Persyn, a member of the synuclein family, has a distinct pattern of expression in the developing nervous system

The synucleins are a unique family of small intracellular proteins that have recently attracted considerable attention because of their involvement in human neurodegenerative diseases. We have cloned a new member of the synuclein family called persyn. In contrast to other synucleins, which are presynaptic proteins of CNS neurons, persyn is a cytosolic protein that is expressed predominantly in the cell bodies and axons of primary sensory neurons, sympathetic neurons, and motoneurons. Northern blotting, in situ hybridization, Western blotting, and immunohistochemistry revealed that persyn mRNA and protein are expressed in these neurons from the earliest stages of axonal outgrowth and are maintained at a high level throughout life. Persyn also becomes detectable in evolutionary recent regions of the brain by adulthood.     

Distinct morphogenetic functions of similar small GTPases: Drosophila Drac1 is involved in axonal outgrowth and myoblast fusion

The small GTPases of the Rac/Rho/Cdc42 subfamily are implicated in actin cytoskeleton-membrane interaction in mammalian cells and budding yeast. The in vivo functions of these GTPases in multicellular organisms are not known. We have cloned Drosophila homologs of rac and CDC42, Drac1, and Dcdc42. They share 70% amino acid sequence identity with each other, and both are highly expressed in the nervous system and mesoderm during neuronal and muscle differentiation, respectively. We expressed putative constitutively active and dominant-negative Drac1 proteins in these tissues. When expressed in neurons, Drac1 mutant proteins cause axon outgrowth defects in peripheral neurons without affecting dendrites. When expressed in muscle precursors, they cause complete failure of, or abnormality in, myoblast fusion. Expressions of analogous mutant Dcdc42 proteins cause qualitatively distinct morphological defects, suggesting that similar GTPases in the same subfamily have unique roles in morphogenesis.     

Genetic analysis on the role of integrin during axon guidance in Drosophila

Heterodimeric cell surface receptor integrin is widely expressed in the nervous system, but its specific role during axon development has not been directly tested in vivo. We show that the Drosophila nervous system expresses low levels of positron-specific (PS) integrin subunits alphaPS1, alphaPS2, and betaPS during embryonic axogenesis. Furthermore, certain subsets of neurons express higher levels of integrin mRNAs than do the rest. Null mutations in either the alphaPS1 or alphaPS2 subunit gene cause widespread axon pathfinding errors that can be rescued by supplying the wild-type integrin subunit to the mutant nervous system. In contrast, misexpressing either the alphaPS1 or alphaPS2 integrin subunit in all neurons leads to no obvious axon pathfinding errors. We propose that integrin does not itself serve as either a "clutch" constituting molecule or a specific growth cone "receptor," as proposed previously, but rather as part of a molecular network that cooperatively guarantees accurate axon guidance.     

A novel cdc2-related protein kinase expressed in the nervous system

We report the cloning and characterization of a cDNA encoding a cdc2-related protein kinase, named PFTAIRE, that is expressed primarily in the postnatal and adult nervous system. We have demonstrated by in situ hybridization and indirect immunofluorescence that several populations of terminally differentiated neurons and some neuroglia expressed PFTAIRE mRNA and protein. In neurons, PFTAIRE protein was localized in the nucleus and cytoplasm of cell bodies. The anatomical, cellular, and ontogenic patterns of PFTAIRE expression in the nervous system differed from those of p34cdc2 and cdk5, which are expressed in brain and several other mitotic tissues. Proteins of approximately 58-60 kDa coprecipitated specifically with PFTAIRE from cytosolic protein preparations of adult mouse brain and transfected cells. These proteins appeared to be the major endogenous substrates associated with this kinase activity. The temporal and spatial expression patterns of PFTAIRE in the postnatal and adult nervous system suggest that PFTAIRE kinase activity may be associated with the postmitotic and differentiated state of cells in the nervous system and that its function may be distinct from those of p34cdc2 and cdk5.     

