The proneural gene amos promotes multiple dendritic neuron formation in the Drosophila peripheral nervous system

In the Drosophila peripheral nervous system, proneural genes direct the formation of different types of sensory organs. Here, we show that amos is a novel proneural gene that promotes multiple dendritic (MD) neuron formation. amos encodes a basic-helix-loop-helix (bHLH) protein of the Atonal family. During embryonic development, amos is expressed in patches of ectodermal cells, and the expression is quickly restricted to sensory organ precursors. Loss of amos function eliminates MD neurons that remain in ASC;atonal mutants. Misexpression of amos generates ectopic MD and other types of neurons. Amos interacts with the ubiquitously expressed Daughter-less protein in vivo and in vitro. Our final misexpression experiments suggest that a domain located outside the DNA-binding domain of Amos determines the MD neuronal specificity.     

Early events in the development of Drosophila peripheral nervous system

1. We have analysed the development of the larval PNS of Drosophila, with the aim of understanding the genetic programme that underlies this development. 2. The achaete-scute gene complex (AS-C), which is required for the development of the adult PNS, is also necessary for the larval PNS. The analysis of different AS-C lesions shows that the larval PNS results from the superimposition of two independent subpatterns, each of which depends on one AS-C gene. 3. The analysis of the two subpatterns reveals hidden homologies between the very different arrangements of sense organs observed on different segments, suggesting that the initial pattern is the same in all segments and is later modified in the different segments. 4. The early arrangement of sensory mother cells can be visualised in a special transgenic line, A37. In this line the initial repetitive pattern inferred above can be directly observed. Furthermore this line makes it possible to decide whether a given mutation acts on the very early steps of the PNS development (determination) or at later stages (differentiation). 5. The line A37 has been used to show that mutations that reduce the PNS such as AS-C- or da- alter the very first steps of the process, while mutations which result in a hypertrophied PNS such as N seem to alter a subsequent step. We end up with an overview of the genetic operations that generate the arrangement of sense organs and sensory neurons.     

Cell lineage analysis of the Drosophila peripheral nervous system

The peripheral nervous system (PNS) of Drosophila provides a very well-characterized model system for studying the genes involved in basic processes of neurogenesis. Because of its simplicity and stereotyped pattern, each cell of the PNS can be individually identified and the phenotypic consequences of mutations can be studied in detail. Thus, some of the genetic mechanisms leading to the formation of type I sensory organs, the external, bristle-type sensory organs (es), and the internal, stretch-receptive chordotonal organs (ch) have been elucidated. Each sensory organ seems to be generated by a stereotyped pattern of cell division of individual ectodermal precursor cells. Recent advances in cell lineage analysis of the PNS have provided a detailed picture of almost all the lineages in the PNS, including those giving rise to the type II sensory neurons, also known as multiple dendritic (md) neurons. This knowledge will be instrumental in the precise characterization of the phenotypes associated with mutations in known and new genes and their interactions which determine cell fate decisions during neurogenesis. Here, we describe and compare three recently developed methods by which cell lineages have been assessed: single cell transplantation, bromodeoxyuridine (BrdU) incorporation studies, and the flp/FRT recombinase system from yeast. In the light of a more complete knowledge of the PNS lineages, we will discuss the effects of known mutations that alter neuronal cell fates. © 1996 Wiley-Liss, Inc.     

The Drosophila homolog of the immunoglobulin recombination signal-binding protein regulates peripheral nervous system development.

The J kappa RBP binds to the immunoglobulin recombination signal sequence flanking the kappa-type J segment. We previously isolated the highly conserved homolog of the J kappa RBP gene from D. melanogaster, which is not thought to have immunoglobulin molecules. Using many deficiency mutants and in situ hybridization, we mapped the Drosophila J kappa RBP gene in a region containing two recessive lethal mutations, i.e., br26 and br7, which shows the dominant Suppressor of Hairless (Su(H)) phenotype in heterozygotes. All six Su(H) alleles analyzed at the DNA level contained mutations in the Drosophila J kappa RBP gene. Since the Su(H) mutation affects peripheral nervous system development, the Drosophila J kappa RBP gene product is involved in gene regulation of peripheral nervous system development. The results also imply that the immunoglobulin recombination signal sequence and the target sequence of the Drosophila J kappa RBP protein might have a common evolutionary origin.     

