Nasal embryonic LHRH factor plays a role in the developmental migration and projection of gonadotropin‐releasing hormone 3 neurons in zebrafish

The initiation of puberty and the functioning of the reproductive system depend on proper development of the hypophysiotropic gonadotropin‐releasing hormone (GnRH) system. One critical step in this process is the embryonic migration of GnRH neurons from the olfactory area to the hypothalamus. Using a transgenic zebrafish model, Tg(gnrh3:EGFP), in which GnRH3 neurons and axons are fluorescently labeled, we investigated whether zebrafish NELF is essential for the development of GnRH3 neurons. The zebrafish nelf cDNA was cloned and characterized. During embryonic development, nelf is expressed in GnRH3 neurons and in target sites of GnRH3 projections and perikarya, before the initiation of their migration. Nelf knockdown resulted in a disruption of the GnRH3 system which included absence or misguiding of GnRH3 axonal outgrowth and incorrect or arrested migration of GnRH3 perikarya. These results suggest that Nelf is an important factor in the developmental migration and projection of GnRH3 neurons in zebrafish. Developmental Dynamics 238:66–75, 2009. © 2008 Wiley‐Liss, Inc.     

ENU‐3 functions in an UNC‐6/netrin dependent pathway parallel to UNC‐40/DCC/frazzled for outgrowth and guidance of the touch receptor neurons in C. elegans

Results: An enu‐3 mutation enhances defects in ventral guidance of the processes of the AVM and PVM touch receptor neurons, the dorsal guidance of the distal tip cell and causes additional architectural defects in axons in unc‐40 mutant strains in an UNC‐6 dependent manner. These observations suggest that ENU‐3 and UNC‐40 function in parallel pathways dependent on UNC‐6. ENU‐3 depends on the presence of UNC‐40 for its full effect on motor neuron axon outgrowth. 相似文献   

Specification of sensory neurons occurs through diverse developmental programs functioning in the brain and spinal cord

Background : Vertebrates possess two populations of sensory neurons located within the central nervous system: Rohon‐Beard (RB) and mesencephalic trigeminal nucleus (MTN) neurons. RB neurons are transient spinal cord neurons whilst MTN neurons are the proprioceptive cells that innervate the jaw muscles. It has been suggested that MTN and RB neurons share similarities and may have a common developmental program, but it is unclear how similar or different their development is. Results : We have dissected RB and MTN neuronal specification in zebrafish. We find that RB and MTN neurons express a core set of genes indicative of sensory neurons, but find these are also expressed by adjacent diencephalic neurons. Unlike RB neurons, our evidence argues against a role for the neural crest during MTN development. We additionally find that neurogenin1 function is dispensable for MTN differentiation, unlike RB cells and all other sensory neurons. Finally, we demonstrate that, although Notch signalling is involved in RB development, it is not involved in the generation of MTN cells. Conclusions : Our work reveals fundamental differences between the development of MTN and RB neurons and suggests that these populations are non‐homologous and thus have distinct developmental and, probably, evolutionary origins. Developmental Dynamics 243:1429–1439, 2014. © 2014 Wiley Periodicals, Inc.     

Effects of Reg‐2 on Survival of Spinal Cord Neurons In Vitro

Regeneration gene protein 2 (Reg‐2) is a small secreted protein expressed in motor and sensory neurons of spinal cord during developmental stages and following injury of peripheral nerves. Reg‐2 appears to act as a neurotrophic factor and protects injured neurons from death during regeneration. To illustrate these potential protective effects in vitro, we investigated the blocking effects of Reg‐2 antibodies on the survival of primary cultured spinal cord neurons and astrocytes, as well as on neurite outgrowth. In addition, the effects of Reg‐2 in neuron injury models induced by peroxide and mitochondrial poisoning were assessed. Our results showed that Reg‐2 antibody markedly reduced survival and neurite outgrowth from neurons, whereas astrocyte survival was unaffected. Addition of Reg‐2 into the culture medium had no effect on neuron survival or neurite outgrowth. However, the addition of the Reg‐2 into culture media after peroxide treatment or cellular hypoxia insult induced by mitochondrial poisoning can reduce lactate dehydrogenase release levels and cell death. Thus, the data suggests that Reg‐2 is essential for the survival and neurite outgrowth of developing spinal cord neurons but not the survival of glial cells, and that Reg‐2 plays protective effects on spinal cord neurons against injury in vitro. Anat Rec, 2010. © 2010 Wiley‐Liss, Inc.     

