An IPTG Inducible Conditional Expression System for Mycobacteria

Conditional expression strains serve as a valuable tool to study the essentiality and to establish the vulnerability of a target under investigation in a drug discovery program. While essentiality implies an absolute requirement of a target function, vulnerability provides valuable information on the extent to which a target function needs to be depleted to achieve bacterial growth inhibition followed by cell death. The critical feature of an ideal conditional expression system is its ability to tightly regulate gene expression to achieve the full spectrum spanning from a high level of expression in order to support growth and near zero level of expression to mimic conditions of gene knockout. A number of bacterial conditional expression systems have been reported for use in mycobacteria. The utility of an isopropylthiogalactoside (IPTG) inducible system in mycobacteria has been reported for protein overexpression and anti-sense gene expression from a replicating multi-copy plasmid. Herein, we report the development of a versatile set of non-replicating IPTG inducible vectors for mycobacteria which can be used for generation of conditional expression strains through homologous recombination. The role of a single lac operator versus a double lac operator to regulate gene expression was evaluated by monitoring the expression levels of β-galactosidase in Mycobacterium smegmatis. These studies indicated a significant level of leaky expression from the vector with a single lac operator but none from the vector with double lac operator. The significance of the double lac operator vector for target validation was established by monitoring the growth kinetics of an inhA, a rpoB and a ftsZ conditional expression strain grown in the presence of different concentrations of IPTG. The utility of this inducible system in identifying target specific inhibitors was established by screening a focussed library of small molecules using an inhA and a rpoB conditional expression strain.     

Tightly regulated, beta-estradiol dose-dependent expression system for yeast

We have refined the regulated expression of UASGAL1, 10-driven genes in yeast by modifying a vector encoding the beta-estradiol inducible activator, GAL4.ER.VP16 (GEV). The expression of GEV was placed under the regulation of the low-level, constitutive MRP7 promoter, and beta-estradiol-regulated expression was monitored by the expression of an integrated UASGAL10-lacZ reporter and by immunoblot analysis of a UASGAL1-regulated gene product. Target gene expression regulated by low levels of GEV has several advantages over the standard galactose-inducible expression systems. (i) Most importantly, the target gene expression is undetectable in the absence of hormone; (ii) target gene expression is beta-estradiol dose-dependent, and variable levels of target gene expression from low to several hundred-fold induction can be achieved; and (iii) induction or depletion studies can be conducted independent of carbon source in gal4 delta strains. In addition, any UASGAL1,10 expression construct can be used without modification of the target gene or many gal4 delta host strains, and GEV vectors are compatible with other inducible yeast expression systems. This method may be useful to researchers investigating the functions of essential genes, dominant negative mutants, mitochondrial genes, and viral, plant, and mammalian genes in yeast assay systems.     

Physiologically responsive gene therapy

The goal of physiologically responsive gene therapy is to allow a host's endogenous regulatory mechanisms to control the production of therapeutic proteins (effectors). Ideally, effector production would be switched on in response to specific signals, stay within therapeutic limits and be switched off when no longer needed. In this way, the unwanted consequences of constitutive, high-level effector expression could be avoided. While recent studies have shown that transgenes can be regulated within animal hosts, they have also highlighted significant problems that require much further research.     

Location effects of a reporter gene on expression levels and on native protein synthesis in Lactococcus lactis and Saccharomyces cerevisiae

