Papers by Maria Elena de Bellard
Marine Biodiversity
The Indo-Pacific is recognized as a hotspot for marine diversity. The taxonomy of certain taxa, s... more The Indo-Pacific is recognized as a hotspot for marine diversity. The taxonomy of certain taxa, such as Discomedusae jellyfish, has been neglected, despite its importance in the fishery industry. This study documents the first records of Discomedusae for the Java Sea using an integrative approach and provide notes about its distribution in the area. We used up to 53 morphological and meristic characters and amplified one mitochondrial marker (COI). The comparison and assessment of these data resulted in the recognition of seven species of Discomedusae, from which five has been recorded for the Indo-Pacific area. Two other species require a taxonomic revision to confirm the species assignation. The distribution of jellyfish in the coast of Java Sea might be correlated with the jellyfish life history and species-specific ranges of tolerance, and not solely determined by the environmental parameters. These findings provide the foundations for extending the taxonomic research in the are...
Frontiers in Cell and Developmental Biology, 2020
Neural crest cells (NCC) migrate extensively in vertebrate embryos to populate diverse derivative... more Neural crest cells (NCC) migrate extensively in vertebrate embryos to populate diverse derivatives including ganglia of the peripheral nervous system. Little is known about the molecular mechanisms that lead migrating trunk NCC to settle at selected sites in the embryo, ceasing their migration and initiating differentiation programs. To identify candidate genes involved in these processes, we profiled genes up-regulated in purified post-migratory compared with migratory NCC using a staged, macroarrayed cDNA library. A secondary screen of in situ hybridization revealed that many genes are specifically enhanced in neural crest-derived ganglia, including macrophage migration inhibitory factor (MIF), a ligand for CXCR4 receptor. Through in vivo and in vitro assays, we found that MIF functions as a potent chemoattractant for NCC. These results provide a molecular profile of genes expressed concomitant with gangliogenesis, thus, offering new markers and potential regulatory candidates involved in cessation of migration and onset of differentiation.
Developmental Dynamics, 2018
Background: Trunk neural crest cells migrate rapidly along characteristic pathways within the dev... more Background: Trunk neural crest cells migrate rapidly along characteristic pathways within the developing vertebrate embryo. Proper trunk neural crest cell migration is necessary for the morphogenesis of much of the peripheral nervous system, melanocytes, and the adrenal medulla. Numerous molecules help guide trunk neural crest cell migration throughout the early embryo. Results: The trophic factor NRG1 is a chemoattractant through in vitro chemotaxis assays and in vivo silencing via a DN-erbB receptor. Interestingly, we also observed changes in migratory responses consistent with a chemokinetic effect of NRG1 in trunk neural crest velocity. Conclusions: NRG1 is a trunk neural crest cell chemoattractant and chemokinetic molecule.
Gene expression patterns : GEP, Jun 1, 2018
Slits ligands and their Robo receptors are involved in quite disparate cell signaling pathways th... more Slits ligands and their Robo receptors are involved in quite disparate cell signaling pathways that include axon guidance, cell proliferation, cell motility and angiogenesis. Neural crest cells emerge by delamination from neural cells in the dorsal neural tube, and give rise to various components of the peripheral nervous system in vertebrates. It is well established that these cells change from a non-migratory to a highly migratory state allowing them to reach distant regions before they differentiate. However, but the mechanism controlling this delamination and subsequent migration are still not fully understood. The repulsive Slit ligand family members, have been classified also as true tumor suppressor molecules. The present study explored in further detail what possible Slit/Robo signals are at play in the trunk neural cells and neural crest cells by carrying out a microarray after Slit2 gain of function in trunk neural tubes. We found that in addition to molecules known to be ...
