The burrowing behavior of the nematode <i>Caenorhabditis elegans</i>: a new assay for the study of neuromuscular disorders

Beron, Celia; Vidal-Gadea, Andrés G.; Cohn, Jesse; Parikh, Adhishri; Hwang, Grace S.; Pierce-Shimomura, Jonathan T.

doi:10.1111/gbb.12217

Cited by 35 publications

(74 citation statements)

References 39 publications

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“…Organisms without body appendages possessing only longitudinal muscles, such as nematodes 46 , are restricted to sinusoidal locomotion as they lack the antagonistic circular muscles necessary for peristalsis. Nematodes are common bioturbators of modern muddy sediments and can create open mucuslined burrows of a size range comparable to that of the Brazilian M. minima (Fig.…”

Section: Nature Ecology and Evolutionmentioning

confidence: 99%

Ichnological evidence for meiofaunal bilaterians from the terminal Ediacaran and earliest Cambrian of Brazil

et al. 2017

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The evolutionary events during the Ediacaran-Cambrian transition (~541 Myr ago) are unparalleled in Earth history. The fossil record suggests that most extant animal phyla appeared in a geologically brief interval, with the oldest unequivocal bilaterian body fossils found in the Early Cambrian. Molecular clocks and biomarkers provide independent estimates for the timing of animal origins, and both suggest a cryptic Neoproterozoic history for Metazoa that extends considerably beyond the Cambrian fossil record. We report an assemblage of ichnofossils from Ediacaran-Cambrian siltstones in Brazil, alongside U-Pb radioisotopic dates that constrain the age of the oldest specimens to 555-542 Myr. X-ray microtomography reveals three-dimensionally preserved traces ranging from 50 to 600 μ m in diameter, indicative of small-bodied, meiofaunal tracemakers. Burrow morphologies suggest they were created by a nematoid-like organism that used undulating locomotion to move through the sediment. This assemblage demonstrates animal-sediment interactions in the latest Ediacaran period, and provides the oldest known fossil evidence for meiofaunal bilaterians. Our discovery highlights meiofaunal ichnofossils as a hitherto unexplored window for tracking animal evolution in deep time, and reveals that both meiofaunal and macrofaunal bilaterians began to explore infaunal niches during the late Ediacaran. NATuRE ECoLoGy & EvoLuTIoN Articles Nature ecology & evolutioNsupport for these suggestions is limited to purported body fossils of sponges 19 and demosponge biomarkers 20 . A considerable gap therefore remains between the fossil record of the late Ediacaran and molecular clock estimates for deep splits in the animal tree, for example the origin of Metazoa and Eumetazoa 3 . Assuming that contemporary molecular clock analyses yield accurate, if imprecise 18 , node ages for animal divergences, a small body size and concomitant limited fossilization potential 21 could reconcile these discordant records of animal evolution (but see ref. 22 ).The small body size of the ancestral bilaterian is supported by recent phylogenomic analyses of deep animal relationships, with acoel flatworms and xenoturbellids (Xenacoelomorpha) being a sister group to all remaining bilaterians (Nephrozoa) 23 , and smallbodied spiralian taxa (the 'Platyzoa') recognized as a paraphyletic grade with respect to macroscopic trochozoans 24 . This suggests that early bilaterians and spiralians were small bodied, possibly meiofaunal, and moved using ciliary gliding.Meiofauna comprises all organisms between 32 and 1,000 μ m in size that inhabit pore-water-rich sediments in freshwater to deepmarine environments 25 . Modern meiofaunal communities include animals, foraminifera and some ciliates, and contribute significantly to sediment bioturbation and bioirrigation 26,27 . The meiofauna can be divided into permanent members (that is, animals with organisms of a small size adapted and restricted to the meiofaunal, interstitial realm) and temporary meiofauna (for example, the ...

