Snare protein expression and adenoviral transfection of amphicrine AR42J.

The amphicrine AR42J acinar cell line is an excellent model to study both exocrine and neuroendocrine exocytotic mechanisms. As a first step toward this goal, we determined the specific isoforms of the v- and t-SNARE and Munc18 families expressed in these cells. In addition, we show that dexamethasone-induced differentiation toward the exocrine phenotype causes an upregulation of several of these proteins. AR42J is notoriously difficult to transfect, limiting its usefulness as a model. However, we have now overcome this obstacle by acheiving high efficiency expression of a beta-galactosidase reporter gene and truncated SNAP-25 gene using adenoviral infection techniques. The AR42J cells can now be used to pursue and elucidate the distinct functions of individual SNARE isoforms used in endocrine and exocrine secretion within a single cell line.     

SNAP-25 inhibits L-type Ca2+ channels in feline esophagus smooth muscle cells

We recently reported that non-secretory gastrointestinal smooth muscle cells also possessed SNARE proteins, of which SNAP-25 regulated Ca(2+)-activated (K(Ca)) and delayed rectifier K(+) channels (K(V)). Voltage-gated, long lasting (L-type) calcium channels (L(Ca)) play an important role in excitation-contraction coupling of smooth muscle. Here, we show that SNAP-25 could also directly inhibit the L-type Ca(2+) channels in feline esophageal smooth muscle cells at the SNARE complex binding synprint site. SNARE proteins could therefore regulate additional cell actions other than membrane fusion and secretion, in particular, coordinated muscle membrane excitability and contraction, through their actions on membrane Ca(2+) and K(+) channels.     

Alcohol/cholecystokinin-evoked pancreatic acinar basolateral exocytosis is mediated by protein kinase C alpha phosphorylation of Munc18c

The pancreatic acinus is the functional unit of the exocrine pancreas whose role is to secrete zymogens into the gut lumen for food digestion via apical exocytosis. We previously reported that supramaximal CCK induced apical blockade and redirected exocytosis to ectopic sites on the basolateral plasma membrane (BPM) of this polarized cell, leading to pancreatitis. Basolateral exocytosis was mediated by protein kinase C phosphorylation of BPM Munc18c, causing its displacement into the cytosol and activation of BPM-bound Syntaxin-4 to form a SNARE complex. To mimic the conditions of alcoholic pancreatitis, we now examined whether 20 mm alcohol followed by submaximal CCK might mimic supramaximal CCK in inducing these pathologic exocytotic events. We show that a non-secretory but clinically relevant alcohol concentration (20 mm) inhibited submaximal CCK (50 pM)-stimulated amylase secretion by blocking apical exocytosis and redirecting exocytosis to less efficient BPM, indeed mimicking supramaximal CCK (10 nM) stimulation. We further demonstrate that basolateral exocytosis caused by both stimulation protocols is mediated by PKC alpha-induced phosphorylation of Munc18c: 1) PKC alpha is activated, which binds and induces phosphorylation of PM-Munc18c at a Thr site, and these events can be inhibited by PKC alpha blockade; 2) PKC alpha inhibition blocks Munc18c displacement from the BPM; 3) PKC alpha inhibition prevents basolateral exocytosis but does not rescue apical exocytosis. We conclude that 20 mm alcohol/submaximal CCK as well supramaximal CCK stimulation can trigger pathologic basolateral exocytosis in pancreatic acinar cells via PKC alpha-mediated activation of Munc18c, which enables Syntaxin-4 to become receptive in forming a SNARE complex in the BPM; and we further postulate this to be an underlying mechanism contributing to alcoholic pancreatitis.     