The engineering of industrially important genetically modified organisms by the integration of heterologous genes into the chromosome is often the method of choice for several reasons concerned with long-term stability, homogeneous population distribution, and the enabling of selection without the addition of antibiotics. However, integration may disrupt endogenous gene expression, giving rise to increased levels of toxic metabolic byproducts or activating otherwise silent genes. The position of integration of a foreign gene in the chromosome can also influence its expression levels, and this effect will be of relevance in terms of optimizing protein production parameters. In this study, we determine how the random integration of a foreign reporter gene might affect expression levels and assess the use of proteome analysis to investigate possible effects on synthesis of endogenous proteins in two important food-relevant microorganisms, Saccharomyces cerevisiae and Lactococcus lactis. Eleven L. lactis integrants carrying the gusA gene were analyzed, and expression levels were found to vary by a factor of threefold in contrast to expression levels of lacZ in 18 S. cerevisiae integrants, which showed a 14-fold variation. Of relevance to industry is whether any changes in expression levels might occur as a consequence of storage of the modified strains. Here it is also shown that the above differences in expression levels were not significantly affected by storage of frozen cultures over a period of several months. Analysis of the protein composition of the yeast and lactococcal integrant strains by separation on one-dimensional (1D) and 2D gels showed no significant variations in position beyond those observed in control samples.     

Glucocorticoid-induced expression of a foreign gene by the GVG system in transformed tobacco BY-2 cells

A glucocorticoid-induced target gene expression system was used to control the expression of the uidA gene, whose product was beta-glucuronidase (GUS), in tobacco BY-2 cell suspension culture. This targeting system showed quick, sensitive, and reversible response to dexamethazone (DEX), an artificial glucocorticoid hormone. Addition of DEX greatly and quickly enhanced uidA gene expression, whose level was as high as that under the control of the CaMV 35S promoter whereas in the absence of DEX, the GUS specific activity was suppressed to be as low as that of nontransformed BY-2 cells. The dilution of DEX decreased GUS specific activity showing that the concentration of DEX plays a major role in controlling the expression level of the target. The use of the glucocorticoid-induced system in plant cell suspension culture was demonstrated to precisely control target gene expression.     

Regulated gene expression in Staphylococcus aureus for identifying conditional lethal phenotypes and antibiotic mode of action

Selectively regulating gene expression in bacteria has provided an important tool for studying gene function. However, well-regulated gene control systems have been restricted primarily for use in laboratory non-pathogenic strains of bacteria (e.g. Escherichia coli, Bacillus subtilis). The development of analogous systems for use in bacterial pathogens such as Staphylococcus aureus would significantly enhance our ability to examine the contribution of any given gene product to pathogen growth and viability. In this report, we adapt, examine and compare three regulated gene expression systems in S. aureus, which had previously been used in B. subtilis. We demonstrate that all three systems function and exhibit titratable induction, together covering a dynamic range of gene expression of approximately 3000-fold. This dynamic range correlates well with the physiological expression levels of cellular proteins. Importantly, we show that one of these systems, the Spac system, is particularly useful for examining gene essentiality and creating specific conditional lethal phenotypes. Moreover, we find that titration of selective target gene products using this system allows direct demonstration of antibiotic mode of action.     

细胞信号转导与可变剪接调控

大多数真核基因能够发生可变剪接,其调控对于生理和病理状态下细胞功能的实现至关重要,而异常可变剪接则可导致多种疾病。虽然已知可变剪接能够在转录后水平调节基因表达,然而目前仍不清楚特定的可变剪接模式是如何被调控的。越来越多的研究发现细胞信号和外界环境刺激能够调控靶基因的剪接模式,并且已发现一些与可变剪接调控有关的信号转导通路,而后者能够通过修饰剪接因子进而改变剪接因子的亚细胞定位或者活性,从而实现对靶基因可变剪接模式的调控。由细胞信号转导通路所构成的网络能够灵活多样地调控基因剪接,一条信号通路可调控多个基因剪接,而多条信号通路也可调控同一基因剪接,对于理解信号转导过程的分子机制具有重要意义。     

Polymorphisms in the large subunit of human RNA polymerase II as target for allele-specific inhibition