Expression of two neuronal markers, growth-associated protein 43 and neuron-specific enolase, in rat glial cells

Recent studies have revealed that proteins such as growth-associated protein 43 (GAP-43) and neuron-specific enolase (NSE), believed for many years to be expressed exclusively in neurons, are also present in glial cells under some circumstances. Here we present an overview of these observations. GAP-43 is expressed both in vitro and in vivo transiently in immature rat oligodendroglial cells of the central nervous system, in Schwann cell precursors, and in non-myelin-forming Schwann cells of the peripheral nervous system. GAP-43 mRNA is also present in oligodendroglial cells and Schwann cells, indicating that GAP-43 is synthesized in these cells. GAP-43 is also expressed in type 2 astrocytes (stellate-shaped astrocytes) and in some reactive astrocytes but not in type 1 astrocytes (flat protoplasmic astrocytes). These results suggest that GAP-43 plays a more general role in neural plasticity during development of the central and peripheral nervous systems. NSE enzymatic activity and protein and mRNA have been detected in rat cultured oligodendrocytes at levels comparable to those of cultured neurons. NSE expression increases during the differentiation of oligodendrocyte precursors into oligodendrocytes. In vivo, NSE protein is expressed in differentiating oligodendrocytes and is repressed in fully mature adult cells. The upregulation of NSE in differentiating oligodendrocytes coincides with the formation of large amounts of membrane structures and of protoplasmic processes. Similarly, NSE becomes detectable in glial neoplasms and reactive glial cells at the time when these cells undergo morphological changes. The expression of the glycolytic isozyme NSE in these cells, which do not normally contain it, could reflect a response to higher energy demands. This expression may also be related to the neurotrophic and neuroprotective properties demonstrated for this enolase isoform. NSE activity and protein and mRNA have also been found in cultured rat type 1-like astrocytes but at much lower levels than in neurons and oligodendrocytes. Thus GAP-43 and NSE should be used with caution as neuron-specific markers in studies of normal and pathological neural development.     

Complementary and overlapping expression of Y1, Y2 and Y5 receptors in the developing and adult mouse nervous system

Neuropeptide Y, a 36 amino acid peptide, mediates its biological effects by activating the Y1, Y2, Y5 and Y6 receptors, which are also receptors for the structurally related peptide YY. Different classes of receptors have been suggested to be involved in different neuropeptide Y functions. In this report, we have characterized the developmental regulation and compared the cellular localization of these receptors in the developing and in the adult central and peripheral nervous systems of the mouse. RNase protection assays revealed that Y1, Y2 and Y5 messenger RNAs were expressed very early in spinal cord, brain, cerebellum and dorsal root ganglion development and were often down-regulated at times corresponding to their acquirement of the adult function in neurotransmission. In situ hybridization of the adult brain showed that Y1 was widely expressed, Y2 displayed a more restricted pattern, Y5 was expressed at very low levels and only in a few brain nuclei and Y6 was not expressed. Virtually all areas containing neurons positive for Y5 also expressed Y1, whereas many Y1-positive cells clearly did not express Y5. In contrast, Y2 was not expressed by the neurons expressing Y1 or Y5. These findings suggest that neuropeptide Y signaling in the brain could be mediated by simultaneous Y1 and Y5 activation. Similar results were also obtained in peripheral sensory neurons. Furthermore, our results suggest that neuropeptide Y/peptide YY receptors play an important role in nervous system development and that selective receptor combinations are responsible for signaling the different effects of neuropeptide Y in the peripheral and central nervous systems.     

Cadherin-6 in the developing mouse brain: expression along restricted connection systems and synaptic localization suggest a potential role in neuronal circuitry

Multiple subtypes of the cadherin homophilic cell-cell adhesion molecule are expressed differentially in developing and mature brains, each being expressed in restricted neuronal groups. Cadherin-6 (cad6) is one of such cadherins. Recent studies of cad6 mRNA expression in the postnatal mouse forebrain showed that it occurs in neurons constituting a specific subset of thalamocortical connections. Here we analyzed the localization of cad6 mRNA as well as its protein in the entire central nervous system and also in cranial ganglia of mice at late embryonic to postnatal stages. Our results showed that cad6 is expressed by a limited population of neurons or their precursors, which are synaptically connected to one another, throughout the perinatal stages, and that this expression delineates restricted neuronal circuits from the central to peripheral nervous systems, which include subpathways of the auditory, somatosensory, solitary, vestibular, and olivocerebellar systems. cad6 proteins were detected in these cad6 mRNA-positive neurons on the surface of their cell bodies or dendrites as well as in the cytoplasm. Confocal microscopic analysis revealed that the cad6 protein distribution overlapped that of synaptotagmin in synapse forming areas, suggesting that homotypic cad6 interactions are involved in synaptic connections between neurons expressing this protein. These findings support the idea that cadherin-mediated cell-cell adhesions take part in specific interneuronal connections.     

