Cell proliferation and cytoarchitectural remodeling during spinal cord reconnection in the fresh-water turtle Trachemys dorbignyi

Rehermann, María Inés; Santiñaque, Federico F.; López-Carro, Beatriz; Russo, Raúl E.; Trujillo‐Cenóz, O.

doi:10.1007/s00441-011-1173-y

Cited by 25 publications

(30 citation statements)

References 76 publications

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“…During embryonic development the transient expression of BLBP parallels neurogenesis, and there is evidence from transgenic mouse studies that nearly all neurons in the mouse brain are derived from BLBP + RG [53]. Additionally, BLBP + cells with RG morphology are localized to the central gelatinosa surrounding the central canal in the adult turtle [72, 75], are implicated in the reconnection of the turtle spinal cord after transection [68, 76] and are directly involved in the regeneration of the axolotl spinal cord after amputation of the tail [77]. In mammalian models of injury, BLBP + cells do not reconnect the spinal cord but undergo mitosis at an increased rate after injury [52].…”

Section: Proliferation In the Intact Spinal Cordmentioning

confidence: 99%

Endogenous Proliferation after Spinal Cord Injury in Animal Models

McDonough

Martínez‐Cerdeño

2012

Stem Cells International

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Spinal cord injury (SCI) results in motor and sensory deficits, the severity of which depends on the level and extent of the injury. Animal models for SCI research include transection, contusion, and compression mouse models. In this paper we will discuss the endogenous stem cell response to SCI in animal models. All SCI animal models experience a similar peak of cell proliferation three days after injury; however, each specific type of injury promotes a specific and distinct stem cell response. For example, the transection model results in a strong and localized initial increase of proliferation, while in contusion and compression models, the initial level of proliferation is lower but encompasses the entire rostrocaudal extent of the spinal cord. All injury types result in an increased ependymal proliferation, but only in contusion and compression models is there a significant level of proliferation in the lateral regions of the spinal cord. Finally, the fate of newly generated cells varies from a mainly oligodendrocyte fate in contusion and compression to a mostly astrocyte fate in the transection model. Here we will discuss the potential of endogenous stem/progenitor cell manipulation as a therapeutic tool to treat SCI.

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Section: Proliferation In the Intact Spinal Cordmentioning

confidence: 99%

Endogenous Proliferation after Spinal Cord Injury in Animal Models

McDonough

Martínez‐Cerdeño

2012

Stem Cells International

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“…By the end of embryogenesis most mammalian radial glia differentiate as astrocytes (Rakic, 2003). However in anamniotes radial glia persist widely in the CNS (García-Verdugo et al, 2002; Naujoks-Manteuffel and Roth, 1989; Zupanc and Clint, 2003), and their continued presence has been implicated in the striking ability of these animals to regenerate following injury (Chernoff et al, 2003; Hui et al, 2010; Rehermann et al, 2011). Thus radial glia have been suggested to represent an endogenous neural stem cell population.…”

Section: Introductionmentioning

confidence: 99%

Radial glial progenitors repair the zebrafish spinal cord following transection

Briona

Dorsky

2014

Experimental Neurology

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In mammals, spinal cord injury results in permanent sensory-motor loss due in part to a failure in reinitiating local neurogenesis. However, zebrafish show robust neuronal regeneration and functional recovery even after complete spinal cord transection. Postembryonic neurogenesis is dependent upon resident multipotent progenitors, which have been identified in multiple vertebrates. One candidate cell population for injury repair expresses Dbx1, which has been shown to label multipotent progenitors in mammals. In this study, we use specific markers to show that cells expressing a dbx1a:GFP reporter in the zebrafish spinal cord are radial glial progenitors that continue to generate neurons after embryogenesis. We also use a novel larval spinal cord transection assay to show that dbx1a:GFP+ cells exhibit a proliferative and neurogenic response to injury, and contribute newly-born neurons to the regenerative blastema. Together, our data indicate that dbx1a:GFP+ radial glia may be stem cells for the regeneration of interneurons following spinal cord injury in zebrafish.

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“…A few recent studies have also demonstrated axon regeneration after complete spinal cord transection in the turtle (Garcia et al, 2012; Rehermann et al, 2009; Rehermann et al, 2011). After injury, axon regeneration, primarily of propriospinal and sensory neurons, is followed by partial restoration of locomotion in ~50% of spinalized turtles (Rehermann et al, 2009; Rehermann et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…After injury, axon regeneration, primarily of propriospinal and sensory neurons, is followed by partial restoration of locomotion in ~50% of spinalized turtles (Rehermann et al, 2009; Rehermann et al, 2011). In this model, histological assays demonstrated that a blood clot filled with red and white blood cells formed immediately after SCI.…”

Section: Introductionmentioning

confidence: 99%

“…At the same time, phagocytic macrophages were observed at the lesion (Rehermann et al, 2009). Studies are just beginning to explore cellular aspects of neurogenesis and molecular programs influencing regeneration in this organism (Garcia et al, 2012; Rehermann et al, 2011). For an illustration of turtle axons regenerating across the lesion site, see Figure 2D.…”

Section: Introductionmentioning

confidence: 99%

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Non-mammalian model systems for studying neuro-immune interactions after spinal cord injury

Bloom¹

2014

Experimental Neurology

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Mammals exhibit poor recovery after injury to the spinal cord, where the loss of neurons and neuronal connections can be functionally devastating. In contrast, it has long been appreciated that many non-mammalian vertebrate species exhibit significant spontaneous functional recovery after spinal cord injury (SCI). Identifying the biological responses that support an organism's inability or ability to recover function after SCI is an important scientific and medical question. While recent advances have been made in understanding the responses to SCI in mammals, we remain without an effective clinical therapy for SCI. A comparative biological approach to understanding responses to SCI in non-mammalian vertebrates will yield important insights into mechanisms that promote recovery after SCI. Presently, mechanistic studies aimed at elucidating responses, both intrinsic and extrinsic to neurons, that result in different regenerative capacities after SCI across vertebrates are just in their early stages. There are several inhibitory mechanisms proposed to impede recovery from SCI in mammals, including reactive gliosis and scarring, myelin associated proteins, and a suboptimal immune response. One hypothesis to explain the robust regenerative capacity of several non-mammalian vertebrates is a lack of some or all of these inhibitory signals. This review presents the current knowledge of immune responses to SCI in several non-mammalian species that achieve anatomical and functional recovery after SCI. This subject is of growing interest, as studies increasingly show both beneficial and detrimental roles of the immune response following SCI in mammals. A long-term goal of biomedical research in all experimental models of SCI is to understand how to promote functional recovery after SCI in humans. Therefore, understanding immune responses to SCI in non-mammalian vertebrates that achieve functional recovery spontaneously may identify novel strategies to modulate immune responses in less regenerative species and promote recovery after SCI.

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Cell proliferation and cytoarchitectural remodeling during spinal cord reconnection in the fresh-water turtle Trachemys dorbignyi

Cited by 25 publications

References 76 publications

Endogenous Proliferation after Spinal Cord Injury in Animal Models

Endogenous Proliferation after Spinal Cord Injury in Animal Models

Radial glial progenitors repair the zebrafish spinal cord following transection

Non-mammalian model systems for studying neuro-immune interactions after spinal cord injury

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