Regulated Antisense RNA Eliminates Alpha-Toxin Virulence in Staphylococcus aureus Infection

The ability to selectively disrupt gene function remains a critical element in elucidating information regarding gene essentiality for bacterial growth and/or pathogenesis. In this study, we adapted a tet regulatory expression system for use in Staphylococcus aureus, with the goal of downregulating gene expression via induction of antisense RNA. We demonstrate that this system exhibits a 50- to 100-fold dose-dependent level of induction in bacterial cells grown in culture (i.e., in vitro) and also functions in mice (i.e., in vivo) following oral administration of inducer. To determine whether induced antisense RNA could interfere with chromosomally derived gene expression, we cloned a fragment of the S. aureus alpha-toxin gene (hla) in antisense orientation downstream of the tet promoter system and introduced the construct into S. aureus. Induced antisense hla RNA downregulated chromosomally derived hla gene expression in vitro approximately 14-fold. Similarly, induction of hla antisense RNA in vivo dramatically reduced alpha-toxin expression in two different murine models of S. aureus infection. Most importantly, this reduction completely eliminated the lethality of the infection. These results indicate that the tet regulatory system functions efficiently in S. aureus and induced antisense RNA can effectively downregulate chromosomal gene expression both in vitro and in vivo.     

Characterization of the Escherichia coli AaeAB efflux pump: a metabolic relief valve?

Treatment of Escherichia coli with p-hydroxybenzoic acid (pHBA) resulted in upregulation of yhcP, encoding a protein of the putative efflux protein family. Also upregulated were the adjacent genes yhcQ, encoding a protein of the membrane fusion protein family, and yhcR, encoding a small protein without a known or suggested function. The function of the upstream, divergently transcribed gene yhcS, encoding a regulatory protein of the LysR family, in regulating expression of yhcRQP was shown. Furthermore, it was demonstrated that several aromatic carboxylic acid compounds serve as inducers of yhcRQP expression. The efflux function encoded by yhcP was proven by the hypersensitivity to pHBA of a yhcP mutant strain. A yhcS mutant strain was also hypersensitive to pHBA. Expression of yhcQ and yhcP was necessary and sufficient for suppression of the pHBA hypersensitivity of the yhcS mutant. Only a few aromatic carboxylic acids of hundreds of diverse compounds tested were defined as substrates of the YhcQP efflux pump. Thus, we propose renaming yhcS, yhcR, yhcQ, and yhcP, to reflect their role in aromatic carboxylic acid efflux, to aaeR, aaeX, aaeA, and aaeB, respectively. The role of pHBA in normal E. coli metabolism and the highly regulated expression of the AaeAB efflux system suggests that the physiological role may be as a "metabolic relief valve" to alleviate toxic effects of imbalanced metabolism.     

Genomic analysis using conditional phenotypes generated by antisense RNA

Antisense technology has been widely used to regulate gene expression. A tetracycline (tet)-regulated antisense-RNA-expressing system has been developed and used to downregulate chromosomally derived genes expressed in Staphylococcus aureus. This downregulation subsequently provides an evaluation of the virulence factor and drug targets. The regulated antisense RNA library allows for genome-wide analyses of the functions of staphylococcal gene products for growth in culture and survival during infection. Moreover, this antisense RNA technology may provide a key tool to identify mechanisms of novel antibacterial compound action.     

A genome-wide strategy for the identification of essential genes in Staphylococcus aureus

To address the need for new approaches to antibiotic drug development, we have identified a large number of essential genes for the bacterial pathogen, Staphylococcus aureus, using a rapid shotgun antisense RNA method. Staphylococcus aureus chromosomal DNA fragments were cloned into a xylose-inducible expression plasmid and transformed into S. aureus. Homology comparisons between 658 S. aureus genes identified in this particular antisense screen and the Mycoplasma genitalium genome, which contains 517 genes in total, yielded 168 conserved genes, many of which appear to be essential in M. genitalium and other bacteria. Examples are presented in which expression of an antisense RNA specifically reduces its cognate mRNA. A cell-based, drug-screening assay is also described, wherein expression of an antisense RNA confers specific sensitivity to compounds targeting that gene product. This approach enables facile assay development for high throughput screening for any essential gene, independent of its biochemical function, thereby greatly facilitating the search for new antibiotics.     

Characterization of essential enolase in <Emphasis Type="Italic">Staphylococcus aureus</Emphasis>

In this study, we characterized the essentiality of enolase for growth of Staphylococcus aureus in vitro by using a TetR-regulated antisense RNA expression technology. The induced enolase antisense RNA dramatically decreased the production of enolase, which in turn inhibited the growth of S. aureus. In addition, we found that the down-regulation of eno expression can effectively inhibit Triton X-100-induced lysis and alleviate penicillin-caused cell lysis. To further confirm the specific effect of enolase on autolysis, we constructed an enolase over-expression system and demonstrated that the over-expression of enolase enhances both Triton X-100 and penicillin-induced cell lysis without increasing cell growth rate. We also performed hydrolase induced autolysis and zymographic assays and found that enolase had no impact on either bacterial sensitivity to hydrolase or hydrolase activity. Moreover, we found that the down-regulating expression of enolase selectively increased bacterial sensitivity to phosphomycin. Taken together, the above results suggest that the enolase is essential for S. aureus and involved in the process of bacterial autolysis.     