Genes involved in the development of the peripheral nervous system of Drosophila

The development of the peripheral nervous system (PNS) requires the activity of a number of genes. The neurogenic and the proneural genes are necessary in the earliest phase; their mutations lead to hyperplasia and partial or total elimination of the PNS respectively. Some of these mutations also affect other developmental processes. Other mutations affect later events: cut transforms one type of sensory organ into another; numb alters the fate of the components of a single sensory organ. We will describe the effects of the best studied mutations on PNS development and discuss the possible role of the wild type genes.     

Patterning of the Drosophila nervous system: the achaete-scute gene complex.

The genes of the achaete-scute complex (AS-C) confer on cells the ability to become neural precursors. Their expression is restricted to groups of cells, the proneural clusters, which occupy specific positions within the embryo neural anlagen and the larva imaginal discs. Neuroblasts or sensory organ mother cells are born within these clusters. Thus, the patterns of expression of the AS-C genes help to define the topology of the nervous system.     

The peripheral nervous system supports blood cell homing and survival in the Drosophila larva

Interactions of hematopoietic cells with their microenvironment control blood cell colonization, homing and hematopoiesis. Here, we introduce larval hematopoiesis as the first Drosophila model for hematopoietic colonization and the role of the peripheral nervous system (PNS) as a microenvironment in hematopoiesis. The Drosophila larval hematopoietic system is founded by differentiated hemocytes of the embryo, which colonize segmentally repeated epidermal-muscular pockets and proliferate in these locations. Importantly, we show that these resident hemocytes tightly colocalize with peripheral neurons and we demonstrate that larval hemocytes depend on the PNS as an attractive and trophic microenvironment. atonal (ato) mutant or genetically ablated larvae, which are deficient for subsets of peripheral neurons, show a progressive apoptotic decline in hemocytes and an incomplete resident hemocyte pattern, whereas supernumerary peripheral neurons induced by ectopic expression of the proneural gene scute (sc) misdirect hemocytes to these ectopic locations. This PNS-hematopoietic connection in Drosophila parallels the emerging role of the PNS in hematopoiesis and immune functions in vertebrates, and provides the basis for the systematic genetic dissection of the PNS-hematopoietic axis in the future.     

Cell polarity and asymmetric division in the peripheral nervous system of Drosophila

During metazoan development, cell fate diversity is generated in part by asymmetric cell divisions, in which mother cells divide to produce two daughter cells with distinct developmental potentials. Adoption of different cell fates often relies on the polarised distribution and unequal segregation of cell-fate determinants. Unequal segregation of cell-fate determinants requires that the mother cell becomes polarised prior to mitosis. In response to this polarisation, cell-fate determinants localise asymmetrically and the mitotic spindle lines up with the pole to which cell-fate determinants accumulate, thereby leading to their unequal partitioning upon cytokinesis. I review here the regulatory mechanisms that establish cell asymmetry and orient this asymmetry relative to the body axis in the sensory organ lineages of Drosophila.     

Role of Drosophila gene dunc-115 in nervous system

Axonal guidance signals are transduced through growth cone surface receptors to the interior leading to changes of actin dynamics and actin binding proteins, which are critical in determining the outcome of actin cytoskeleton reorganization. We report here the characterization of the Drosophila actin binding protein abLIM/Unc-115 homolog Dunc-115 and its role in the nervous system. Three Dunc-115 isoforms are identified as Dunc-115L, M and S, respectively. While Dunc-115L is a canonical homolog of Unc-115 with four LIM domains and one villin headpiece domain, Dunc-115M and S are novel isoforms without counterparts in other species. Our molecular modeling shows Dunc-115L is likely to bind to actin. Mutant analysis reveals that Dunc-115 is involved in axonal projection in both the visual and central nervous system.     

