REDOX Balance in Oligodendrocytes Is Important for Zebrafish Visual System Regeneration.

Zebrafish (Danio rerio) present continuous growth and regenerate many parts of their body after an injury. Fish oligodendrocytes, microglia and astrocytes support the formation of new connections producing effective regeneration of the central nervous system after a lesion. To understand the role of oligodendrocytes and the signals that mediate regeneration, we use the well-established optic nerve (ON) crush model. We also used sox10 fluorescent transgenic lines to label fully differentiated oligodendrocytes. To quench the effect of reactive oxygen species (ROS), we used the endogenous antioxidant melatonin. Using these tools, we measured ROS production by flow cytometry and explored the regeneration of the optic tectum (OT), the response of oligodendrocytes and their mitochondria by confocal microscopy and Western blot. ROS are produced by oligodendrocytes 3 h after injury and JNK activity is triggered. Concomitantly, there is a decrease in the number of fully differentiated oligodendrocytes in the OT and in their mitochondrial population. By 24 h, oligodendrocytes partially recover. Exposure to melatonin blocks the changes observed in these oligodendrocytes at 3 h and increases their number and their mitochondrial populations after 24 h. Melatonin also blocks JNK upregulation and induces aberrant neuronal differentiation in the OT. In conclusion, a proper balance of ROS is necessary during visual system regeneration and exposure to melatonin has a detrimental impact.

Oligodendrocyte origin and development in the zebrafish visual system.

Oligodendrocytes are the myelinating cells in the central nervous system. In birds and mammals, the oligodendrocyte progenitor cells (OPCs) originate in the preoptic area (POA) of the hypothalamus. However, it remains unclear in other vertebrates such as fish. Thus, we have studied the early progression of OPCs during zebrafish visual morphogenesis from 2 days post fertilization (dpf) until 11 dpf using the olig2:EGFP transgenic line; and we have analyzed the differential expression of transcription factors involved in oligodendrocyte differentiation: Sox2 (using immunohistochemistry) and Sox10 (using the transgenic line sox10:tagRFP). The first OPCs (olig2:EGFP/Sox2) were found at 2 dpf in the POA. From 3 dpf onwards, these olig2:EGFP/Sox2 cells migrate to the optic chiasm, where they invade the optic nerve (ON), extending toward the retina. At 5 dpf, olig2:EGFP/Sox2 cells in the ON also colocalize with sox10:tagRFP. When olig2:EGFP cells differentiate and present more projections, they become positive only for sox10:tagRFP. olig2:EGFP/sox10: tagRFP cells ensheath the ON by 5 dpf when they also become positive for a myelin marker, based on the mbpa:tagRFPt transgenic line. We also found olig2:EGFP cells in other regions of the visual system. In the central retina at 2 dpf, they are positive for Sox2 but later become restricted to the proliferative germinal zone without this marker. In the ventricular areas of the optic tectum, olig2:EGFP cells present Sox2 but arborized ones sox10:tagRFP instead. Our data matches with other models, where OPCs are specified in the POA and migrate to the ON through the optic chiasm.

Doublecortin in the Fish Visual System, a Specific Protein of Maturing Neurons.

Doublecortin (DCX) is a microtubule associated protein, essential for correct central nervous system development and lamination in the mammalian cortex. It has been demonstrated to be expressed in developing-but not in mature-neurons. The teleost visual system is an ideal model to study mechanisms of adult neurogenesis due to its continuous life-long growth. Here, we report immunohistochemical, in silico, and western blot analysis to detect the DCX protein in the visual system of teleost fish. We clearly determined the expression of DCX in newly generated cells in the retina of the cichlid fish Astatotilapia burtoni, but not in the cyprinid fish Danio rerio. Here, we show that DCX is not associated with migrating cells but could be related to axonal growth. This work brings to light the high conservation of DCX sequences between different evolutionary groups, which make it an ideal marker for maturing neurons in various species. The results from different techniques corroborate the absence of DCX expression in zebrafish. In A. burtoni, DCX is very useful for identifying new neurons in the transition zone of the retina. In addition, this marker can be applied to follow axons from maturing neurons through the neural fiber layer, optic nerve head, and optic nerve.

