Molecular modeling of wild-type and antifolate resistant mutant Plasmodium falciparum DHFR

The development of drug resistance is reducing the efficiency of antifolates as antimalarials. This phenomenon has been linked to the occurrence of mutations in the parasite's dihydrofolate reductase (DHFR). In this way, the resistance to pyrimethamine and cycloguanil, two potent inhibitors of P. falciparum DHFR, is mainly related to mutations (single and crossed) at residues 16, 51, 59, 108 and 164 of the enzyme. In this work, we have refined a recently proposed homology-model of P. falciparum DHFR, and the resulting structure was used to obtain models for 14 mutant enzymes, employing molecular modeling. Ternary complexes of the mutant enzymes with these inhibitors have been superimposed to equivalent ternary complexes of the wild-type enzyme, allowing the proposition of hypotheses for the role of each mutation in drug resistance. Based on these results, possible reasons for antifolate resistance have been proposed.     

Towards an understanding of drug resistance in malaria: three-dimensional structure of Plasmodium falciparum dihydrofolate reductase by homology building.

A three-dimensional (3-D) model of dihydrofolate reductase (DHFR) from Plasmodium falciparum has been constructed by homology building. The model building has been based on a structural alignment of five X-ray structures of DHFR from different species. The 3-D model of the plasmodial DHFR was obtained by amino acid substitution in the human DHFR, which was chosen as template, modification of four loops (two insertions, two deletions) and subsequent energy minimization. The active site of P. falciparum DHFR was analyzed and compared to human DHFR with respect to sequence variations and structural differences. Based on this analysis the molecular consequences of point mutations known to be involved in drug resistance were discussed. The significance of the most important point mutation causing resistance, S108N, could be explained by the model, whereas the point mutations associated with enhanced resistance, N51I and C59R, seem to have a more indirect effect on inhibitor binding.     

Insights into antifolate resistance from malarial DHFR-TS structures

Plasmodium falciparum dihydrofolate reductase-thymidylate synthase (PfDHFR-TS) is an important target of antimalarial drugs. The efficacy of this class of DHFR-inhibitor drugs is now compromised because of mutations that prevent drug binding yet retain enzyme activity. The crystal structures of PfDHFR-TS from the wild type (TM4/8.2) and the quadruple drug-resistant mutant (V1/S) strains, in complex with a potent inhibitor WR99210, as well as the resistant double mutant (K1 CB1) with the antimalarial pyrimethamine, reveal features for overcoming resistance. In contrast to pyrimethamine, the flexible side chain of WR99210 can adopt a conformation that fits well in the active site, thereby contributing to binding. The single-chain bifunctional PfDHFR-TS has a helical insert between the DHFR and TS domains that is involved in dimerization and domain organization. Moreover, positively charged grooves on the surface of the dimer suggest a function in channeling of substrate from TS to DHFR active sites. These features provide possible approaches for the design of new drugs to overcome antifolate resistance.     

Geographical spread and structural basis of sulfadoxine-pyrimethamine drug-resistant malaria parasites

The global spread of sulfadoxine (Sdx, S) and pyrimethamine (Pyr, P) resistance is attributed to increasing number of mutations in DHPS and DHFR enzymes encoded by malaria parasites. The association between drug resistance mutations and SP efficacy is complex. Here we provide an overview of the geographical spread of SP resistance mutations in Plasmodium falciparum (Pf) and Plasmodium vivax (Pv) encoded dhps and dhfr genes. In addition, we have collated the mutation data and mapped it on to the three-dimensional structures of DHPS and DHFR which have become available. Data from genomic databases and 286 studies were collated to provide a comprehensive landscape of mutational data from 2005 to 2019. Our analyses show that the Pyr-resistant double mutations are widespread in Pf/PvDHFR (P. falciparum ～61% in Asia and the Middle East, and in the Indian sub-continent; in P. vivax ～33% globally) with triple mutations prevailing in Africa (～66%) and South America (～33%). For PfDHPS, triple mutations dominate South America (～44%), Asia and the Middle East (～34%) and the Indian sub-continent (～27%), while single mutations are widespread in Africa (～45%). Contrary to the status for P. falciparum, Sdx-resistant single point mutations in PvDHPS dominate globally. Alarmingly, highly resistant quintuple and sextuple mutations are rising in Africa (PfDHFR-DHPS) and Asia (Pf/PvDHFR-DHPS). Structural analyses of DHFR and DHPS proteins in complexes with substrates/drugs have revealed that resistance mutations map proximal to Sdx and Pyr binding sites. Thus new studies can focus on discovery of novel inhibitors that target the non-substrate binding grooves in these two validated malaria parasite drug targets.     

