Formation of the transverse nerve in moth embryos. II. Stereotyped growth by the axons of identified neuroendocrine neurons

Does corazonin signal nutritional stress in insects?

The undecapeptide corazonin, initially discovered from the American cockroach as a strong cardioaccelerator, is now known to be ubiquitously present in arthropods, although it is absent from some species, notably Coleoptera. The structure of its precursor is similar to the GnRH precursor, while it acts through a receptor related to the GnRH receptor; corazonin thus appears to be an arthropod homolog of GnRH. It is produced by neuroendocrine cells in the brain, as well as interneurons in the ventral nerve cord. These two cell types are generally present in insects; in most species there are also other neurons producing corazonin. Its function in insects has remained obscure; its cardioacceleratory effects are limited to a few cockroach species, while in other species different physiological effects have been described. Most spectacularly it induces changes associated with the gregarious phase in migratory locusts and in the silkworm it reduces the size of the cocoon formed. Corazonin is able to induce ecdysis in two moth species, however locusts and flies in which the corazonin gene is no longer expressed, ecdyse normally and, hence, it is not clear whether corazonin is essential for ecdysis. As the corazonin neuroendocrine cells in the brain express receptors for two midgut peptides, it seems likely that their activity is modulated by the midgut endocrine cells. I propose that in insects corazonin might be released under conditions of nutritional stress, which can explain several of the observed physiological effects of this neurohormone.

Transient cell-cell interactions in neural circuit formation

The wiring of the nervous system requires a complex orchestration of developmental events. Emerging evidence suggests that transient cell-cell interactions often serve as positional cues for axon guidance and synaptogenesis during the assembly of neural circuits. In contrast to the relatively stable cellular interactions between synaptic partners in mature circuits, these transient interactions involve cells that are not destined to be pre- or postsynaptic cells. Here we review the roles of these transient cell-cell interactions in a variety of developmental contexts and describe the mechanisms through which they organize neural connections.

Different isoforms of fasciclin II play distinct roles in the guidance of neuronal migration during insect embryogenesis

During the formation of the enteric nervous system (ENS) of the moth Manduca sexta, identified populations of neurons and glial cells participate in precisely timed waves of migration. The cell adhesion receptor fasciclin II is expressed in the developing ENS and is required for normal migration. Previously, we identified two isoforms of Manduca fasciclin II (MFas II), a glycosyl phosphatidylinositol-linked isoform (GPI-MFas II) and a transmembrane isoform (TM-MFas II). Using RNA and antibody probes, we found that these two isoforms were expressed in cell type-specific patterns: GPI-MFas II was expressed by glial cells and newly generated neurons, while TM-MFas II was confined to differentiating neurons. The expression of each isoform also corresponded to the motile state of the different cell types: GPI-MFas II was detected on tightly adherent or slowly spreading cells, while TM-MFas II was expressed by actively migrating neurons and was localized to their most motile regions. Manipulations of each isoform in embryo culture showed that they played distinct roles: whereas GPI-MFas II acted strictly as an adhesion molecule, TM-MFas II promoted the motility of the EP cells as well as maintaining fasciculation with their pathways. These results indicate that precisely regulated patterns of isoform expression govern the functions of fasciclin II within the developing nervous system.

Identification of the cellular target for eclosion hormone in the abdominal transverse nerves of the tobacco hornworm, Manduca sexta

The isolated abdominal central nervous system of Manduca sexta undergoes an increase in cyclic GMP (cGMP) when exposed to the insect peptide eclosion hormone (EH) before pupal ecdysis. Previously, cGMP immunocytochemistry revealed that the EH-stimulated increase in cGMP was contained in numerous filamentous processes within the transverse nerve associated with each abdominal ganglion. These processes seemed to be the axons of neurosecretory cells projecting to this neurohemal organ. In the present paper, we now show that the EH-stimulated cGMP is not present in neurosecretory terminals. There is no colocalization of the EH-stimulated cGMP with immunoreactivity of two peptides, known to be present in axons in the transverse nerves. Furthermore, there is no colocalization of EH-stimulated cGMP with the synaptic vesicle protein, synaptotagmin. The neurosecretory axons are localized to a narrow band at the anterior margin of the transverse nerve, whereas the cellular elements showing an EH-stimulated cGMP increase are primarily present in the posterior region. There are two cell types in this region: a granular and a nongranular type. The cGMP immunoreactivity seems to be contained within the nongranular type. During adult development, the cells of the posterior compartment spread in a thin layer between the transverse and dorsal nerves, become positive for myosin immunoreactivity between pupal stages 5 and 8, and seem to form the adult ventral diaphragm muscles. We conclude that the EH-sensitive filaments in the transverse nerves of Manduca are most likely to be intrinsic cells that subsequently develop into the ventral diaphragm muscles of the adult.

