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Structure Analysis Of FabI And FabZ Enzymes Of The Fatty Acid Biosynthesis Pathway Of Plasmodium FalciparumMaity, Koustav 09 1900 (has links) (PDF)
The emergence of drug resistant strains of Plasmodium has given a new face to the old disease, malaria. One of the approaches is to block metabolic pathways of the pathogen. The current thesis describes the X-ray crystallographic analysis of two enzymes of the fatty acid biosynthesis pathway of the malaria parasite Plasmodium falciparum. In order to understand the functional mechanism and mode of inhibitor binding, enzyme-inhibitor complexes were characterized, which could help in further improvement of the efficacy of the inhibitors and hence to fight against the disease.
The introductory chapter of the thesis presents a discussion on malaria and different metabolic pathways of the pathogen which could be suitable targets for novel antimalarials. In continuation to that, the pathway of our choice the fatty acid biosynthesis and an overview of the structural features of the enzymes involved in the pathway that have been characterized from different organisms are also described. The second chapter includes the tools of X-ray crystallography that were used for structural studies of the present work. It also discusses the biochemical, biophysical and other computational methods used to further characterize the enzymes under study.
Triclosan, a well known inhibitor of Enoyl Acyl Carrier Protein Reductase (FabI) from several pathogenic organisms, is a promising lead compound to design effective drugs. The X-ray crystal structures of Plasmodium falciparum FabI (PfFabI), in complex with triclosan variants having different substituted and unsubstituted groups at different key functional locations, were determined and compared with triclosan binding which form the basis of chapter 3. The structures revealed that 4 and 2’ substituted compounds have more interactions with the protein, cofactor and solvent molecules as compared to triclosan. New water molecules were found to interact with some of these inhibitors. Substitution at the 2’ position of triclosan caused the relocation of a conserved water molecule, leading to an additional hydrogen bond with the inhibitor. This observation can help in conserved water based inhibitor design. 2’ and 4’ unsubstituted compounds showed a movement away from the hydrophobic pocket to compensate for the interactions made by the halogen groups of triclosan. This compound also makes additional interactions with the protein and cofactor which compensates for the lost interactions due to the unsubstitution at 2’ and 4’. In cell culture, this inhibitor shows less potency, which indicates that the chlorines at 2’ and 4’ positions increase the ability of the inhibitor to cross multilayered membranes. This knowledge helps us to modify the different functional groups of triclosan to get more potent inhibitors.
Certain residues in the substrate binding tunnel of PfFabI were mutated to identify the role of these residues in substrate binding and protein stability, which forms the 4th chapter of the thesis. The substrate binding site residue Ala372 of PfFabI has been mutated to Methionine and Valine which increased the affinity of the enzyme towards triclosan to almost double, close to that of Escherichia coli FabI (EcFabI) which has a Methionine at the structurally similar position of Ala372 of PfFabI. Kinetic studies of the mutants of PfFabI and the crystal structure analysis of the A372M mutant revealed that a more hydrophobic environment enhances the affinity of the enzyme for the inhibitor. A triclosan derivative showed a 3-fold increase in the affinity towards the mutants compared to the wild type, due to additional interactions with the A372M mutant as revealed by the crystal structure. The enzyme has a conserved salt bridge which stabilizes the substrate binding loop and appears to be important for the active conformation of the enzyme. A second set of mutants generated to check this hypothesis exhibited loss of function, except in one case where, the crystal structure showed that the substrate binding loop is stabilized by a water bridge network.