Bifunctional thymidylate synthase-dihydrofolate reductase in protozoa

Protozoa contain thymidylate synthase (TS) and dihydrofolate reductase (DHFR) on the same polypeptide. In the bifunctional protein, the DHFR domain is on the amino terminus, TS is on the carboxyl terminus, and the two domains are separated by a junction peptide of varying size depending on the source. The native protein is composed of a dimer of two such subunits and is 110-140 kDa. Most studies of the bifunctional TS-DHFR have been performed with the protein from anti-folate resistant strains of Leishmania major, which show amplification of the TS-DHFR gene and overproduction of the bifunctional protein. The Leishmania TS-DHFR has also been highly expressed in heterologous systems. There appears to be extensive communication among domains and channeling of the H2folate product of TS to DHFR. Anti-folates commonly used to treat microbial infections are poor inhibitors of L. major DHFR. However, selective inhibition of L. major vs. human DHFR does not appear difficult to achieve, and selective inhibitors are known. The TS-DHFR from Plasmodium falciparum has also been cloned and has recently been expressed in Escherichia coli, albeit in small amounts. Interestingly, pyrimethamine-resistant strains of P. falciparum all have a common point mutation in the DHFR coding sequence (Thr/Ser 108 to Asn), which causes decreased binding of the folate analog. It is suggested that if an appropriate inhibitor of the pyrimethamine-resistant P. falciparum DHFRs can be found, it may serve in combination with pyrimethamine as an antimalarial regimen with low propensity for the development of resistance. In the future, we project that we will have a detailed knowledge of the structure and function of TS-DHFRs, and have the essential tools necessary for a molecular-based approach to drug design.     

Genome comparison of progressively drug resistant Plasmodium falciparum lines derived from drug sensitive clone

Chloroquine has been the mainstay of malaria chemotherapy for the past five decades, but resistance is now widespread. Pyrimethamine or proguanil form an important component of some alternate drug combinations being used for treatment of uncomplicated Plasmodium falciparum infections in areas of chloroquine resistance. Both pyrimethamine and proguanil are dihydrofolate reductase (DHFR) inhibitors, the proguanil acting primarily through its major metabolite cycloguanil. Resistance to these drugs arises due to specific point mutations in the dhfr gene. Cross resistance between cycloguanil and pyrimethamine is not absolute. It is, therefore, important to investigate mutation rates in P. falciparum for pyrimethamine and proguanil so that DHFR inhibitor with less mutation rate is favored in drug combinations. Hence, we have compared mutation rates in P. falciparum genome for pyrimethamine and cycloguanil. Using erythrocytic stages of P. falciparum cultures, progressively drug resistant lines were selected in vitro and comparing their RFLP profile with a repeat sequence. Our finding suggests that pyrimethamine has higher mutation rate compared to cycloguanil. It enhances the degree of genomic polymorphism leading to diversity of natural parasite population which in turn is predisposes the parasites for faster selection of resistance to some other antimalarial drugs.     

Probing the role of parasite-specific, distant structural regions on communication and catalysis in the bifunctional thymidylate synthase-dihydrofolate reductase from Plasmodium falciparum

