Dynamic expression of the cell adhesion molecule fasciclin I during embryonic development in Drosophila.

A number of different cell surface glycoproteins expressed in the central nervous system (CNS) have been identified in insects and shown to mediate cell adhesion in tissue culture systems. The fasciclin I protein is expressed on a subset of CNS axon pathways in both grasshopper and Drosophila. It consists of four homologous 150-amino acid domains which are unrelated to other sequences in the current databases, and is tethered to the cell surface by a glycosyl-phosphatidylinositol linkage. In this paper we examine in detail the expression of fasciclin I mRNA and protein during Drosophila embryonic development. We find that fasciclin I is expressed in several distinct patterns at different stages of development. In blastoderm embryos it is briefly localized in a graded pattern. During the germ band extended period its expression evolves through two distinct phases. Fasciclin I mRNA and protein are initially localized in a 14-stripe pattern which corresponds to segmentally repeated patches of neuroepithelial cells and neuroblasts. Expression then becomes confined to CNS and peripheral sensory (PNS) neurons. Fasciclin I is expressed on all PNS neurons, and this expression is stably maintained for several hours. In the CNS, fasciclin I is initially expressed on all commissural axons, but then becomes restricted to specific axon bundles. The early commissural expression pattern is not observed in grasshopper embryos, but the later bundle-specific pattern is very similar to that seen in grasshopper. The existence of an initial phase of expression on all commissural bundles helps to explain the loss-of-commissures phenotype of embryos lacking expression of both fasciclin I and of the D-abl tyrosine kinase. Fasciclin I is also expressed in several nonneural tissues in the embryo.     

Sequence analysis and neuronal expression of fasciclin I in grasshopper and Drosophila

The fasciclin I, II, and III glycoproteins are expressed on different subsets of axon bundles (fascicles) in insect embryos and are thus candidates for surface recognition molecules involved in growth cone guidance. Here we present the sequence of grasshopper fasciclin I and the identification and sequence of the Drosophila fasciclin I homolog. In both species, fasciclin I appears to be an extrinsic membrane protein with a signal sequence but no transmembrane region; the protein comprises four homologous domains of approximately 150 amino acids each. Antibodies against Drosophila fasciclin I reveal that it is expressed on the surface of a subset of commissural axon pathways in the embryonic central nervous system and on all sensory axon pathways in the peripheral nervous system. This pattern of expression is similar to that in grasshopper.     

Fasciclin III: a novel homophilic adhesion molecule in Drosophila

Drosophila fasciclin III is an integral membrane glycoprotein that is expressed on a subset of neurons and fasciculating axons in the developing CNS, as well as in several other tissues during development. Here we report on the isolation of a full-length cDNA encoding an 80 kd form of fasciclin III. We have used this cDNA, under heat shock control, to transfect the relatively nonadhesive Drosophila S2 cell line. Examination of these transfected cells indicates that fasciclin III is capable of mediating adhesion in a homophilic, Ca2+-independent manner. Sequence analysis reveals that fasciclin III encodes a transmembrane protein with no significant homology to any known protein, including the previously characterized families of vertebrate cell adhesion molecules. The distribution of this adhesion molecule on subsets of fasciculating axons and growth cones during Drosophila development suggests that fasciclin III plays a role in growth cone guidance.     

Drosophila fasciclin I is a novel homophilic adhesion molecule that along with fasciclin III can mediate cell sorting

Fasciclin I is a membrane-associated glycoprotein that is regionally expressed on a subset of fasciculating axons during neuronal development in insects; it is expressed on apposing cell surfaces, suggesting a role in specific cell adhesion. In this paper we show that Drosophila fasciclin I is a novel homophilic cell adhesion molecule. When the nonadhesive Drosophila S2 cells are transfected with the fasciclin I cDNA, they form aggregates that are blocked by antisera against fasciclin I. When cells expressing fasciclin I are mixed with cells expressing fasciclin III, another Drosophila homophilic adhesion molecule, the mixture sorts into aggregates homogeneous for either fasciclin I- or fasciclin III-expressing cells. The ability of these two novel adhesion molecules to mediate cell sorting in vitro suggests that they might play a similar role during neuronal development.     