The main focus of chapter 5 is β-Hydroxyacyl-acyl carrier protein dehydratase of Plasmoduim falciparum (PfFabZ) which catalyzes the third and important reaction of the fatty acid elongation cycle. The crystal structure of PfFabZ was available in its hexameric (active) and dimeric (inactive) forms. However, until now PfFabZ has not been crystallized with any bound inhibitors. We have designed a new condition to crystallize PfFabZ with its inhibitors bound in the active site, and determined the crystal structures of three of these complexes. This is the first report of the crystal structures of PfFabZ with competitive inhibitor complexes and the first such study on any FabZ enzyme with active site inhibitors. These inhibitors in the active site stabilize the substrate binding loop, revealing the substrate binding tunnel with an overall shape of “U”. In the crystal structure, the residue Phe169 located in the middle of the tunnel was found to be in two different conformations, open and closed, implying that it controls the length of the tunnel and makes it suitable for accommodating longer substrates merely by changing its side chain conformation. The hydrophobic nature of the substrate binding channel signifies the specificity for the hydrophobic tail of fatty acid substrates. The volume of the active site tunnel is determined by the sequence as well as by the conformation of the substrate binding site loop region and varies between organisms for accommodating fatty acids of different chain lengths. All PfFabZ inhibitors reported here bind to the active site through specific contacts like hydrogen bonds with catalytic residues and hydrophobic interactions. This report on the crystal structures of the complexes of PfFabZ provides the structural basis of the inhibitory mechanism of the enzyme, that could be used to improve the potency of inhibitors against an important component of fatty acid synthesis common to many infectious organisms.
The hot dog fold has been found in more than sixty proteins since the first report of its existence about a decade ago. The fold appears to have a strong association with fatty acid biosynthesis, its regulation and metabolism, as the proteins with this fold are predominantly coenzyme A-binding enzymes with a variety of substrates located at their active sites. We have analyzed the structural features and sequences of proteins having the hot dog fold. This study reveals that though the basic architecture of the fold is well conserved in these proteins, significant differences exist in their sequence, nature of substrate and oligomerization. Segments with certain conserved sequence motifs seem to play crucial structural and functional roles in various classes of these proteins. The analysis discussed in chapter 6, led to predictions regarding the functional classification and identification of possible catalytic residues of a number of hot dog fold-containing hypothetical proteins whose structures were determined in high throughput structural genomics projects.
Rv0098, predicted to be the FabZ of Mycobacterium tuberculosis, was cloned, expressed, purified, crystallized, and X-ray diffraction data were collected. Molecular replacement trials with all “hot dog” fold proteins failed to yield any significant solution due to the low sequence similarity (<20%) of Rv0098 compared to other FabZs. During the trials of structure solution by multiple isomorphous replacement method, structure of Rv0098 was published and it was shown to be a long-chain fatty acyl-CoA thioesterase (FcoT). The crystal structure of Rv0098 did not explain the molecular basis of substrate specificity of varying chain lengths. Molecular dynamics studies were carried out, which revealed that certain residues of the substrate binding tunnel are flexible and thus modulates the length of the tunnel. Flexibility of the loop at the base of the tunnel was also found to be important for determining the length of the tunnel for accommodating appropriate substrates. The structural basis of accommodating long chain substrates by Rv0098 is discussed in chapter 7, by combining the crystallographic and molecular dynamics studies.
Part of the work presented in the thesis has been reported in the following publications.
Karmodiya, K., Sajad, S., Sinha, S., Maity, K., Suguna, K. and Surolia, N. (2007) Conformational stability and thermodynamic characterization of homotetrameric Plasmodium falciparum beta-ketoacyl-ACP reductase. IUBMB Life 59, 441-9.
Pidugu, L. S., Maity, K., Ramaswamy, K., Surolia, N. and Suguna, K. (2009) Analysis of proteins with the 'hot dog' fold: prediction of function and identification of catalytic residues of hypothetical proteins. BMC Struct Biol 9, 37.
Kapoor, N., Banerjee, T., Babu, P., Maity, K., Surolia, N. and Surolia, A. (2009) Design, development, synthesis, and docking analysis of 2'-substituted triclosan analogs as inhibitors for Plasmodium falciparum enoyl-ACP reductase. IUBMB Life 61, 1083-91.
Maity, K., Bhargav, S. P., Sankaran, B., Surolia, N., Surolia, A. and Suguna, K. (2010) X-ray crystallographic analysis of the complexes of enoyl acyl carrier protein reductase of Plasmodium falciparum with triclosan variants to elucidate the importance of different functional groups in enzyme inhibition. IUBMB Life 62, 467-76.