The lack of specificity of cancer treatment causes damage to normal cells as well, which limits the therapeutic range. To circumvent this problem one would need to use an absolute difference between normal cells and cancer cells as therapeutic target. Such a difference exists in the genome of all individuals suffering from a tumor that is characterized by loss of genetic material [loss of heterozygosity (LOH)]. Due to LOH, the tumor is hemizygous for a number of genes, whereas the normal cells of the individual are heterozygous for these genes. Theoretically, polymorphic sites in these genes can be utilized to selectively target the cancer cells with an antisense oligonucleotide, provided that it can discriminate the alleles and inhibit gene expression. Furthermore, the targeted gene should be essential for cell survival, and 50% gene expression sufficient for the cell to survive. This will allow selective killing of cancer cells without concomitant toxicity to normal cells. As an initial step in the experimental test of this putative selective cancer cell therapy, we have developed a set of antisense phosphorothioate oligonucleotides which can discriminate the two alleles of a polymorphic site in the gene encoding the large subunit of RNA polymerase II. Our data show that the exact position of the antisense oligonucleotide on the mRNA is of essential importance for the oligonucleotide to be an effective inhibitor of gene expression. Shifting the oligonucleotide position only a few bases along the mRNA sequence will completely abolish the inhibitory activity of the antisense oligonucleotide. Reducing the length of the oligonucleotides to 16 bases increases the allele specificity. This study shows that it is possible to design oligonucleotides that selectively target the matched allele, whereas the expression level of the mismatched allele, that differs by one nucleotide, is only slightly affected.     

ESR and NMR studies provide evidence that phosphatidyl glycerol specifically interacts with poxvirus membranes

Background

Human cytomegalovirus (HCMV) is a ubiquitous herpesvirus that typically causes asymptomatic infections in healthy individuals but may lead to serious complications in newborns and immunodeficient individuals. The emergence of drug-resistant strains of HCMV has posed a need for the development of new drugs and treatment strategies. Antisense molecules are promising gene-targeting agents for specific regulation of gene expression. External guide sequences (EGSs) are oligonucleotides that consist of a sequence complementary to a target mRNA and recruit intracellular RNase P for specific degradation of the target RNA. The UL49-deletion BAC of HCMV was significantly defective in growth in human foreskin fibroblasts. Therefore, UL49 gene may serve as a potential target for novel drug development to combat HCMV infection. In this study, DNA-based EGS molecules were synthesized to target the UL49 mRNA of human cytomegalovirus (HCMV).

Results

By cleavage activity assessing in vitro, the EGS aimed to the cleavage site 324 nt downstream from the translational initiation codon of UL49 mRNA (i.e. EGS324) was confirmed be efficient to direct human RNase P to cleave the target mRNA sequence. When EGS324 was exogenously administered into HCMV-infected human foreskin fibroblasts (HFFs), a significant reduction of ~76% in the mRNA and ~80% in the protein expression of UL49 gene, comparing with the cells transfected with control EGSs. Furthermore, a reduction of about 330-fold in HCMV growth were observed in HCMV-infected HFFs treated with the EGS.

Conclusions

These results indicated that UL49 gene was essential for replication of HCMV. Moreover, our study provides evidence that exogenous administration of a DNA-based EGS can be used as a potential therapeutic approach for inhibiting gene expression and replication of a human virus.     

Location Effects of a Reporter Gene on Expression Levels and on Native Protein Synthesis in Lactococcus lactis and Saccharomyces cerevisiae

The engineering of industrially important genetically modified organisms by the integration of heterologous genes into the chromosome is often the method of choice for several reasons concerned with long-term stability, homogeneous population distribution, and the enabling of selection without the addition of antibiotics. However, integration may disrupt endogenous gene expression, giving rise to increased levels of toxic metabolic byproducts or activating otherwise silent genes. The position of integration of a foreign gene in the chromosome can also influence its expression levels, and this effect will be of relevance in terms of optimizing protein production parameters. In this study, we determine how the random integration of a foreign reporter gene might affect expression levels and assess the use of proteome analysis to investigate possible effects on synthesis of endogenous proteins in two important food-relevant microorganisms, Saccharomyces cerevisiae and Lactococcus lactis. Eleven L. lactis integrants carrying the gusA gene were analyzed, and expression levels were found to vary by a factor of threefold in contrast to expression levels of lacZ in 18 S. cerevisiae integrants, which showed a 14-fold variation. Of relevance to industry is whether any changes in expression levels might occur as a consequence of storage of the modified strains. Here it is also shown that the above differences in expression levels were not significantly affected by storage of frozen cultures over a period of several months. Analysis of the protein composition of the yeast and lactococcal integrant strains by separation on one-dimensional (1D) and 2D gels showed no significant variations in position beyond those observed in control samples.     

