Regenerative capacity in the lamprey spinal cord is not altered after a repeated transection

Hanslik, Kendra L.; Allen, Scott R.; Harkenrider, Tessa L.; Fogerson, Stephanie M.; Guadarrama, Eduardo; Morgan, James L.

doi:10.1101/410530

Cited by 3 publications

(7 citation statements)

References 70 publications

(139 reference statements)

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“…ASE applicability can also be appreciated from other examples in the literature. Lamprey spinal cord cryosections were processed for triple immunofluorescence using ASE following repeated spinal transections to evaluate the resilience of its neuroregenerative capacity (Hanslik et al, 2019). Rodent brains were processed for triple immunogold electron microscopy using ASE, revealing a subcellular relocalization from the synapse periphery to within the synaptic cleft of GABA-A receptors during mutanthuntingtin evoked neurodegeneration (Rosas-Arellano et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

A Low Cost Antibody Signal Enhancer Improves Immunolabeling in Cell Culture, Primate Brain and Human Cancer Biopsy

et al. 2020

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This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Section: Discussionmentioning

confidence: 99%

A Low Cost Antibody Signal Enhancer Improves Immunolabeling in Cell Culture, Primate Brain and Human Cancer Biopsy

et al. 2020

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“…Following video recording at 10.5 weeks post injury, the descending reticulospinal axons were bulk labeled in order to assess the extent of axon regeneration, as previously described (Armstrong et al, 2003; Hanslik et al, 2018; Lau et al, 2013). Briefly, animals were re-anesthetized in MS-222, and a second spinal lesion was made 0.5 cm rostral to the original transection site.…”

Section: Methodsmentioning

confidence: 99%

“…By alternating these contractions on each side of the body the lamprey can generate successive traveling waves that make up each swimming cycle (McClellan, 1989; Williams, 1989; Williams and McMillen, 2015). The speed of the observed body wave is slower than that of the muscle contraction as a result of the interaction of forces acting on the body which include the forces generated by the muscles and the resistive forces of the fluid acting on the body (Ding et al, 2012; Tytell et al, 2010; Williams, 1989; Williams and McMillen, 2015) Demonstrating the robustness of this behavior, within several months after a complete spinal cord transection, lampreys are able to achieve robust recovery of swimming behaviors (Cohen et al, 1999; Hanslik et al, 2018; Katz et al, 2020; McClellan, 1989; McClellan, 1994; Oliphint et al, 2010; Rovainen, 1976; Selzer, 1978). Remarkably, they can also recover normal swimming after a second spinal re-transection (Hanslik et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Lampreys spontaneously recover swimming behaviors within 8-12 weeks after their spinal cord is transected rostrally at the level of the 5th gill due, in part, to long-distance regeneration of descending axons (McClellan, 1994; Oliphint et al, 2010; Rovainen, 1976). Initially, such transected animals are completely paralyzed (Hanslik et al, 2018; Oliphint et al, 2010). Axon regeneration begins two to three weeks after spinal cord transection with axons beginning to regenerate and some observed locomotor function just caudal to where the spinal cord was transected.…”

Section: Introductionmentioning

confidence: 99%

“…Despite lampreys being well documented as robust regenerators after a rostral spinal cord transection (e.g. in the gill region) and progressing from paralysis to full mobility within 10-12 weeks post injury, the extent of axon regeneration supporting this behavioral recovery is variable from animal-to-animal (Cohen et al, 1986; Hanslik et al, 2018; Oliphint et al, 2010; Rovainen, 1976; Selzer, 1978). Therefore, to understand the relationship between neural regeneration and behavioral recovery, we quantified the kinematics and swimming abilities of larval lampreys that had different levels of axon regeneration across the site of spinal transection and compared performance of control lamprey (non-transected) to lamprey who recovered from having their spinal cord transected 10.5 weeks prior at the 5 th gill or at mid-body.…”

Section: Introductionmentioning

confidence: 99%

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Swimming kinematics and performance of spinal transected lampreys with different levels of axon regeneration

Fies

Gemmell

Fogerson

et al. 2021

Preprint

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Neural and functional recovery in lampreys from spinal cord transection has been well documented. However, the extent of axon regeneration is highly variable and it is not known whether it is related to the level of behavioral recovery. To address this, we examined how swimming kinematics were related to axon regeneration by quantifying the relationship between swimming performance and percent axon regeneration of transected lampreys after 11 weeks of recovery. We found that swimming speed was not related to percent axon regeneration but it was closely related to body wave frequency and speed. However, wave frequency and speed varied greatly within individuals which resulted in swimming speed also varying within individuals. In fact, most recovered individuals, regardless of percent axon regeneration, could swim at fast and slow speeds. However, none of the transected individuals were able to generate body waves as large as the control lampreys. In order to swim faster, transected lampreys increased their wave frequencies and, as a result, transected lampreys had much higher frequencies than control lamprey at comparable swimming velocities. These data suggest that the control lampreys swam more efficiently than transected lampreys. In conclusion, there appears to be a minimal recovery threshold in terms of percent axon regeneration required for lampreys to be capable of swimming, however, there also seems to be a limit to how much they can behaviorally recover.

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Resilience of neural networks for locomotion

Haspel

Severi

Fauci

et al. 2021

The Journal of Physiology

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Locomotion is an essential behaviour for the survival of all animals. The neural circuitry underlying locomotion is therefore highly robust to a wide variety of perturbations, including injury and abrupt changes in the environment. In the short term, fault tolerance in neural networks allows locomotion to persist immediately after mild to moderate injury. In the longer term, in many invertebrates and vertebrates, neural reorganization including anatomical regeneration can restore locomotion after severe perturbations that initially caused paralysis. Despite decades of research, very little is known about the mechanisms underlying locomotor resilience at the level of the underlying neural circuits and coordination of central pattern generators (CPGs). Undulatory locomotion is an ideal behaviour for exploring principles of circuit organization, neural control and resilience of locomotion, offering a number of unique advantages including experimental accessibility and modelling tractability. In comparing three well‐characterized undulatory swimmers, lampreys, larval zebrafish and Caenorhabditis elegans, we find similarities in the manifestation of locomotor resilience. To advance our understanding, we propose a comparative approach, integrating experimental and modelling studies, that will allow the field to begin identifying shared and distinct solutions for overcoming perturbations to persist in orchestrating this essential behaviour.

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Regenerative capacity in the lamprey spinal cord is not altered after a repeated transection

Cited by 3 publications

References 70 publications

A Low Cost Antibody Signal Enhancer Improves Immunolabeling in Cell Culture, Primate Brain and Human Cancer Biopsy

A Low Cost Antibody Signal Enhancer Improves Immunolabeling in Cell Culture, Primate Brain and Human Cancer Biopsy

Swimming kinematics and performance of spinal transected lampreys with different levels of axon regeneration

Resilience of neural networks for locomotion

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