BackgroundBangladesh is a malaria hypo-endemic country sharing borders with India and Myanmar. Artemisinin combination therapy (ACT) remains successful in Bangladesh. An increase of artemisinin-resistant malaria parasites on the Thai-Cambodia and Thai-Myanmar borders is worrisome. K13 propeller gene (PF3D7_1343700 or PF13_0238) mutations have been linked to both in vitro artemisinin resistance and in vivo slow parasite clearance rates. This group undertook to evaluate if mutations seen in Cambodia have emerged in Bangladesh where ACT use is now standard for a decade.MethodsSamples were obtained from Plasmodium falciparum-infected malaria patients from Upazila health complexes (UHC) between 2009 and 2013 in seven endemic districts of Bangladesh. These districts included Khagrachari (Matiranga UHC), Rangamati (Rajasthali UHC), Cox’s Bazar (Ramu and Ukhia UHC), Bandarban (Lama UHC), Mymensingh (Haluaghat UHC), Netrokona (Durgapur and Kalmakanda UHC), and Moulvibazar (Sreemangal and Kamalganj UHC).ResultsOut of 296 microscopically positive P. falciparum samples, 271 (91.6%) were confirmed as mono-infections by both real-time PCR and nested PCR. The K13 propeller gene from 253 (93.4%) samples was sequenced bi-directionally. One non-synonymous mutation (A578S) was found in Bangladeshi clinical isolates. The A578S mutation was confirmed and lies adjacent to the C580Y mutation, the major mutation causing delayed parasite clearance in Cambodia. Based on computational modeling A578S should have a significant effect on tertiary structure of the protein.ConclusionThe data suggest that P. falciparum in Bangladesh remains free of the C580Y mutation linked to delayed parasite clearance. However, the mutation A578S is present and based on structural analysis could affect K13 gene function. Further in vivo clinical studies are required to validate the effect of this mutation.
BackgroundDrug resistance, absence of an effective vaccine, and inadequate public health measures are major impediments to controlling Plasmodium falciparum malaria worldwide. The development of antimalarials to which resistance is less likely is paramount. To this end, we have exploited the chaperone function of P. falciparum Hsp90 (PfHsp90) that serves to facilitate the expression of resistance determinants.MethodsThe affinity and activity of a purine analogue Hsp90 inhibitor (PU-H71) on PfHsp90 was determined using surface plasmon resonance (SPR) studies and an ATPase activity assay, respectively. In vitro, antimalarial activity was quantified using flow cytometry. Interactors of PfHsp90 were determined by LC-MS/MS. In vivo studies were conducted using the Plasmodium berghei infection mouse model.ResultsPU-H71 exhibited antimalarial activity in the nanomolar range, displayed synergistic activity with chloroquine in vitro. Affinity studies reveal that the PfHsp90 interacts either directly or indirectly with the P. falciparum chloroquine resistance transporter (PfCRT) responsible for chloroquine resistance. PU-H71 synergized with chloroquine in the P.berghei mouse model of malaria to reduce parasitemia and improve survival.ConclusionsWe propose that the interaction of PfHsp90 with PfCRT may account for the observed antimalarial synergy and that PU-H71 is an effective adjunct for combination therapy.
Microscopy and field adaptable rapid diagnostic tests (RDTs) are not sensitive and specific in certain conditions such as poor training of microscopists, lack of electricity, or the inability to detect non-falciparum malaria. More sensitive point of care testing (POCT) would reduce delays in diagnosis and initiation of therapy. In the current study, we have evaluated the efficacy of non-instrumented nucleic acid amplification (NINA) coupled with LAMP for detection of traveler’s malaria (n = 140) in comparison with microscopy, nested PCR, and the only FDA-approved rapid diagnostic test. NINA-LAMP was 100% sensitive and 98.6% specific when compared to nested PCR. For non-falciparum detection, NINA-LAMP sensitivity was 100% sensitive compared to nested PCR whereas RDT sensitivity was 71%. LAMP is highly sensitive and specific for symptomatic malaria diagnosis regardless of species in a POCT setting.
Malaria continues to exact a great human toll in tropical settings. Antimalarial resistance is rife and the parasite inexorably develops mechanisms to outwit our best drugs, including the now first-line choice, artesunate. Novel strategies to circumvent resistance are needed. Here we detail drug development focusing on heat shock protein 90 and its central role as a chaperone. A growing body of evidence supports the role for Hsp90 inhibitors as adjunctive drugs able to restore susceptibility to traditionally efficacious compounds like chloroquine.
The CCR5 chemokine receptor is the major coreceptor for HIV-1 and the receptor for CC-chemokines, MIP-1alpha, MIP-1beta, and regulated upon activation normal T-cell-expressed and secreted. Individuals, who are homozygous for the nonfunctional CCR5Delta32 allele, are largely resistant to HIV-1 infection. Four unique mutations that affect the amino acid sequence of CCR5 have been identified in South Africa. We have assessed the effect of these mutations on CCR5 interactions with chemokines and HIV Envelope protein. The LeuPhe mutation did not affect CCR5 expression, chemokine binding, intracellular signaling, or interaction with Envelope. The ArgGln mutant was similar to wild-type CCR5, but ligand-independent intracellular signaling suggests that it is partially constitutively active. The AspVal mutation decreased chemokine-binding affinity, chemokine-stimulated intracellular signaling, and receptor expression. It also decreased HIV Envelope-mediated cell fusion. The ArgStop mutant showed no measurable chemokine binding or signaling and no measurable expression of CCR5 at the cell surface or within the cell. Consistent with lack of cell surface expression, it did not support envelope-mediated cell fusion. These results show that South African CCR5 variants have a range of phenotypes in vitro that may reflect altered chemokine responses and susceptibility to HIV infection in individuals who carry these alleles.
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