Clonal analysis of Drosophila embryonic neuroblasts: neural cell types, axon projections and muscle targets

An experimental analysis of neurogenesis requires a detailed understanding of wild-type neural development. Recent DiI cell lineage studies have begun to elucidate the family of neurons and glia produced by each Drosophila embryonic neural precursor (neuroblast). Here we use DiI labeling to extend and clarify previous studies, but our analysis differs from previous studies in four major features: we analyze and compare lineages of every known embryonic neuroblast; we use an in vivo landmark (engrailed-GFP) to increase the accuracy of neuroblast identification; we use confocal fluorescence and Nomarski microscopy to collect three-dimensional data in living embryos simultaneously for each DiI-labeled clone, the engrailed-GFP landmark, and the entire CNS and muscle target field (Nomarski images); and finally, we analyze clones very late in embryonic development, which reveals novel cell types and axon/dendrite complexity. We identify the parental neuroblasts for all the cell types of the embryonic CNS: motoneurons, intersegmental interneurons, local interneurons, glia and neurosecretory cells (whose origins had never been determined). We identify muscle contacts for every thoracic and abdominal motoneuron at stage 17. We define the parental neuroblasts for neurons or glia expressing well-known molecular markers or neurotransmitters. We correlate Drosophila cell lineage data with information derived from other insects. In addition, we make the following novel conclusions: (1) neuroblasts at similar dorsoventral positions, but not anteroposterior positions, often generate similar cell lineages, and (2) neuroblasts at similar dorsoventral positions often produce the same motoneuron subtype: ventral neuroblasts typically generate motoneurons with dorsal muscle targets, while dorsal neuroblasts produce motoneurons with ventral muscle targets. Lineage data and movies can be found at http://www.biologists.com/Development/movies/dev8623.htmlhttp://www.neuro.uoregon.edu/doelab/lineages/

Developmental expression of heterotrimeric G proteins in the nervous system of Manduca sexta

The heterotrimeric G proteins are a conserved family of guanyl nucleotide-binding proteins that appear in all eukaryotic cells but whose developmental functions are largely unknown. We have examined the developmental expression of representative G proteins in the developing nervous system of the moth Manduca sexta. Using affinity-purified antisera against different G alpha subunits, we found that each of the G proteins exhibited distinctive patterns of expression within the developing central nervous system (CNS), and that these patterns underwent progressive phases of spatial and temporal regulation that corresponded to specific aspects of neuronal differentiation. Several of the G proteins examined (including Gs alpha and G(o) alpha) were expressed in an apparently ubiquitous manner in all neurons, but other proteins (including Gi alpha) were ultimately confined to a more restricted subset of cells in the mature CNS. Although most of the G proteins examined could be detected within the central ganglia, only G(o) alpha-related proteins were seen in the developing peripheral nerves; manipulations of G protein activity in cultured embryos suggested that this class of G protein may contribute to the regulation of neuronal motility during axonal outgrowth. G(o) alpha-related proteins were also localized to the developing axons and terminals of the developing adult limb during metamorphosis. These intracellular signaling molecules may, therefore, play similar developmental roles in both the embryonic and postembryonic nervous system.

Rearrangement of epithelial cell types in an insect wing monolayer is accompanied by differential expression of a cell surface protein

