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1-deoxy-D-xylulose-5-phosphate Synthase (DXS) Mechanistic Study and its Implication in the Development of Novel Antibiotics and AntimalarialsHanda, Sumit 01 January 2012 (has links)
Isoprenoids are the largest family of biologically active compounds, synthesized by five carbon subunits namely isopentenyl pyrophosphate (IPP) and dimethylallyl pyrophosphate (DMAPP). For long time the mevalonate-dependent (MVA) pathway has been considered as the sole source of IPP and DMAPP, until recently a new non-mevalonte dependent (NMVA) pathway was discovered. This new pathway utilizes entirely different set of enzymes for isoprenoids synthesis and don't have any homologues in humans. NMVA pathway is the only source of isoprenoids for certain eubacteria, parasite and plants. Absence of the NMVA pathway in higher organisms has opened a new platform for the development of novel antibiotics and antimalarials.
1-deoxy-D-xylulose-5-phosphate synthase (DXS), the first enzyme in NMVA pathway has been reported as the rate limiting enzyme in the synthesis of IPP and DMAPP and has been the center of interest for inhibitor development. Reaction mechanism of thiamine pyrophosphate (TPP) and Mg2+ dependent DXS enzyme has been studied in this report. Using steady state kinetics analysis, product inhibition and dead end inhibitor, the mechanism of substrate (pyruvate and D-glyceraldehyde-3-phosphate) addition was studied. Due to different domain organization in DXS as compared to theother TPP dependent enzyme, the mechanism of addition was found to be random sequential rather than ping-pong mechanism.
Based on bioinformatics tool and in vitro studies it has been established that NMVA exists in all the plasmodium species, thus making the enzymes involved in NMVA as an alluring target for new antimalarial drugs. All the plasmodium species and other member of the phylum apicomplexa harbor apicoplast an organelle which is homologous to the chloroplast of plants and algae. All the enzymes from NMVA pathway translocate to apicoplast from nucleus through a secretory pathway using signaling and transit peptide. In this study DXS from P. vivax has been cloned and expressed in E. coli using genomic DNA and codon optimized synthetic DNA as a source. Expression of full length DXS with signal and transit peptide as well as mature protein without these peptide using serial deletion has been studied. Kinetic parameters of P.vivax DXS have been calculated and found to be comparable to the DXS from other species.
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Investigations into the Non-Mevalonate Isoprenoid Biosynthesis Pathway's First Two Enzymes utilizing Hybrid QM/MM TechniquesWhite, Justin K. 17 November 2017 (has links)
Molecular drug design begins with the identication of a problem to solve. This work identies the growing resistance among human pathogens to current treatments. Once the problem is identied and understood, solutions must be proposed. This one is straight forward, we need new antimicrobial drugs. More specically, we need to identify novel targets to inhibit. A large portion of antibiotics focus on disruption of macromolecular production while only a few target metabolic systems. Finally, you need to propose solutions based on the information gathered. In order to avoid existing resistance, it is important to avoid the macromolecular route and focus on metabolic enzymes. Preferably, the pathway would have little overlap or similarity with pathways found in the treatment organism. With this in mind, the non-mevalonate (NMA) pathway poses as a very good target for drug design. Many pathogens have been found to be strictly dependent on this pathway while it is absent in humans. Additionally, fosmidomycin has already been shown to inhibit this pathway. Initially thought to just inhibit the 1-deoxy-D-xylulose 5- phosphate (DXP) reductoisomerase (DXR), it has been shown to inhibit several enzymes along the path to a lesser extent. Ideally, this could be repeated or improve upon for future drug design.
With this in mind, the initial stages of the rst two enzymes of the NMA pathway were examined utilizing quantum mechanical/molecular mechanical (QM/MM) techniques. The rst enzyme was DXP synthase (DXS), which catalyzes a transketolase-like condensation of pyruvate and glyceraldehyde-3-phosphate to produce DXP. DXS and other transketolases are dependent on the thiamine diphosphate (TDP) cofactor, which must be deprotonated of the imidazolium C2 atom producing a highly reactive ylide. A tautomerization occurs prior to this deprotonation to prime the pyrimidinium ring N4 atom to perform the C2 abstraction. The question at hand was the identity of a general base to perform the N4 abstraction. The results favored a water-mediate mechanism with a higher than usual Ez of 22.7 kcal/mol. An observation pertaining the tautomerization pertained to the aromaticity of the pyrimidine ring. Upon further investigation, aromaticity was found to play a signicant role in the ΔE observed. Aromaticity might contribute 14.2 kcal/mol to the barrier height. This high energy would drive the reaction forward producing the ylide.
Investigation of the DXR enzyme followed this work. Initially, the work was going to focus on the 2 mechanisms proposed for activity, alpha-ketol rearrangement and retroaldol/ aldol mechanism. Subsequent publications involving secondary kinetic isotope effects (KIEs) add to the pile of evidence supporting the retro-aldol/aldol mechanism. So the project was retooled to investigate the energetic dierences between two metal binding modes. The results of this work support a metal coordination across the C3-C4 bond, which eventually extends coordination to include the C2 oxygen. This conformation was help explain the tight binding eecting observation of the putative intermediates (transition states) and aldehyde intermediate. Additionally, as the C2-C3 mode consistently transfers a proton to the phosphate group of DXP or produces an elongated C-O bond, the C2-C3 mode would not be favorable.
Further investigations of these enzymes (e.g. completing the step begin, continuing through the reaction) could provide further illumination into the mechanism of action and possibly reveal new avenues of drug design. Examining the enzymes downstream in the NMA pathway might provide details of interest. Of particular interest is the radical reaction proposed for HDR/IspH. The nal step of the pathway produces IDP and DMADP in a 4:1 proportion, which corresponds to the general system requirements for production of the long chain, branched isoprenoids. It would be interesting to compute the mechanism to see if energetics could provide further insights. Additionally, normal mode analysis coupled with vibrational subsystem analysis could identify allosteric sites for feedback sensitivity.
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