The catecholaminergic nerve plexus of Holothuroidea

Díaz-Balzac, Carlos A.; Mejías, Wigberto; Jimenez, L; García‐Arrarás, José E.

doi:10.1007/s00435-010-0103-y

Cited by 15 publications

(12 citation statements)

References 38 publications

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“…However, some of the differences observed in the enteric nervous system of the three species could also be due to variations associated with the level of the intestinal tissue that was studied and not necessarily species differences. Such differences have been well documented in H. glaberrima where, for example an intestinal catecholaminergic plexus is observed in the esophagus and descending small intestine but is not found in other intestinal regions (Diaz-Balzac et al 2010b). In this respect, it is important to highlight that the posterior (large) intestine of H. mexicana was studied, but for the other two species the sections were obtained at mid-body level, thus it is not clear if the intestinal tissue at that level corresponds (anatomically or functionally) to a more small intestine (nutrient absorptive function) or large intestine (feces compaction function) type.…”

Section: Discussionmentioning

confidence: 73%

“…Similarly, anti-nurr1 is the first marker that appears to preferentially identify cells of the hyponeural component over those of the ectoneural component, contrary to anti-galanin, which preferentially identify cells and fibers of the ectoneural component (Diaz-Miranda et al 1996). This is particularly surprising in view of the fact that in vertebrates, Nurr1 function has been associated with the catecholaminergic neurotransmitter system (Zetterstrom et al 1997), but previous studies from our group have shown that the holothurian catecholaminergic system is present within the ectoneural component of the radial nerve cord (Diaz-Balzac et al 2010b). Finally, most of the cells immunoreactive to anti-PH3 and anti-pax6 were found outside of the radial nerve cord, suggesting that they correspond to a peripheral nervous system component and that most of the fibers identified by these antibodies within the radial nerve cord itself might correspond to afferent fibers originating from the somas localized in peripheral regions, such as the podial nerve or enteric nervous system.…”

Section: Discussionmentioning

confidence: 90%

“…1A–B). The nervous system in these organs has been thoroughly described in previous studies by our group (Diaz-Balzac et al 2010a; Diaz-Balzac et al 2010b; Diaz-Balzac et al 2007; Diaz-Miranda et al 1995; Diaz-Miranda et al 1996) and thus provides an excellent starting point for comparison of the immunoreactivity observed with the new markers.…”

Section: Resultsmentioning

confidence: 97%

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Novel markers identify nervous system components of the holothurian nervous system

2014

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Echinoderms occupy a key position in the evolution of deuterostomes. As such, the study of their nervous system can shed important information on the evolution of the vertebrate nervous system. However, the study of the echinoderm nervous system has lagged behind when compared to that of other invertebrates due to the lack of tools available. In this study, we tested three commercially available antibodies as markers of neural components in holothurians. Immunohistological experiments with antibodies made against the mammalian transcription factors Pax6 and Nurr1, and against phosphorylated histone H3 showed that these markers identified cells and fibers within the nervous system of Holothuria glaberrima. Most of the fibers recognized by these antibodies were co-labeled with the well-known neural marker, RN1. Additional experiments showed that similar immunoreactivity was found in the nervous tissue of three other holothurian species (Holothuria mexicana, Leptosynapta clarki and Sclerodactyla briareus), thus extending our findings to the three orders of Holothuroidea. Furthermore, these markers identified different subdivisions of the holothurian nervous system. Our study presents three additional markers of the holothurian nervous system, expanding the available toolkit to study the anatomy, physiology, development and evolution of the echinoderm nervous system.

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Section: Discussionmentioning

confidence: 73%

Section: Discussionmentioning

confidence: 90%

Section: Resultsmentioning

confidence: 97%

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Novel markers identify nervous system components of the holothurian nervous system

2014

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“…Smaller subpopulations of neurons have also been characterized by using previously described nervous system markers, particularly neurotransmitters or their synthesizing enzymes or neuropeptides. Thus, the gabaergic and catecholaminergic nervous system components of echinoderms have been described [ 9 , 10 ] as have been many neurons, neuroendocrine cells and fibers that express neuropeptides. This is the case for SALMFamide [ 11 , 12 ], GFSKLYFamide [ 13 ], galanin [ 14 ], and FMRFamide [ 15 ].…”

Section: Introductionmentioning

confidence: 99%

Holothurian Nervous System Diversity Revealed by Neuroanatomical Analysis

et al. 2016

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The Echinodermata comprise an interesting branch in the phylogenetic tree of deuterostomes. Their radial symmetry which is reflected in their nervous system anatomy makes them a target of interest in the study of nervous system evolution. Until recently, the study of the echinoderm nervous system has been hindered by a shortage of neuronal markers. However, in recent years several markers of neuronal and fiber subpopulations have been described. These have been used to identify subpopulations of neurons and fibers, but an integrative study of the anatomical relationship of these subpopulations is wanting. We have now used eight commercial antibodies, together with three antibodies produced by our group to provide a comprehensive and integrated description and new details of the echinoderm neuroanatomy using the holothurian Holothuria glaberrima (Selenka, 1867) as our model system. Immunoreactivity of the markers used showed: (1) specific labeling patterns by markers in the radial nerve cords, which suggest the presence of specific nerve tracts in holothurians. (2) Nerves directly innervate most muscle fibers in the longitudinal muscles. (3) Similar to other deuterostomes (mainly vertebrates), their enteric nervous system is composed of a large and diverse repertoire of neurons and fiber phenotypes. Our results provide a first blueprint of the anatomical organization of cells and fibers that form the holothurian neural circuitry, and highlight the fact that the echinoderm nervous system shows unexpected diversity in cell and fiber types and their distribution in both central and peripheral nervous components.

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“…Until recently, almost all knowledge of the nervous system of echinoderms was based on classical histology carried out early during the last century and, more recently, on electron microscopy studies (e.g., Bouland et al., 1982; Cavey, 2006; Flammang & Jangoux, 1992; Hyman, 1955; McKenzie, 1987; Pentreath & Cobb, 1972; VandenSpiegel et al., 1995). With the development of new neural markers, neuronal populations expressing different neurotransmitters, such as catecholamines and neuropeptides, have been identified, contributing to a more comprehensive view of the echinoderm nervous system (Díaz‐Balzac, Abreu‐Arbelo, & García‐Arrarás, 2010; Díaz‐Balzac & García‐Arrarás, 2018; Díaz‐Balzac, Mejías, Jiménez, & García‐Arrarás, 2010; Díaz‐Balzac et al., 2007, 2014; Díaz‐Miranda, Blanco, & Garcia‐Arraras, 1995; Hoekstra, Moroz, & Heyland, 2012; Inoue, Tamori, & Motokawa, 2002).…”

Section: Introductionmentioning

confidence: 99%