Ion Channel Contributions to Wing Development in Drosophila melanogaster.

During morphogenesis, cells communicate with each other to shape tissues and organs. Several lines of recent evidence indicate that ion channels play a key role in cellular signaling and tissue morphogenesis. However, little is known about the scope of specific ion-channel types that impinge upon developmental pathways. The Drosophila melanogaster wing is an excellent model in which to address this problem as wing vein patterning is acutely sensitive to changes in developmental pathways. We conducted a screen of 180 ion channels expressed in the wing using loss-of-function mutant and RNAi lines. Here we identify 44 candidates that significantly impacted development of the Drosophila melanogaster wing. Calcium, sodium, potassium, chloride, and ligand-gated cation channels were all identified in our screen, suggesting that a wide variety of ion channel types are important for development. Ion channels belonging to the pickpocket family, the ionotropic receptor family, and the bestrophin family were highly represented among the candidates of our screen. Seven new ion channels with human orthologs that have been implicated in human channelopathies were also identified. Many of the human orthologs of the channels identified in our screen are targets of common general anesthetics, anti-seizure and anti-hypertension drugs, as well as alcohol and nicotine. Our results confirm the importance of ion channels in morphogenesis and identify a number of ion channels that will provide the basis for future studies to understand the role of ion channels in development.

Gαi is required for carvedilol-induced ß1 adrenergic receptor ß-arrestin biased signaling.

The ß1 adrenergic receptor (ß1AR) is recognized as a classical Gαs-coupled receptor. Agonist binding not only initiates G protein-mediated signaling but also signaling through the multifunctional adapter protein ß-arrestin. Some ßAR ligands, such as carvedilol, stimulate ßAR signaling preferentially through ß-arrestin, a concept known as ß-arrestin-biased agonism. Here, we identify a signaling mechanism, unlike that previously known for any Gαs-coupled receptor, whereby carvedilol induces the transition of the ß1AR from a classical Gαs-coupled receptor to a Gαi-coupled receptor stabilizing a distinct receptor conformation to initiate ß-arrestin-mediated signaling. Recruitment of Gαi is not induced by any other ßAR ligand screened, nor is it required for ß-arrestin-bias activated by the ß2AR subtype of the ßAR family. Our findings demonstrate a previously unrecognized role for Gαi in ß1AR signaling and suggest that the concept of ß-arrestin-bias may need to be refined to incorporate the selective bias of receptors towards distinct G protein subtypes.

Inwardly rectifying potassium channels influence Drosophila wing morphogenesis by regulating Dpp release.

Loss of embryonic ion channel function leads to morphological defects, but the underlying reason for these defects remains elusive. Here, we show that inwardly rectifying potassium (Irk) channels regulate release of the Drosophila bone morphogenetic protein Dpp in the developing fly wing and that this is necessary for developmental signaling. Inhibition of Irk channels decreases the incidence of distinct Dpp-GFP release events above baseline fluorescence while leading to a broader distribution of Dpp-GFP. Work by others in different cell types has shown that Irk channels regulate peptide release by modulating membrane potential and calcium levels. We found calcium transients in the developing wing, and inhibition of Irk channels reduces the duration and amplitude of calcium transients. Depolarization with high extracellular potassium evokes Dpp release. Taken together, our data implicate Irk channels as a requirement for regulated release of Dpp, highlighting the importance of the temporal pattern of Dpp presentation for morphogenesis of the wing.

An inwardly rectifying K+ channel is required for patterning.

Mutations that disrupt function of the human inwardly rectifying potassium channel KIR2.1 are associated with the craniofacial and digital defects of Andersen-Tawil Syndrome, but the contribution of Kir channels to development is undefined. Deletion of mouse Kir2.1 also causes cleft palate and digital defects. These defects are strikingly similar to phenotypes that result from disrupted TGFß/BMP signaling. We use Drosophila melanogaster to show that a Kir2.1 homolog, Irk2, affects development by disrupting BMP signaling. Phenotypes of irk2 deficient lines, a mutant irk2 allele, irk2 siRNA and expression of a dominant-negative Irk2 subunit (Irk2DN) all demonstrate that Irk2 function is necessary for development of the adult wing. Compromised Irk2 function causes wing-patterning defects similar to those found when signaling through a Drosophila BMP homolog, Decapentaplegic (Dpp), is disrupted. To determine whether Irk2 plays a role in the Dpp pathway, we generated flies in which both Irk2 and Dpp functions are reduced. Irk2DN phenotypes are enhanced by decreased Dpp signaling. In wild-type flies, Dpp signaling can be detected in stripes along the anterior/posterior boundary of the larval imaginal wing disc. Reducing function of Irk2 with siRNA, an irk2 deletion, or expression of Irk2DN reduces the Dpp signal in the wing disc. As Irk channels contribute to Dpp signaling in flies, a similar role for Kir2.1 in BMP signaling may explain the morphological defects of Andersen-Tawil Syndrome and the Kir2.1 knockout mouse.

Efficient cleavage of Bid and procaspase-7 by caspase-2 at lower pH.

The activity of caspase-2 was examined under varying biochemical conditions with the synthetic and protein substrates, Bid and procaspase-7. The results indicate that it was largely influenced by pH which might be one reason behind the inconsistency for the cleavage of its established substrates during caspase-2-induced apoptosis.

Caspase-2 cleaves DNA fragmentation factor (DFF45)/inhibitor of caspase-activated DNase (ICAD).

To investigate the signal transduction pathway of caspase-2, cell permeable Tat-reverse-caspase-2 was constructed, characterized and utilized for biochemical and cellular studies. It could induce the cell death as early as 2h, and caspase-2-specific VDVADase activity but not other caspase activities including DEVDase and IETDase. Interestingly, nuclear DNA fragmentation occurred and consistently DNA fragmentation factor (DFF45)/Inhibitor of caspase-activated DNase (ICAD) was cleaved inside the cell as well as in vitro, suggesting a role of caspase-2 in nuclear DNA fragmentation.

Both dimerization and interdomain processing are essential for caspase-4 activation.

A subgroup of caspase family of inflammatory caspases (-1, -4, -5, -11, and -12) play important role during cytokine maturation and inflammation but their regulation is not well understood as much as the initiator and effector caspases. Here, the biochemical mechanism of caspase-4 activation is elucidated. With citrate, a well-known kosmotrope to enhance the monomer-dimer transition, caspase-4 was activated approximately 40 times that was comparable with that of caspase-9 ( approximately 75-fold increments). The activation reaction was mainly bimolecular (n=1.67+/-0.04) for monomeric caspase-4. In addition, the interdomain cleavage was also responsible to activate caspase-4 more than 100-fold, again comparable with that of effector caspases where the proteolytic processing is considered as the sole activation mechanism. Thus, caspase-4 shows a novel activation mechanism of the synergism between dimerization and proteolysis that sharply differs from the established activation mechanism of dimerization for initiators and interdomain cleavage for effector caspases.