225-LB: Targeting ß-Cell Endoplasmic Reticulum (ER) TALK-1 Channels to Restore Ca2+ Homeostasis and Reduce ER Stress in Diabetes

Abstract

Perturbations in Ca2+ homeostasis contribute to β-cell failure in diabetes, limiting insulin secretion and exacerbating hyperglycemia. TALK-1 is the most islet-restricted and most abundantly expressed K+ channel of the β-cell. ER TALK-1 channels provide K+ countercurrent for [Ca2+]ER release, thereby tuning [Ca2+]ER storage and release. During β-cell Ca2+ influx, TALK-1-enhanced [Ca2+]ER release leads to activation of the hyperpolarizing Ca2+ activated K+ channels, thus increasing the silent phase duration between Ca2+ oscillations. A gain-of-function mutation in TALK-1(L114P) causes MODY, by disrupting cytoplasmic and ER Ca2+ handling. However, the ability to probe ER TALK-1 channels as a therapeutic target to normalize β-cell Ca2+ handling and reduce ER stress in diabetes has not been determined. Here, using a high throughput fluorescence-based thallium (TI+) flux assay (z’ =0.64) in a TALK-1 overexpression cell line, we identified 80 TALK-1 selective inhibitors from a small molecule library of 50,000 compounds. 4 potent inhibitors that also inhibited the ER membrane TALK-1 channels were identified by monitoring cyclopiazonic acid-induced [Ca2+]ER release (e.g. K2P16-i7(IC50=5.3μM); 63.36% [Ca2+]ER recovery, p-value=0.02). We also tested these inhibitors for their efficacy in controlling mouse islet [Ca2+]ER storage as well as cytosolic Ca2+ oscillations. TALK-1 inhibitors significantly increased islet [Ca2+]ER storage and Ca2+ oscillation frequency (e.g.K2P16-i7; [Ca2+]ER AUC=60.9a.u., peaks/min=0.45 vs. DMSO; [Ca2+]ER AUC=49.7a.u., peaks/min= 0.17, p-value<0.05). Importantly, the inhibitors did not alter [Ca2+]ER and glucose-stimulated Ca2+ oscillation frequency in TALK-1 KO islets. In summary, we have identified the first ER TALK-1 selective inhibitors that can not only be utilized to assess the role of TALK-1 in human β-cell Ca2+ handling and GSIS, but also potentially reduce ER dysfunction during diabetes pathogenesis. Disclosure A. Y. Nakhe: None. P. Dadi: None. D. Westover: None. E. Days: None. J. Denton: None. D. Jacobson: None.