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Query: UMLS:C0024530 (malaria)
44,886 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Haeme metabolism remains a vulnerable problem for the intraerythrocytic Plasmodium which catabolises haemoglobin as a source of amino acids in an acidic, oxygen-rich lysosome-like digestive vacuole. Haeme monomer, capable of generating oxygen radicals, transforms into an inert crystal named malarial pigment or haemozoin by forming unique dimers that then crystalise. Laveran first described pigmented bodies in humans to define a protozoan as the aetiologic agent of malaria. The trail of malaria pigment enabled Ross to implicate the mosquito in the life cycle of Plasmodium. In 1991, Slater and Cerami postulated a unique iron-carboxylate bond between two haemes in haemozoin crystals based on infrared and X-ray spectroscopy data. Additionally, parasite extracts were shown to possess a 'haeme polymerase' enzymatic activity as the process of crystal formation was then termed. Importantly, the quinolines, such as choloroquine, inhibit haemozoin formation. A Plasmodium falciparum derived histidine-rich protein II, which binds haeme and initiates haemozoin formation, is present in the digestive vacuole. Pfhistidine-rich protein II and Pfhistidine-rich protein III are sufficient, but not necessary for haemozoin formation as a laboratory clone lacking both still makes the haeme crystals. The reduvid bug, and the Schistosoma and Haemoproteus genera also make haemozoin. Recently, Bohle and coworkers used X-ray diffraction to document the iron-carboxylate bond in intact desiccated parasites and to show that a Fe1-O41 head to tail haeme dimer is the unit building block of haemozoin. The role of the Plasmodium histidine-rich protein family members, lipids or potential novel proteins in the exact molecular assembly of the large molecular weight haeme crystals in the protein rich digestive vacuole needs to be solved. Accurate experimental determination of the role of haemozoin formation and inhibition as the target of chloroquine is fundamental to determination of the mechanism of quinoline drug action and resistance. The enhanced understanding of the biosynthetic pathway leading to haemozoin formation using functional proteomic tools and the mechanisms through which existing antimalarial drugs affect Plasmodium haeme chemistry will help design improved chaemotherapeutic agents.
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PMID:Theories on malarial pigment formation and quinoline action. 1243 49

The quinolines have been used in the treatment of malaria, arthritis, and lupus for many years, yet the precise mechanism of their action remains unclear. In this study, we used a functional proteomics approach that exploited the structural similarities between the quinoline compounds and the purine ring of ATP to identify quinoline-binding proteins. Several quinoline drugs were screened by displacement affinity chromatography against the purine binding proteome captured with gamma-phosphate-linked ATP-Sepharose. Screening of the human red blood cell purine binding proteome identified two human proteins, aldehyde dehydrogenase 1 (ALDH1) and quinone reductase 2 (QR2). In contrast, no proteins were detected upon screening of the Plasmodium falciparum purine binding proteome with the quinolines. In a complementary approach, we passed cell lysates from mice, red blood cells, or P. falciparum over hydroxychloroquine- or primaquine-Sepharose. Consistent with the displacement affinity chromatography screen, ALDH and QR2 were the only proteins recovered from mice and human red blood cell lysate and no proteins were recovered from P. falciparum. Furthermore, the activity of QR2 was potently inhibited by several of the quinolines in vitro. Our results show that ALDH1 and QR2 are selective targets of the quinolines and may provide new insights into the mechanism of action of these drugs.
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PMID:Discovery of novel targets of quinoline drugs in the human purine binding proteome. 1243 4

The quinolines, hydroxychloroquine (Plaquenil) and chloroquine are used primarily for their anti-inflammatory effects in the treatment of auto-immune conditions such as rheumatoid arthritis. Another common use of these drugs is the prophylaxis and suppression of malaria. The use of quinolines may cause several ocular side-effects. The most significant complication is irreversible macular damage resulting in both visual acuity and visual field loss. However, the Royal College of Ophthalmologists, UK (RCO) recently recommended against the monitoring of patients receiving quinoline therapy as it was deemed to be too costly, given the low incidence of retinal complications. In this article, we present a case of hydroxychloroquine retinopathy, describe the ocular changes associated with quinoline therapy and recommend an optometric review schedule for patients who are currently taking these drugs. Furthermore, we recommend a proactive approach toward medical practitioners prescribing these drugs for optometric-based monitoring of these patients.
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PMID:Management of patients undergoing hydroxychloroquine (Plaquenil) therapy. 1247 64

Antimalarial chemotherapy has become more complex and challenging because of multidrug resistant strains of Plasmodium falciparum. Due to resistance of malarial parasite against well known drugs, the chemotherapy of malaria has become complicated. In this review we have discussed brief introduction followed by life cycle of malaria parasite. The list of commercially available antimalarial drugs along with there action on different stages of parasite have been discussed. A brief description of their mechanism of action and advantages and disadvantages were reported. The natural products as antimalarial have been discussed in the review. On the basis of chemical classes the natural products were divided in the following categories; Quinoline alkaloids, Iso-quinoline alkaloids, Indoloquinoline alkaloids, Carbolines, Bis-isoquinoline, 4-Quinazole derivatives, Trioxanes, Terpenes, Naphthoquinone, Anthraquinones, Chalcones, Hydroxy flavanones, Coumarins and phenolic glycoside. The combination chemotherapy has been highlighted in the review. The Biochemical and Immunological changes in malarial infection are discussed along with complications of malarial chemotherapy due to resistance. In the conclusion section, the future strategies for the chemotherapy of malaria have been discussed.
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PMID:Perspective in antimalarial chemotherapy. 1267 7

