiatives. Viral vectors, based on the Adeno-Associated Virus (AAV) type 2, have emerged as one of the most promising types of vectors for therapeutic applications due to excellent transduction efficiencies of a broad variety of dividing and mitotically inert cell types and due to their unique safety features.     

A lentiviral vector with novel multiple cloning sites: stable transgene expression in vitro and in vivo

Gene delivery has become an important tool for biological research and gene therapy trials. Lentiviral vector (LV) mediated gene transfer is a preferred approach for stable, sustained transgenic expression. We report here step-wise development of an Indian human immunodeficiency virus type 2 (HIV-2) isolate derived third generation lentiviral vector with a novel, versatile multiple cloning site (MCS) that can also facilitate single step sub-cloning of a PCR amplified transgene cassette by T/A cloning strategy apart from useful cohesive/blunt end cloning. Efficiency of the vector systems was functionally demonstrated by development of a transgenic enhanced green fluorescence protein (GFP) expressing cell line. Further, a GFP down regulated cell line was derived from the said cell line through LV mediated shRNA expression by cloning the GFP-shRNA cassette using the T/A cloning strategy. Subsequently long term expression of GFP transgene in nude mouse spleen/liver was also documented till 30 days. This LV platform with the enhanced user friendly cloning options will be an important advancement in gene transfer technology.