Bih-Hwa Shieh

Regulation of the TRP Ca2+ Channel by INAD in Drosophila Photoreceptors

Drosophila vision involves a G protein-coupled phospholipase C-mediated signaling pathway that leads to membrane depolarization through activation of Na+ and Ca2+ channels. InaD mutant flies have a M442K point mutation and display a slow recovery of the Ca2+ dependent current. We report that anti-INAD antibodies coimmunoprecipitate TRP, identified by its electrophoretic mobility, cross reactivity with anti-TRP antibody, and absence in a null allele trp mutant. This interaction is abolished by the InaD point mutation in vitro and in vivo. Interaction was localized to the 19 amino acid C-terminus of TRP by overlay assays, and to the PDZ domain of INAD, encompassing the point mutation. Given the impaired electrophysiology of the InaD mutant, this novel interaction suggests that INAD functions as a regulatory subunit of the TRP Ca2+ channel.

The cyclophilin homolog ninaA is a tissue-specific integral membrane protein required for the proper synthesis of a subset of Drosophila rhodopsins

Mutations in the Drosophila ninaA gene cause dramatic reductions in rhodopsin levels, leading to impaired visual function. The ninaA protein is a homolog of peptidyl-prolyl cis-trans isomerases. We find that ninaA is unique among this family of proteins in that it is an integral membrane protein, and it is expressed in a cell type-specific manner. We have used transgenic animals misexpressing different rhodopsins in the major class of photoreceptor cells to demonstrate that ninaA is required for normal function by two homologous rhodopsins, but not by a less conserved member of the Drosophila rhodopsin gene family. This demonstrates in vivo substrate specificity in a cyclophilin-like molecule. We also show that vertebrate retina contains a ninaA-related protein and that ninaA is a member of a gene family in Drosophila. These data offer insights into the in vivo role of this important family of proteins.

A NOVEL PROTEIN ENCODED BY THE INAD GENE REGULATES RECOVERY OF VISUAL TRANSDUCTION IN DROSOPHILA

InaDp215 is a point mutation that affects photoreceptor function in Drosophila. To understand the molecular basis of the defect, we isolated the InaD gene and found it encodes a photoreceptor-specific polypeptide of 674 residues. Within its sequence are two repeats that share remarkable homology with a family of cytoskeleton-associated proteins that are involved in signal transduction. Patch-clamp recordings from isolated photoreceptor cells of InaDp215 show a slow deactivation of the light-induced current. This defective deactivation of InaD appears dependent on calcium influx; removal of extracellular calcium masks its abnormal phenotype. Moreover, InaD photoreceptors show increases sensitivity to dim light. We propose that InaD is involved in the negative feedback regulation of the light-activated signaling cascade in Drosophila photoreceptors.

Purification and Molecular Cloning of an 8R-Lipoxygenase from the Coral Plexaura homomalla Reveal the Related Primary Structures of R- and S-Lipoxygenases

Lipoxygenases that form S configuration fatty acid hydroperoxides have been purified or cloned from plant and mammalian sources. Our objectives were to characterize one of the lipoxygenases with R stereospecificity, many of which are described in marine and freshwater invertebrates. Characterization of the primary structure of an R-specific enzyme should help provide a new perspective to consider the enzyme-substrate interactions that are the basis of the specificity of all lipoxygenases. We purified an 8R-lipoxygenase of the prostaglandin-containing coral Plexaura homomalla by cation and anion exchange chromatography. This yielded a colorless enzyme preparation, a band of ∼100 kDa on SDS-polyacrylamide gel electrophoresis, and turnover numbers of 4000 min−1 of 8R-lipoxygenase activity in peak chromatographic fractions. The full-length cDNA was cloned by PCR using peptide sequence from the purified protein and by 5′- and 3′-rapid amplification of cDNA ends. The cDNA encodes a polypeptide of 715 amino acids, including over 70 amino acids identified by peptide microsequencing. A peptide presequence of 52 amino acids is cleaved to give the mature protein of 76 kDa; the difference from the estimated size by SDS-PAGE implies a post-translational modification of the P. homomalla enzyme. All of the iron-binding histidines of S-lipoxygenases are conserved in the 8R-lipoxygenase. However, the C-terminal amino acid is a threonine, as opposed to the isoleucine that provides the carboxylate ligand to the iron in all known S-lipoxygenases. These results establish that the 8R-lipoxygenase is related in primary structure to the S-lipoxygenases. A model of the basis of R and S stereospecificity is described.