Plasmodium falciparum thymidylate synthase-dihydrofolate reductase (TS-DHFR) is an essential enzyme in nucleotide biosynthesis and a validated molecular drug target in malaria. Because P. falciparum TS and DHFR are highly homologous to their human counterparts, existing active-site antifolate drugs can have dose-limiting toxicities. In humans, TS and DHFR are two separate proteins. In P. falciparum, however, TS-DHFR is bifunctional, with both TS and DHFR active sites on a single polypeptide chain of the enzyme. Consequently, P. falciparum TS-DHFR contains unique distant or nonactive regions that might modulate catalysis: (1) an N-terminal tail and (2) a linker region tethering DHFR to TS, and encoding a crossover helix that forms critical electrostatic interactions with the DHFR active site. The role of these nonactive sites in the bifunctional P. falciparum TS-DHFR is unknown. We report the first in-depth, pre-steady-state kinetic characterization of the full-length, wild-type (WT) P. falciparum TS-DHFR enzyme and probe the role of distant, nonactive regions through mutational analysis. We show that the overall rate-limiting step in the WT P. falciparum TS-DHFR enzyme is TS catalysis. We further show that if TS is in an activated (liganded) conformation, the DHFR rate is 2-fold activated, from 60 s-1 to 130 s-1 in the WT enzyme. The TS rate is also reciprocally activated by approximately 1.5-fold if DHFR is in an activated, ligand-bound conformation. Mutations to the linker region affect neither catalytic rate nor domain-domain communication. Deletion of the N-terminal tail, although in a location remote from the active site, decreases the DHFR single rate and the bifunctional TS-DHFR rate by a factor of 2. The 2-fold activation of the DHFR rate by TS ligands remains intact, although even the activated N-terminal mutant has just half the DHFR activity of the WT enzyme. However, the reciprocal communication between TS active site and DHFR ligands is impaired in N-terminal mutants. Surprisingly, deletion of the analogous N-terminal tail in Leishmania major TS-DHFR causes a 3-fold enhancement of the DHFR rate from approximately 14 s-1 to approximately 40 s-1. In summary, our results demonstrate a complex interplay of domain-domain communication and nonactive-site modulation of catalysis in P. falciparum TS-DHFR. Furthermore, each parasitic TS-DHFR is activated by unique mechanisms, modulated by their nonactive site regions. Finally, our studies suggest the N-terminal tail of P. falciparum TS-DHFR is a highly selective, novel target for potential antifolate development in malaria.     

Mutations in Plasmodium falciparum dihydrofolate reductase and dihydropteroate synthase of isolates from the Amazon region of Brazil

Since the late 1970s pyrimethamine-sulfadoxine (PS; FansidarTM Hoffman-LaRoche, Basel) has been used as first line therapy for uncomplicated malaria in the Amazon basin. Unfortunately, resistance has developed over the last ten years in many regions of the Amazon and PS is no longer recommended for use in Brazil. In vitro resistance to pyrimethamine and cycloguanil (the active metabolite of proguanil) is caused by specific point mutations in Plasmodium falciparum dihydrofolate reductase (DHFR), and in vitro resistance to sulfadoxine has been associated with mutations in dihydropteroate synthase (DHPS). In association with a proguanil-sulfamethoxazole clinical trial in Brazil, we performed a nested mutation-specific polymerase chain reaction to measure the prevalence of DHFR mutations at codons 50, 51, 59, 108 and 164 and DHPS mutations at codons 436, 437, 540, 581 and 613 at three sites in the Brazilian Amazon. Samples from two isolated towns showed a high degree of homogeneity, with the DHFR Arg-50/Ile-51/Asn-108 and DHPS Gly-437/Glu-540/Gly-581 mutant genotype accounting for all infections in Peixoto de Azevedo (n = 15) and 60% of infections in Apiacás (n = 10), State of Mato Grosso. The remaining infections in Apiacás differed from this predominant genotype only by the addition of the Bolivia repeat at codon 30 and the Leu-164 mutation in DHFR. By contrast, 17 samples from Porto Velho, capital city of the State of Rond?nia, with much in- and out-migration, showed a wide variety of DHFR and DHPS genotypes.     

Synthesis and evaluation of naphthyl bearing 1,2,3-triazole analogs as antiplasmodial agents,cytotoxicity and docking studies

Novel series of naphthyl bearing 1,2,3-triazoles (4a–t) were synthesized and evaluated for their in vitro antiplasmodial activity against pyrimethamine (Pyr)-sensitive and resistant strains of Plasmodium falciparum. The synthesized compounds were assessed for their cytotoxicity employing human embryonic kidney cell line (HEK-293), and none of them was found to be toxic. Among them 4j, 4k, 4l, 4m, 4n, 4t exhibited significant antiplasmodial activity in both strains, of which compounds 4m, 4n and 4t (～3.0-fold) displayed superior activity to Pyr against resistant strain. Pyr and selected compounds (4n, 4p and 4t) that repressed parasite development also inhibited PfDHFR activity of the soluble parasite extract, suggesting that anti-parasitic activity of these compounds is a result of inhibition of the parasite DHFR. In silico studies suggest that activity of these compounds might be enhanced due to π-π stacking.     