Cultures of glial cells from optic nerve of two adult teleost fish: Astatotilapia burtoni and Danio rerio.

BACKGROUND: In vitro studies are very useful to increase the knowledge of different cell types and could be the key to understand cell metabolism and function. Fish optic nerves (ON) can recover visual functions by reestablishing its structure and reconnecting the axons of ganglion cells. This is because fish show spontaneous regeneration of the central nervous system which does not occur in mammals. In addition, several studies have indicated that glial cells of ON have different properties in comparison to the glial cells from brain or retina. Consequently, providing an in vitro tool will be highly beneficial to increase the knowledge of these cells. NEW METHOD: We developed a cell culture protocol to isolate glial cells from ON of two teleost fish species, Danio rerio and Astatotilapia burtoni. RESULTS: The optimized protocol allowed us to obtain ON cells and brain-derived cells from adult teleost fish. These cells were characterized as glial cells and their proprieties in vitro were analyzed.Comparison with Existing Method(s): Although it is striking that ON glial cells show peculiarities, their study in vitro has been limited by the only published protocol going back to the 1990s. Our protocol makes glial cells of different fish species available for experiments and studies to increase the understanding of these glial cell types. CONCLUSIONS: This validated and effective in vitro tool increases the possibilities on studies of glial cells from fish ON which implies a reduction in animal experimentation.

Sox2 expression in the visual system of two teleost species.

The visual system of teleost fish shows growth and regeneration capacities during the entire animal's life. Thus, the visual system of adult fish serves as a model for studying neurogenesis in the vertebrate central nervous system (CNS). Our study focused on the expression pattern of Sox2 in the fish visual system. Sox2 is a transcription factor known for its function in keeping stem cell properties, and as a regulator of cell fate during development, especially in the visual system. We used two different fish species: Astatotilapia burtoni and Danio rerio. In the visual system of fish, we identified Sox2 positive cells in the stem cell niche in the peripheral retina, in Müller cells and amacrine cells in the differentiated retina, and glial cells in the optic nerve (ON). We did not observe hardly any Sox2 expression in the optic nerve head (ONH). In the ON, Sox2 positive glial cells were lining the fascicles of new axons. Taking together, the broad spectrum of Sox2 expression indicates that this protein has different functions in the CNS of adult vertebrates. The results suggest that Sox2 has functions associated with the pathway of new axons from the retina. To understand the variety of cell types and subtypes and their plasticity potential in the visual system of fish will be essential to comprehend the growing and regenerating CNS in adult vertebrates.

Expression and localization of the polarity protein CRB2 in adult mouse brain: a comparison with the CRB1rd8 mutant mouse model.

Acquisition of cell polarization is essential for the performance of crucial functions, like a successful secretion and appropriate cell signaling in many tissues, and it depends on the correct functioning of polarity proteins, including the Crumbs complex. The CRB proteins, CRB1, CRB2 and CRB3, identified in mammals, are expressed in epithelial-derived tissues like brain, kidney and retina. CRB2 has a ubiquitous expression and has been detected in embryonic brain tissue; but currently there is no data regarding its localization in the adult brain. In our study, we characterized the presence of CRB2 in adult mice brain, where it is particularly enriched in cortex, hippocampus, hypothalamus and cerebellum. Double immunofluorescence analysis confirmed that CRB2 is a neuron-specific protein, present in both soma and projections where colocalizes with certain populations of exocytic and endocytic vesicles and with other members of the Crumbs complex. Finally, in the cortex of CRB1rd8 mutant mice that contain a mutation in the Crb1 gene generating a truncated CRB1 protein, there is an abnormal increase in the expression levels of the CRB2 protein which suggests a possible compensatory mechanism for the malfunction of CRB1 in this mutant background.

Sox10 Expression in Goldfish Retina and Optic Nerve Head in Controls and after the Application of Two Different Lesion Paradigms.