Selection of recombinant anti-HuD Fab fragments from a phage display antibody library of a lung cancer patient with paraneoplastic encephalomyelitis

Antibodies against the HuD antigen expressed in small-cell lung cancer (SCLC) cross-react with proteins expressed in neurons of the central and peripheral nervous system and are associated with paraneoplastic encephalomyelitis and sensory neuropathy (PEM/SN). We isolated anti-HuD Fab fragments from an antibody phage display library that was constructed from mRNA of a metastatic lymph node from a patient with SCLC and Pem/SN. Fab GLN495 recognized HuD and other related proteins (HuC and Hel-N1, or Hu antigens) in immunoblots of these recombinant proteins and in immunohistochemical and Western blot analysis of SCLC and neurons. Fab GLN495 inhibited up to 75% of the anti-Hu antibodies of the patient from which it was derived, suggesting that recognizes a dominant epitope in the polyclonal anti-Hu antibody response. Fab GLN495 also competed with anti-Hu sera from most but not all patients with PEM/SN, indicating that the same epitope is recognized by a large subgroup of patients. Human monoclonal anti-HuD antibodies may be useful in diagnosis of HuD expressing tumors and in clarifying the autoimmune etiology of PEM/SN. This study, the first to demonstrate that tumor specific recombinant antibodies can be isolated from metastatic lymph node tissue, shows that this approach may be generally applicable to isolate human antibodies against tumor specific antigens.     

Brain-derived neurotrophic factor promotes the differentiation of various hippocampal nonpyramidal neurons, including Cajal-Retzius cells, in organotypic slice cultures

Brain-derived neurotrophic factor (BDNF) is widely expressed in the central nervous system, where its function is poorly understood. The aim of this study was to investigate the effects of BDNF on the differentiation of hippocampal nonpyramidal neurons using organotypic slice cultures prepared from postnatal rats. The application of BDNF induced an increase in immunostaining for the microtubule-associated protein (MAP)-2 in non-pyramidal neurons of the stratum oriens. BDNF promotes the elongation of the dendrites of these neurons, as demonstrated by analysis after biocytin labeling. Calbindin-D- and calretinin-containing subgroups of nonpyramidal cells in the stratum oriens were responsive to BDNF but not to nerve growth factor, as shown by an increase in the number of neurons immunostained for these proteins. BDNF also induced an increase in neuropeptide Y immunostaining of stratum oriens neurons. In contrast, BDNF had no effect on parvalbumin immunostaining, despite the fact that these cells express the BDNF receptor trkB. In addition, BDNF increased calretinin immunoreactivity in Cajal-Retzius cells situated around the hippocampal fissure. The Cajal-Retzius neurons persisted in slices beyond the time at which they degenerate in vivo. However, BDNF is not required for the survival of these cells, because they also persisted in slices from BDNF knock-out mice. The present results indicate that BDNF exerts an effect on the morphology of stratum oriens nonpyramidal cells and their calcium-binding protein levels. BDNF also regulates the calretinin content of Cajal-Retzius cells but is not necessary for their survival.     

Insulin receptor in Aplysia neurons: characterization, molecular cloning, and modulation of ion currents

We have isolated the cDNA for a tyrosine kinase receptor that is expressed in the nervous system of Aplysia californica and that is similar to the vertebrate insulin receptor. Binding studies and immunocytochemical staining show that the receptor is abundant in the bag cell neurons. Application of vertebrate insulin to clusters of bag cell neurons stimulates the phosphorylation of the receptor on tyrosine residues, and exposure of isolated bag cell neurons to insulin produces an increase in height and a decrease in duration of the action potentials that can be detected within 15-30 min. These effects were not seen with insulin-like growth factor-1. In voltage-clamped neurons, insulin produces an increase in the amplitude of the voltage-dependent Ca2+ current that can be blocked by preincubation with herbimycin A, an inhibitor of tyrosine kinases. Insulin also enhances a delayed K+ current. We suggest that insulin-like peptides regulate the excitability of the bag cell neurons.     

