A strategy to identify novel antimicrobial compounds : a bioinformatics and HTS approach
Bacterial infections are again becoming difficult to treat because the microbes are growing increasingly resistant to the antibiotics in use today. The need for novel antimicrobial compounds is urgent and to achieve this new targets are crucial. In this thesis we present a strategy for identification of such targets via a bioinformatics approach. In our first study we compared proteins with unknown and hypothetical function of the spirochete Treponema pallidum to five other pathogens also causing chronic or persistent infections in humans (Yersinia pestis, Neisseria gonorrhoeae, Helicobacter pylori, Borrelia burgdorferi and Streptococcus pneumoniae). T. pallidum was used as a starting point for the comparisons since this organism has a condensed genome (1.1 Mb). As we aimed at identifying conserved proteins important for in vivo survival or virulence of the pathogens we reasoned that T. pallidum would have deleted genes not important in the human host. This comparison yielded 17 ORFs conserved in all six pathogens, these were deleted in our model organism, Yersinia pseudotuberculosis, and the virulence of these mutant strains was evaluated in a mouse model of infection. Five genes were found to be essential for virulence and thus constitute possible antimicrobial drug targets.We have studied one of these virulence associated genes (vags), vagH, in more detail. Functional and phenotypic analysis revealed that VagH is an S-adenosyl-methionine dependent methyltransferase targeting Release factor 1 and 2 (RF1 and RF2). The analysis also showed that very few genes and proteins were differentially expressed in the vagH mutant compared to wild-type Yersinia. One major finding was that expression of the Type III secretion system effectors, the Yops, were down regulated in a vagH mutant. We dissected this phenotype further and found that the down regulation was due to lowered amounts of the positive regulator LcrF. This can be suppressed either by a deletion of yopD or by over expression of the Ribosomal Recycling Factor (RRF). These results indicate that YopD in addition to its role in translational regulation of the Yops also plays a part in the regulation of LcrF translation. We suggest also that the translation of LcrF is particularly sensitive to the amount of translation competent ribosomes and that one effect of a vagH mutation in Y. pseudotuberculosis is that the number of free ribosomes is reduced; this in turn reduces the amount of LcrF produced thereby causing a down regulation of the T3SS. This down regulation is likely the cause of the attenuated virulence of the vagH mutant.Finally, we set up a high throughput screening assay to screen a library of small molecules for compounds with inhibiting the VagH methyltransferase activity. Five such compounds were identified and two were found to inhibit VagH also in bacterial culture. Furthermore, analogues to one of the compounds showed improved inhibitory properties and inhibited the T3SS-dependent cytotoxic response induced by Y. pseudotuberculosis on HeLa cells.We have successfully identified five novel targets for antimicrobial compounds and in addition we have discovered a new class of molecules with antimicrobial properties.
Source Type:Doctoral Dissertation
Keywords:MEDICINE; Microbiology, immunology, infectious diseases; Microbiology; Medical microbiology; Antibiotic resistance; Yersinia; T3SS; virulence associated genes; VagH; HemK/PrmC; Release factors; small molecular inhibitors; HTS
Date of Publication:01/01/2006