Brain Research, 2016
Myelin is probably one of the most fascinating and innovative biological acquisition: a glia plas... more Myelin is probably one of the most fascinating and innovative biological acquisition: a glia plasma membrane tightly wrapped around an axon and insulating it. Chondrichthyans (cartilaginous fishes) form a large group of vertebrates, and they are among oldest extant jawed vertebrate lineage. It has been known from studies 150 years ago, that they are positioned at the root of the successful appearance of compact myelin and main adhesive proteins in vertebrates. More importantly, the ultrastructure of their compact myelin is indistinguishable from the one observed in tetrapods and the first true myelin basic protein (MBP) and myelin protein zero (MPZ) seem to have originated on cartilaginous fish or their ancestors, the placoderms. Thus, the study of their myelin formation would bring new insights in vertebrate's myelin evolution. Chondrichthyans central nervous system (CNS) myelin composition is also very similar to peripheral nervous system (PNS) myelin composition. And while they lack true proteolipid protein (PLP) like tetrapods, they express a DM-like protein in their myelin.
Acta histochemica, Jan 21, 2015
The development of the nervous system involves cells remaining within the neural tube (CNS) and a... more The development of the nervous system involves cells remaining within the neural tube (CNS) and a group of cells that delaminate from the dorsal neural tube and migrate extensively throughout the developing embryo called neural crest cells (NCC). These cells are a mesenchymal highly migratory group of cells that give rise to a wide variety of cell derivatives: melanocytes, sensory neurons, bone, Schwann cells, etc. But not all NCC can give rise to all derivatives, they have fate restrictions based on their axial level of origin: cranial, vagal, trunk and sacral. Our aim was to provide a thorough presentation on how does trunk neural crest cell migration looks in the chicken embryo, in wholemount and in sections using the unique chicken marker HNK1. The description presented here makes a good guideline for those interested in viewing trunk NCC migration patterns. We show how before HH14 there are few trunk NCC delaminating and migrating, but between HH15 through HH19 trunk NCC delami...
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[Venezuelan equine encephalitis. Review]
Investigación clínica, 1989
The Venezuelan equine encephalomyelitis (VEE) is one the most serious viral infections of the ner... more The Venezuelan equine encephalomyelitis (VEE) is one the most serious viral infections of the nervous system. It has a wide geographic distribution and may give rise to sequela like mental retardation, amnesia, abortion, epilepsy and hidroanencephaly in infected humans and animals. The pathology of this infection is focused mainly in two tissues: lymphohematopoietic and nervous. The VEE virus has a special cytopathic activity on the nervous cells (glia and neurons) while the lesions produced in the myelin are probably a consequence of the immunological response of the host to the infection. The alterations produced by the VEE virus in different neuronal types can originate changes in the brain concentrations of several neurotransmitters and their receptors. Some biochemical modifications that have also been reported could be due to the cytopathic effect of the virus.
Journal of Visualized Experiments, 2012
Neural crest cells (NCCs) are a transient population of cells present in vertebrate development t... more Neural crest cells (NCCs) are a transient population of cells present in vertebrate development that emigrate from the dorsal neural tube (NT) after undergoing an epithelial-mesenchymal transition 1,2. Following EMT, NCCs migrate large distances along stereotypic pathways until they reach their targets. NCCs differentiate into a vast array of cell types including neurons, glia, melanocytes, and chromaffin cells 1-3. The ability of NCCs to reach and recognize their proper target locations is foundational for the appropriate formation of all structures containing trunk NCC-derived components 3. Elucidating the mechanisms of guidance for trunk NCC migration has therefore been a matter of great significance. Numerous molecules have been demonstrated to guide NCC migration 4. For instance, trunk NCCs are known to be repelled by negative guidance cues such as Semaphorin, Ephrin, and Slit ligands 5-8. However, not until recently have any chemoattractants of trunk NCCs been identified 9. Conventional in vitro approaches to studying the chemotactic behavior of adherent cells work best with immortalized, homogenously distributed cells, but are more challenging to apply to certain primary stem cell cultures that initially lack a homogenous distribution and rapidly differentiate (such as NCCs). One approach to homogenize the distribution of trunk NCCs for chemotaxis studies is to isolate trunk NCCs from primary NT explant cultures, then lift and replate them to be almost 100% confluent. However, this plating approach requires substantial amounts of time and effort to explant enough cells, is harsh, and distributes trunk NCCs in a dissimilar manner to that found in in vivo conditions. Here, we report an in vitro approach that is able to evaluate chemotaxis and other migratory responses of trunk NCCs without requiring a homogenous cell distribution. This technique utilizes time-lapse imaging of primary, unperturbed trunk NCCs inside a modified Zigmond chamber (a standard Zigmond chamber is described elsewhere 10). By exposing trunk NCCs at the periphery of the culture to a chemotactant gradient that is perpendicular to their predicted natural directionality, alterations in migratory polarity induced by the applied chemotactant gradient can be detected. This technique is inexpensive, requires the culturing of only two NT explants per replicate treatment, avoids harsh cell lifting (such as trypsinization), leaves trunk NCCs in a more similar distribution to in vivo conditions, cuts down the amount of time between explantation and experimentation (which likely reduces the risk of differentiation), and allows time-lapse evaluation of numerous migratory characteristics.