Molecular monitoring of the Leu-164 mutation of dihydrofolate reductase in a highly sulfadoxine/pyrimethamine-resistant area in Africa

The selection of point mutation at codon 164 (from isoleucine to leucine) of the dihydrofolate reductase (DHFR) enzyme in Plasmodium falciparum is associated with high sulfadoxine /pyrimethamine (SP) resistance. Using the yeast expression system that allows the detection of dhfr allele present at low level, the presence of this mutation had previously been reported between 1998-1999 in Muheza, Tanzania, an area of high SP resistance. Eighty five P. falciparum isolates, obtained from the same area between 2002 and 2003, were analysed for the presence of Leu-164 mutation, using standard protocol based on PCR-RFLP. None of the isolates had the Leu-164 mutation.     

Multicomplex-based pharmacophore modeling in conjunction with multi-target docking and molecular dynamics simulations for the identification of PfDHFR inhibitors

Abstract

Plasmodium falciparum dihydrofolate reductase enzyme (PfDHFR) is counted as one of the attractive and validated antimalarial drug targets. However, the point mutations in the active site of wild-type PfDHFR have developed resistance against the well-known antifolates. Therefore, there is a dire need for the development of inhibitors that can inhibit both wild-type and mutant-type DHFR enzyme. In the present contribution, we have constructed the common feature pharmacophore models from the available PfDHFR. A representative hypothesis was prioritized and then employed for the screening of natural product library to search for the molecules with complementary features responsible for the inhibition. The screened candidates were processed via drug-likeness filters and molecular docking studies. The docking was carried out on the wild-type PfDHFR (3QGT); double-mutant PfDHFR (3UM5 and 1J3J) and quadruple-mutant PfDHFR (1J3K) enzymes. A total of eight common hits were obtained from the docking calculations that could be the potential inhibitors for both wild and mutant type DHFR enzymes. Eventually, the stability of these candidates with the selected proteins was evaluated via molecular dynamics simulations. Except for SPECS14, all the prioritized candidates were found to be stable throughout the simulation run. Overall, the strategy employed in the present work resulted in the retrieval of seven candidates that may show inhibitory activity against PfDHFR and could be further exploited as a scaffold to develop novel antimalarials.

Communicated by Ramaswamy H. Sarma     

Basis for antifolate action and resistance in malaria

Resistance to antifolates of the malaria parasite Plasmodium falciparum stems from stepwise mutations of the target enzyme dihydrofolate reductase (DHFR). New drugs can be developed against resistant parasites, which are assumed to have limited possibilities in mutations. Mechanisms of resistance other than reduced binding of inhibitors to mutant enzymes may be possible and need to be further explored. New synergistic combinations of drugs targeting DHFR and dihydropteroate synthase may be employed, with new provisions against development of resistance.     

Elucidation of sulfadoxine resistance with structural models of the bifunctional Plasmodium falciparum dihydropterin pyrophosphokinase-dihydropteroate synthase

Resistance of the most virulent human malaria parasite, Plasmodium falciparum, to antifolates is spreading with increasing speed, especially in Africa. Antifolate resistance is mainly caused by point mutations in the P. falciparum dihydropteroate synthase (DHPS) and dihydrofolate reductase (DHFR) target proteins. Homology models of the bifunctional P. falciparum dihydropterin pyrophosphokinase-dihydropteroate synthase (PPPK-DHPS) enzyme as well as the separate domains complete with bound substrates were constructed using the crystal structures of Saccharomyces cerevisiae (PPPK-DHPS), Mycobacterium tuberculosis (DHPS), Bacillus anthracis (DHPS), and Escherichia coli (PPPK) as templates. The resulting structures were subsequently solvated and refined using molecular dynamics. The active site residues of DHPS are highly conserved in S. cerevisiae, M. tuberculosis, E. coli, S. aureus, and B. anthracis, an attribute also shared by P. falciparum DHPS. Sulfadoxine was superimposed into the equivalent position of the p-aminobenzoic acid substrate and its binding parameters were refined using minimization and molecular dynamics. Sulfadoxine appears to interact mainly with P. falciparum DHPS mainly through hydrophobic interactions. Rational explanations are provided by the model for the sulfadoxine resistance-causing effects of four of the five known mutations in P. falciparum DHPS. A possible structure for the bifunctional PPPK-DHPS was derived from the structure from the S. cerevisiae bifunctional enzyme. The active site residues of P. falciparum PPPK are also conserved when compared to S. cerevisiae, Haemophilus influenzae, and E. coli. The informative nature of these models opens up avenues for structure-based drug design approaches toward the development of alternative and more effective inhibitors of P. falciparum PPPK-DHPS.     