Interaction of eye protein kinase C and INAD in Drosophila. Localization of binding domains and electrophysiological characterization of a loss of association in transgenic flies

Drosophila eye-specific protein kinase C (eye-PKC) is involved in light adaptation and deactivation. eye-PKC, NORPA (phospholipase Cβ), and transient-receptor-potential (TRP) (calcium channel) are integral components of a signal transduction complex organized by INAD, a protein containing five PDZ domains. We previously demonstrated the direct association between the third PDZ domain of INAD with TRP in addition to the carboxyl-terminal half of INAD with the last three residues of NORPA. In this work, the molecular interaction between eye-PKC and INAD is defined via the yeast two-hybrid and ligand overlay assays. We show that the second PDZ domain of INAD interacts with the last three residues in the carboxyl-terminal tail of eye-PKC, Thr-Ile-Ile. The association between eye-PKC and INAD is disrupted by an amino acid substitution (Ile-700 to Asp) at the final residue of eye-PKC. In flies lacking endogenous eye-PKC (inaC p215), normal visual physiology is restored upon expression of wild-type eye-PKC, whereas the eye-PKCI700D mutant is completely inactive. Flies homozygous for inaC p209 andInaD p215, a mutation that causes a loss of the INAD-TRP association, were generated. These double mutants display a more severe response inactivation than either of the single mutants. Based on these findings, we conclude that the in vivoactivity of eye-PKC depends on its association with INAD and that the sensitivity of photoreceptors is cooperatively regulated by the presence of both eye-PKC and TRP in the signaling complex.

Scaffolding Protein INAD Regulates Deactivation of Vision by Promoting Phosphorylation of Transient Receptor Potential by Eye Protein Kinase C in Drosophila

Drosophila visual signaling is one of the fastest G-protein-coupled transduction cascades, because effector and modulatory proteins are organized into a macromolecular complex (“transducisome”). Assembly of the complex is orchestrated by inactivation no afterpotential D (INAD), which colocalizes the transient receptor potential (TRP) Ca2+ channel, phospholipase Cβ, and eye protein kinase C (eye-PKC), for more efficient signal transduction. Eye-PKC is critical for deactivation of vision. Moreover, deactivation is regulated by the interaction between INAD and TRP, because abrogation of this interaction in InaDp215 results in slow deactivation similar to that of inaCp209 lacking eye-PKC. To elucidate the mechanisms whereby eye-PKC modulates deactivation, here we demonstrate that eye-PKC, via tethering to INAD, phosphorylates TRP in vitro. We reveal that Ser982 of TRP is phosphorylated by eye-PKC in vitro and, importantly, in the fly eye, as shown by mass spectrometry. Furthermore, transgenic expression of modified TRP bearing an Ala substitution leads to slow deactivation of the visual response similar to that of InaDp215. These results suggest that the INAD macromolecular complex plays an essential role in termination of the light response by promoting efficient phosphorylation at Ser982 of TRP for fast deactivation of the visual signaling.

Acetylcholine receptor synthesis rate and levels of receptor subunit messenger RNAs in chick muscle.

Levels of mRNAs specific for the alpha-, gamma- and delta-subunit of the nicotinic acetylcholine receptor were measured in chick skeletal muscle by solution hybridization, using a genomic DNA probe containing the intramembrane segments M2 and M3 of the alpha-subunit and probes comprising exons 2-6 and exons 4-8, respectively, of the gamma- and delta-subunit. In the innervated calf musculature of adult chickens, receptor-specific messages were detected in approx. 100-fold excess over the amount required to account for the observed synthesis rate. Within 1 week after section of the sciatic nerve, alpha-, gamma- and delta-subunit message levels rose 112-, 42- and 24-fold, respectively, while receptor expression rate increased about 150-fold. The rise in message levels preceded the denervation-induced increase in receptor concentration. In differentiating myogenic cells all three messages were found in excess over the amounts required for the observed rate of receptor synthesis. Treatment of differentiated myotubes with drugs that change receptor synthesis rate selectively affects alpha-subunit mRNA. In all situations in vitro and in vivo the alpha-subunit mRNA was found to reach final levels faster, and to be from 3 to over 30 times more abundant, than the other messages. These observations corroborate earlier evidence for a regulatory mechanism in which the supply of mRNA determines acetylcholine receptor synthesis rate. They also suggest that receptor expression is not simply proportional to acetylcholine receptor subunit mRNA concentrations, but rather is controlled, to a considerable extent, by the efficiency with which the receptor-specific mRNAs and/or the subunits they code for are subsequently utilized.

