Selective expression of glionexin,a glial glycoprotein,in insect mechanoreceptors

The distribution of a glial cell-associated glycoprotein, glionexin (GX), on sensory receptors of the adult cricket Acheta domesticus is described, using the monoclonal antibody 5B12 as an immunohistochemical probe. GX was previously shown to be widely distributed in the embryo and to persist in the postembryonic to adult central nervous system. Here we demonstrate that it is restricted in the adult periphery to three subclasses of mechano-receptor sensilla: large socketed hair mechanoreceptors, their associated campaniform sensilla, and chordotonal organs. GX was not detected in photoreceptors, chemoreceptors, or other mechanoreceptors. The pattern of distribution differs significantly within the three subclasses of mechanoreceptors. In the hair and campaniform receptors GX is restricted to the extracellular space among glial cells clustered around the axon hillock region, but in chordotonal organs it surrounds the scolopidium at the tip of dendrites. The highly restricted distribution of GX in the periphery suggests possible functions that include mechanical stability of the sensory apparatus and ionic homeostasis in the respective neuronal spike-generating regions. The developmental modulation of GX expression is taken to imply multiple functions for the molecule during the life of the insect. 1994 John Wiley & Sons, Inc.     

Development of wing sensory axons in the central nervous system of Drosophila during metamorphosis

The development of new, adult-specific axonal pathways in the central nervous system (CNS) of insects during metamorphosis is still largely uncharacterized. Here we used axonal labeling with DiI to describe the timing and pattern of growth of sensory axons originating in the wing of Drosophila as they establish their adult projection pattern in the CNS during pupal life. The wing of Drosophila carries a small number of readily identifiable sensory organs (sensilla) whose neurons are located in the periphery and whose axons travel along specific routes within the adult CNS. The neurons are born and undergo axonogenesis in a characteristic order. The order of axon arrival in the CNS appears to be the same as that of their development in the periphery. Within the CNS, the formation of four prominent axon bundles leading to distant termination sites is followed by the formation of a compact axon termination site near the point of wing nerve entry into the CNS. This sensillum-specific pattern persists into adulthood without discernible modification. We also find a small number of axons filled with DiI prior to the formation of the four permanent bundles. We have only been able to fill them for a few hours in early pupal life and therefore consider them to be transient. The bundles of wing sensory axons travel within tracts that contain other axons as well. Using immunocytochemistry, the tracts start to be histologically identifiable at around 12 h after pupariation (AP), and grow substantially as metamorphosis proceeds. Wing sensory neurons are found in the tracts by 18–20 h AP and the full adult pattern is established by 48 h AP. When sensory axons first enter the CNS, they fan out in the region where their appropriate tracts are located, but they do not wander extensively. They quickly form bundles that become increasingly compact over time. Calculations show that the rate of axon extension within the CNS varies from bundle to bundle and is equal to or greater than that of the same axons growing through wing tissue. © 1995 John Wiley & Sons, Inc.     

The restricted spatial and temporal expression of a nervous-system-specific antigen involved in axon outgrowth during development of the grasshopper

To identify molecules important for pathfinding by growing axons, monoclonal antibodies (mAb) have been generated against embryonic grasshopper tissue. One mAb, 2B2, shows labeling exclusively in the nervous system. It recognizes a surface epitope on neuronal growth cones, filopodia and axons in the central nervous system (CNS). Initially, the antigen is expressed on all processes of the CNS; after 70% of embryonic development, localization of the 2B2 mAb is restricted to a small subset of axon tracts within the ganglia. Immunoprecipitation from embryonic membrane extracts with the 2B2 mAb reveals a unique band of 160 x 10(3) Mr. Functional studies with the 2B2 mAb demonstrate that the antigen is important in growth cone-axon interactions during process outgrowth. Growth cones that extend along axonal substrata are either blocked in growth or grow along an aberrant pathway when embryos are cultured in the presence of the 2B2 mAb. However, pioneer neurons that extend processes on non-neuronal substrata grow normally.     