Plasmodium falciparum: gene mutations and amplification of dihydrofolate reductase genes in parasites grown in vitro in presence of pyrimethamine

Samples of three pyrimethamine-sensitive clones of Plasmodium falciparum were grown for periods of 22-46 weeks in media containing stepwise increases in pyrimethamine concentrations and were seen to develop up to 1000-fold increases in resistance to the drug. With clone T9/94RC17, the dihydrofolate reductase (DHFR) gene was sequenced from 10 uncloned populations and 29 pure clones, all having increased resistance to pyrimethamine, and these sequences were compared with the sequence of the original pyrimethamine-sensitive clone. No changes in amino acid sequence were found to have occurred. Some resistant clones obtained by this method were then examined by pulsed-field gel electrophoresis, and the results indicated that there had been an increase in the size of chromosome 4. This was confirmed by hybridization of Southern blots with a chromosome 4-specific probe, the vacuolar ATPase subunit B gene, and a probe to DHFR. Dot-blotting with an oligonucleotide probe to DHFR confirmed that there had been increases up to 44-fold in copy number of the DHFR gene in the resistant strains. Resistant clones obtained by this procedure were then grown in medium lacking pyrimethamine for a period of nearly 2 years, and reversion nearly to the level of pyrimethamine sensitivity of the original clone T9/94RC17 was found to occur after about 16 months. Correspondingly, the chromosome 4 of the reverted population reverted to a size like that of the original sensitive clone T9/94RC17. The procedure of growing parasites in stepwise increases of pyrimethamine concentration was repeated with two other pyrimethamine-sensitive clones: TM4CB8-2.2.3 and G112CB1.1. (The DHFR gene of these clones encodes serine at position 108, in place of threonine as in clone T9/94RC17, and it was thought that this difference might conceivably affect the rate of mutation to asparagine at this position). Clones TM4CB8-2.2.3 and G112CB1.1 also responded by developing gradually increased resistance to pyrimethamine. However, in clone TM4CB8-2.2.3 a single mutation from Ile to Met at position 164 in the DHFR gene sequence was identified, and in clone G112CB1.1 there was a single mutation from Ala to Ser at position 16, but no mutations at position 108 were obtained in any of the clones studied here. In addition, chromosome 4 of clone TM4CB8-2.2.3 increased in size, presumably due to amplification of the DHFR gene. No increase in size was seen in clone G112CB1.1. We conclude that whereas some mutations producing changes in the amino acid sequence of the DHFR molecule may occur occasionally in clones or populations of P. falciparum grown in vitro in the presence of pyrimethamine, amplification of the DHFR gene following adaptation to growth in medium containing pyrimethamine occurs as a regular feature. The bearing of these findings on the development of pyrimethamine-resistant forms of malaria parasites in endemic areas is discussed.     