CNS myelination requires cytoplasmic dynein function

Background: Cytoplasmic dynein provides the main motor force for minus‐end‐directed transport of cargo on microtubules. Within the vertebrate central nervous system (CNS), proliferation, neuronal migration, and retrograde axon transport are among the cellular functions known to require dynein. Accordingly, mutations of DYNC1H1, which encodes the heavy chain subunit of cytoplasmic dynein, have been linked to developmental brain malformations and axonal pathologies. Oligodendrocytes, the myelinating glial cell type of the CNS, migrate from their origins to their target axons and subsequently extend multiple long processes that ensheath axons with specialized insulating membrane. These processes are filled with microtubules, which facilitate molecular transport of myelin components. However, whether oligodendrocytes require cytoplasmic dynein to ensheath axons with myelin is not known. Results: We identified a mutation of zebrafish dync1h1 in a forward genetic screen that caused a deficit of oligodendrocytes. Using in vivo imaging and gene expression analyses, we additionally found evidence that dync1h1 promotes axon ensheathment and myelin gene expression. Conclusions: In addition to its well known roles in axon transport and neuronal migration, cytoplasmic dynein contributes to neural development by promoting myelination. Developmental Dynamics 244:134–145, 2015. © 2014 Wiley Periodicals, Inc.     

Zebrafish bashful/laminin-alpha 1 mutants exhibit multiple axon guidance defects.

Laminin is known to provide a highly permissive substratum and in some cases directional information for axon outgrowth in vitro. However, there is still little known about laminin function in guiding axons in vivo. We investigated the axon guidance role of laminin-alpha1 in the developing zebrafish nervous system. Analysis of zebrafish bashful (bal)/laminin-a1 mutants revealed multiple functions for laminin-alpha1 in the outgrowth and guidance of central nervous system (CNS) axons. Most CNS axon pathways are defective in bal embryos. Some axon types, including retinal ganglion cell axons, early forebrain axons, and hindbrain reticulospinal axons, make specific pathfinding errors, suggesting laminin-alpha1 is required for directional decisions. Other axon tracts are defasciculated or not fully extended in bal embryos, suggesting a function for laminin-alpha1 in regulating adhesion or providing a permissive substratum for growth. In addition, some neurons have excessively branched axons in bal, indicating a potential role for laminin-alpha1 in branching. In contrast to CNS axons, most peripheral axons appear normal in bal mutants. Our results, thus, reveal important and diverse functions for laminin-alpha1 in guiding developing axons in vivo.     

Zebrafish wnt3 is expressed in developing neural tissue

Wnt signaling regulates embryonic patterning and controls stem cell homeostasis, while aberrant Wnt activity is associated with disease. One Wnt family member, Wnt3, is required in mouse for specification of mesoderm, and later regulates neural patterning, apical ectodermal ridge formation, and hair growth. We have identified and performed preliminary characterization of the zebrafish wnt3 gene. wnt3 is expressed in the developing tailbud and neural tissue including the zona limitans intrathalamica (ZLI), optic tectum, midbrain‐hindbrain boundary, and dorsal hindbrain and spinal cord. Expression in these regions suggests that Wnt3 participates in processes such as forebrain compartmentalization and regulation of tectal wiring topography by retinal ganglia axons. Surprisingly, wnt3 expression is not detectable during mesoderm specification, making it unlikely that Wnt3 regulates this process in zebrafish. This lack of early expression should make it possible to study later Wnt3‐regulated patterning events, such as neural patterning, by knockdown studies in zebrafish. Developmental Dynamics 238:1768–1795, 2009. © 2009 Wiley‐Liss, Inc.     

Distinct roles for Sema3A, Sema3F, and an unidentified trophic factor in controlling the advance of geniculate axons to gustatory lingual epithelium

Geniculate ganglion axons arrive in the lingual mesenchyme on embryonic day 13 (E13), 3–4 days before penetrating fungiform papilla epithelium (E17). This latency may result from chemorepulsion by epithelial Sema3A (Dillon et al. (2004) Journal of Comparative Neurology 470, 13–24), or Sema3F, which we report is also expressed in this epithelium. Sema3A and Sema3F repelled or suppressed geniculate neurite outgrowth, respectively, and these effects were stage and neurotrophic factor dependent. BDNF-stimulated outgrowth is repelled by Sema3A until E17, but insensitive to Sema3F from E16. NT-4-stimulated neurite outgrowth is sensitive to Sema3A and Sema3F through E18, but NT-4 has not been detected in E15–18 tongue. E15–18 tongue explants did not exhibit net chemorepulsion of geniculate neurites, but the ability of tongue explants to support geniculate neurite outgrowth fluctuates: E12–13 (Rochlin et al. (2000), Journal of Comparative Neurology, 422, 579–593) and E17–18 explants promote and may attract geniculate neurites, but stages corresponding to intralingual arborization do not. The E18 trophic and tropic effects were evident even in the presence of BDNF or NT-4, suggesting that some other factor is responsible. Intrinsic neurite outgrowth capability (without exogenous neurotrophic factors) fluctuated similarly: ganglia deteriorated at E15, but exhibited moderate outgrowth at E18. The chemorepulsion studies are consistent with a role for Sema3A, not Sema3F, in restricting geniculate axons from the epithelium until E17, when axons penetrate the epithelium. The transient inability of tongue explants to promote geniculate neurite outgrowth may signify an alternative mechanism for restricting geniculate axons from the epithelium: limiting trophic factor access. This work was supported by a research grant from the NIDCD, 1 R03 DC04965-01 to MWR.     