Glial interactions with neurons during Drosophila embryogenesis

A monoclonal antibody (Mab5B12) demonstrating specificity for glial cells within the central and peripheral nervous systems of Drosophila has been used in combination with neural-specific antibodies to study the early organization of the Drosophila embryo. The embryonic central nervous system of Drosophila contains cells within the ventral midline that are recognized by monoclonal antibody 5B12. These cells are not recognized by either a polyclonal antiserum to horse radish peroxidase, which recognizes several antigens on the surface of Drosophila neurons, or Mab22C10, which recognizes an antigen specific to the peripheral nervous system. Mab5B12-positive cells lie dorsal both to the developing anterior and posterior commissures in each thoracic and abdominal segment and to the supraoesophageal commissure. They ensheath these commissures in later stage embryos. Other Mab5B12-positive cells lie dorsolateral to the CNS and send processes laterally to the lateral sensilla during axonogenesis in the PNS. These cells surround the axons of the intersegmental and segmental nerves. Other cells that line the advancing ectoderm during dorsal closure and surround the anal pads also express the Mab5B12 antigen. Neuronal cell cultures derived from Drosophila gastrulae contain cells expressing the Mab5B12 antigen. These cells can be found separate or in close association with neuronal clusters and their axons.     

Defasciculation as a neuronal pathfinding strategy: involvement of a specific glycoprotein

Leech sensory afferents change their growth behavior as they enter the CNS. Arriving from the periphery in fasciculated tracts, they abruptly defasciculate and expand into diffuse trees before reassembling into four distinct central tracts. In the organ-cultured germinal plate, growing sensory afferents were incubated with monovalent Fab fragments of the Lan3-2 antibody, which recognizes a 130 kd sensory neuron protein by its mannose epitope. Very low concentrations of Lan3-2 (6 and 12 nM) specifically inhibited the central defasciculation of sensory afferents, which then continued growing as a single tract. In contrast, monoclonal antibody Lan3-6, which binds to an internal sensory antigen, failed to yield the same effect. These observations suggest that this sensory neuron 130 kd surface glycoprotein participates in a developmentally significant heterophilic interaction specific for the CNS.     

F-spondin/spon1b expression patterns in developing and adult zebrafish

F-spondin, an extracellular matrix protein, is an important player in embryonic morphogenesis and CNS development, but its presence and role later in life remains largely unknown. We generated a transgenic zebrafish in which GFP is expressed under the control of the F-spondin (spon1b) promoter, and used it in combination with complementary techniques to undertake a detailed characterization of the expression patterns of F-spondin in developing and adult brain and periphery. We found that F-spondin is often associated with structures forming long neuronal tracts, including retinal ganglion cells, the olfactory bulb, the habenula, and the nucleus of the medial longitudinal fasciculus (nMLF). F-spondin expression coincides with zones of adult neurogenesis and is abundant in CSF-contacting secretory neurons, especially those in the hypothalamus. Use of this new transgenic model also revealed F-spondin expression patterns in the peripheral CNS, notably in enteric neurons, and in peripheral tissues involved in active patterning or proliferation in adults, including the endoskeleton of zebrafish fins and the continuously regenerating pharyngeal teeth. Moreover, patterning of the regenerating caudal fin following fin amputation in adult zebrafish was associated with F-spondin expression in the blastema, a proliferative region critical for tissue reconstitution. Together, these findings suggest major roles for F-spondin in the CNS and periphery of the developing and adult vertebrate.     

Cellular expression patterns of acetylcholinesterase activity during grasshopper development

We examined the expression of acetylcholinesterase (AChE) in the nervous system and epidermal body structures during embryonic and larval development of two grasshopper species: Locusta migratoria and Schistocerca americana. Histochemical labelling was blocked by the enzyme inhibitors eserine and BW284c51, but not by iso-OMPA, showing that the staining reflected true AChE activity. The majority of staining was localized on the cell surface but granular intracellular staining was also visible in many cell bodies. In both species, the cellular expression of AChE followed a similar but complex spatiotemporal staining pattern. Initially, mainly epidermal tissue structures were stained in the various body appendages (stages 25%–30%). Labelling subsequently appeared in outgrowing neurons of the central nervous system (CNS) and in the nerves innervating the limbs and dorsal body wall (stages 30%–40%). The latter staining originated in motoneurons of the ventral nerve cord. In a third phase (after 45%), the somata of certain identified mechanosensory neurons started to express AChE activity, presumably reflecting cholinergic differentiation. Staining was also found in repo-positive glial cells of the CNS, longitudinal glia of connectives, glia of the stomatogastric nervous system and glial cells ensheathing peripheral nerves. Glial cells remained AChE-positive during larval to adult development, whereas motoneurons lost their AChE expression. The expression pattern in non-neuronal cells and glutamatergic motoneurons and the developmental appearance of AChE prior to synaptogenesis in the CNS suggest non-cholinergic functions of AChE during grasshopper embryogenesis. Financial support was provided by the Deutsche Forschungsgemeinschaft (Bi 262/7-1 and 262/11-1)     