Modulation of the K(v)4.3 channel by syntaxin 1A

The SNARE protein syntaxin 1A (Syn1A) is known to inhibit delayed rectifier K(+) channels of the K(v)1 and K(v)2 families with heterogeneous effects on their gating properties. In this study, we explored whether Syn1A could directly modulate K(v)4.3, a rapidly inactivating K(v) channel with important roles in neuroendocrine cells and cardiac myocytes. Immunoprecipitation studies in HEK293 cells coexpressing Syn1A and K(v)4.3 revealed a direct interaction with increased trafficking to the plasma membrane without a change in channel synthesis. Paradoxically, Syn1A inhibited K(v)4.3 current density. In particular, Syn1A produced a left-shift in steady-state inactivation of K(v)4.3 without affecting either voltage dependence of activation or gating kinetics, a pattern distinct from other K(v) channels. Combined with our previous reports, our results further verify the notion that the mechanisms involved in Syn1A-K(v) interactions vary significantly between K(v) channels, thus providing a wide scope for Syn1A modulation of exocytosis and membrane excitability.     

Synaptosome-associated protein of 25 kilodaltons modulates Kv2.1 voltage-dependent K(+) channels in neuroendocrine islet beta-cells through an interaction with the channel N terminus

Insulin secretion is initiated by ionic events involving membrane depolarization and Ca(2+) entry, whereas exocytic SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) proteins mediate exocytosis itself. In the present study, we characterize the interaction of the SNARE protein SNAP-25 (synaptosome-associated protein of 25 kDa) with the beta-cell voltage-dependent K(+) channel Kv2.1. Expression of Kv2.1, SNAP-25, and syntaxin 1A was detected in human islet lysates by Western blot, and coimmunoprecipitation studies showed that heterologously expressed SNAP-25 and syntaxin 1A associate with Kv2.1. SNAP-25 reduced currents from recombinant Kv2.1 channels by approximately 70% without affecting channel localization. This inhibitory effect could be partially alleviated by codialysis of a Kv2.1N-terminal peptide that can bind in vitro SNAP-25, but not the Kv2.1C-terminal peptide. Similarly, SNAP-25 blocked voltage-dependent outward K(+) currents from rat beta-cells by approximately 40%, an effect that was completely reversed by codialysis of the Kv2.1N fragment. Finally, SNAP-25 had no effect on outward K(+) currents in beta-cells where Kv2.1 channels had been functionally knocked out using a dominant-negative approach, indicating that the interaction is specific to Kv2.1 channels as compared with other beta-cell Kv channels. This study demonstrates that SNAP-25 can regulate Kv2.1 through an interaction at the channel N terminus and supports the hypothesis that SNARE proteins modulate secretion through their involvement in regulation of membrane ion channels in addition to exocytic membrane fusion.     

Progesterone Receptor Membrane Component 1 Is a Functional Part of the Glucagon-like Peptide-1 (GLP-1) Receptor Complex in Pancreatic β Cells