The second PDZ domain of INAD is a type I domain involved in binding to eye protein kinase C. Mutational analysis and naturally occurring variants.

INAD is a scaffolding protein containing five PSD95/dlg/zonular occludens-1 (PDZ) domains that tether NORPA (phospholipase Cβ4), the TRP calcium channel, and eye-PKC in Drosophila photoreceptors. We previously showed that eye-PKC interacted with the second PDZ domain (PDZ2) of INAD. Sequence comparison with a prototypical type I PDZ domain predicts that PDZ2 is the best candidate among the five PDZ domains to recognize eye-PKC that contains a type I PDZ ligand, Ile-Thr-Ile-Ile, at its carboxyl terminus. Replacement of Ile−3 in eye-PKC with charged residues resulted in a drastic reduction of the PDZ2 interaction. Substitution of a conserved His with Arg at the second α-helix of PDZ2 led to a reduced binding; however, a Leu replacement resulted in an enhanced eye-PKC association. We isolated and sequenced the InaD gene. The coding sequence of InaDcontains nine exons spanning 3 kilobases. Translation of coding sequences from three wild-type alleles revealed three SNPs affecting residues, 282, 319, and 333 of INAD. These polymorphisms are localized in PDZ2. Interestingly, we found two of three PDZ2 variants displayed a greater affinity for eye-PKC. In summary, we evaluated the molecular basis of the eye-PKC and PDZ2 association by mutational analysis and concluded that PDZ2 of INAD is a type I domain important for the eye-PKC interaction.

A unique isoform of phospholipase Cβ4 highly expressed in the cerebellum and eye

We report a unique isoform of PLCbeta4 in rat, PLCbeta4c, that has an additional 37-nucleotide exon inserted between nucleotides 3459-3460 of the previously published PLCbeta4a coding sequence. This insertion results in replacement of 22 amino acid residues at the carboxyl terminal tail of PLCbeta4a with 41 unique residues. A human EST for PLCbeta4 also contains this exon and this exon was mapped to within a 5.5 kb intron of the human PLCbeta4 gene. PLCbeta4c is the third PLCbeta4 isoform to be identified which has a unique carboxyl-terminal tail. PLCbeta4b differs from PLCbeta4a by truncation 162 amino acid residues from the carboxyl terminus which are replaced with 10 distinct amino acid residues. Reverse transcription-polymerase chain reaction experiments show that both PLCbeta4a and PLCbeta4c mRNA are expressed throughout the rat brain and that PLCbeta4c mRNA is highly expressed in the eye and cerebellum. RNase protection assays demonstrate that both PLCbeta4a and PLCbeta4c transcripts are abundant in the cerebellum. The different carboxyl terminal tails of PLCbeta4 isoforms may allow for differential targeting and subcellular localization, contributing to regulation of PLC beta4-mediated signal transduction.

Role of Protein Phosphatase 2A in Regulating the Visual Signaling in Drosophila

Drosophila visual signaling, a G-protein-coupled phospholipase Cβ (PLCβ)-mediated mechanism, is regulated by eye-protein kinase C (PKC) that promotes light adaptation and fast deactivation, most likely via phosphorylation of inactivation no afterpotential D (INAD) and TRP (transient receptor potential). To reveal the critical phosphatases that dephosphorylate INAD, we used several biochemical analyses and identified protein phosphatase 2A (PP2A) as a candidate. Importantly, the catalytic subunit of PP2A, microtubule star (MTS), is copurified with INAD, and an elevated phosphorylation of INAD by eye-PKC was observed in three mts heterozygotes. To explore whether PP2A (MTS) regulates dephosphorylation of INAD by counteracting eye-PKC [INAC (inactivation no afterpotential C] in vivo, we performed ERG recordings. We discovered that inaCP209 was semidominant, because inaCP209 heterozygotes displayed abnormal light adaptation and slow deactivation. Interestingly, the deactivation defect of inaCP209 heterozygotes was rescued by the mtsXE2258 heterozygous background. In contrast, mtsXE2258 failed to modify the severe deactivation of norpAP16, indicating that MTS does not modulate NORPA (no receptor potential A) (PLCβ). Together, our results strongly indicate that dephosphorylation of INAD is catalyzed by PP2A, and a reduction of PP2A can compensate for a partial loss of function in eye-PKC, restoring the fast deactivation kinetics in vivo. We thus propose that the fast deactivation of the visual response is modulated in part by the phosphorylation of INAD.