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Section: Nature Ecology and Evolutionmentioning

confidence: 99%

Ichnological evidence for meiofaunal bilaterians from the terminal Ediacaran and earliest Cambrian of Brazil

et al. 2017

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“…5E, 5F). More body bends possibly indicate a more W-shaped locomotion, which has been described previously in burrowing worms, as opposed to the Sshaped crawling or C-shaped swimming motion (63). Since burrowing requires the effort to move in a viscous medium, one could assume that Group 100 animals crawling in MF have to apply effort to push also their way forward, thus they integrate more bends to their locomotion.…”

Section: The Impact Of Internally Localized Magnetic Fields On C Elementioning

confidence: 71%

Caenorhabditis elegans locomotion is affected by internalized paramagnetic nanoparticles in the presence of magnetic field

Gourgou

Zhang

Mirzakhalili

et al. 2018

Preprint

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C . elegans with internalized magnetic nanoparticles are placed inside magnetic field to explore effects on locomotion. We hypothesize that internal magnetic fields created by nanoparticles induce localized effects on C . elegans ' locomotion machinery. To test our hypothesis, we use young adult hermaphrodite C . elegans fed on E . coli OP50 mixed with magnetic/paramagnetic nanoparticles of 1μm, 100nm and 40nm diameter. The presence of particles inside the worms' body is verified by fluorescent and electron microscopy. A custom-made software is used to track freely moving C . elegans in the absence or presence of magnetic field sequentially for 200+200sec. We use established metrics to quantify locomotion-related parameters, including posture, motion and path features. Results show that key features of C . elegans locomotion (e.g., speed, number of bends, motion state and range) are affected by the magnetic field in worms with internalized particles, in contrast to untreated worms, which remain unaffected. Our work contributes on clarifying the magnetic field effect on C . elegans locomotion and introduces C . elegans as a potential model system to explore in vivo the effect of magnetic field gradient on living organisms.

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“…Recent work is starting to establish assays for the study of such types of locomotion. One example is burrowing, with a downward tendency, using magnetic cues for orientation (Beron et al, 2015; Vidal-Gadea et al, 2015). Another is nictation, a dispersal behavior, in which dauer larvae stand on their tails displaying undulating body movements trying to attach to a larger animal in order to get dispersed and potentially reach new food sources (Lee et al, 2012).…”

Section: Discussionmentioning

confidence: 99%

“…Simple dorsal and ventral contractions can hardly explain three-dimensional movements, which would require additional left-right body movements and thus a more complex regulation of musculature though a separate innervation of each muscle quadrant. C. elegans shows a number of additional types of movements that appear to be more complex than locomotion on a plane surface such as burrowing into substrates, nictation, which is a dispersal behavior during which worms assume an upright posture, and turning from their left to their right side (Lee et al, 2012; Beron et al, 2015; Vidal-Gadea et al, 2015). Left-right turning, or flipping, occurs mostly during lethargus.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the NK2 homeobox gene ceh-24 reveals sublateral motor neuron control of left-right turning during sleep

Schwarz

Bringmann

2017

eLife

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Sleep is a behavior that is found in all animals that have a nervous system and that have been studied carefully. In Caenorhabditis elegans larvae, sleep is associated with a turning behavior, called flipping, in which animals rotate 180° about their longitudinal axis. However, the molecular and neural substrates of this enigmatic behavior are not known. Here, we identified the conserved NK-2 homeobox gene ceh-24 to be crucially required for flipping. ceh-24 is required for the formation of processes and for cholinergic function of sublateral motor neurons, which separately innervate the four body muscle quadrants. Knockdown of cholinergic function in a subset of these sublateral neurons, the SIAs, abolishes flipping. The SIAs depolarize during flipping and their optogenetic activation induces flipping in a fraction of events. Thus, we identified the sublateral SIA neurons to control the three-dimensional movements of flipping. These neurons may also control other types of motion.DOI: http://dx.doi.org/10.7554/eLife.24846.001

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The burrowing behavior of the nematode Caenorhabditis elegans: a new assay for the study of neuromuscular disorders

Cited by 35 publications

References 39 publications

Ichnological evidence for meiofaunal bilaterians from the terminal Ediacaran and earliest Cambrian of Brazil

Ichnological evidence for meiofaunal bilaterians from the terminal Ediacaran and earliest Cambrian of Brazil

Caenorhabditis elegans locomotion is affected by internalized paramagnetic nanoparticles in the presence of magnetic field

Analysis of the NK2 homeobox gene ceh-24 reveals sublateral motor neuron control of left-right turning during sleep

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