CHO/dhfr-细胞定点整合高效表达系统的建立

为了克服随机整合建立高表达细胞株时“位置效应”所带来的不可预知的后果,我们尝试建立基于定点整合的CHO高效表达系统。首先设计一个新的高效筛选载体pMCEscan。该载体含有报告基因（k2tPA）、扩增基因（dhfr）、重组酶识别序列（FRT）及筛选基因（neo）,且neo基因的表达经过系统的弱化,确保能够对基因组中的整合位点进行大规模的高效筛选。然后利用该载体转染CHO／dhfr^-细胞并进行大规模筛选以获得足够多的阳性克隆,并对阳性克隆进行系统分析,筛选出报告基因表达水平高、单拷贝且扩增效果好的克隆,此克隆被认为筛选载体整合入CHO细胞基因组中转录热点（Hotspot）区域,从而获得了能够实现外源基因在基因组中定点整合和有效表达的CHO／dhfr-细胞系。随后利用位点特异性重组系统（FLP-FRT）将外源基因定点整合到Hotspot区域,以实现外源基因在CHO细胞基因组中的定点整合及高效表达。并利用该细胞系实现了k2tPA的高表达,表达量达到17．1μg／10^6cell·24h。该研究致力于CHO细胞基因组中高表达位点的寻找和确认,建立基于定点整合的哺乳动物细胞高效表达系统。     

Enhancement of photoheterotrophic biohydrogen production at elevated temperatures by the expression of a thermophilic clostridial hydrogenase

The working temperature of a photobioreactor under sunlight can be elevated above the optimal growth temperature of a microorganism. To improve the biohydrogen productivity of photosynthetic bacteria at higher temperatures, a [FeFe]-hydrogenase gene from the thermophile Clostridium thermocellum was expressed in the mesophile Rhodopseudomonas palustris CGA009 (strain CGA-CThydA) using a log-phase expression promoter P( pckA ) to drive the expression of heterogeneous hydrogenase gene. In contrast, a mesophilic Clostridium acetobutylicum [FeFe]-hydrogenase gene was also constructed and expressed in R. palustris (strain CGA-CAhydA). Both transgenic strains were tested for cell growth, in vivo hydrogen production rate, and in vitro hydrogenase activity at elevated temperatures. Although both CGA-CThydA and CGA-CAhydA strains demonstrated enhanced growth over the vector control at temperatures above 38?°C, CGA-CThydA produced more hydrogen than the other strains. The in vitro hydrogenase activity assay, measured at 40?°C, confirmed that the activity of the CGA-CThydA hydrogenase was higher than the CGA-CAhydA hydrogenase. These results showed that the expression of a thermophilic [FeFe]-hydrogenase in R. palustris increased the growth rate and biohydrogen production at elevated temperatures. This transgenic strategy can be applied to a broad range of purple photosynthetic bacteria used to produce biohydrogen under sunlight.     

Directing neuron-specific transgene expression in the mouse CNS

Recent advances in molecular genetics have produced many novel strategies for directing the expression of both functional and regulatory elements in transgenic mice. With the application of such approaches, the specific populations that comprise CNS networks can be both visualized and manipulated. Transgenic methods now range from the use of specific enhancer elements and large genomic regions assembled using BACs and PACs, to the use of gene targeting to a specific locus. In addition, the advent of transactivators and site-specific recombinases has provided unprecedented spatial and temporal control for directing expression in the CNS using a combination of appropriate alleles. As a result, the promise of being able to use transgenics to target specific neuronal populations is now being realized.