Maity, K., Banerjee, T., Narayanappa, P., Surolia, N., Surolia, A. and Suguna, K. (2010) Effect of substrate binding loop mutations on the structure, kinetics and inhibition of Enoyl Acyl Carrier Protein Reductase from Plasmodium falciparum. (Communicated)
Maity, K., Bharat, S. V., Kapoor, N., Surolia, N., Surolia, A. and Suguna, K. (2010) Insights into the functional and inhibitory mechanism of the β-Hydroxyacyl-Acyl Carrier Protein Dehydratase of Plasmodium falciparum from the crystal structures of its complexes with active site inhibitors. (Communicated)
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Biochemical And Molecular Insights Into β-Hydroxyacyl-Acyl Carrier Protein Dehydratase (FabZ) From Plasmodium FalciparumKumar, Shailendra 10 1900 (has links)
Malaria, caused by Plasmodium, is one of the most devastating infectious diseases of the world in terms of mortality as well as morbidity (WHO, 2002). The development of resistance in the Plasmodium falciparum against the present antimalarials has made the situation very alarming (Trape et al., 2000). To combat this situation, new antimalarials as well as identification of new drug targets are urgently required. The discovery of the presence of type II fatty acid biosynthesis system in the malarial parasite has offered several promising new targets for this mission.
This thesis describes the successful cloning of fabZ from Plasmodium falciparum, its expression in E. coli, single step affinity purification, kinetic characterization and most importantly discovery of two small molecule inhibitors (Sharma et al., 2003). The study was executed to gain insights into the structure and function of PfFabZ to get better understanding of the interactions with its substrate analogs, novel inhibitors and also acyl carrier protein (PfACP). The
molecular details of the interactions of the two novel inhibitors were also determined. Lastly, the residues of PfFabZ important for the interaction with PfACP were successfully elucidated.
Chapter 1 presents a brief review of the literature about the disease as well as the life cycle, biology and the metabolic pathways operational in malarial parasite, Plasmodium falciaparum. The discovery of type II FAS in P. falciparum and the aims and the scope of the thesis are also discussed. The quest of developing new antimalarials, study of the mechanism of actions of antimalarials such as quinine and its derivatives along with the major metabolic pathways (Purine, pyrimidine, phospholipids, carbohydrate metabolism, folate and heme biosynthesis pathways etc.) existing in P. falciparum are described in detail in this chapter. Origin and importance of apicoplast in P. falciaprum is also described in brief. For long, it was believed that Plasmodium spp. are incapable of de novo fatty acid synthesis but this view has undergone substantial revision due to the recent discovery of plant and bacterial type of fatty acid biosynthesis pathway in them (Surolia and Surolia, 2001). As this pathway is distinct from that of the human host it has accelerated the momentum for the discovery of new antimalarials (Surolia and Surolia, 2001). The Chapter also surveys the details of type II FAS in bacteria, particularly that of E. coli (Rock and Cronan, 1996). The dehydratase step which is the third step of fatty acid elongation cycle has been covered in considerable detail. Lastly, it focuses on the recent advancement in the understanding of fatty acid biosynthesis system in Plasmodium falciparum along with some inhibitors targeting the malarial FAS.