Genetic analysis of growth cone guidance in Drosophila: fasciclin II functions as a neuronal recognition molecule

fasiclin II (fas II), a member of the immunoglobulin superfamily, was previously characterized and cloned in grasshopper. To analyze the function of this molecule, we cloned the Drosophila fas II homolog and generated mutants in the gene. In both grasshopper and Drosophila, fasciclin II is expressed on the MP1 fascicle and a subset of other axon pathways. In fas II mutant Drosophila embryos, the CNS displays no gross phenotype, but the MP1 fascicle fails to develop. The MP1, dMP2, and vMP2 growth cones fail to recognize one another or other axons that normally join the MP1 pathway. During their normal period of axon out-growth, these growth cones stall and do not join any other neighboring pathway. Thus, fasciclin II functions as a neuronal recognition molecule for the MP1 axon pathway. These studies serve as molecular confirmation for the existence of functional labels on specific axon pathways in the developing nervous system.     

Semaphorin-1a acts in concert with the cell adhesion molecules fasciclin II and connectin to regulate axon fasciculation in Drosophila

Semaphorins comprise a large family of phylogenetically conserved secreted and transmembrane glycoproteins, many of which have been implicated in repulsive axon guidance events. The transmembrane semaphorin Sema-1a in Drosophila is expressed on motor axons and is required for the generation of neuromuscular connectivity. Sema-1a can function as an axonal repellent and mediates motor axon defasciculation. Here, by manipulating the levels of Sema-1a and the cell adhesion molecules fasciclin II (Fas II) and connectin (Conn) on motor axons, we provide further evidence that Sema-1a mediates axonal defasciculation events by acting as an axonally localized repellent and that correct motor axon guidance results from a balance between attractive and repulsive guidance cues expressed on motor neurons.     

Expression of fasciclin I and II glycoproteins on subsets of axon pathways during neuronal development in the grasshopper

The "labeled pathways" hypothesis predicts that axon fascicles in the embryonic neuropil are differentially labeled by surface recognition molecules used for growth cone guidance. To identify candidates for such recognition molecules, we generated monoclonal antibodies (MAbs) that recognize surface antigens expressed on subsets of axon fascicles in the grasshopper embryo. The 3B11 and 8C6 MAbs immunoprecipitate 70- and 95-kd membrane glycoproteins called fasciclin I and II, respectively, which are expressed on different subsets of axon fascicles during development. These two glycoproteins are expressed regionally on particular portions of embryonic axons in correlation with their patterns of fasciculation, dynamically during the period of axon outgrowth in a manner consistent with a role in growth cone guidance, and at other times and places during embryogenesis, suggesting multiple developmental roles.     

Genetic analysis of a Drosophila neural cell adhesion molecule: interaction of fasciclin I and Abelson tyrosine kinase mutations

Drosophila fasciclin I is a homophilic cell adhesion molecule expressed in the developing embryo on the surface of a subset of fasciculating CNS axons, all PNS axons, and some nonneuronal cells. We have identified protein-null mutations in the fasciclin I (fas I) gene, and show that these mutants are viable and do not display gross defects in nervous system morphogenesis. The Drosophila Abelson (abl) proto-oncogene homolog encodes a cytoplasmic tyrosine kinase that is expressed during embryogenesis primarily in developing CNS axons; abl mutants show no gross defects in CNS morphogenesis. However, embryos doubly mutant for fas I and abl display major defects in CNS axon pathways, particularly in the commissural tracts where expression of these two proteins normally overlaps. The double mutant shows a clear defect in growth cone guidance; for example, the RP1 growth cone (normally fas I positive) does not follow its normal path across the commissure.     