The distribution of adhesive molecules on surfaces of cells represents covert information for specifying positions of cells within a tissue. In insect wing epithelia where cells are arranged in two monolayers separated by an extracellular space, these adhesive molecules are found on basal and lateral surfaces of cells. Protein 3B11 is one surface protein whose expression changes in concert with movement and alignment of cells in wing monolayers of Manduca as well as with migration of tracheoles between the two monolayers of the wing. As epithelial cells segregate into periodic, transverse rows of alternating cell types (scale cells and generalized epithelial cells), the expression of 3B11 changes from a uniform distribution throughout the epithelial monolayer to a distribution correlated with a cell's final position and phenotype. Initially protein 3B11 is uniformly expressed on nonadherent surfaces of cells, but with the inception of cell rearrangement, differential expression of 3B11 on basolateral surfaces of cells--both adherent and nonadherent surfaces--becomes a function of epithelial cell type. At the completion of the cell movements associated with segregation of cell types, 3B11 is once again uniformly expressed throughout the wing epithelium. Also, as the upper and lower epithelial monolayers interact at their basal surfaces during adult development, 3B11 is expressed at the interface between the two epithelial monolayers and presumably functions in the nonspecific interaction between these monolayers. Examining the expression patterns of this protein as well as other adhesion molecules in wing epithelia should reveal general rules about either the simplicity or the complexity of the molecular prepatterns that orchestrate overt tissue patterns in epithelial monolayers.

Postembryonic development of leucokinin I-immunoreactive neurons innervating a neurohemal organ in the turnip moth Agrotis segetum

In the abdominal ganglia of the turnip moth Agrotis segetum, an antibody against the cockroach neuropeptide leucokinin I recognizes neurons with varicose fibers and terminals innervating the perisympathetic neurohemal organs. In the larva, the abdominal perisympathetic organs consist of a segmental series of discrete neurohemal swellings on the dorsal unpaired nerve and the transverse nerves originating at its bifurcation. These neurohemal structures are innervated by varicose terminals of leucokinin I-immunoreactive (LKIR) fibers originating from neuronal cell bodies located in the preceding segment. In the adult, the abdominal segmental neurohemal units are more or less fused into a plexus that extends over almost the whole abdominal nerve cord. The adult plexus consists of peripheral nerve branches and superficial nerve fibers beneath the basal lamina of the neural sheath of the nerve cord. During metamorphosis, the LKIR fibers closely follow the restructuration of the perisympathetic organs. In both larvae and adults the LKIR fibers in the neurohemal structures originate from the same cell bodies, which are distributed as ventrolateral bilateral pairs in all abdominal ganglia. The transformation of the series of separated and relatively simple larval neurohemal organs into the larger, continuous and more complex adult neurohemal areas occurs during the first of the two weeks of pupal life. The efferent abdominal LKIR neurons of the moth Agrotis segetum thus belong to the class of larval neurons which persist into adult life with substantial peripheral reorganization occurring during metamorphosis.

Guidepost cells

Guidepost cells, as classically defined in the grasshopper embryo have only rarely been found in other systems. If the concept of guidepost cells is expanded, recognizing that any special role of specific cells in axon guidance is a function of the entire landscape in which axons are growing, and that growth cone--guidepost interactions may share mechanisms with many other cell--cell interactions, then numerous examples are found in both the peripheral and central nervous systems of many species.

The timing of initial neuropeptide expression by an identified insect neuron does not depend on interactions with its normal peripheral target

To study the developmental regulation of a neuropeptide phenotype, we have analyzed the biochemical and morphological differentiation of two identifiable neurons in embryos of the moth, Manduca sexta. The central cell, CF, and the peripheral cell, L1, are both neuroendocrine neurons that express neuropeptides related to the molluscan tetrapeptide FMRFamide. Both neurons project axons to the transverse nerve in each thoracic segment. Within the CF and L1 cells, neuropeptide-like immunoreactivity was localized to secretory granules that had cell-specific morphologies and sizes. The onset of neuropeptide expression in the two cell types displayed a similar pattern: immunoreactivity was first detected in distal processes and soon after within cell bodies. However, the onsets occurred at different times: for the CF cell, neuropeptides were first seen at 60%-63% of embryonic development, after the neuron had extended a long axon into the periphery, while L1 neuropeptide expression began at approximately 42%, as it first extended its growth cone. These times were related in that they corresponded to the arrival times of the respective growth cones at a similar position in the developing peripheral nerve. Within this region of the nerve, the growth cones of both cell types-exhibited a transient and cell-specific interaction with an identified mesodermal cell, called the Syncytium. Like the L1 and B neurons (Carr and Taghert, 1988b), the CF growth cones typically grew past this cell, yet remained attached to it by lamellipodial and filopodial processes of the axon. Ultrastructurally, the interaction involved filopodial adhesion to and insertion within the Syncytial cell. Two other nonneuroendocrine cell types grew axons past this same region, but showed no such tendencies. To test the hypothesis that the morphological and biochemical differentiation of these cells was somehow linked, central ganglia were isolated (as individuals or connected as ganglionic chains) in tissue culture, prior to the time when CF growth cones entered the periphery and prior to the development of CF neuropeptide expression. In the majority of cases, CF neurons nevertheless displayed their neuropeptide phenotype at a normal and cell-specific stage. We conclude that the initiation of neuropeptide expression is highly correlated with schedules of morphological differentiation in these neurons, but that, in the case of the CF neuron, it is not regulated by interactions of the growth cone with peripheral structures.