The mammalian central nervous system (CNS) is unable to regenerate. In contrast, the CNS of fish, including the visual system, is able to regenerate after damage. Moreover, the fish visual system grows continuously throughout the life of the animal, and it is therefore an excellent model to analyze processes of myelination and re-myelination after an injury. Here we analyze Sox10+ oligodendrocytes in the goldfish retina and optic nerve in controls and after two kinds of injuries: cryolesion of the peripheral growing zone and crushing of the optic nerve. We also analyze changes in a major component of myelin, myelin basic protein (MBP), as a marker for myelinated axons. Our results show that Sox10+ oligodendrocytes are located in the retinal nerve fiber layer and along the whole length of the optic nerve. MBP was found to occupy a similar location, although its loose appearance in the retina differed from the highly organized MBP+ axon bundles in the optic nerve. After optic nerve crushing, the number of Sox10+ cells decreased in the crushed area and in the optic nerve head. Consistent with this, myelination was highly reduced in both areas. In contrast, after cryolesion we did not find changes in the Sox10+ population, although we did detect some MBP- degenerating areas. We show that these modifications in Sox10+ oligodendrocytes are consistent with their role in oligodendrocyte identity, maintenance and survival, and we propose the optic nerve head as an excellent area for research aimed at better understanding of de- and remyelination processes.

Optimization and in vivo toxicity evaluation of G4.5 PAMAM dendrimer-risperidone complexes.

Risperidone is an approved antipsychotic drug belonging to the chemical class of benzisoxazole. This drug has low solubility in aqueous medium and poor bioavailability due to extensive first-pass metabolism and high protein binding (>90%). Since new strategies to improve efficient treatments are needed, we studied the efficiency of anionic G4.5 PAMAM dendrimers as nanocarriers for this therapeutic drug. To this end, we explored dendrimer-risperidone complexation dependence on solvent concentration, pH and molar relationship. The best dendrimer-risperidone incorporation (46 risperidone molecules per dendrimer) was achieved with a mixture of chloroform:methanol 50∶50 v/v solution pH 3. In addition, to explore the possible effects of this complex, in vivo studies were carried out in the zebrafish model. Changes in the development of dopaminergic neurons and motoneurons were studied using tyrosine hydroxylase and calretinin, respectively. Physiological changes were studied through histological sections stained with hematoxylin-eosin to observe possible morphological brain changes. The most significant changes were observed when larvae were treated with free risperidone, and no changes were observed when larvae were treated with the complex.

Effects of retinoic acid exposure during zebrafish retinogenesis.

Retinoic acid (RA) is an important morphogen involved in retinal development. Perturbations in its levels cause retinal malformations such as microphthalmia. However, the cellular changes in the retina that lead to this phenotype are little known. We have used the zebrafish to analyse the effects of systemic high RA levels on retinogenesis. For this purpose we exposed zebrafish embryos to 0.1µM or 1µM RA from 24 to 48h post-fertilisation (hpf), the period which corresponds to the time of retinal neurogenesis and initial retinal cell differentiation. We did not find severe alterations in 0.1µM RA treated animals, but the exposure to 1µM RA significantly reduced retinal size upon treatment, and this microphthalmia persisted through larval development. We monitored histology and cell death and quantified both the proliferation rate and cell differentiation from 48hpf onwards, focusing on the retina and optic nerve of normal and 1µM treated animals. Retinal lamination and initial neurogenesis are not affected by RA exposure, but we found widespread apoptosis after RA treatment that could be the main cause of microphthalmia. Proliferating cells increased their number at 3days post-fertilisation (dpf) but decreased significantly at 5dpf maintaining the microphthalmic phenotype. Retinal cell differentiation was affected; some cell markers do not reach normal levels at larval stages and some cell types present an increased number compared to those of control animals. We also found the presence of young axons growing ectopically within the retina. Moreover although the optic axons leave the retina and form the optic chiasm they do not reach the optic tectum. The alterations observed in treated animals become more severe as larvae develop.

Characterization of Pax2 expression in the goldfish optic nerve head during retina regeneration.