Neural Crest Migration Methods in the Chicken Embryo
Cell Migration
Neural crest cells emerge from the neural tube early in development. They migrate extensively thr... more Neural crest cells emerge from the neural tube early in development. They migrate extensively throughout the embryo and form most of the head and peripheral nervous system, giving rise to sensory and sympathetic ganglia, heart regions, adrenal cells, head bones, teeth, muscle cells, sensory organs, melanocytes, and other cell types. The neural crest is interesting because of its unique origin, development and differentiation. These cells are initially part of the dorsal neural tube, with a clear epithelial character; later, they transform into actively motile mesenchymal cells. Little is known about the underlying mechanism directing this process. It remains unknown why neural crest cells target particular derivatives (neurons, heart muscle and glia) and body regions (peripheral nerves, heart, skin, head and gut). Neural crest migration can be divided into three stages: 1) emigration from the neural tube; 2) migration along defined pathways; and 3) cessation of migration. At the onset of migration, neural crest cells lose their epithelial nature within the neural tube and transform into a migratory, mesenchymal cell type. Neural crest development has been best studied in avian embryos, which are amenable to surgical manipulation, cell marking techniques, cell culture and transgenesis by electroporation and retrovirally mediate gene transfer. The methods outlined below are those typically used to study and understand the different factors and signals necessary for the neural crest development before and during their migration.
Neuron, 1999
allows extensive regrowth of neurons on myelin in vitro or after injury in vivo (Caroni and Schwa... more allows extensive regrowth of neurons on myelin in vitro or after injury in vivo (Caroni and Schwab, 1988; Schnell and Schwab, 1990). In addition, we (Mukhopadhyay et al., 1994) and others (McKerracher et al., 1994) have shown myelin-associated glycoprotein (MAG), a well
International Journal of Developmental Neuroscience, 2015
Neural crest cells emerge from the dorsal neural tube early in development and give rise to senso... more Neural crest cells emerge from the dorsal neural tube early in development and give rise to sensory and sympathetic ganglia, adrenal cells, teeth, melanocytes and especially enteric nervous system. Several inhibitory molecules have been shown to play important roles in neural crest migration, among them are the chemorepulsive Slit1-3. It was known that Slits chemorepellants are expressed at the entry to the gut, and thus could play a role in the differential ability of vagal but not trunk neural crest cells to invade the gut and form enteric ganglia. Especially since trunk neural crest cells express Robo receptor while vagal do not. Thus, although we know that Robo mediates migration along the dorsal pathway in neural crest cells, we do not know if it is responsible in preventing their entry into the gut. The goal of this study was to further corroborate a role for Slit molecules in keeping trunk neural crest cells away from the gut. We observed that when we silenced Robo receptor in trunk neural crest, the sympathoadrenal (somites 18-24) were capable of invading gut mesenchyme in larger proportion than more rostral counterparts. The more rostral trunk neural crest tended not to migrate beyond the ventral aorta, suggesting that there are other repulsive molecules keeping them away from the gut. Interestingly, we also found that when we silenced Robo in sacral neural crest they did not wait for the arrival of vagal crest but entered the gut and migrated rostrally, suggesting that Slit molecules are the ones responsible for keeping them waiting at the hindgut mesenchyme. These combined results confirm that Slit molecules are responsible for keeping the timeliness of colonization of the gut by neural crest cells.