Merlin, the neurofibromatosis type 2 gene product, and beta1 integrin associate in isolated and differentiating Schwann cells

Neurofibromatosis type 2, a disease characterized by the formation of multiple nervous system tumors, especially schwannomas, is caused by mutation in the gene-encoding merlin/schwannomin. The molecular mechanism by which merlin functions as a tumor suppressor is unknown, but is hypothesized to involve plasma membrane and cytoskeleton interaction. Several merlin antibodies were used to study merlin expression, localization, and protein association in primary cultures of rat sensory neurons, Schwann cells (SCs), and SCs grown with neurons (SC/N cultures) before and during differentiation into myelinating cells. Western blot analysis revealed that neurons predominantly expressed a 68-kD protein, but SCs expressed two additional 88- and 120-kD related proteins. Extensive immunological characterization demonstrated that the 88-kD protein shared three domains with the 68-kD merlin protein. Western blot analysis of soluble and insoluble culture fractions demonstrated that the majority of merlin and related proteins were soluble in isolated SCs and undifferentiated SC/N cultures, but became insoluble in myelinating SC/N cultures. Double immunofluorescence staining suggested that merlin translocated from the perinuclear cytoplasm in undifferentiated SCs to the subplasmalemma in differentiating SCs and partially colocalized with beta1 integrin. Finally, beta1 integrin antibody coimmunoprecipitated 68-kD merlin from isolated SC and undifferentiated SC/N cultures, but predominantly the 88-kD protein from differentiating SC/N cultures. Together, these results provide evidence that merlin interacts with beta1 integrin and that merlin localization changes from a cytosolic to cytoskeletal compartment during SC differentiation.     

GFR alpha-4 and the tyrosine kinase Ret form a functional receptor complex for persephin

Glial-cell-line-derived neurotrophic factor (GDNF), neurturin and persephin are structurally related, secreted proteins that are widely expressed in the nervous system and other tissues and promote the survival of a variety of neurons during development. GDNF and neurturin signal through multicomponent receptors that consist of the Ret receptor tyrosine kinase and one of two structurally related glycosyl-phosphatidylinositol (GPI)-linked ligand-binding subunits: GFR alpha-1 is the preferred ligand-binding subunit for GDNF, and GFR alpha-2 is the preferred ligand-binding subunit for neurturin. Two additional members of the GFR alpha family of GPI-linked proteins have recently been cloned: GFR alpha-3 and GFR alpha-4. We have shown that persephin binds efficiently only to GFR alpha-4, and labelled persephin is effectively displaced from cells expressing GFR alpha-4 by persephin but not by GDNF or neurturin. Using microinjection to introduce expression plasmids into cultured neurons, we have also shown that coexpression of Ret with GFR alpha-4, confers a marked survival response to persephin but not to GDNF or neurturin. These results demonstrate that GFR alpha-4 is the ligand-binding subunit for persephin and that persephin, like GDNF and neurturin, also requires Ret for signalling.     

Cooperative function of POU proteins and SOX proteins in glial cells

Glial cells of the oligodendrocyte lineage express several highly related POU proteins including Tst-1/Oct6/SCIP and Brn-1. Tst-1/Oct6/SCIP, but not Brn-1 efficiently cooperated with Sox10, the only SRY box protein so far identified in oligodendrocytes. Here we show that, in addition to Sox10, cells of the oligodendrocyte lineage contain significant amounts of the related SRY box proteins Sox4 and Sox11. During development, Sox11 was strongly expressed in the central nervous system. It was first detected in neural precursors throughout the neuroepithelium. During later stages of neural development, Sox11 was additionally expressed in areas of the brain in which neurons undergo differentiation. In agreement with its expression in neural precursors, Sox11 levels in cells of the oligodendrocyte lineage were high in precursors and down-regulated during terminal differentiation. Outside the nervous system, expression of Sox11 was also detected in the developing limbs, face, and kidneys. Structure function analysis revealed that Sox11 has a strong intrinsic transactivation capacity which is mediated by a transactivation domain in its carboxyl-terminal part. In addition, Sox11 efficiently synergized with Brn-1. Synergy was dependent on binding of both proteins to adjacent DNA elements, and required the presence of the respective transactivation domain in each protein. Our data suggest the existence of a specific code in which POU proteins require specific Sox proteins to exhibit cooperative effects in glial cells.