Utilization of exogenous folate in the human malaria parasite Plasmodium falciparum and its critical role in antifolate drug synergy

The antifolate combination pyrimethamine/sulphadoxine (PYR/SDX; Fansidar) is frequently used to combat chloroquine-resistant malaria. Its success depends upon pronounced synergy between the two components, which target dihydrofolate reductase (DHFR) and dihydropteroate synthetase (DHPS) in the folate pathway. This synergy permits clearance of parasites resistant to either drug alone, but its molecular basis is still unexplained. Plasmodium falciparum can use exogenous folate, which is normally present in vivo, bypassing SDX inhibition of DHPS and, apparently, precluding synergy under these conditions. However, we have measured parasite inhibition by SDX/PYR combinations in assays in which folate levels are strictly controlled. In parasites that use exogenous folate efficiently, SDX inhibition can be restored by levels of PYR significantly lower than those required to inhibit DHFR. Isobolograms show that the degree of synergy between PYR and SDX is highly dependent upon prevailing folate concentrations and are indicative of PYR acting to block folate uptake and/or utilization. No significant synergy was observed at physiological drug levels when PYR/SDX acted on purified DHFR, whether wild type or mutant. We conclude that the primary basis for antifolate synergy in these organisms arises from PYR targeting a site (or sites) in addition to DHFR, which restores DHPS as a relevant target for SDX.     

Interligand Overhauser effects in type II dihydrofolate reductase

R67 dihydrofolate reductase (DHFR) is a type II DHFR produced by bacteria as a resistance mechanism to the increased clinical use of the antibacterial drug trimethoprim. Type II DHFRs are not homologous in either sequence or structure with chromosomal DHFRs. The type II enzymes contain four identical subunits which form a homotetramer containing a single active site pore accessible from either end. Although the crystal structure of the complex of R67 DHFR with folate has been reported [Narayana et al. (1995) Nat. Struct. Biol. 2, 1018], the nature of the ternary complex which must form with substrate and cofactor is unclear. We have performed transferred NOE and interligand NOE (ILOE) studies to analyze the ternary complexes formed from NADP(+) and folate in order to probe the structure of the ternary complex. Consistent with previous studies of the binary complex formed from another type II DHFR, the ribonicotinamide bond of NADP(+) was found to adopt a syn conformation, while the adenosine moiety adopts an anti conformation. Large ILOE peaks connecting NADP(+) H4 and H5 with folate H9 protons are observed, while the absence of a large ILOE connecting NADP(+) H4 and H5 with folate H7 indicates that the relative orientation of the two ligands differs significantly from the orientation in the chromosomal enzyme. To obtain more detailed insight, we prepared and studied the folate analogue 2-deamino-2-methyl-5,8-dideazafolate (DMDDF) which contains additional protons in order to provide additional NOEs. For this analogue, the exchange characteristics of the corresponding ternary complex were considerably poorer, and it was necessary to utilize higher enzyme concentrations and higher temperature in order to obtain ILOE information. The results support a structure in which the NADP(+) and folate/DMDDF molecules extend in opposite directions parallel to the long axis of the pore, with the nicotinamide and pterin ring systems approximately stacked at the center. Such a structure leads to a ternary complex which is in many respects similar to the gas-phase theoretical calculations of the dihydrofolate-NADPH transition state by Andres et al. [(1996) Bioorg. Chem. 24, 10-18]. Analogous NMR studies performed on folate, DMDDF, and R67 DHFR indicate formation of a ternary complex in which two symmetry-related binding sites are occupied by folate and DMDDF.     

Heterologous expression of active thymidylate synthase-dihydrofolate reductase from Plasmodium falciparum

The coding sequence of the bifunctional thymidylate synthase-dihydrofolate reductase (TS-DHFR) from a moderately pyrimethamine-resistant strain (HB3) of Plasmodium falciparum was assembled in a pUC expression vector. The coding sequence possesses unique Nco1 and Xba1 sites which flank 243 bp of the DHFR gene that include all point mutations thus far linked to pyrimethamine resistance. Wild-type (3D7) and highly pyrimethamine-resistant (7G8) TS-DHFRs were made from this vector by cassette mutagenesis using Nco1-Xba1 fragments from the corresponding cloned TS-DHFR genes. Catalytically active recombinant TS-DHFRs were expressed in Escherichia coli, albeit at low levels. Both TS and DHFR coeluted upon gel filtration and copurified upon affinity and anion exchange chromatography. Gel filtration and SDS-PAGE indicated that the enzyme was a dimer with identical 67-kDa subunits, characteristic of protozoan TS-DHFRs. Amino-terminal sequencing gave 10 amino acids which perfectly matched the sequence predicted from the nucleotide sequence. The recombinant TS-DHFR was purified to homogeneity by 10-formylfolate affinity chromatography followed by Mono Q FPLC. The inhibition properties of pyrimethamine toward the purified recombinant enzymes show that the point mutations are the molecular basis of pyrimethamine resistance in P. falciparum.     