Surgical generation of supernumerary appendages for studying neuronal specificity in Drosophila melanogaster

The ability of sensory neurons to establish specific synaptic contacts in the central nervous system (CNS) can be studied by changing the spatial relationship between the periphery and the CNS. In contrast to the genetic displacement of appendages by homoeotic mutations, the surgical approach used in this study allows one to place homologous as well as heterologous appendages to the same site on the body surface. Using an improved technique of “surface transplantation,” we generated supernumerary appendages of any desired type in a particular abdominal position. The sensory axons originating from these grafts enter the CNS through the main abdominal nerve and arborize in the fused abdominal ganglia; many fibers extend also into thoracic centers. In the abdominal ganglia, terminals from dorsal transplants (wings and halteres) stay on the ipsilateral side, whereas terminals from ventral transplants (legs and antennae) distribute ipsi- and contralaterally. The same preference holds true for dorsal and ventral abdominal bristles, respectively, whose projection patterns served as a reference. In thoracic ganglia, axons from dorsal and ventral grafts yield completely different terminal patterns. Dorsal grafts project into the ipsilateral wing center, even in the mutant wingless, in which normal wing afferents are suppressed. In contrast, fibers from ventral grafts often extend along the thoracic midline. These data indicate that sensory axons of homologous appendages on the one hand, and their central targets on the other, share serially repeated surface markers. This may enable sensory fibers to recognize centers of homologous appendages.     

胚胎海马伞移植物对成年大鼠海马胆碱能纤维生长的引导效应

在胚胎和新生的中枢神经系统(CNS)内,发育中的纤维束通道能引导轴突的生长。为了了解发育中的纤维束通道能否引导成年CNS轴突的生长,将胚胎海马伞移植到成年大鼠的海马,两周后,用AChE组织化学方法检查移植物内的胆碱能纤维。结果如下:在胚胎的海马伞移植物内出现大量的胆碱能纤维,但在成年的海马伞移植物内没有宿主的胆碱能纤维长入;如果在移植胚胎海马伞的同时,切断宿主的海马伞-穹窿通路,则在胚胎移植物和宿主海马内均无胆碱能纤维;将胚胎海马伞作成悬浮液进行移植,在移植部位,仅能看到少数长的胆碱能纤维;但是若把胚胎海马伞的组织碎片粘附在硝化纤维素滤纸条周围,再移植到成年大鼠海马内,来自宿主海马的大量胆碱能纤维被吸引围绕着滤纸条并沿其表面生长。结果似乎表明:胚胎海马伞或胚胎海马伞碎片都能有效引导宿主海马胆碱能纤维的生长。因此,胚胎海马伞和其它发育中的CNS纤维束通道可能是引导成年CNS轴突生长的良好天然基质。     

Temporal and spatial patterns of expression of p35, a regulatory subunit of cyclin-dependent kinase 5, in the nervous system of the mouse

The protein p35 is a regulatory subunit of cyclin-dependent kinase 5. It has no recognized homology to cyclins but binds to and activates cyclin-dependent kinase 5 directly in the absence of other protein molecules. Cyclin-dependent kinase 5 was initially isolated by homology to the key cell cycle regulator cdc2 kinase and later identified as a neuronal kinase that phosphorylates histone H1, tau or neurofilaments. This kinase is localized in axons of the developing and mature nervous system. To understand the role of p35 as a regulator of cyclin-dependent kinase 5 activity in the CNS, we examined the pattern of expression of p35 mRNA in the nervous system of embryonic, early postnatal and adult mice. In separate experiments, we also examined the spatial distribution of cyclin-dependent kinase 5 mRNA and the activity of cyclin-dependent kinase 5/p35 kinase complex. Postmitotic cells express p35 mRNA immediately after they leave the zones of cell proliferation. It is also expressed in developing axonal tracts in the brain. Cyclin-dependent kinase 5 mRNA is present in postmitotic and in proliferative cells throughout the embryonic central nervous system. During early postnatal period signal for p35 mRNA declines while that for cyclin-dependent kinase 5 mRNA increases throughout the brain. In the adult brain although both p35 and cyclin-dependent kinase 5 mRNAs are expressed at relatively high levels in certain structures associated with the limbic system, considerable differences exist in the patterns of their distribution in other parts of the brain. These data suggest that the p35/cyclin-dependent kinase 5 complex may be associated with early events of neuronal development such as neuronal migration and axonal growth while in the limbic system of the mature brain it may be associated with the maintenance of neuronal plasticity.     

