Fasciclin 2 engages EGFR in an auto-stimulatory loop to promote imaginal disc cell proliferation in Drosophila.

How cell to cell interactions control local tissue growth to attain a species-specific organ size is a central question in developmental biology. The Drosophila Neural Cell Adhesion Molecule, Fasciclin 2, is expressed during the development of neural and epithelial organs. Fasciclin 2 is a homophilic-interaction protein that shows moderate levels of expression in the proliferating epithelia and high levels in the differentiating non-proliferative cells of imaginal discs. Genetic interactions and mosaic analyses reveal a cell autonomous requirement of Fasciclin 2 to promote cell proliferation in imaginal discs. This function is mediated by the EGFR, and indirectly involves the JNK and Hippo signaling pathways. We further show that Fasciclin 2 physically interacts with EGFR and that, in turn, EGFR activity promotes the cell autonomous expression of Fasciclin 2 during imaginal disc growth. We propose that this auto-stimulatory loop between EGFR and Fasciclin 2 is at the core of a cell to cell interaction mechanism that controls the amount of intercalary growth in imaginal discs.

Cross-talk between P2X4 and gamma-aminobutyric acid, type A receptors determines synaptic efficacy at a central synapse.

The essence of neuronal function is to generate outputs in response to synaptic potentials. Synaptic integration at postsynaptic sites determines neuronal outputs in the CNS. Using immunohistochemical and electrophysiological approaches, we first reveal that steroidogenic factor 1 (SF-1) green fluorescent protein (GFP)-positive neurons in the ventromedial nucleus of the hypothalamus express P2X4 subunits that are activated by exogenous ATP. Increased membrane expression of P2X4 channels by using a peptide competing with P2X4 intracellular endocytosis motif enhances neuronal excitability of SF-1 GFP-positive neurons. This increased excitability is inhibited by a P2X receptor antagonist. Furthermore, increased surface P2X4 receptor expression significantly decreases the frequency and the amplitude of GABAergic postsynaptic currents of SF-1 GFP-positive neurons. Co-immunopurification and pulldown assays reveal that P2X4 receptors complex with aminobutyric acid, type A (GABA(A)) receptors and demonstrate that two amino acids in the carboxyl tail of the P2X4 subunit are crucial for its physical association with GABA(A) receptors. Mutation of these two residues prevents the physical association, thereby blocking cross-inhibition between P2X4 and GABA(A) receptors. Moreover, disruption of the physical coupling using competitive peptides containing the identified motif abolishes current inhibition between P2X4 and GABA(A) receptors in recombinant system and P2X4 receptor-mediated GABAergic depression in SF-1 GFP-positive neurons. Our present work thus provides evidence for cross-talk between excitatory and inhibitory receptors that appears to be crucial in determining GABAergic synaptic strength at a central synapse.

Regulation of ASIC activity by ASIC4--new insights into ASIC channel function revealed by a yeast two-hybrid assay.

ASIC4 is a member of the acid-sensing ion channel family that is broadly expressed in the mammalian nervous system, but has no known function. We demonstrate here that transfected ASIC4 is targeted to the plasma membrane in CHO-K1 cells, where it associates with ASIC1a and downregulates exogenous ASIC1a expression. This effect could also be observed on endogenous H+-gated currents in TSA-201 cells and ASIC3 currents in CHO-K1 cells, suggesting a physiological role for ASIC4 in regulating ASIC currents involved in pain mechanisms. Using a yeast two-hybrid assay we found that ASICs interact with proteins involved in diverse functions, including cytoskeletal proteins, enzymes, regulators of endocytosis and G-protein-coupled pathways. ASIC4 is the sole member of this ion channel class to interact strongly with polyubiquitin. The distinct functionally related sets of interacting proteins that bind individual ASICs identified in the yeast two-hybrid screen suggest potential roles for ASICs in a variety of cellular functions.

Annexin II light chain p11 promotes functional expression of acid-sensing ion channel ASIC1a.

Acid-sensing ion channels (ASICs) have been implicated in a wide variety of physiological functions. We have used a rat dorsal root ganglion cDNA library in a yeast two-hybrid assay to identify sensory neuron proteins that interact with ASICs. We found that annexin II light chain p11 physically interacts with the N terminus of ASIC1a, but not other ASIC isoforms. Immunoprecipitation studies confirmed an interaction between p11 and ASIC1 in rat dorsal root ganglion neurons in vivo. Coexpression of p11 and ASIC1a in CHO-K1 cells led to a 2-fold increase in expression of the ion channel at the cell membrane as determined by membrane-associated immunoreactivity and cell-surface biotinylation. Consistent with these findings, peak ASIC1a currents in transfected CHO-K1 cells were up-regulated 2-fold in the presence of p11, whereas ASIC3-mediated currents were unaffected by p11 expression. Neither the pH dependence of activation nor the rates of desensitization were altered by p11, suggesting that its primary role in regulating ASIC1a activity is to enhance cell-surface expression of ASIC1a. These data demonstrate that p11, already known to traffic members of the voltage-gated sodium and potassium channel families as well as transient receptor potential and chloride channels, also plays a selective role in enhancing ASIC1a functional expression.

Ion channel activities implicated in pathological pain.

Altered expression of voltage-gated sodium, calcium and potassium channels has been associated with neuropathic pain conditions. In addition, roles for the ligand-gated P2X3 and NMDA receptors, as well as pacemaker HCN channels have also been invoked in the pathogenesis of neuropathic pain. In this chapter, evidence of an important role for post-translational regulation of Nav1.9 in setting pain thresholds is presented. Despite the importance of tactile allodynia and mechanical hyperalgesia in chronic pain, we remain ignorant of the molecular nature of mechanosensors present in sensory neurons. A number of candidate mechanosensor genes, identified because of their structural similarity with mechanosensors in Caenorbabditis elegans and Drosophila melanogaster have been identified. Acid-sensing ion channels (ASICs) are structurally related to putative mechanosensors in C. elegans, whilst transient receptor potential channels (TRPs) have been implicated in mechanosensation in the Drosophila acoustic system. Evidence against a role for ASICs as primary transducers of mechanosensation is provided here, and recent evidence implicating TRP channels is reviewed. Finally, the use of sensory neuron-specific gene deletion approaches to unravel the significance of individual ion channels in the regulation of sensory neuron excitability and the induction of pain will be described.