Validation of antibacterial mechanism of action using regulated antisense RNA expression in Staphylococcus aureus

Validation of antibiotic mode of action in whole bacterial cells is a key step for antibiotic drug discovery. In this study, one potential drug target, enoyl-acyl carrier protein reductase (FabI), an essential enzyme in the fatty acid biosynthesis pathway, was used to evaluate the feasibility of using a regulated antisense RNA interference approach to determine antibiotic mode of action. Antisense isogenic strains expressing antisense RNA to fabI were created using a tetracycline-regulated vector in Staphylococcus aureus. We demonstrated that down-regulation of FabI expression by induction of fabI antisense RNA induces a conditional lethal phenotype. In contrast, partial down-regulation gives a viable cell with a significant increase in sensitivity to FabI-specific inhibitors (i.e., a sensitized phenotype). More importantly, the mode of action for novel FabI inhibitors has been confirmed using this genetic approach in whole cell assay. These results indicate that controlled antisense technology provides a robust tool for defining and tracking the mode of action of novel antibacterial agents.     

Gene silencing in Escherichia coli using antisense RNAs expressed from doxycycline‐inducible vectors

Here, we report on the construction of doxycycline (tetracycline analogue)‐inducible vectors that express antisense RNAs in Escherichia coli. Using these vectors, the expression of genes of interest can be silenced conditionally. The expression of antisense RNAs from the vectors was more tightly regulated than the previously constructed isopropyl‐β‐D‐galactopyranoside‐inducible vectors. Furthermore, expression levels of antisense RNAs were enhanced by combining the doxycycline‐inducible promoter with the T7 promoter‐T7 RNA polymerase system; the T7 RNA polymerase gene, under control of the doxycycline‐inducible promoter, was integrated into the lacZ locus of the genome without leaving any antibiotic marker. These vectors are useful for investigating gene functions or altering cell phenotypes for biotechnological and industrial applications.

Significance and Impact of the Study

A gene silencing method using antisense RNAs in Escherichia coli is described, which facilitates the investigation of bacterial gene function. In particular, the method is suitable for comprehensive analyses or phenotypic analyses of genes essential for growth. Here, we describe expansion of vector variations for expressing antisense RNAs, allowing choice of a vector appropriate for the target genes or experimental purpose.     

Persistent expression of the tumor suppressor gene DCC is essential for neuronal differentiation.

Cell differentiation is associated either with a complete loss of proliferative potential or with a change in growth requirements. Neoplastic transformation may result from the activation of oncogenes that support growth or from inactivation or loss of tumor suppressor genes, which are thought to regulate differentiation. To examine the relationship between tumor suppressor genes and cell differentiation, we chose the gene "deleted in colorectal cancer" (DCC) and studied its role in a pheochromocytoma cell line, PC-12, using antisense RNA as well as antisense oligonucleotides to DCC. When exposed to nerve growth factor for several days, PC-12 cells develop long dendrites. This morphological change follows the transient expression of immediate early genes and is associated with an up-regulation of DCC. Interestingly, if the up-regulation of DCC was counteracted using an antisense RNA technique, the morphological changes were prevented, but the other parameters of the nerve growth factor response were unaffected. Moreover, when DCC expression was inhibited by antisense oligonucleotides to DCC in nerve growth factor-differentiated cells, the neuron-like phenotype was reversed. Our results demonstrate that the gene DCC is involved in a distal segment of neural differentiation and provide the first direct evidence that a tumor suppressor gene plays a role in cell differentiation.     

Conditional mutation of an essential putative glycoprotease eliminates autolysis in Staphylococcus aureus

Our previous studies demonstrated that a putative Staphylococcus aureus glycoprotease (Gcp) is essential for bacterial survival, indicating that Gcp may be a novel target for developing antibacterial agents. However, the biological function of Gcp is unclear. In order to elucidate the reason that Gcp is required for growth, we examined the role of Gcp in bacterial autolysis, which is an important biological process for bacterial growth. Using both a spacp-regulated gcp expression strain and a TetR-regulated gcp antisense expression strain, we found that the down-regulation of gcp expression can effectively inhibit Triton X-100-induced lysis, eliminate penicillin- and vancomycin-caused cell lysis, and dramatically increase tolerance to hydrolases. Moreover, we determined whether resistance to lysis is due to a defect in murein hydrolase activity by using a zymogram analysis. The results showed that the cell lysate of a down-regulated gcp expression mutant displayed several bands of decreased murein hydrolytic activity. Furthermore, we explored the potential mechanism of Gcp's involvement in autolysis and demonstrated that Gcp may function independently from several key autolysins (Atl, LytM, and LytN) and regulators (ArlRS, Mgr/Rat, and CidA). Taken together, the above results indicate that the essential Gcp is involved in the modification of substrates of murein hydrolases as well as in the regulation of expression and/or activity of some murein hydrolases, which, in turn, may play important roles in bacterial viability.     