Antigenic and functional characterization of a rat central nervous system-derived cell line immortalized by a retroviral vector

We have immortalized rat central nervous system (CNS) cells of primary cultures of rat optic nerve with murine leukemia virus psi-2,SV-40-6, which is defective in assembly and contains the SV-40 large T antigen and neomycin resistance genes, to produce a cell line that we named A7. After drug selection, greater than 90% of the growing cells expressed nuclear SV-40 large T cells and a fraction of these contained the astrocyte-specific marker, glial fibrillary acidic protein. The majority of these cells also expressed surface marker A4 (specific for neural tube derivatives), Ran 2, p185 (the 185-kD phosphoprotein product of the neu oncogene), and fibronectin, but did not express the astrocyte enzymes glutamine synthetase and monoamine oxidase B. Surface markers characteristic of glial progenitors (A2B5) and oligodendrocytes (galactocerebroside) were not detected. After two rounds of cell cloning, subclone A7.6-3 expressed Ran 2, fibronectin, and the neural cell adhesion molecule (N-CAM) but not glial fibrillary acidic protein and A4. The A7 cell line and subclones also displayed certain functions of type 1 astrocytes: the conditioned medium of these cells had a potent mitogenic activity for glial progenitor cells which could be neutralized by anti-platelet-derived growth factor antibodies and monolayers of these cells supported the growth of embryonic hypothalamic neurons. We conclude that a retrovirus containing SV-40 large T antigen can immortalize rat CNS cells and that such immortalized glial cells retain at least two important functions of type 1 astrocytes: the ability to secrete platelet-derived growth factor and to support the growth of embryonic CNS neurons. Moreover, such stable immortalized clonal cell lines can be used to study gene regulation in glial cells.     

Identity, origin, and migration of peripheral glial cells in the Drosophila embryo

Glial cells are crucial for the proper development and function of the nervous system. In the Drosophila embryo, the glial cells of the peripheral nervous system are generated both by central neuroblasts and sensory organ precursors. Most peripheral glial cells need to migrate along axonal projections of motor and sensory neurons to reach their final positions in the periphery. Here we studied the spatial and temporal pattern, the identity, the migration, and the origin of all peripheral glial cells in the truncal segments of wildtype embryos. The establishment of individual identities among these cells is reflected by the expression of a combinatorial code of molecular markers. This allows the identification of individual cells in various genetic backgrounds. Furthermore, mutant analysis of two of these marker genes, spalt major and castor, reveal their implication in peripheral glial development. Using confocal 4D microscopy to monitor and follow peripheral glia migration in living embryos, we show that the positioning of most of these cells is predetermined with minor variations, and that the order in which cells migrate into the periphery is almost fixed. By studying their lineages, we uncovered the origin of each of the peripheral glial cells and linked them to identified central and peripheral neural stem cells.     

Larval legs of mulberry silkworm Bombyx mori are prototypes for the adult legs

Morphological diversity of leg appendages is one of the hallmarks of developmental evolution. Limbs in insects may develop either from their embryonic prototypes or from imaginal discs harbored inside the larva. Bombyx mori (B. mori), a Lepidopteran insect, develops adult wings from larval wing imaginal discs. However, it has been debated whether the adult legs of B. mori arise from imaginal discs or from the larval legs. Here we addressed how the larval legs relate to their adult counterparts. We present the morphological landmarks during early leg development. We used expression of developmental genes like Distalless and extradenticle to mark leg primordia. Finally, we employed classical excision approach to develop a fate map of the adult leg. Excision and ablation of thoracic legs along proximo-distal axis at various times during larval development resulted in the loss of corresponding adult leg segments. Our data suggest that B. mori legs develop from larval appendages rather than leg imaginal discs.     