The Pax2 transcription factor plays a crucial role in axon-guidance and astrocyte differentiation in the optic nerve head (ONH) during vertebrate visual system development. However, little is known about its function during regeneration. The fish visual system is in continuous growth and can regenerate. Müller cells and astrocytes of the retina and ONH play an important role in these processes. We demonstrate that pax2a in goldfish is highly conserved and at least two pax2a transcripts are expressed in the optic nerve. Moreover, we show two different astrocyte populations in goldfish: Pax2(+) astrocytes located in the ONH and S100(+) astrocytes distributed throughout the retina and the ONH. After peripheral growth zone (PGZ) cryolesion, both Pax2(+) and S100(+) astrocytes have different responses. At 7 days after injury the number of Pax2(+) cells is reduced and coincides with the absence of young axons. In contrast, there is an increase of S100(+) astrocytes in the retina surrounding the ONH and S100(+) processes in the ONH. At 15 days post injury, the PGZ starts to regenerate and the number of S100(+) astrocytes increases in this region. Moreover, the regenerating axons reach the ONH and the pax2a gene expression levels and the number of Pax2(+) cells increase. At the same time, S100(+)/GFAP(+)/GS(+) astrocytes located in the posterior ONH react strongly. In the course of the regeneration, Müller cell vitreal processes surrounding the ONH are primarily disorganized and later increase in number. During the whole regenerative process we detect a source of Pax2(+)/PCNA(+) astrocytes surrounding the posterior ONH. We demonstrate that pax2a expression and the Pax2(+) astrocyte population in the ONH are modified during the PGZ regeneration, suggesting that they could play an important role in this process.

Characterisation and differential expression during development of a duplicate Disabled-1 (Dab1) gene from zebrafish.

We identified a new duplicated Dab1 gene (drDab1b) spanning around 25kb of genomic DNA in zebrafish. Located in zebrafish chromosome 2, it is composed of 11 encoding exons and shows high sequence similarity to other Dab1 genes, including drDab1a, a zebrafish Dab1 gene previously characterised. drDab1b encodes by alternative splicing at least five different isoforms. Both drDab1a and drDab1b show differential gene expression levels in distinct adult tissues and during development. drDab1b is expressed in peripheral tissues (gills, heart, intestine, muscle), the immune system (blood, liver) and the central nervous system (CNS), whereas drDab1a is only expressed in gills, muscle and the CNS, suggesting a division of functions for two Dab1 genes in zebrafish adult tissues. RT-PCR analysis also reveals that both drDab1 genes show distinct developmental-specific expression patterns throughout development. drDab1b expression was higher than that of drDab1a, suggesting a major role of drDab1b in comparison with drDab1a during development and in different adult tissues. In addition, new putative Dab1 (a and/or b) from different teleost species were identified in silico and predicted protein products are compared with the previously characterised Dab1, demonstrating that the Dab1b group is more ancestral than their paralogue, the Dab1a group.

Prox1 expression in rod precursors and Müller cells.

The transcription factor Prox1 acts in rodent retinogenesis, at least in promoting cell cycle withdrawal and horizontal cell production. In the mature retina, this protein is detected at the inner nuclear layer of all vertebrate groups. We have made a neurochemical characterisation of Prox1(+) cell types in two different vertebrate groups: mammals and fish. As well as Prox1(+) horizontal cells, we have observed Prox1(+)/PKC-alpha(+) rod bipolar cells in mouse and cone ON and mixed b bipolar cells in goldfish. In mouse, only some CB(+) and CR(+) amacrine cells are Prox1(+) and the TH(+) and CR(+) amacrine cells are Prox1(-). However, in goldfish all CR(+) amacrine cells and TH(+) interplexiform cells are Prox1(+) and in the GCL displaced amacrine cells are also Prox1(+). Besides its expression in different interneuron subpopulations, we demonstrate, for the first time, the presence of Prox1 in the GS(+) and CRALBP(+) Müller cells in the retina of adult mammals and in developing and mature retina of fish. The presence of Prox1 in these cells appears to be related to survival or maintenance of their phenotype. We also demonstrate that in fish, where retinal formation persists into adulthood, Prox1 is expressed in dividing PCNA(+) cells at the peripheral growing zone, in rod progenitors at the inner and outer nuclear layers as well as in early progenitors during a retinal regeneration process after cryo-lesion of the peripheral growing zone. Therefore, Prox1 functions in vertebrate retinogenesis may be more complex than previously expected.