Drosophila fasciclin I, a neural cell adhesion molecule, has a phosphatidylinositol lipid membrane anchor that is developmentally regulated

Fasciclin I is a homophilic neural cell adhesion molecule which is regionally expressed on a subset of fasciculating axons in both the grasshopper and Drosophila embryo, suggesting a role in axonal recognition. It is also dynamically expressed on a variety of other embryonic tissues. Biochemical analysis of the fasciclin I glycoprotein from Drosophila embryonic membranes and Schneider 1 cells indicates that it is tightly associated with the lipid bilayer by a phosphatidylinositol lipid moiety. In Drosophila embryos a large fraction of fasciclin I protein has lost its membrane anchor. The ratio of this soluble form to the phosphatidylinositol-linked form changes during embryogenesis. We speculate that removal of the phosphatidylinositol lipid from the fasciclin I protein could be a mechanism to regulate its adhesive function.     

A proposed structural model of domain 1 of fasciclin III neural cell adhesion protein based on an inverse folding algorithm.

Fasciclin III is an integral membrane protein expressed on a subset of axons in the developing Drosophila nervous system. It consists of an intracellular domain, a transmembrane region, and an extracellular region composed of three domains, each predicted to form an immunoglobulin-like fold. The most N-terminal of these domains is expected to be important in mediating cell-cell recognition events during nervous system development. To learn more about the structure/function relationships in this cellular recognition molecule, a model structure of this domain was built. A sequence-to-structure alignment algorithm was used to align the protein sequence of the fasciclin III first domain to the immunoglobulin McPC603 structure. Based on this alignment, a model of the domain was built using standard homology modeling techniques. Side-chain conformations were automatically modeled using a rotamer search algorithm and the model was minimized to relax atomic overlaps. The resulting model is compact and has chemical characteristics consistent with related globular protein structures. This model is a de novo test of the sequence-to-structure alignment algorithm and is currently being used as the basis for mutagenesis experiments to discern the parts of the fasciclin III protein that are necessary for homophilic molecular recognition in the developing Drosophila nervous system.     

Fasciclin IV: sequence, expression, and function during growth cone guidance in the grasshopper embryo.

Monoclonal antibody 6F8 was used to characterize and clone fasciclin IV, a new axonal glycoprotein in the grasshopper, and to study its function during growth cone guidance. Fasciclin IV is dynamically expressed on a subset of axon pathways in the developing CNS and on circumferential bands of epithelial cells in developing limb buds. One of these bands corresponds to the location where the growth cones of the Ti1 pioneer neurons make a characteristic turn while extending toward the CNS. Embryos cultured in the 6F8 antibody or Fab exhibit aberrant formation of this axon pathway. cDNA sequence analysis suggests that fasciclin IV has a signal sequence; long extracellular, transmembrane, and short cytoplasmic domains; and shows no homology with any protein in the available data bases. Thus, fasciclin IV appears to be a novel integral membrane protein that functions in growth cone guidance.     

Pathway recognition by neuronal growth cones: genetic analysis of neural cell adhesion molecules in Drosophila.

Genetic analysis has finally come of age in the study of neural cell adhesion molecules and their function during growth cone guidance in Drosophila. Recent studies have shown that fasciclin II, a neural cell adhesion molecule of the immunoglobulin superfamily, functions as a recognition molecule for the MP1 axon pathway, thus serving as the first molecular confirmation for the existence of functional labels on specific axon pathways in the developing organism.     

Notch-mediated segmentation and growth control of the Drosophila leg.

The possession of segmented appendages is a defining characteristic of the arthropods. By analyzing both loss-of-function and ectopic expression experiments, we show that the Notch signaling pathway plays a fundamental role in the segmentation and growth of the Drosophila leg. Local activation of Notch is necessary and sufficient to promote the formation of joints between segments. This segmentation process requires the participation of the Notch ligands, Serrate and Delta, as well as Fringe. These three proteins are each expressed in the developing leg and antennal imaginal discs in a segmentally repeated pattern that is regulated downstream of the action of Wingless and Decapentaplegic. Our studies further show that Notch activation is both necessary and sufficient to promote leg growth. We also identify target genes regulated both positively and negatively downstream of Notch signaling that are required for normal leg development. Together, these observations outline a regulatory hierarchy for the segmentation and growth of the leg. The Notch pathway is also deployed for segmentation during vertebrate somitogenesis, which raises the possibility of a common origin for the segmentation of these distinct tissues.     