Spatial gradients of chemotropic factors from immobilized patterns to guide axonal growth and regeneration

In this study, we investigated the effect of varying localized concentration gradients of NGF and Sema3A on the axonal outgrowth of embryonic chick DRG explants and primary neurons in vitro. Immobilized 2D NGF or Sema3A micropatterns were produced using photolithography on tissue culture cover slips. Two distinct regions were identified: slow, with little or no change in concentration of chemotropic factor; and steep, with a transition from low to high. The direction of axonal outgrowth was defined as proximal or distal, with proximal growing towards the higher concentration of immobilized NGF/Sema3A and vice versa for distal. Axons grew preferentially in the proximal direction when explants were seeded onto steep NGF, and distally in response to steep Sema3A. On slow NGF, or on slow Sema3A there was no difference in the directional specificity of axonal outgrowth. DRG primary neurons seeded onto steep NGF migrated proximally, whereas neurons seeded onto slow NGF migrated in all directions. Conversely, neurons seeded onto steep or slow Sema3A did not extend any axons. Our 2D immobilized micropatterns of chemotropic factors show promise for further development of in vitro nerve tissue engineering studies.     

Mammalian Nkx2.2+ perineurial glia are essential for motor nerve development

Results: In conjunction with RNA expression analysis and antibody labeling, we observed Nkx2.2⁺ cells along peripheral motor nerves at all stages of development and in adult tissue. Additionally, in mice lacking Nkx2.2, we demonstrate that Nkx2.2⁺ perineurial glia are essential for motor nerve development and Schwann cell differentiation. 相似文献   

Pard3 regulates contact between neural crest cells and the timing of Schwann cell differentiation but is not essential for neural crest migration or myelination

Background : Schwann cells, which arise from the neural crest, are the myelinating glia of the peripheral nervous system. During development neural crest and their Schwann cell derivatives engage in a sequence of events that comprise delamination from the neuroepithelium, directed migration, axon ensheathment, and myelin membrane synthesis. At each step neural crest and Schwann cells are polarized, suggesting important roles for molecules that create cellular asymmetries. In this work we investigated the possibility that one polarity protein, Pard3, contributes to the polarized features of neural crest and Schwann cells that are associated with directed migration and myelination. Results : We analyzed mutant zebrafish embryos deficient for maternal and zygotic pard3 function. Time‐lapse imaging revealed that neural crest delamination was normal but that migrating cells were disorganized with substantial amounts of overlapping membrane. Nevertheless, neural crest cells migrated to appropriate peripheral targets. Schwann cells wrapped motor axons and, although myelin gene expression was delayed, myelination proceeded to completion. Conclusions : Pard3 mediates contact inhibition between neural crest cells and promotes timely myelin gene expression but is not essential for neural crest migration or myelination. Developmental Dynamics 243:1511–1523, 2014. © 2014 Wiley Periodicals, Inc.     

Slitrk gene duplication and expression in the developing zebrafish nervous system

Results : As a prelude to examining the functional roles of Slitrks, we identified eight slitrk orthologs in zebrafish and observed that seven of the eight orthologs were actively transcribed in the nervous system at embryonic, larval, and adult stages. Similar to previous findings in mice and humans, zebrafish slitrks exhibited unique but overlapping spatial and temporal expression patterns in the developing brain, retina, and spinal cord. 相似文献   

Cranial sensory ganglia neurons require intrinsic N-cadherin function for guidance of afferent fibers to their final targets

Cell adhesion molecules, such as N-cadherin (cdh2), are essential for normal neuronal development, and as such have been implicated in an array of processes including neuronal differentiation and migration, and axon growth and fasciculation. cdh2 is expressed in neurons of the peripheral nervous system during development, but its role in these cells during this time is poorly understood. Using the transgenic zebrafish line, tg(p2xr3.2:eGFP^sl1), we have examined the involvement of cdh2 in the formation of sensory circuits by the peripheral nervous system. The tg(p2xr3.2:eGFP^sl1) fish allows visualization of neurons comprising the trigeminal, facial, glossopharyngeal and vagal ganglia and their axons throughout development. Reduction of cdh2 in this line was achieved by either crosses to the cdh2-mutant strain, glass onion (glo) or injection of a cdh2 morpholino (MO) into single-cell embryos. Here we show that cdh2 function is required to alter the directional vectors of growing axons upon reaching intermediate targets. The central axons enter the hindbrain appropriately but fail to turn caudally towards their final targets. Similarly, the peripheral axons extend ventrally, but fail to turn and project along a rostral/caudal axis. Furthermore, by expressing dominant negative cdh2 constructs selectively within cranial sensory ganglia (CSG) neurons, we found that cdh2 function is necessary within the axons to elicit these stereotypic turns, thus demonstrating that cdh2 acts cell autonomously. Together, our in vivo data reveal a novel role for cdh2 in the establishment of circuits by peripheral sensory neurons.     