Segment-specific modifications of a neuropeptide phenotype in embryonic neurons of the moth, Manduca sexta

We have studied differences in the development of segmentally homologous neurons to identify factors that may regulate a neuropeptide phenotype. Bilaterally paired homologs of the peripheral neuron L1 were identified in the thoracic and abdominal segments in embryos of the moth Manduca: each bipolar neuron arises at a stereotyped location and, at 40% of embryogenesis, projects its major process within the transverse nerve of its own segment. Shortly after the initiation of axonogenesis (approximately 41%), L1 homologs in all but the prothoracic segment (T1) were labelled specifically by an antiserum to the molluscan neuropeptide Phe-Met-Arg-Phe-NH2 (authentic FMRFamide). Levels of peptide-immunoreactivity (IR) were comparable in all such segmental homologs up to the approximately 60% stage of embryogenesis, whereupon two distinct levels of peptide IR were displayed: homologs in the three most rostral segments (T2, T3, and A1; [abdominal segment 1]) showed high levels and were called Type I L1 neurons; homologs in the more caudal segments (A2-A8) typically showed low levels of IR and were called Type II L1 neurons. This segment-specific difference represented mature differentiated states and was retained in postembryonic stages. Intracellular dye fills of embryonic L1 neurons revealed that the morphogenesis of the Type I and II L1 neuron homologs was similar until approximately 48% of embryogenesis; thereafter it differed in two salient ways: (1) the cell bodies of Type II L1 neurons migrated approximately 150 microns laterally from their point of origin, and (2) the distal processes of the Type II L1 neurons contacted the heart, whereas those of Type I L1 neurons did not. Ultrastructural studies of both mature and developing L1 homologs showed that the FMRFamide-like antigen(s) localized specifically to secretory granules. Further, whereas the secretory granules in segmental homologs appeared similar initially (i.e., at approximately 50% of development), following the establishment of segment-specific differences, secretory granules found in mature Type I and II L1 neurons were cell type-specific.

The development of identified neurosecretory cells in the tobacco hornworm, Manduca sexta

The prothoracicotropic hormone (PTTH) is a principal neuropeptide regulator of insect postembryonic molting and metamorphosis. In the tobacco hornworm, Manduca sexta, PTTH is produced by two neurosecretory cells (NSC) located in each protocerebral lobe of the brain. The development of these neurons, the L-NSC III, has been investigated immunocytologically to establish the time course of their morphological differentiation. PTTH may be one of the earliest neuropeptides expressed in insect embryos. PTTH-immunoreactivity was initially detected in the somata at 24 to 30% of embryonic development. Neurites sprouted shortly thereafter and began to grow medially through the brain anlage. By 42% embryonic development, the neurites had decussated to the contralateral brain lobe. As development progressed, the L-NSC III neurites grew along specific tracts through the contralateral brain lobe reaching the ventrolateral regions of the brain by approximately 60% development. The axons exited the brain through a retrocerebral nerve, the nervi corporis cardiaci I + II. At approximately 63% development, the axons innervated the corpus allatum and began branching to form neurohemal terminals for PTTH release. At 60% development, short collaterals began extending in the protocerebral neuropil. During the remainder of embryogenesis, both the dendritic collaterals and the terminal neurohemal varicosities continued to elongate and arborize. By 85% embryonic development, the basic architecture of the L-NSC III was established.

