Slo-1K channels, TRP-2 channels, emodepside and diethylcarbamazine in Filaria

丝虫中的 Slo-1K 通道、TRP-2 通道、艾默德苷和二乙基卡马嗪

• 批准号: 10264892
• 负责人: Richard John Martin
• 金额: $ 46.91万
• 依托单位: IOWA STATE UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2020
• 资助国家: 美国
• 起止时间: 2020-09-16 至 2025-08-31
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10264892
• 关键词: Adult; Adverse effects; African; Anthelmintics; Arachidonic Acids; Area; Basic Science; Blindness; Brugia; Brugia malayi; Calcium; Combined Modality Therapy; Development; Diethylcarbamazine; Disease; Disputes; Dopachrome isomerase; Evolution; Exposure to; Eye; Female; Filarial Elephantiases; Homologous Gene; Human; In Situ; In Vitro; Infection; Insecta; Intestinal Volvulus; Ion Channel; Knowledge; Larva; Life Cycle Stages; Loa; Loa loa; Loiasis; Mediating; Messenger RNA; Microfilaria; Molecular; Muscle; Nematoda; Nematode infections; Ocular Onchocerciasis; Onchocerca; Onchocerca volvulus; Onchocerciasis; Oocytes; Parasites; Parasitic nematode; Pathway interactions; Pharmaceutical Preparations; Pharmacology; Pharmacotherapy; Potassium Channel; Prevention; Prophylactic treatment; RNA Splicing; Recovery; Research; Resistance; Risk; Services; Site; Surgical Flaps; Techniques; Testing; Toxic effect; Variant; cell motility; comparative; desensitization; design; detection sensitivity; differential expression; drug action; filaria; gastrointestinal; human model; innovation; knock-down; male; mortality; neglected tropical diseases; novel therapeutics; patch clamp; phase II trial; programs; response; sex; success; vaccine access

Project Summary Filariases are a group of neglected tropical diseases produced by infection with microfilaria of Clade III parasitic nematodes that are transmitted by biting insects. One example is the lymphatic filariasis produced by Brugia malayi. Lymphatic filariasis is a debilitating and disfiguring disease which occurs in 120 million people worldwide. Other filarial diseases are River Blindness produced by Onchocerca volvulus and loiasis produced by Loa loa. Prevention and treatment of these nematode parasite diseases relies on the use of anthelmintic drugs because no effective vaccines are available. Prophylaxis using Mass Drug Administration [MDA] programs are limited by the efficacy of existing anthelmintics. Diethylcarbamazine is a mainstay for the treatment of lymphatic filariasis and loiasis in most parts of the world, except in areas where onchocerciasis is present because it is contra-indicated by risks of blindness. Diethylcarbamazine produces rapid clearance of microfilaria and causes ~40% mortality of adult parasites (macrofilaricide). A number of studies have suggested that diethylcarbamazine has an indirect host- mediated mode of action and that diethylcarbamazine acts by changing host arachidonic acid pathways. We have observed that diethylcarbamazine has direct effects on filarial nematodes. We present preliminary observations that show that diethylcarbamazine increases the opening of TRP-2 channels in Brugia malayi, and opening of calcium-activated SLO-1 K channels. The effect is a rapid, transient inhibition of motility followed by recovery: the response accommodates. Emodepside is an emerging and important cyclooctadepsipeptide class of anthelmintic that also has effects on microfilaria and adult filaria. Emodepside treatments could allow a major advance over existing mass drug administration (MDA) programs which require regular treatments to kill adult parasites. One of the sites of action of emodepside is on nematode SLO-1 K channels where opening of the channels inhibits motility, but it is not effective against all filaria. Here we propose to compare effects on filarial SLO- 1 K channels from Brugia, Onchocerca and Loa and to examine actions and interactions of these two drugs to explore their mode of action. We have 3 aims: Aim #1: Characterize, in vitro, the concentration motility-inhibition-response relationships of diethylcarbamazine and emodepside and their combination on: A) Brugia microfilaria; B) Brugia adult females; C) Brugia adult males. We will test the hypothesis that effects of diethylcarbamazine and emodepside are additive, synergistic or antagonistic and dependent of life-cycle stage and sex. Aim #2 Characterize the SLO-1 K channel current responses to diethylcarbamazine and emodepside in isolated Brugia malayi muscle flaps under patch-clamp We will test the hypotheses: a) that the effects of emodepside and diethylcarbamazine interact; b) that the interactions of diethylcarbamazine and emodepside are dependent on the presence of TRP-2 by knockdown of TRP-2 channels; and c) that TRP-2 and SLO-1 channel message & channel opening accommodates during prolonged exposure to diethylcarbamazine or emodepside. Aim #3: Characterize the comparative molecular pharmacology of: a) different SLO-1 K channels of Brugia malayi, Onchocerca volvulus and Loa loa and; b) TRP-2 channels of Brugia malayi and Loa loa expressed in oocytes. We will test the hypothesis that the pharmacology and potencies of emodepside and diethylcarbamazine on SLO-1 K channels and TRP-2 channels of, Brugia, Onchocerca and Loa are different and also different to a human channel homologue. We will examine channel desensitization. The proposal is innovative, using a combination of techniques to test the effects of diethylcarbamazine and emodepside on their putative target sites, SLO-1 K channels of filarial. The overall impact of using our mixture of techniques, will be discovery and comparison of effects of diethylcarbamazine and emodepside on different species of filarial TRP-2 channels and SLO-1 K channels. Knowledge of the molecular actions of these drugs is required for: a) molecular detection of sensitivity of different filarial species and resistance; b) designing new drugs and combination therapies; c) predicting and understanding sensitivities of different nematode parasite species; and d) predicting possible host toxicity.

项目总结