Glucagon-like peptide-1 (GLP-1) is an incretin hormone that regulates glucose homeostasis. Because of their direct stimulation of insulin secretion from pancreatic β cells, GLP-1 receptor (GLP-1R) agonists are now important therapeutic options for the treatment of type 2 diabetes. To better understand the mechanisms that control the insulinotropic actions of GLP-1, affinity purification and mass spectrometry (AP-MS) were employed to uncover potential proteins that functionally interact with the GLP-1R. AP-MS performed on Chinese hamster ovary cells or MIN6 β cells, both expressing the human GLP-1R, revealed 99 proteins potentially associated with the GLP-1R. Three novel GLP-1R interactors (PGRMC1, Rab5b, and Rab5c) were further validated through co-immunoprecipitation/immunoblotting, fluorescence resonance energy transfer, and immunofluorescence. Functional studies revealed that overexpression of PGRMC1, a novel cell surface receptor that associated with liganded GLP-1R, enhanced GLP-1-induced insulin secretion (GIIS) with the most robust effect. Knockdown of PGRMC1 in β cells decreased GIIS, indicative of positive interaction with GLP-1R. To gain insight mechanistically, we demonstrated that the cell surface PGRMC1 ligand P4-BSA increased GIIS, whereas its antagonist AG-205 decreased GIIS. It was then found that PGRMC1 increased GLP-1-induced cAMP accumulation. PGRMC1 activation and GIIS induced by P4-BSA could be blocked by inhibition of adenylyl cyclase/EPAC signaling or the EGF receptor–PI3K signal transduction pathway. These data reveal a dual mechanism for PGRMC1-increased GIIS mediated through cAMP and EGF receptor signaling. In conclusion, we identified several novel GLP-1R interacting proteins. PGRMC1 expressed on the cell surface of β cells was shown to interact with the activated GLP-1R to enhance the insulinotropic actions of GLP-1.Glucagon-like peptide-1 (GLP-1)¹ is a gastrointestinal hormone secreted by intestinal L cells upon food intake that is best known for its role in controlling glucose homeostasis. Acting through its cognate glucagon-like peptide-1 receptor (GLP-1R), GLP-1 has several important physiological and pharmacological functions. GLP-1 is best known for enhancing glucose-stimulated insulin secretion (GSIS) from the pancreatic β cells. Importantly, the insulinotropic properties of GLP-1 are maintained in patients with type 2 diabetes (1), which is characterized by insufficient insulin secretion from pancreatic β cells and an inability to maintain glucose homeostasis. Therefore, therapeutic strategies targeting GLP-1R have been developed to treat type 2 diabetes (2, 3). In addition to augmenting insulin secretion, GLP-1 has been known to improve glucose sensing, proinsulin biosynthesis, survival, and proliferation of β cells (3, 4) in a variety of experimental models. GLP-1 also has several extrapancreatic effects, including actions on the central nervous system to inhibit food intake (5), the stomach to decrease gastric emptying and gastric acid secretion (6), and the lungs to stimulate secretion of macromolecules from airways (7). Additionally, GLP-1 has an effect on the heart and possibly the kidney to modulate blood pressure and heart rate (8, 9).The GLP-1R is a member of the B1 family of G protein–coupled receptors (secretin receptor family). In mammals, GLP-1R is expressed in multiple tissues, including pancreatic β cells and δ cells (10), hypothalamus, lung, stomach, heart, kidney (11), and thyroid (12), which in part explains its diverse actions. Upon ligand binding, the GLP-1R is capable of coupling to diverse cell signal transduction pathways, but it is best known for its actions on G protein Gs α and adenylate cyclase activity to increase intracellular cAMP. It is known that other proteins can affect GLP-1R activity in addition to G proteins, including β-arrestin and caveolin, which affect receptor internalization and trafficking. β-Arrestin 1 is also required for proper GLP-1-stimulated cAMP production (13–15). More recently, it was shown that another B1 family member, gastric inhibitory polypeptide receptor heterodimerizes with GLP-1R, decreasing GLP-1-induced β-arrestin recruitment and mobilization (16). Very recently, our group identified several novel potential GLP-1R interactors using a membrane-based split-ubiquitin yeast two-hybrid (MYTH) assay (17). Three β cell–expressing membrane-bound interactors, solute carrier family 15 member 4 (SLC15A4), amyloid β A4 precursor-like protein 1 (APLP1), and adaptor-related protein complex 2 subunit mu (AP2M1), were further selected for individual knockdown in mouse insulinoma (MIN6) β cells using small interfering RNAs (siRNAs). GLP-1-induced insulin secretion was significantly enhanced when these genes were silenced, suggesting that these interactor proteins attenuate GLP-1R activity. These findings demonstrated that GLP-1R protein interactions are complex and the interactors can have measurable effects on receptor trafficking and downstream signaling. Such interactions may in part explain the diverse tissue-specific effects of GLP-1 and offer avenues for controlling GLP-1 actions in a tissue-selective manner.Although the MYTH system is well established (18) and has been applied to study G protein–coupled receptor interactomes (17), it is limited on two fronts. Firstly, it must be performed in yeast which is not an ideal representation of the mammalian system. Secondly, it is technically difficult to activate the receptor in MYTH, thus, effects of ligand stimulation on the receptor interactome cannot be assessed. Recently, affinity purification–mass spectrometry (AP-MS) has become a powerful tool for discovering and examining novel protein–protein interactions, including those between membrane-bound proteins in mammalian cells (19–21). In the current study, we applied AP-MS to discover novel GLP-1R interactors and employed a human GLP-1R harboring a FLAG^® epitope. GLP-1R-Flag was expressed in either Chinese hamster ovary (CHO) cells or MIN6 β cells, and interactors were studied in the presence or absence of GLP-1.