Muscle assembly in simple systems

Muscle development has been the subject of intense scrutiny at cellular, biochemical and molecular levels, yet little is known about the factors that generate anatomically distinct muscles during embryogenesis. We now know that at least some muscles are initially organized by interactions with particular cells that appear early in development, the muscle organizers. These organizers have been described in both arthropods and annelids, and serve similar functions in both groups: they provide cellular scaffolding during the early and relatively simple anatomical stages of embryogenesis, which is then used to pattern the assembly of large numbers of pre-myocytes. Thus, single cells provide an early framework that is retained even as the embryo becomes vastly more complex. Furthermore, studies have shown that the muscle organizer is necessary for motor neuron growth cones to locate (or recognize) the appropriate target region. In other words, the motor neurons extend toward muscles during muscle histogenesis and can use the muscle organizer for guidance, rather than the definitive muscle which has not yet emerged. The discovery of these identifiable tissue organizers has opened several intriguing avenues by which the roles of cell-cell interactions in development can be further addressed. Additionally, the discovery of these cells implies that in order to understand the ways in which motor neurons are initially matched to particular muscle targets we should also study the organizers that may provide positional introductions between future synaptic partners.

Development of the enteric nervous system in the moth. II. Stereotyped cell migration precedes the differentiation of embryonic neurons

The enteric plexus is a discrete portion of the enteric nervous system (ENS) in the larval moth Manduca sexta. It consists of a stereotyped array of nerves extending across specific regions of both the foregut and midgut. Within these nerves are approximately 400 neurons (the EP cells), which do not appear to be uniquely identifiable but exhibit a spectrum of morphological and biochemical phenotypes. In this report we have described the morphogenetic events by which the enteric plexus is created during embryogenesis and have characterized the morphological differentiation of the EP neurons. In particular, we have demonstrated a prominent role for stereotyped cellular migration in the formation of this region of the ENS. The neurons of the enteric plexus arise from the dorsal epithelium of the foregut in the form of a dense, triangular packet. Between 40 and 65% of embryogenesis, the cells of this packet become progressively dispersed by a sequence of migratory events: an initial, slow phase of migration that is circumferentially directed around the foregut, and a rapid, dispersing phase by which the EP cells achieve their mature distributions across the foregut and midgut surface. These migratory phases occur along defined pathways on the gut and result in cellular translocations of up to 250 microns. In the early phase, some migrating neurons extend long axons in stereotyped directions, while others retain a simple bipolar morphology. Neurons of both morphological types are interspersed throughout the initial packet of cells and participate equally in the migratory process. Toward the end of migration, cells with the simpler morphology also extend axons along predictable pathways. Several additional subtypes subsequently differentiate in various regions within the plexus. The expression of specific peptidergic substances (related to the molluscan peptide Phe-Met-Arg-Phe-NH2, as described in the accompanying paper (P. F. Copenhaver and P. H. Taghert, 1988, Dev. Biol. 130, 70-84) commences within the EP cell population only after these migratory phases are complete and can be correlated with the outcome of cellular migration: only neurons that navigate onto the midgut regions of the plexus subsequently exhibit the peptidergic phenotype. This system should provide an excellent model with which to examine the mechanisms underlying the migratory process and the potential roles of cellular migration in regulating neuronal differentiation.

Formation of the transverse nerve in moth embryos. I. A scaffold of nonneuronal cells prefigures the nerve

We have studied the embryonic development of the transverse nerve (TN), an unpaired segmental nerve of the moth Manduca sexta. Two identified motor neurons and 16 identified neuroendocrine neurons project axons within the larval TN; therefore, the TN is both a peripheral nerve and a neurohaemal organ. At 33% of embryogenesis, and prior to the arrival of any neuronal growth cones, the position, shape, and trajectory of the TN are anticipated by two groups of nonneuronal cells that we call the strap and the bridge. At this time the strap and the bridge together consist of approximately 100 cells, all of which express a cell surface epitope recognized by the monoclonal antibody TN-1. As development proceeds, both the number of nonneuronal cells within the strap and the bridge and the fraction that expresses the TN-1 antigen(s) decrease. Moreover, individual cells within the strap become morphologically identifiable before the arrival of the neuronal growth cones. Most of the axons that project to the TN also express the TN-1 antigen(s) during their period of outgrowth. The two motor neuron growth cones are the first to reach the environment of the strap and the bridge, doing so at approximately 37%; having encountered these cellular structures, the growth cones restrict their navigation to this preexisting scaffolding, until they reach their muscle target. The neuroendocrine growth cones arrive later and also grow within the confines of the strap and the bridge (J.N. Carr and P.H. Taghert, 1988, Dev. Biol, 130, 500-512). In this first paper we describe the development of the strap and the bridge, and the interactions of the motor neuron growth cones with these structures. The observations are novel in documenting the extent and precision to which a peripheral nerve pathway is prefigured by a contiguous assemblage of nonneuronal cells.