Chloroquine has been used in Madagascar since 1945 and remains the first-line treatment for uncomplicated cases of malaria. Low-grades of resistance type R1 and R2 have been reported. Thus, in vitro tests were performed in order to monitor the drug sensitivity of Plasmodium falciparum from different study sites, with the aim of identifying alternatives to chloroquine. Chloroquine IC50 values ranged from 0.2 nM to 283.4 nM (n = 190, mean IC50 = 52.6 nM; 95% CI = 46.1-59.1 nM). Fifteen isolates (7.9%) were chloroquine-resistant. One mefloquine-resistant isolate was detected (1/139). The test isolates were sensitive to amodiaquine (n = 118), quinine (n = 212), pyrimethamine (n = 86) and cycloguanil (n = 79). The median IC50 for amodiaquine was 12.3 nM (mean IC50 = 15.3 nM, 95% CI = 13.3-17.3 nM). Amodiaquine was 3.4 times as active as chloroquine in vitro and 7 times as active as quinine against P. falciparum. These results indicate that amodiaquine may be a potent alternative to chloroquine in Madagascar. There was positive correlation between tested quinoline-containing drugs activities, which suggests in vitro cross-susceptibility.
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PMID:In vitro sensitivity of Plasmodium falciparum to amodiaquine compared with other major antimalarials in Madagascar. 1270 75

Quinoline resistance in malaria is frequently compared with P-glycoprotein-mediated multidrug resistance (mdr) in mammalian cells. We have previously reported that nonylphenolethoxylates, such as NP30, are potential Plasmodium falciparum P-glycoprotein substrates and drug efflux inhibitors. We used in vitro assays to compare the ability of verapamil and NP30 to sensitize two parasite isolates to four quinolines: chloroquine (CQ), mefloquine (MF), quinine (QN), and quinidine (QD). NP30 was able to sensitize (reversal, >80%) P. falciparum to MF, QN, QD, and, to a lesser extent, CQ. The presence of 2 micro M verapamil had no effect on mefloquine resistance; however, the presence of verapamil modulated the activities of QN and QD in a manner parallel to that observed for CQ. Genetic analysis of putative quinoline resistance genes did not suggest an association between known point mutations in pfcrt and pfmdr1 and NP30 sensitization activity. We conclude that the sensitization action of NP30 is distinct both phenotypically and genotypically from that of verapamil.
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PMID:Reversal of mefloquine and quinine resistance in Plasmodium falciparum with NP30. 1287 95

The emergence and spread of drug-resistant malaria parasites is the major threat to effective malaria control. So far, malaria control has relied heavily on a restricted number of chemically related drugs belonging to either the quinoline or the antifolate groups. Only recently have the artemisinin-type compounds been used widely, predominantly in Southeast Asia. Experience has shown that resistance eventually curtails the life span of antimalarial drugs. If measures are not applied to contain resistance, the investment put into the development of new drugs will be squandered. Current efforts focus, on the one hand, on research into novel compounds with mechanisms of action that are different to the traditionally used drugs, and, on the other hand, on measures to prevent or delay resistance when drugs are introduced. Drug discovery and development are long, risky and expensive ventures. Whilst very few new antimalarial drugs were developed in the last quarter of the 20th century (only four of the nearly 1,400 drugs registered worldwide during 1975-1999), various private and public institutions are at work to discover and develop new compounds. Today, the antimalarial pipeline is relatively healthy. Projects are underway at different stages of drug development, from pre-development to registration. However, there is relatively little novelty, as current development projects still rely upon the traditional quinoline, antifolate and, in particular, artemisinin compounds. New structures are expected from the more upstream discovery efforts but it will take time before they become drugs. Therefore, whilst waiting for the drugs of tomorrow, there is a pressing need for immediately available, effective and affordable drugs that will have long life spans. Drug combinations that have independent modes of action are seen as a way of enhancing efficacy while ensuring mutual protection against resistance. Most research work has focussed on the use of artesunate combined with currently used standard drugs, namely mefloquine, amodiaquine, sulfadoxine/pyrimethamine and chloroquine. There is clear evidence that combinations improve efficacy without increasing toxicity. However, the absolute cure rates that are achieved by combinations vary widely and are dependent on the level of resistance of the standard drug. From these studies, further work is underway to produce fixed dose combinations that will be packaged in blister packs. Malaria control programmes need efficacious drugs that can be used with ease by the populations of endemic countries. This review will summarise current antimalarial drug developments and outline recent clinical research that aims to bring artemisinin-based combinations to those that need them most.
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PMID:Antimalarial compounds: from bench to bedside. 1450 10