Developmental expression patterns of acetylcholinesterase and cholineacetyltransferase in zebrafish retina

During recent years a key role as morphogen has been postulated for the neurotransmitter acetylcholine in the developing Central Nervous System. Acetylcholine released from growing axons regulates growth, differentiation and plasticity. The acetylcholine distribution is frequently defined by acetylcholinesterase and choline acetyltransferase expression patterns. The cholinergic/cholinoceptive system in the adult zebrafish retina has been described. Nevertheless, there are no data regarding the developing retina. The acetylcholinesterase and choline acetyltransferase distribution patterns during zebrafish retinal development are very similar. In both cases the first positive elements appear in the plexiform layers and in later stages reactive amacrine cells have been observed in the ganglion cell layer and inner nuclear layer. In the adult retina a cholinergic and cholinoceptive neuropile band is observed in the inner plexiform layer. Displaced amacrine cells and amacrine cells positive to both markers have been observed. Transient expressions of choline acetyltransferase in the optic nerve and outer plexiform layer and of acetylcholinesterase in amacrine cells and displaced amacrine cells are observed during retinal development coinciding with the arrangement of the pioneering retinal projections into the optic tectum. The mature distribution pattern of the cholinergic/ cholinoceptive system in the adult retina is conserved along the phylogenetic scale, thus it seems to be a primary feature acquired relatively early during the evolution of vertebrates (AU)

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Pax2 in the optic nerve of the goldfish, a model of continuous growth.

Pax2 is a well known transcription factor which participates in optic nerve development. It assures the correct arrival and package of the newly formed retinal axons and the adequate differentiation of the newly formed glial cells. Pax2 protein expression is continuous throughout adult life in the goldfish optic nerve. We have found two populations of astrocytes in the optic nerve: Pax2(+) and Pax2(-). Moreover, we have observed that the Pax2(+) astrocytes from the optic nerve head present differences in number and organization to those of the rest of the optic nerve. In the optic nerve head some Pax2(+) astrocytes, principally localized in the glia limitans, have thin GFAP(+) processes and weak cytokeratin and ZO1 immunolabeling. Several Pax2(+) astrocytes are in close association with the GFAP(+)/GS(+) Müller cell vitreal processes and with the growing Zn8(+) retinal ganglion cell axons. However, in the intraorbital segment, Pax2(+) astrocytes are more numerous and they have strongly cytokeratin(+)/ZO1(+) processes and form part of the reticular astrocytes and the glia limitans. We also found Pax2(-) astrocytes in both the optic nerve head and the intraorbital segment. In the intraorbital segment there are GS(+)/Pax2(-) cells which are absent from the optic nerve head. We propose that the maintenance of Pax2 protein expression in adult goldfish optic nerve could be related to the continuous addition of new ganglion cell axons and new glial cells.

Development of the cholinergic system in the brain and retina of the zebrafish.

We have analyzed the distribution pattern of choline acetyltransferase (ChAT) in the zebrafish brain and retina during ontogeny. ChAT-immunoreactive (ChAT-ir) neurons are observed in the prosencephalon from 60 h postfertilization (hpf) onwards, exclusively in the preoptic area (basal plate of p6) derived from the secondary prosencephalon. In the mesencephalon, ChAT-ir cells are observed in both the optic tectum and the tegmentum. Stained cells in the tegmentum are observed from 60 hpf onwards, while in the optic tectum they appear after hatching. In the rhombencephalon, ChAT-ir cells are first observed in the isthmic region (rh1) and in the medulla oblongata (rh5-rh7) at the end of embryonic life. The rhombencephalic cholinergic cell groups develop in a gradual caudorostral sequence. Motoneurons of the spinal cord are ChAT-ir from 48 hpf onwards. The retina displays ChAT-ir neuropil in both the inner and outer plexiform layers from embryonic life, whereas stained amacrine cells are only observed after hatching. The staining in the outer plexiform layer gradually decreases during juvenile development. The optic nerve axons show a transient expression of ChAT at the end of embryonic development. The early presence of ChAT immunolabeling suggests an important neuromodulator role for acetylcholine in the first developmental stages.