Characterization and application of a glucose-repressible promoter in Francisella tularensis

Francisella tularensis, the causative agent of tularemia, is a category A biodefense agent. The examination of gene function in this organism is limited due to the lack of available controllable promoters. Here, we identify a promoter element of F. tularensis LVS that is repressed by glucose (termed the Francisella glucose-repressible promoter, or FGRp), allowing the management of downstream gene expression. In bacteria cultured in medium lacking glucose, this promoter induced the expression of a red fluorescent protein allele, tdtomato. FGRp activity was used to produce antisense RNA of iglC, an important virulence factor, which severely reduced IglC protein levels. Cultivation in glucose-containing medium restored IglC levels, indicating the usefulness of this promoter for controlling both exogenous and chromosomal gene expression. Moreover, FGRp was shown to be active during the infection of human macrophages by using the fluorescence reporter. In this environment, the FGRp-mediated expression of antisense iglC by F. tularensis LVS resulted in reduced bacterial fitness, demonstrating the applicability of this promoter. An analysis of the genomic sequence indicated that this promoter region controls a gene, FTL_0580, encoding a hypothetical protein. A deletion analysis determined the critical sites essential for FGRp activity to be located within a 44-bp region. This is the first report of a conditional promoter and the use of antisense constructs in F. tularensis, valuable genetic tools for studying gene function both in vitro and in vivo.     

bri3, a novel gene, participates in tumor necrosis factor-alpha-induced cell death

bri3 was identified to be a novel gene up-regulated in TNF-treated cells with suppressed subtractive hybridization (SSH) in our laboratory. Previous studies showed that overexpression of BRI3 induced apoptosis in L929 cells. To further study the function of bri3, we disrupted its expression by expressing bri3 antisense RNA. The antisense RNA promoted resistance to TNF-induced cell death by more than 1000-fold in L929 cells, suggesting the involvement of BRI3 in TNF-induced cell death in this cell line. Analysis of cell death caused by other apoptotic inducers showed that the effect of BRI3 antisense RNA is highly specific to TNF-induced cell death. Taken together, bri3 appears to play an important role in TNF-induced cell death. Finally, we reported here that BRI3 may be localized to lysosome and function through lysosome.     

HCRP1, a novel gene that is downregulated in hepatocellular carcinoma, encodes a growth-inhibitory protein

One of the most frequent allelic deletions in hepatocellular carcinoma (HCC) has been found at chromosome 8p21-23. We reported here the identification and characterization of a novel gene for a hepatocellular carcinoma related protein 1 (HCRP1) localized at 8p22, which was isolated by positional candidate cloning. The expression of the gene for HCRP1 was most abundant in normal human liver tissue and significantly reduced or undetected in HCC tissues. The analysis of subcellular distribution showed that HCRP1 diffused in the cytoplasm with a significant fraction accumulated in the nuclei. After introduction of the sense and antisense cDNA of HCRP1 into HCC cell line SMMC-7721, we observed that the overexpression of HCRP1 significantly inhibited both anchorage-dependent and anchorage-independent cell growth in vitro. Using the transgenic short hairpin RNA (shRNA) to knock down the expression of HCRP1 gene in the other HCC cell line BEL-7404 resulted in the cell growth greatly enhanced. Moreover, reduction of the HCRP1 gene expression could also elevate the invasive ability of BEL-7404 cells. Our results strongly suggest that HCRP1 might be a growth inhibitory protein and associated with decreasing the invasion of HCC cells.     

Delineating Bacteriostatic and Bactericidal Targets in Mycobacteria Using IPTG Inducible Antisense Expression

In order to identify novel high value antibacterial targets it is desirable to delineate whether the inactivation of the target enzyme will lead to bacterial death or stasis. This knowledge is particularly important in slow growing organisms, like mycobacteria, where most of the viable anti-tubercular agents are bactericidal. A bactericidal target can be identified through the conditional deletion or inactivation of the target gene at a relatively high cell number and subsequently following the time course of survival for the bacteria. A simple protocol to execute conditional inactivation of a gene is by antisense expression. We have developed a mycobacteria specific IPTG inducible vector system and monitored the effect of antisense inhibition of several known essential genes in mycobacteria by following their survival kinetics. By this method, we could differentiate between genes whose down regulation lead to bacteriostatic or bactericidal effect. Targets for standard anti-tubercular drugs like inhA for isoniazid, rpoB and C for rifampicin, and gyr A/B for flouroquinolones were shown to be bactericidal. In contrast targets like FtsZ behaved in a bacteriostatic manner. Induction of antisense expression in embB and ribosomal RNA genes, viz., rplJ and rpsL showed only a marginal growth inhibition. The specificity of the antisense inhibition was conclusively shown in the case of auxotrophic gene ilvB. The bactericidal activity following antisense expression of ilvB was completely reversed when the growth media was supplemented with the isoleucine, leucine, valine and pantothenate. Additionally, under these conditions the expression of several genes in branched chain amino acid pathway was severely suppressed indicating targeted gene inactivation.