Embryonic development of glial cells and myelin in the shark,Chiloscyllium punctatum

Glial cells are responsible for a wide range of functions in the nervous system of vertebrates. The myelinated nervous systems of extant elasmobranchs have the longest independent history of all gnathostomes. Much is known about the development of glia in other jawed vertebrates, but research in elasmobranchs is just beginning to reveal the mechanisms guiding neurodevelopment. This study examines the development of glial cells in the bamboo shark, Chiloscyllium punctatum, by identifying the expression pattern of several classic glial and myelin proteins. We show for the first time that glial development in the bamboo shark (C. punctamum) embryo follows closely the one observed in other vertebrates and that neural development seems to proceed at a faster rate in the PNS than in the CNS. In addition, we observed more myelinated tracts in the PNS than in the CNS, and as early as stage 32, suggesting that the ontogeny of myelin in sharks is closer to osteichthyans than agnathans.     

CNS midline cells influence the division and survival of lateral glia in the Drosophila nervous system

Central nervous system (CNS) midline cells are essential for identity determination and differentiation of neurons in the Drosophila nervous system. It is not clear, however, whether CNS midline cells are also involved in the development of lateral glial cells. The roles of CNS midline cells in lateral glia development were elucidated using general markers for lateral glia, such as glial cell missing and reverse polarity, and specific enhancer trap lines labeling the longitudinal, A, B, medial cell body, peripheral, and exit glia. We found that CNS midline cells were necessary for the proper expression of glial cell missing, reverse polarity, and other lateral glia markers only during the later stages of development, suggesting that they are not required for initial identity determination. Instead, CNS midline cells appear to be necessary for proper division and survival of lateral glia. CNS midline cells were also required for proper positioning of three exit glia at the junction of segmental and intersegmental nerves, as well as some peripheral glia along motor and sensory axon pathways. This study demonstrated that CNS midline cells are extrinsically required for the proper division, migration, and survival of various classes of lateral glia from the ventral neuroectoderm.     

Characterization of two novel lipocalins expressed in the Drosophila embryonic nervous system

We have found two novel lipocalins in the fruit fly Drosophila melanogaster that are homologous to the grasshopper Lazarillo, a singular lipocalin within this protein family which functions in axon guidance during nervous system development. Sequence analysis suggests that the two Drosophila proteins are secreted and possess peptide regions unique in the lipocalin family. The mRNAs of DNLaz (for Drosophila neural Lazarillo) and DGLaz (for Drosophila glial Lazarillo) are expressed with different temporal patterns during embryogenesis. They show low levels of larval expression and are highly expressed in pupa and adult flies. DNLaz mRNA is transcribed in a subset of neurons and neuronal precursors in the embryonic CNS. DGLaz mRNA is found in a subset of glial cells of the CNS: the longitudinal glia and the medial cell body glia. Both lipocalins are also expressed outside the nervous system in the developing gut, fat body and amnioserosa. The DNLaz protein is detected in a subset of axons in the developing CNS. Treatment with a secretion blocker enhances the antibody labeling, indicating the DNLaz secreted nature. These findings make the embryonic nervous system expression of lipocalins a feature more widespread than previously thought. We propose that DNLaz and DGLaz may have a role in axonal outgrowth and pathfinding, although other putative functions are also discussed.     

Spatiotemporal heterogeneity of CNS radial glial cells and their transition to restricted precursors

Radial glia are among the first cells that develop in the embryonic central nervous system. They are progenitors of glia and neurons but their relationship with restricted precursors that are also derived from neuroepithelia is unclear. To clarify this issue, we analyzed expression of cell type specific markers (BLBP for radial glia, 5A5/E-NCAM for neuronal precursors and A2B5 for glial precursors) on cortical radial glia in vivo and their progeny in vitro. Clones of cortical cells initially expressing only BLBP gave rise to cells that were A2B5+ and eventually lost BLBP expression in vitro. BLBP is expressed in the rat neuroepithelium as early as E12.5 when there is little or no staining for A2B5 and 5A5. In E13.5-15.5 forebrain, A2B5 is spatially restricted co-localizing with a subset of the BLBP+ radial glia. Analysis of cells isolated acutely from embryonic cortices confirmed that BLBP expression could appear without, or together with, A2B5 or 5A5. The numbers of BLBP+/5A5+ cells decreased during neurogenesis while the numbers of BLBP+/A2B5+ cells remained high through the beginning of gliogenesis. The combined results demonstrate that spatially restricted subpopulations of radial glia along the dorsal-ventral axis acquire different markers for neuronal or glial precursors during CNS development.