Evolution of the nematode intestine: a critical host interface Abstract More than two billion people are infected with parasitic nematodes. These pathogens are a major cause of neglected diseases that lead to mortality and diverse forms of morbidity in humans, while interfering with normal development in children. Parasitic nematodes reduce productivity of food animals and crops which are critical for economical and nutritional well-being, especially for people in developing countries. The control and treatment of these infections is challenged by the absence of vaccines, the limited choice of anthelmintics and evolution of anthelmintic resistance in these pathogens. The biological and molecular complexity of nematodes has further impeded research on development of new therapies for treatment and control. Our research focuses on the versatility of the nematode intestine as a target for new therapies. Our recent progress has established a broad and deep understanding of the molecular architecture underlying intestinal cell functions at the pan-Nematoda level. We also developed a new experimental model to investigate essential features of the nematode intestine as it relates to pan-Nematoda development of new targets for therapies to treat and control these pathogens in humans and animals. Progress to date has formed a solid foundation upon which the current proposal will capitalize in advancing capabilities to thoroughly investigate the potential of nematode intestinal functions in providing new therapies for nematode infections. Using the multi-omics resource that we have built, we will develop computational schema to identify and prioritize pan-Nematoda proteins/pathways that warrant investigation as anthelmintic targets (Aim 1). Druggable targets among prioritized proteins/pathways will be identified, followed by a systematic identification of inhibitors that can be experimentally evaluated using existing and emerging model systems (Aim 2).
Aims 1 and 2 will generate the first large-scale databases of this kind for nematodes, which will have exceptionally high value for our research and that of many other investigators. Preliminary results identified microtubule-dependent apical exocytosis as a high priority process for investigation, which will be investigated in Aim 3, utilizing the Ascaris suum intestinal cell and perfusion model. This research will establish an experimental system to thoroughly investigate apical exocytosis, evaluate chemical inhibitors of this pathway and test inhibitors of other pathways identified from Aims 1 and 2.
In Aim 4, progress made in preceding aims will be extended to two other core species, Haemonchus contortus and Trichuris suis, to assess the pan-Nematoda application of findings related to conserved intestinal cell processes and inhibitors. Advances are expected in establishing a new paradigm in research on parasitic nematodes that is designed to have pan-Nematoda application. Extensive databases resulting from secondary and tertiary integration of existing information offers unprecedented guidance for researchers in the field. That information will be used to guide experimental approaches for the purpose of validating predictions and testing efficacy of inhibitors that may reflect initial progress toward development of new broad spectrum anthelmintics.

Public Health Relevance

Parasitic nematodes are major causes of disease in over 2 billion humans worldwide. Therapies to treat and control diseases caused by these pathogens are limited, as are model research systems to elucidate new therapies, or improve on existing ones. The intestine of parasitic nematodes has proven a valuable target for new therapies, while facile models to conduct research on this tissue have heretofore been lacking. We have developed extensive bioinformatics databases to predict prospective therapeutic targets with pan-Nematoda application and a novel experimental model to test these predictions. The research will integrate these capabilities to identify targets for new anthelmintics with pan-Nematoda application to treat diseases afflicting nearly one third of the human population.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM097435-06
Application #
9356517
Study Section
Genetic Variation and Evolution Study Section (GVE)
Program Officer
Janes, Daniel E
Project Start
2011-04-15
Project End
2020-08-31
Budget Start
2017-09-01
Budget End
2018-08-31
Support Year
6
Fiscal Year
2017
Total Cost
Indirect Cost
Name
Washington University
Department
Genetics
Type
Schools of Medicine
DUNS #
068552207
City
Saint Louis
State
MO
Country
United States
Zip Code
63130
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Zarlenga, Dante; Wang, Zhengyuan; Mitreva, Makedonka (2016) Trichinella spiralis: Adaptation and parasitism. Vet Parasitol 231:8-21

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