As each enzyme of the Plasmodium FAS can serve as good antimalarial targets, my work focuses on the dehydratase step catalyzed by β-hydroxyacyl-ACP dehydratase (PfFabZ). Cloning, expression and kinetic characterization of PfFabZ forms the major content of Chapter 2. The PlasmoDB data base was searched for this gene and the mined out open reading frame contained sequence
of the putative FabZ together with the bipartite leader polypeptide. Our aim was to
clone the mature PfFabZ without the bipartite leader sequence. Amplification of
the mature pffabZ using Plasmodium falciparum genomic DNA revealed the
presence of an intron in the ORF and the gene was finally cloned by RT-PCR in
pET-28a(+) vector. It was expressed with an N-terminal hexahistidine tag in BL-21(DE3) cells and purified to near homogeneity but the protein was insoluble and unstable. Truncation of 12 residues from the N-terminal end improved the stability
and solubility of the protein by 3-5 fold. Truncated PfFabZ was used for all future
experiments. FabZs from other sources are reported to be hexamer in solution but
PfFabZ showed homodimeric arrangement in the conditions used for gel filtration as well as dynamic light scattering studies. Kinetics of PfFabZ was characterized
using substrate analogs, β-hydroxybutryl-CoA (forward substrate) and Crotonoyl-CoA (reverse substrate). Both the forward and reverse reaction were thoroughly
characterized by spectrophotometry and HPLC and the reverse reaction was found to be 7 times faster than the forward reaction. Km οf crotonoyl-CoA was calculated to be 86 µM and kcat/Km of 220 M-1s-1 whereas the Kmfor β-hydroxybutryl-CoA was found to be 199 µM and kcat/Kmof 80.2 M-1s-1. The kinetic data clearly indicates the higher affinity of PfFabZ for the reverse substrate.
Chapter 3 describes the discovery of two small molecules inhibitors, NAS-21 and NAS-91 for PfFabZ, their detailed inhibition kinetics and their effect on the growth of Plasmodium falciparum in culture. These inhibitors were the first inhibitors to be reported for FabZ class of enzymes with an IC50 ranging below 15 µM. Both of them inhibited PfFabZ following competitive kinetics with respect to the substrates utilized for both the forward and reverse reactions. The inhibition data were analyzed by Lineweaver-Burk and Dixon plots and both inhibitors showed competitive inhibition kinetics with dissociation constant in
submicromolar range. Binding constants for both the inhibitors were also determined by fluorescence titration method and were calculated to be 1.6 (± 0.04) X 106 M-1 for NAS-91 and 1.2 (± 0.03) X 106 M-1 for NAS-21. These inhibitors were checked on Plasmodium falciparum culture and both inhibited parasite growth with IC50 values of 7 µM and 100 µM for NAS-21 and NAS-91,
respectively. They also inhibited the incorporation of [1,2-14C]-acetate in the fatty acids of the P. falciparum conforming the inhibition of fatty acid biosynthesis.
FabZ class of enzymes are thought to contain His-Glu as a catalytic dyad. Based on the disparity in the arrangement of residues at the active site of the dimeric (Swarnamukhi et al., 2006) and hexameric forms of PfFabZ in the crystal structures (Kosteriva et al., 2005), we set out to elucidate the active site residues in PfFabZ which is described in Chapter 4. The role of each of the presumed active site residues His-133 and Glu-147 along with Arg-99 and His-98 were
analyzed by chemical modification studies and site directed mutagenesis. Single and double mutants were prepared and the activity of the mutants was monitored by spectrophotometry and isothermal titration calorimetry (ITC). It was concluded that in PfFabZ, His-133 and Glu-147 makes the catalytic dyad, His-98 might be important in directing the substrate in correct orientation while Arg-99 is involved in maintaining the active site loop in proper orientation rather than taking direct part in catalysis. Chapter 4 also concludes that dimeric form of PfFabZ is inactive species and turns into active hexameric form in the presence of substrate.
Chapter 5 describes the molecular details of NAS-21 and NAS-91 interactions with PfFabZ. The fact that both these compounds inhibited PfFabZ in competitive manner, prompted me to examine their interaction with the residues in the active site tunnel. Apart from the His-133 and Glu-147 catalytic dyad the only
polar residue is His-98 and chemical modification and site directed mutagenesis
studies were done to elucidate the interactions of these residues with NAS-21 and NAS-91. Both the inhibitors were able to protect the modification of histidines by
DEPC in wild type PfFabZ, His-98-Ala mutant and His-133-Ala mutant but with differential strength, indicating that they do interact with histidines. The interaction of these inhibitors was further confirmed by determining the dissociation constants of wPfFabZ, His-98-Ala, His-133-Ala, His-98-Ala/His-133-Ala double mutant, Glu-147-Ala mutant by fluorescence titration method.
