Regulation of exocytosis in chromaffin cells by phosducin-like protein, a protein interacting with G protein betagamma subunits

Splice isoforms of phosducin-like protein control the expression of heterotrimeric G proteins

Heterotrimeric G proteins play an essential role in cellular signaling; however, the mechanism regulating their synthesis and assembly remains poorly understood. A line of evidence indicates that the posttranslational processing of G protein β subunits begins inside the protein-folding chamber of the chaperonin containing t-complex protein 1. This process is facilitated by the ubiquitously expressed phosducin-like protein (PhLP), which is thought to act as a CCT co-factor. Here we demonstrate that alternative splicing of the PhLP gene gives rise to a transcript encoding a truncated, short protein (PhLPs) that is broadly expressed in human tissues but absent in mice. Seeking to elucidate the function of PhLPs, we expressed this protein in the rod photoreceptors of mice and found that this manipulation caused a dramatic translational and posttranslational suppression of rod heterotrimeric G proteins. The investigation of the underlying mechanism revealed that PhLPs disrupts the folding of Gβ and the assembly of Gβ and Gγ subunits, events normally assisted by PhLP, by forming a stable and apparently inactive tertiary complex with CCT preloaded with nascent Gβ. As a result, the cellular levels of Gβ and Gγ, which depends on Gβ for stability, decline. In addition, PhLPs evokes a profound and rather specific down-regulation of the Gα transcript, leading to a complete disappearance of the protein. This study provides the first evidence of a generic mechanism, whereby the splicing of the PhLP gene could potentially and efficiently regulate the cellular levels of heterotrimeric G proteins.

Disruption of the chaperonin containing TCP-1 function affects protein networks essential for rod outer segment morphogenesis and survival

Type II Chaperonin Containing TCP-1 (CCT, also known as TCP-1 Ring Complex, TRiC) is a multi-subunit molecular machine thought to assist in the folding of ∼ 10% of newly translated cytosolic proteins in eukaryotes. A number of proteins folded by CCT have been identified in yeast and cultured mammalian cells, however, the function of this chaperonin in vivo has never been addressed. Here we demonstrate that suppressing the CCT activity in mouse photoreceptors by transgenic expression of a dominant-negative mutant of the CCT cofactor, phosducin-like protein (PhLP), results in the malformation of the outer segment, a cellular compartment responsible for light detection, and triggers rapid retinal degeneration. Investigation of the underlying causes by quantitative proteomics identified distinct protein networks, encompassing ∼ 200 proteins, which were significantly affected by the chaperonin deficiency. Notably among those were several essential proteins crucially engaged in structural support and visual signaling of the outer segment such as peripherin 2, Rom1, rhodopsin, transducin, and PDE6. These data for the first time demonstrate that normal CCT function is ultimately required for the morphogenesis and survival of sensory neurons of the retina, and suggest the chaperonin CCT deficiency as a potential, yet unexplored, cause of neurodegenerative diseases.

Mechanism of assembly of G protein betagamma subunits by protein kinase CK2-phosphorylated phosducin-like protein and the cytosolic chaperonin complex

Phosducin-like protein (PhLP) is a widely expressed binding partner of the G protein betagamma subunit complex (Gbetagamma) that has been recently shown to catalyze the formation of the Gbetagamma dimer from its nascent polypeptides. Phosphorylation of PhLP at one or more of three consecutive serines (Ser-18, Ser-19, and Ser-20) is necessary for Gbetagamma dimer formation and is believed to be mediated by the protein kinase CK2. Moreover, several lines of evidence suggest that the cytosolic chaperonin complex (CCT) may work in concert with PhLP in the Gbetagamma-assembly process. The results reported here delineate a mechanism for Gbetagamma assembly in which a stable ternary complex is formed between PhLP, the nascent Gbeta subunit, and CCT that does not include Ggamma. PhLP phosphorylation permits the release of a PhLP x Gbeta intermediate from CCT, allowing Ggamma to associate with Gbeta in this intermediate complex. Subsequent interaction of Gbetagamma with membranes releases PhLP for another round of assembly.