Journal of Cell Biology, 2003
Neural crest precursors to the autonomic nervous system form different derivatives depending upon... more Neural crest precursors to the autonomic nervous system form different derivatives depending upon their axial level of origin; for example, vagal, but not trunk, neural crest cells form the enteric ganglia of the gut. Here, we show that Slit2 is expressed at the entrance of the gut, which is selectively invaded by vagal, but not trunk, neural crest. Accordingly, only trunk neural crest cells express Robo receptors. In vivo and in vitro experiments demonstrate that trunk, not vagal, crest cells avoid cells or cell membranes expressing Slit2, thereby contributing to the differential ability of neural crest populations to invade and innervate the gut. Conversely, exposure to soluble Slit2 significantly increases the distance traversed by trunk neural crest cells. These results suggest that Slit2 can act bifunctionally, both repulsing and stimulating the motility of trunk neural crest cells.
Neuron Glia Biology, 2007
Both neurons and glia of the PNS are derived from the neural crest. In this study, we have examin... more Both neurons and glia of the PNS are derived from the neural crest. In this study, we have examined the potential function of lunatic fringe in neural tube and trunk neural crest development by gain-of-function analysis during early stages of nervous system formation. Normally lunatic fringe is expressed in three broad bands within the neural tube, and is most prominent in the dorsal neural tube containing neural crest precursors. Using retrovirally-mediated gene transfer, we find that excess lunatic fringe in the neural tube increases the numbers of neural crest cells in the migratory stream via an apparent increase in cell proliferation. In addition, lunatic fringe augments the numbers of neurons and upregulates Delta-1 expression. The results indicate that, by modulating Notch/Delta signaling, lunatic fringe not only increases cell division of neural crest precursors, but also increases the numbers of neurons in the trunk neural crest.
Neurochemical Research, 2014
The authors would like to publish this erratum to add accuracy and better explanation to the orig... more The authors would like to publish this erratum to add accuracy and better explanation to the original published article. Several changes for more accuracy are provided by the authors who also apologize that they did not see these inaccuracies earlier before publication.
Neurochemical Research, 2010
The Schwann cells are the myelinating glia of the peripheral nervous system that originated durin... more The Schwann cells are the myelinating glia of the peripheral nervous system that originated during development from the highly motile neural crest. However, we do not know what the guidance signals for the Schwann cell precursors are. Therefore, we set to test some of the known
Molecular and Cellular Neuroscience, 1996
Myelin-associated glycoprotein (MAG) is a potent inhibitor growing them in culture (Bixby and Har... more Myelin-associated glycoprotein (MAG) is a potent inhibitor growing them in culture (Bixby and Harris, 1991; Dohof axonal regeneration from both cerebellar neurons and erty and Walsh, 1989), many types of CNS neurons can adult dorsal root ganglion (DRG) neurons. In contrast, extend long axons. Consequently, the lack of regenera-MAG promotes axonal growth from newborn DRG neution in vivo is now believed to be due, at least in part, to rons. Here, we show that the switch in response to MAG the presence of molecules in the pathway of the regenerfrom promotion to inhibition of neurite outgrowth by DRG ating axon that inhibit regrowth (Johnson, 1993; Schwab neurons occurs sharply at Postnatal Day 3. To date, of all et al., 1993; Keynes and Cook, 1995). In the adult mammathe neurons tested a postnatal switch in response is only lian CNS a number of inhibitory molecules have recently observed for DRG neurons; MAG inhibits axonal growth
Molecular and Cellular Neuroscience, 1997
Myelin-associated glycoprotein (MAG) is a potent inhibitor of axonal regeneration when used as a ... more Myelin-associated glycoprotein (MAG) is a potent inhibitor of axonal regeneration when used as a substrate for growth. However, to be characterized definitively as inhibitory rather than nonpermissive, MAG must also inhibit axonal regeneration when presented in solution. Here, we show that soluble dMAG (extracellular domain only), released in abundance from myelin and found in vivo and chimeric MAG-Fc, can potently inhibit axonal regeneration. For both dMAG and MAG-Fc, inhibition is dosedependent. If myelin-conditioned medium is immunodepleted of dMAG, or if a MAG antibody is included with MAG-Fc, inhibition is completely neutralized. Together with MAG's ability to induce growth cone collapse, these results demonstrate that MAG is an inhibitory molecule and not merely nonpermissive. The results also suggest that MAG binds to a specific receptor and initiates a signal transduction cascade to effect inhibition. Importantly, these results indicate that soluble dMAG detected in vivo could contribute to the lack of regeneration in the mammalian CNS after injury.
