C Bainbridge1, A Schuler1, A G Vidal-Gadea2. 1. School of Biological Sciences, Illinois State University, 339 Science Laboratory Building, Normal, IL 61790-4120, USA. 2. School of Biological Sciences, Illinois State University, 339 Science Laboratory Building, Normal, IL 61790-4120, USA. Electronic address: avidal@ilstu.edu.
Abstract
BACKGROUND: The study of locomotion in vermiform animals has largely been restricted to animals crawling on agar surfaces. While this has been fruitful in the study of neuronal basis of disease and behavior, the reduced physical challenge posed by these environments has prevented these organisms from being equally successful in the study of neuromuscular diseases. Our burrowing assay allowed us to study the effects of muscular exertion on locomotion and muscle degeneration during disease (Beron et al., 2015), as well as the natural burrowing preference of diverse Caenorhabditis elegans strains (Vidal-Gadea et al., 2015). NEW METHOD: We describe a simple, rapid, and affordable set of assays to study the burrowing behavior of nematodes and other vermiform organisms which permits the titration of muscular exertion in test animals. RESULTS: We show that our burrowing assay design is versatile and can be adapted for use in widely different experimental paradigms. COMPARISON WITH EXISTING METHOD(S): Previous assays for the study of neuromuscular integrity in nematodes relied on movement through facile and homogeneous environments. The ability of modulating substrate density allows our burrowing assay to be used to separate animal populations where muscular fitness or health are not visible differentiable by standard techniques. CONCLUSION: The simplicity, versatility, and potential for greatly facilitating the study of previously challenging neuromuscular disorders makes this assay a valuable addition that overcomes many of the limitations inherent to traditional behavioral tests of vermiform locomotion.
BACKGROUND: The study of locomotion in vermiform animals has largely been restricted to animals crawling on agar surfaces. While this has been fruitful in the study of neuronal basis of disease and behavior, the reduced physical challenge posed by these environments has prevented these organisms from being equally successful in the study of neuromuscular diseases. Our burrowing assay allowed us to study the effects of muscular exertion on locomotion and muscle degeneration during disease (Beron et al., 2015), as well as the natural burrowing preference of diverse Caenorhabditis elegans strains (Vidal-Gadea et al., 2015). NEW METHOD: We describe a simple, rapid, and affordable set of assays to study the burrowing behavior of nematodes and other vermiform organisms which permits the titration of muscular exertion in test animals. RESULTS: We show that our burrowing assay design is versatile and can be adapted for use in widely different experimental paradigms. COMPARISON WITH EXISTING METHOD(S): Previous assays for the study of neuromuscular integrity in nematodes relied on movement through facile and homogeneous environments. The ability of modulating substrate density allows our burrowing assay to be used to separate animal populations where muscular fitness or health are not visible differentiable by standard techniques. CONCLUSION: The simplicity, versatility, and potential for greatly facilitating the study of previously challenging neuromuscular disorders makes this assay a valuable addition that overcomes many of the limitations inherent to traditional behavioral tests of vermiform locomotion.
Authors: K J Hughes; A Rodriguez; K M Flatt; S Ray; A Schuler; B Rodemoyer; V Veerappan; K Cuciarone; A Kullman; C Lim; N Gutta; S Vemuri; V Andriulis; D Niswonger; L Barickman; W Stein; A Singhvi; N E Schroeder; A G Vidal-Gadea Journal: Proc Natl Acad Sci U S A Date: 2019-02-12 Impact factor: 11.205
Authors: Leila Lesanpezeshki; Jennifer E Hewitt; Ricardo Laranjeiro; Adam Antebi; Monica Driscoll; Nathaniel J Szewczyk; Jerzy Blawzdziewicz; Carla M R Lacerda; Siva A Vanapalli Journal: Sci Rep Date: 2019-10-23 Impact factor: 4.379
Authors: Rebecca A Ellwood; Jennifer E Hewitt; Roberta Torregrossa; Ashleigh M Philp; Justin P Hardee; Samantha Hughes; David van de Klashorst; Nima Gharahdaghi; Taslim Anupom; Luke Slade; Colleen S Deane; Michael Cooke; Timothy Etheridge; Mathew Piasecki; Adam Antebi; Gordon S Lynch; Andrew Philp; Siva A Vanapalli; Matthew Whiteman; Nathaniel J Szewczyk Journal: Proc Natl Acad Sci U S A Date: 2021-03-02 Impact factor: 11.205