Two subclasses of quinoline antimalarial drugs are used clinically. Both act on the endolysosomal system of malaria parasites, but in different ways. Treatment with 4-aminoquinoline drugs, such as chloroquine, causes morphologic changes and hemoglobin accumulation in endocytic vesicles. Treatment with quinoline-4-methanol drugs, such as quinine and mefloquine, also causes morphologic changes, but does not cause hemoglobin accumulation. In addition, chloroquine causes undimerized ferriprotoporphyrin IX (ferric heme) to accumulate whereas quinine and mefloquine do not. On the contrary, treatment with quinine or mefloquine prevents and reverses chloroquine-induced accumulation of hemoglobin and undimerized ferriprotoporphyrin IX. This difference is of particular interest since there is convincing evidence that undimerized ferriprotoporphyrin IX in malaria parasites would interact with and serve as a target for chloroquine. According to the ferriprotoporphyrin IX interaction hypothesis, chloroquine would bind to undimerized ferriprotoporphyrin IX, delay its detoxification, cause it to accumulate, and allow it to exert its intrinsic biological toxicities. The ferriprotoporphyrin IX interaction hypothesis appears to explain the antimalarial action of chloroquine, but a drug target in addition to ferriprotoporphyrin IX is suggested by the antimalarial actions of quinine and mefloquine. This article summarizes current knowledge of the role of ferriprotoporphyrin IX in the antimalarial actions of quinoline drugs and evaluates the currently available evidence in support of phospholipids as a second target for quinine, mefloquine and, possibly, the chloroquine-ferriprotoporphyrin IX complex.
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PMID:Ferriprotoporphyrin IX, phospholipids, and the antimalarial actions of quinoline drugs. 1496 91

The emergence and spread of drug resistant malaria represents a considerable challenge to controlling malaria. To date, malaria control has relied heavily on a comparatively small number of chemically related drugs, belonging to either the quinoline or the antifolate groups. Only recently have the artemisinin derivatives been used but mostly in south east Asia. Experience has shown that resistance eventually curtails the life-span of antimalarial drugs. Controlling resistance is key to ensuring that the investment put into developing new antimalarial drugs is not wasted. Current efforts focus on research into new compounds with novel mechanisms of action, and on measures to prevent or delay resistance when drugs are introduced. Drug discovery and development are long, risky and costly ventures. Antimalarial drug development has traditionally been slow but now various private and public institutions are at work to discover and develop new compounds. Today, the antimalarial development pipeline is looking reasonably healthy. Most development relies on the quinoline, antifolate and artemisinin compounds. There is a pressing need to have effective, easy to use, affordable drugs that will last a long time. Drug combinations that have independent modes of action are seen as a way of enhancing efficacy while ensuring mutual protection against resistance. Most research work has focused on the use of artesunate combined with currently used standard drugs, namely, mefloquine, amodiaquine, sulfadoxine/pyrimethamine, and chloroquine. There is clear evidence that combinations improve efficacy without increasing toxicity. However, the absolute cure rates that are achieved by combinations vary widely and depend on the level of resistance of the standard drug. From these studies, further work is underway to produce fixed dose combinations that will be packaged in blister packs. This review will summarise current antimalarial drug developments and outline recent clinical research that aims to bring artemisinin based combinations to those that need them most.
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PMID:Developing artemisinin based drug combinations for the treatment of drug resistant falciparum malaria: A review. 1504 98

Quinone oxidoreductase 2 (QR2) purified from human red blood cells was recently shown to be a potential target of the quinoline antimalarial compounds [Graves et al., (2002) Mol. Pharmacol. 62, 1364]. QR2 catalyzes the two-electron reduction of menadione via the oxidation of N-alkylated or N-ribosylated nicotinamides. To investigate the mechanism and consequences of inhibition of QR2 by the quinolines further, we have used steady-state and transient-state kinetics to define the mechanism of QR2. Importantly, we have shown that QR2 when isolated from an overproducing strain of E. coli is kinetically equivalent to the enzyme from the native human red blood cell source. We observe ping-pong kinetics consistent with one substrate/inhibitor binding site that shows selectivity for the oxidation state of the FAD cofactor, suggesting that selective inhibition of the liver versus red blood cell forms of malaria may be possible. The reductant N-methyldihydronicotinamide and the inhibitor primaquine bind exclusively to the oxidized enzyme. In contrast, the inhibitors quinacrine and chloroquine bind exclusively to the reduced enzyme. The quinone substrate menadione, on the other hand, binds nonspecifically to both forms of the enzyme. Single-turnover kinetics of the reductive half-reaction are chemically and kinetically competent and confirm the inhibitor selectivity seen in the steady-state experiments. Our studies shed light on the possible in vivo potency of the quinolines and provide a foundation for future studies aimed at creating more potent QR2 inhibitors and at understanding the physiological significance of QR2.
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PMID:Kinetic mechanism of quinone oxidoreductase 2 and its inhibition by the antimalarial quinolines. 1507

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