The results obtained from chemical modification and fluorescence titration studies confirmed that NAS-21 interacts strongly with histidines, His-98 and His-133 but not with Glu-147. On the other hand NAS-91 interacts loosely with His-98 and His-133 but strongly with Glu-147. Chapter 5 concludes with the observation that both the inhibitors (NAS-21 and NAS-91) interact with the active site residues of PfFabZ, preventing the substrate to enter the active site tunnel. Acyl carrier protein (ACP) is a small acidic protein to which the acyl chain intermediates are tethered and shuttled from one enzyme to another for the completion of fatty acid elongation cycle. Whenever acyl carrier proteins are expressed in E. coli, they are present in three forms apo, holo and acyl-ACPs.
Chapter 6 describes a novel method for the expression of histidine tagged PfACP in pure holo form, protocol for the cleavage of his-tag from PfACP by thrombin preparation of homogenous singly enriched ie PfACP [15N]-labeled or [13C]-labeled PfACP as well as doubly enriched [15N]-[13C] PfACP samples for its structure elucidation by NMR (Sharma et al., 2005). These studies also constituted reporting of a holo-ACP structure from any of the sources for the first time (Sharma, et. al. 2006).
The purified pure holo-PfACP was further used for the interaction studies with PfFabZ. Earlier studies have shown that ACP interacts with FAS enzymes via helix II with conserved set of residues but the molecular details of the interactions are poorly known (Zhang, et. al., 2003). We have recently solved the NMR structure (Sharma, et. al., 2006) of PfACP and crystal structure of PfFabZ (Swarnamukhi, et. al., 2006). So, both the structures were docked using Cluspro
server. Chapter 7 elucidates the roles of important residues on PfFabZ surface near the active site entry which are responsible for interacting with PfACP.
The residues lining the active site entry were identified and mutated. The residues
lining the active site tunnel of PfFabZ are Arg102, Lys104, Lys105, Lys123,
Leu94, Phe95, Ala96, Gly97, Ile128, Ile145, Phe150 and Ala151. Charged residues were mutated to alanine and also to oppositely charged residues while the neutral residues were changed to charged residues. The interaction of PfFabZ mutants with PfACP was studied by ACP independent enzymatic assay and surface plasmon resonance (SPR) spectroscopy. It was concluded that PfFabZ and PfACP interaction is mainly governed by electrostatic interaction made by the
charged residues (Lys104 being the most important residue) and is fine tuned by
hydrophobic interactions.
Chapter 8 summarizes the findings of the thesis. FabZ from Plasmodium falciparum was cloned and biochemically characterized. Two inhibitors for this enzyme were discovered and their molecular details of binding to PfFabZ were elucidated. The presence of catalytic dyad was confirmed and finally the residues of PfFabZ important for interaction with PfACP were elucidated.
Appendix I describes the inhibition of PfENR (enoyl ACP reductase), the rate limiting and the fourth enzyme of the fatty acid elongation pathway by green tea extracts. Three tea catechins (EGCG, EGC and ECG) and two plant polyphenols (quercetin and buteine) were selected for the inhibition study. All the catechins inhibited PfENR potently with Ki values in nanomolar range. Among the five compounds studied, EGCG was found to be the best inhibitor. All of them blocked the NADH binding site showing competitive kinetics with respect to NADH and uncompetitive kinetics with crotonoyl-CoA, the substrate analog. Most importantly, the catechins potentiated the inhibition of PfENR by triclosan, a well known PfENR inhibitor. We also report that in the presence of tea catechins triclosan behaves as a slow-tight binding inhibitor of PfENR. The overall inhibition constant of triclosan in the presence of EGCG was calculated to be 2pM which is 50 times better than the earlier reported values with NAD+ (Kapoor, et. al., 2004).
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