Comparative analysis of the distribution of choline acetyltransferase in the central nervous system of cyprinids.

The general organization of the cholinergic system in the central nervous system is similar among vertebrates, though fish show higher variability. Thus, in zebrafish, cholinergic cells are absent from the habenula and the rhombencephalic reticular formation, where such neurons are present in most vertebrate species analyzed. In this work, we compared the distribution of choline acetyltransferase in the central nervous system of both zebrafish and tench, in order to investigate whether these divergences in the distribution of cholinergic cells in zebrafish are species-specific, or a feature shared by members of the cyprinid family. Our data show that these two cyprinid possess in common some peculiarities in their cholinergic system that are not present in the rest of fish analyzed (e.g. absence of cholinergic cells in the habenula and their presence in the descendent octaval nucleus). Nonetheless, some cholinergic cells were observed in the dorsal thalamus and rhombencephalic reticular nuclei of the tench, which were absent in the same regions in zebrafish. The comparative analysis suggests a divergent evolution of the cholinergic system among close-related cyprinid species.

Cholinergic elements in the zebrafish central nervous system: Histochemical and immunohistochemical analysis.

Recently, the zebrafish has been extensively used for studying the development of the central nervous system (CNS). However, the zebrafish CNS has been poorly analyzed in the adult. The cholinergic/cholinoceptive system of the zebrafish CNS was analyzed by using choline acetyltransferase (ChAT) immunohistochemistry and acetylcholinesterase (AChE) histochemistry in the brain, retina, and spinal cord. AChE labeling was more abundant and more widely distributed than ChAT immunoreactivity. In the telencephalon, ChAT-immunoreactive (ChAT-ir) cells were absent, whereas AChE-positive neurons were observed in both the olfactory bulb and the telencephalic hemispheres. The diencephalon was the region with the lowest density of AChE-positive cells, mainly located in the pretectum, whereas ChAT-ir cells were exclusively located in the preoptic region. ChAT-ir cells were restricted to the periventricular stratum of the optic tectum, but AChE-positive neurons were observed throughout the whole extension of the lamination except in the marginal stratum. Although ChAT immunoreactivity was restricted to the rostral tegmental, oculomotor, and trochlear nuclei within the mesencephalic tegmentum, a widespread distribution of AChE reactivity was observed in this region. The isthmic region showed abundant AChE-positive and ChAT-ir cells in the isthmic, secondary gustatory and superior reticular nucleus and in the nucleus lateralis valvulae. ChAT immunoreactivity was absent in the cerebellum, although AChE staining was observed in Purkinje and granule cells. The medulla oblongata showed a widespread distribution of AChE-positive cells in all main subdivisions, including the octavolateral area, reticular formation, and motor nuclei of the cranial nerves. ChAT-ir elements in this area were restricted to the descending octaval nucleus, the octaval efferent nucleus and the motor nuclei of the cranial nerves. Additionally, spinal cord motoneurons appeared positive to both markers. Substantial differences in the ChAT and AChE distribution between zebrafish and other fish species were observed, which could be important because zebrafish is widely used as a genetic or developmental animal model.

Enfermedades vectoriales: dengue clásico y hemorrágico, paludismo y paludismo grave / Vectorial diseases: dengue and malaria

El área Nº32 se encuentra en el Cantón Yaguachi con una superficie de 32.000 Km. al noreste de la provincia del Guayas, tiene un clíma húmedo.Los casos de morbilidad que se presentan afectan a toda la población especialmente a grupos vulnerables como son los niños menores de 5 años, mujeres y ancianos. Las condiciones que favorecen al incremento de las enfermedades están ligadas a varios factores como son la contaminación del medio ambiente, los cambios climáticos la deficiente infraestructura higiénico-sanitaria, los factores cultural, etc. La Emergencia Sanitaria que viven las provincias de las costa ante la amenaza de una epidemia de alto potencial epidemiológico como son los casos de dengue hemorrágico, paludismo los factores de riesgo que existen en este cantón como son los grandes