Regulation of neuroendocrine exocytosis by the ARF6 GTPase-activating protein GIT1

Neuroendocrine cells release hormones and neuropeptides by exocytosis, a highly regulated process in which secretory granules fuse with the plasma membrane to release their contents in response to a calcium trigger. Using chromaffin and PC12 cells, we have recently described that the granule-associated GTPase ARF6 plays a crucial role in exocytosis by activating phospholipase D1 at the plasma membrane and, presumably, promoting the fusion reaction between the two membrane bilayers. ARF6 is activated by the nucleotide exchange factor ARNO following docking of granules to the plasma membrane. We show here that GIT1, a GTPase-activating protein stimulating GTP hydrolysis on ARF6, is the second molecular partner that turns over the GDP/GTP cycle of ARF6 during cell stimulation. Western blot and immunofluorescence experiments indicated that GIT1 is cytosolic in resting cells but is recruited to the plasma membrane in stimulated cells, where it co-localizes with ARF6 at the granule docking sites. Over-expression of wild-type GIT1 inhibits growth hormone secretion from PC12 cells; this inhibitory effect was not observed in cells expressing a GIT1 mutant impaired in its ARF-GTPase-activating protein (GAP) activity or in cells expressing other ARF6-GAPs. Conversely reduction of GIT1 by RNA interference increased the exocytotic activity. Using a real time assay for individual chromaffin cells, we found that microinjection of GIT1 strongly reduced the number of exocytotic events. These results provide the first evidence that GIT1 plays a function in calcium-regulated exocytosis in neuroendocrine cells. We propose that GIT1 represents part of the pathway that inactivates ARF6-dependent reactions and thereby negatively regulates and/or terminates exocytotic release.

Phosducin-like Protein Regulates G-Protein βγ Folding by Interaction with Tailless Complex Polypeptide-1α

Phosducin-like protein (PhLP) exists in two splice variants PhLP(LONG) (PhLP(L)) and PhLP(SHORT) (PhLP(S)). Whereas PhLP(L) directly inhibits Gbetagamma-stimulated signaling, the G betagamma-inhibitory mechanism of PhLP(S) is not understood. We report here that inhibition of Gbetagamma signaling in intact HEK cells by PhLP(S) was independent of direct Gbetagamma binding; however, PhLP(S) caused down-regulation of Gbeta and Ggamma proteins. The down-regulation was partially suppressed by lactacystine, indicating the involvement of proteasomal degradation. N-terminal fusion of Gbeta or Ggamma with a dye-labeling protein resulted in their stabilization against down-regulation by PhLP(S) but did not lead to a functional rescue. Moreover, in the presence of PhLP(S), stabilized Ggamma subunits did not coprecipitate with stabilized Gbeta subunits, suggesting that PhLP(S) might interfere with Gbetagamma folding. PhLP(S) and several truncated mutants of PhLP(S) interacted with the subunit tailless complex polypeptide-1alpha (TCP-1alpha) of the CCT chaperonin complex, which is involved in protein folding. Knock-down of TCP-1alpha in HEK cells by small interfering RNA also led to down-regulation of Gbetagamma. We therefore conclude that the strong inhibitory action of PhLP(S) on Gbetagamma signaling is the result of a previously unrecognized mechanism of Gbetagamma-regulation, inhibition of Gbetagamma-folding by interference with TCP-1alpha.

Role of the isoprenyl pocket of the G protein beta gamma subunit complex in the binding of phosducin and phosducin-like protein