Identification and expression patterns of members of the protease‐activated receptor (par) gene family during zebrafish development

Protease‐activated receptors (PARs) play critical roles in hemostasis in vertebrates including zebrafish. However, the zebrafish gene classification appears to be complex, and the expression patterns of par genes are not established. Based on analyses of genomic organization, phylogenetics, protein primary structure, and protein internalization, we report the identification of four zebrafish PARs: par1, par2a, par2b, and par3. This classification differs from one reported previously. We also show that these genes have distinct spatiotemporal expression profiles in embryos and larvae, with par1, par2a, and par2b expressed maternally and ubiquitously during gastrula stages and their expression patterns refined at later stages, and par3 expressed only in 3‐day‐old larvae. Notably, the expression patterns of zebrafish par1 and par2b resemble those of their mammalian counterparts, suggesting that receptor function is conserved among vertebrates. This conservation is supported by our findings that Par1 and Par2b are internalized following exposure to thrombin and trypsin, respectively. Developmental Dynamics, 2011. © 2010 Wiley‐Liss, Inc.     

Allergen challenge of peripheral blood mononuclear cells from patients with seasonal allergic rhinitis increases IL‐17RB,which regulates basophil apoptosis and degranulation

Background Previously, expression profiling has been used to analyse allergen‐challenged T‐helper type 2 cells, nasal biopsies and nasal fluid cells from patients with seasonal allergic rhinitis (SAR). Allergen‐challenged peripheral blood mononuclear cells (PBMCs) provide a human in vitro model of how antigen‐presenting cells, CD4⁺ T cells and effector cells such as basophils interact in allergic inflammation. Objective To identify novel genes and pathways in allergen‐challenged PBMCs from patients with SAR using gene expression profiling and functional studies. Methods PBMCs from 11 patients with SAR and 23 healthy controls were analysed with gene expression profiling. mRNA expression of IL17RB in basophils was evaluated using quantitative real‐time PCR. Membrane protein expression and apoptosis of basophils were examined by flow cytometry. Degranulation of basophils was assessed by measuring β‐hexosaminidase release. Cytokine release was measured using ELISA. Results Gene expression microarray analysis of allergen‐challenged PBMCs showed that 209 out of 44 000 genes were differentially expressed in patients compared with controls. IL17RB was the gene whose expression increased most in patients (P<0.0001). FACS analysis of PBMCs showed, for the first time, that basophils express IL‐17RB. Following allergen challenge, IL‐17RB protein increased significantly on basophils from patients compared with controls (P<0.05). IL‐3 significantly increased both mRNA and protein expressions of IL17RB. Activation of IL‐17RB by its ligand, IL‐25, inhibited apoptosis of basophils. Moreover, IgE‐mediated degranulation was enhanced by IL‐25. Conclusion Increased expression of IL‐17RB on allergen‐challenged basophil is regulated by IL‐3, inhibits apoptosis and promotes IgE‐mediated degranulation of basophils. Cite this as: H. Wang, R. Mobini, Y. Fang, F. Barrenäs, H. Zhang, Z. Xiang and M. Benson, Clinical & Experimental Allergy, 2010 (40) 1194–1202.     

Sequence and expression of the zebrafish alpha‐actinin gene family reveals conservation and diversification among vertebrates

alpha‐actinins are actin microfilament crosslinking proteins. Vertebrate actinins fall into two classes: the broadly‐expressed actinins 1 and 4 (actn1 and actn4) and muscle‐specific actinins, actn2 and actn3. Members of this family have numerous roles, including regulation of cell adhesion, cell differentiation, directed cell motility, intracellular signaling, and stabilization of f‐actin at the sarcomeric Z‐line in muscle. Here we identify five zebrafish actinin genes including two paralogs of ACTN3. We describe the temporal and spatial expression patterns of these genes through embryonic development. All zebrafish actinin genes have unique expression profiles, indicating specialization of each gene. In particular, the muscle actinins display preferential expression in different domains of axial, pharyngeal, and cranial musculature. There is no identified avian actn3 and approximately 16% of humans are null for ACTN3. Duplication of actn3 in the zebrafish indicates that variation in actn3 expression may promote physiological diversity in muscle function among vertebrates. Developmental Dynamics 238:2936–2947, 2009. © 2009 Wiley‐Liss, Inc.