Characterization and stereochemistry of cofactor oxidation by a type II dihydrofolate reductase

Type II dihydrofolate reductases (DHFRs) encoded by the R67 and R388 plasmids are different both in sequence and in structure from known chromosomal DHFRs. These plasmid-derived DHFRs are responsible for conferring trimethoprim resistance to the host strain. A derivative of R388 DHFR, RBG200, has been cloned and overproduced [Vermersch, P. S., Klass, M. R., & Bennett, G. N. (1986) Gene 41, 289]. With this cloned and overproduced protein, a rapid purification procedure has been developed that yields milligram quantities of apparently homogeneous RBG200 DHFR with a specific activity 1.5-fold greater than that previously reported for the purified R388 protein [Amyes, S. G. B., & Smith, J. T. (1976) Eur. J. Biochem. 61, 597]. The pH versus activity profile and the native molecular weight of RBG200 DHFR were found to be similar to those previously reported for other type II DHFRs but different from those of the known chromosomal DHFRs. Stereospecifically labeled [4(S)-2H,4(R)-1H]NADPH was synthesized and used to determine the stereospecificity of NADPH oxidation by RBG200 DHFR. RBG200 DHFR was found to specifically transfer the pro-R hydrogen of NADPH to dihydrofolate, making it a member of the A-stereospecific class of dehydrogenases. Thus, although RBG200 DHFR is different both in sequence and in structure from known chromosomal enzymes, both enzymes catalyze identical hydrogen-transfer reactions. Two distinct binary RBG200 DHFR-NADP+ complexes were detected by monitoring the 1H NMR chemical shifts and line widths of the coenzyme in the presence of RBG200 DHFR.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sulfadoxine resistance in the human malaria parasite Plasmodium falciparum is determined by mutations in dihydropteroate synthetase and an additional factor associated with folate utilization

Sulfadoxine/pyrimethamine (Fansidar) is widely used in Africa for treating chloroquine-resistant falciparum malaria. To clarify how parasite resistance to this combination arises, various lines of Plasmodium falciparum were used to investigate the role of naturally occurring mutations in the target enzyme, dihydropteroate synthetase (DHPS), in the parasite response to sulfadoxine inhibition. An improved drug assay was employed to identify a clear correlation between sulfadoxine-resistance levels and the number of DHPS mutations. Moreover, tight linkage was observed between DHPS mutations and high-level resistance in the 16 progeny of a genetic cross between sulfadoxine-sensitive (HB3) and sulfadoxine-resistant (Dd2) parents. However, we also demonstrate a profound influence of exogenous folate on IC₅₀ values, which, under physiological conditions, may have a major role in determining resistance levels. Importantly, this phenotype does not segregate with dhps genotypes in the cross, but shows complete linkage to the two alleles of the dihydrofolate reductase ( dhfr ) gene inherited from the parental lines. However, in unrelated lines, this folate effect correlates less well with DHFR sequence, indicating that the gene responsible may be closely linked to dhfr , rather than dhfr itself. These results have major implications for the acquisition of Fansidar resistance by malaria parasites.     

Cloning and heterologous expression of Plasmodium ovale dihydrofolate reductase-thymidylate synthase gene

Plasmodial bifunctional dihydrofolate reductase-thymidylate synthase (DHFR-TS) is a validated antimalarial drug target. In this study, expression of the putative dhfr-ts of Plasmodium ovale rescued the DHFR chemical knockout and a TS null bacterial strain, demonstrating its DHFR and TS catalytic functions. PoDHFR-TS was expressed in Escherichia coli BL21 (DE3) and affinity purified by Methotrexate Sepharose column. Biochemical and enzyme kinetics characterizations indicated that PoDHFR-TS is similar to other plasmodial enzymes, albeit with lower catalytic activity but better tolerance of acidic pH. Importantly, the PoDHFR from Thai isolate EU266602 remains sensitive to the antimalarials pyrimethamine and cycloguanil, in contrast to P. falciparum and P. vivax isolates where resistance to these drugs is widespread.