Molecular and Cellular Neuroscience, 1998
The mammalian CNS does not regenerate after injury due largely to myelin-specific inhibitors of a... more The mammalian CNS does not regenerate after injury due largely to myelin-specific inhibitors of axonal growth. The PNS, however, does regenerate once myelin is cleared and myelin proteins are down-regulated by Schwann cells. Myelin-associated glycoprotein (MAG), a sialic acid binding protein, is a potent inhibitor of neurite outgrowth when presented to neurons in culture. Here, we present additional evidence that strongly supports the suggestion that MAG contributes to the overall inhibitory properties of myelin. When myelin from MAG؊/؊ mice is used as a substrate, axonal length is 100 and 60% longer for neonatal cerebellar and older DRG neurons, respectively, compared to MAG؉/؉ myelin. The converse is true for neurites from neonatal DRG neurons, which are twice as long on MAG؉/؉ relative to MAG؊/؊ myelin, consistent with MAG's dual role of promoting axonal growth from neonatal DRG neurons but inhibiting growth in older DRG and all other postnatal neurons examined. Furthermore, desialylating neurons reverses inhibition by CNS myelin by 45%. Contrary to previous reports, under these conditions PNS myelin is also inhibitory for axonal regeneration. Importantly, results using PNS MAG؊/؊ myelin as a substrate suggest that MAG contributes to this inhibition. Finally, when Schwann cells not expressing MAG and permissive for axonal growth are induced to express MAG by retroviral infection, not only is axonal outgrowth greatly inhibited by these cells but so also is neurite branching. This suggests for the first time that MAG not only affects axonal regeneration but may also play a role in the control of axonal sprouting.
Microscopy Research and Technique, 2009
The capacity to image a growing embryo while simultaneously studying the developmental function o... more The capacity to image a growing embryo while simultaneously studying the developmental function of specific molecules provides invaluable information on embryogenesis. However, until recently, this approach was accomplished with difficulty both because of the advanced technology needed and because an easy method of minimizing damage to the embryo was unavailable. Here we present a novel way of adapting the well-known EC culture of whole chick embryos to time-lapse imaging and to functional molecular studies using blocking agents. The novelty of our method stems from the ability to apply blocking agents ex ovo as well as in ovo. We were able to study the function of a set of molecules by culturing developing embryos ex ovo in tissue culture media containing these molecules or by injecting them underneath the live embryo in ovo. The in ovo preparation is particularly valuable since it extends the period of time during which the developmental function of the molecule can be studied and it provides an easy, reproducible method for screening a batch of molecules. These new techniques will prove very helpful in visualizing and understanding the role of specific molecules during embryonic morphogenesis, including blood vessel formation.
Myelin‐associated glycoprotein, MAG, selectively binds several neuronal proteins
Journal of Neuroscience Research, 1999
Myelin-associated glycoprotein (MAG) is a potent inhibitor of axonal regeneration and also, depen... more Myelin-associated glycoprotein (MAG) is a potent inhibitor of axonal regeneration and also, depending on the age and type of neuron, can promote axonal growth. In addition, MAG influences stability of both myelin and the axon in the intact, mature nervous system. The identity of the neuron/axonal MAG-binding receptor responsible for effecting these responses is not known. Here we show that a soluble, chimeric form of MAG, MAG-Fc, can bind to the neuronal cell body and neurites equally well, in a sialic acid-dependent manner. Importantly, MAG-Fc specifically precipitates a number of surface proteins from post-natal cerebellar, dorsal root ganglion (DRG) and PC12 neurons. These proteins are not precipitated by a control Fc-containing chimera and are not apparent when a MAG antibody is included in the precipitation mix as a competitive inhibitor. Based on molecular weight, two prominent proteins of 190 and 250 kD are precipitated from all three neuron types. The 190 kD protein is a sialoglycoprotein, since it is not apparent in the precipitate from neurons which have been desialylated. Other proteins are precipitated but are less abundant and are different for each type of neuron. One or more of these proteins is/are likely to be the functional MAG receptor.
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Papers by Maria Elena de Bellard