Guidance receptor degradation is required for neuronal connectivity in the Drosophila nervous system

Axon pathfinding and synapse formation rely on precise spatiotemporal localization of guidance receptors. However, little is known about the neuron-specific intracellular trafficking mechanisms that underlie the sorting and activity of these receptors. Here we show that loss of the neuron-specific v-ATPase subunit a1 leads to progressive endosomal guidance receptor accumulations after neuronal differentiation. In the embryo and in adult photoreceptors, these accumulations occur after axon pathfinding and synapse formation is complete. In contrast, receptor missorting occurs sufficiently early in neurons of the adult central nervous system to cause connectivity defects. An increase of guidance receptors, but not of membrane proteins without signaling function, causes specific gain-of-function phenotypes. A point mutant that promotes sorting but prevents degradation reveals spatiotemporally specific guidance receptor turnover and accelerates developmental defects in photoreceptors and embryonic motor neurons. Our findings indicate that a neuron-specific endolysosomal degradation mechanism is part of the cell biological machinery that regulates guidance receptor turnover and signaling.     

Sculpting the nervous system: glial control of neuronal development

Glial cells are not passive spectators during nervous system assembly, rather they are active participants that exert significant control over neuronal development. Well-established roles for glia in shaping the developing nervous system include providing trophic support to neurons, modulating axon pathfinding, and driving nerve fasciculation. Exciting recent studies have revealed additional ways in which glial cells also modulate neurodevelopment. Glial cells regulate the number of neurons at early developmental stages by dynamically influencing neural precursor divisions, and at later stages by promoting neuronal cell death through engulfment. Glia also participate in the fine sculpting of neuronal connections by pruning excess axonal projections, shaping dendritic spines, and secreting multiple factors that promote synapse formation and functional maturation. These recent insights provide further compelling evidence that glial cells, through their diverse cellular actions, are essential contributors to the construction of a functionally mature nervous system.     

The principal neuronal gD-type 3-O-sulfotransferases and their products in central and peripheral nervous system tissues.

Within the nervous system, heparan sulfate (HS) of the cell surface and extracellular matrix influences developmental, physiologic and pathologic processes. HS is a functionally diverse polysaccharide that employs motifs of sulfate groups to selectively bind and modulate various effector proteins. Specific HS activities are modulated by 3-O-sulfated glucosamine residues, which are generated by a family of seven 3-O-sulfotransferases (3-OSTs). Most isoforms we herein designate as gD-type 3-OSTs because they generate HS(gD+), 3-O-sulfated motifs that bind the gD envelope protein of herpes simplex virus 1 (HSV-1) and thereby mediate viral cellular entry. Certain gD-type isoforms are anticipated to modulate neurobiologic events because a Drosophila gD-type 3-OST is essential for a conserved neurogenic signaling pathway regulated by Notch. Information about 3-OST isoforms expressed in the nervous system of mammals is incomplete. Here, we identify the 3-OST isoforms having properties compatible with their participation in neurobiologic events. We show that 3-OST-2 and 3-OST-4 are principal isoforms of brain. We find these are gD-type enzymes, as they produce products similar to a prototypical gD-type isoform, and they can modify HS to generate receptors for HSV-1 entry into cells. Therefore, 3-OST-2 and 3-OST-4 catalyze modifications similar or identical to those made by the Drosophila gD-type 3-OST that has a role in regulating Notch signaling. We also find that 3-OST-2 and 3-OST-4 are the predominant isoforms expressed in neurons of the trigeminal ganglion, and 3-OST-2/4-type 3-O-sulfated residues occur in this ganglion and in select brain regions. Thus, 3-OST-2 and 3-OST-4 are the major neural gD-type 3-OSTs, and so are prime candidates for participating in HS-dependent neurobiologic events.