Regulation of CNS and motor axon guidance in Drosophila by the receptor tyrosine phosphatase DPTP52F.

Receptor-linked protein tyrosine phosphatases (RPTPs) regulate axon guidance and synaptogenesis in Drosophila embryos and larvae. We describe DPTP52F, the sixth RPTP to be discovered in Drosophila. Our genomic analysis indicates that there are likely to be no additional RPTPs encoded in the fly genome. Five of the six Drosophila RPTPs have C. elegans counterparts, and three of the six are also orthologous to human RPTP subfamilies. DPTP52F, however, has no clear orthologs in other organisms. The DPTP52F extracellular domain contains five fibronectin type III repeats and it has a single phosphatase domain. DPTP52F is selectively expressed in the CNS of late embryos, as are DPTP10D, DLAR, DPTP69D and DPTP99A. To define developmental roles of DPTP52F, we used RNA interference (RNAi)-induced phenotypes as a guide to identify Ptp52F alleles among a collection of EMS-induced lethal mutations. Ptp52F single mutant embryos have axon guidance phenotypes that affect CNS longitudinal tracts. This phenotype is suppressed in Dlar Ptp52F double mutants, indicating that DPTP52F and DLAR interact competitively in regulating CNS axon guidance decisions. Ptp52F single mutations also cause motor axon phenotypes that selectively affect the SNa nerve. DPTP52F, DPTP10D and DPTP69D have partially redundant roles in regulation of guidance decisions made by axons within the ISN and ISNb motor nerves.     

MICALs,a family of conserved flavoprotein oxidoreductases,function in plexin-mediated axonal repulsion

Members of the semaphorin family of secreted and transmembrane proteins utilize plexins as neuronal receptors to signal repulsive axon guidance. It remains unknown how plexin proteins are directly linked to the regulation of cytoskeletal dynamics. Here, we show that Drosophila MICAL, a large, multidomain, cytosolic protein expressed in axons, interacts with the neuronal plexin A (PlexA) receptor and is required for Semaphorin 1a (Sema-1a)-PlexA-mediated repulsive axon guidance. In addition to containing several domains known to interact with cytoskeletal components, MICAL has a flavoprotein monooxygenase domain, the integrity of which is required for Sema-1a-PlexA repulsive axon guidance. Vertebrate orthologs of Drosophila MICAL are neuronally expressed and also interact with vertebrate plexins, and monooxygenase inhibitors abrogate semaphorin-mediated axonal repulsion. These results suggest a novel role for oxidoreductases in repulsive neuronal guidance.     

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.     

CRYP-2: A receptor-type tyrosine phosphatase selectively expressed by developing vertebrate neurons

Axonal growth and guidance, like other aspects of neuronal differentiation, can be regulated by changes in tyrosine phosphorylation. Although much is known concerning the role of tyrosine kinases in these processes, relatively little is known about the nature and function of protein tyrosine phosphatases (PTPs) that may be involved. To identify the PTPs expressed in the embryonic chicken CNS at the time of axon growth, we performed a polymerase chain reaction based “screen” using degenerate primers directed against conserved regions of the PTP catalytic domain. We obtained five distinct PTP-related cDNAs, two of which code for novel PTPs. One, designated CRYP-2, is selectively expressed in the CNS. Full-length cloning of CRYP-2 revealed that it is a receptor-type PTP with an adhesion molecule-like extracellular region comprising fibronectin (FN) type III repeats and a single catalytic domain in the intracellular region. It is alternatively spliced in the juxtamembrane region, similar to other PTPs recently cloned. CRYP-2 mRNA is strongly expressed in the brain during the time of axon growth; it is downregulated toward the end of embryo-genesis. Western blot analysis identifies a 330-kDa glycoprotein as CRYP-2 and confirms that the protein is downregulated after hatching. Immunostaining of cerebellar neurons in vitro reveals that CRYP-2 is expressed on neuronal cell bodies and processes, but not on glia. The CAM-like structure, developmental pattern of expression, and neuron-specific localization of the CRYP-2 PTP suggest that it is involved in neuronal differentiation, particularly axon growth. © 1996 John Wiley & Sons, Inc.