Phosducin (Pdc) and phosducin-like protein (PhLP) regulate G protein-mediated signaling by binding to the betagamma subunit complex of heterotrimeric G proteins (Gbetagamma) and removing the dimer from cell membranes. The binding of Pdc induces a conformational change in the beta-propeller structure of Gbetagamma, creating a pocket between blades 6 and 7. It has been proposed that the isoprenyl group of Gbetagamma inserts into this pocket, stabilizing the Pdc.Gbetagamma structure and decreasing the affinity of the complex for the lipid bilayer. To test this hypothesis, the binding of Pdc and PhLP to several Gbetagamma dimers containing variants of the beta or gamma subunit was measured. These variants included modifications of the isoprenyl group (gamma), residues involved in the conformational change (beta), and residues lining the proposed prenyl pocket (beta). Switching prenyl groups from farnesyl to geranylgeranyl or vice versa had little effect on binding. However, alanine substitution of one residue in the beta subunit involved in the conformational change (W332) decreased binding 5-fold. Alanine substitution of certain residues within the prenyl pocket caused only minor decreases in binding, while a lysine substitution of T329 within the pocket inhibited binding 10-fold. Molecular modeling of the binding energy of the Pdc.Gbeta(1)gamma(2) complex required insertion of the geranylgeranyl group into the prenyl pocket in order to accurately predict the effects of prenyl pocket amino acid substitutions. Finally, a dimer containing a gamma subunit with no prenyl group (gamma(2)-C68S) decreased binding by nearly 20-fold. These results support the structural model in which the prenyl group escapes contact with the aqueous milieu by inserting into the prenyl pocket and stabilizing the Pdc-binding conformation of Gbetagamma.

Regulation of phosducin-like protein by casein kinase 2 and N-terminal splicing

Phosducin-like protein (PhLP) is a member of the phosducin family of G-protein betagamma-regulators and exists in two splice variants. The long isoform PhLP(L) and the short isoform PhLP(S) differ by the presence or absence of an 83-amino acid N terminus. In isolated biochemical assay systems, PhLP(L) is the more potent Gbetagamma-inhibitor, whereas the functional role of PhLP(S) is still unclear. We now report that in intact HEK 293 cells, PhLP(S) inhibited Gbetagamma-induced inositol phosphate generation with approximately 20-fold greater potency than PhLP(L). Radiolabeling of transfected HEK 293 cells with [(32)P] revealed that PhLP(L) is constitutively phosphorylated, whereas PhLP(S) is not. Because PhLP(L) has several consensus sites for the constitutively active kinase casein kinase 2 (CK2) in its N terminus, we tested the phosphorylation of the recombinant proteins by either HEK cell cytosol in the presence or absence of kinase inhibitors or by purified CK2. PhLP(L) was a good CK2 substrate, whereas PhLP(S) and phosducin were not. Progressive truncation and serine/threonine to alanine mutations of the PhLP(L) N terminus identified a serine/threonine cluster (Ser-18/Thr-19/Ser-20) within a small N-terminal region of PhLP(L) (amino acids 5-28) as the site in which PhLP(L) function was modified in HEK 293 cells. In native tissue, PhLP(L) also seems to be regulated by phosphorylation because phosphorylated and non-phosphorylated forms of PhLP(L) were detected in mouse brain and adrenal gland. Moreover, the alternatively spliced isoform PhLP(S) was also found in adrenal tissue. Therefore, the physiological control of G-protein regulation by PhLP seems to involve phosphorylation by CK2 and alternative splicing of the regulator.

Calcium-regulated exocytosis of dense-core vesicles requires the activation of ADP-ribosylation factor (ARF)6 by ARF nucleotide binding site opener at the plasma membrane

The ADP ribosylation factor (ARF) GTP binding proteins are believed to mediate cytoskeletal remodeling and vesicular trafficking along the secretory pathway. Here we show that ARF6 is specifically associated with dense-core secretory granules in neuroendocrine PC12 cells. Stimulation with a secretagogue triggers the recruitment of secretory granules to the cell periphery and the concomitant activation of ARF6 by the plasma membrane-associated guanine nucleotide exchange factor, ARF nucleotide binding site opener (ARNO). Expression of the constitutively inactive ARF6(T27N) mutant inhibits secretagogue-dependent exocytosis from PC12 cells. Using a mutant of ARF6 specifically impaired for PLD1 stimulation, we find that ARF6 is functionally linked to phospholipase D (PLD)1 in the exocytotic machinery. Finally, we show that ARNO, ARF6, and PLD1 colocalize at sites of exocytosis, and we demonstrate direct interaction between ARF6 and PLD1 in stimulated cells. Together, these results provide the first direct evidence that ARF6 plays a role in calcium-regulated exocytosis in neuroendocrine cells, and suggest that ARF6-stimulated PLD1 activation at the plasma membrane and consequent changes in membrane phospholipid composition are critical for formation of the exocytotic fusion pore.