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In pancreatic islets, formation of β-secretory granule cores involves early proinsulin homohexamerization and subsequent insulin condensation. We examined proinsulin conformational maturation by monitoring accessibility of protein disulfide bonds. Proinsulin disulfides are intact immediately upon synthesis, but are ≥90% sensitive to in vivo reduction with 2 mM dithiothreitol; wash out of dithiothreitol leads to reoxidation, proinsulin transport, and conversion to insulin. With t ∼10 min, newly synthesized proinsulin becomes resistant to disulfide reduction, correlating with endoplasmic reticulum (ER) export. However, inhibition of ER export with brefeldin A blocks acquisition of resistance to reduction, and once proinsulin arrives in the Golgi, it resists reduction despite brefeldin treatment. Moreover, in vivo, resistance of proinsulin disulfides is overcome after increasing dithiothreitol > 10-fold, or in vitro, in islets lysed in a zinc-free, but not a zinc-containing, medium. Employing 30 mM dithiothreitol in vivo, a further decrease in disulfide accessibility is observed following proinsulin conversion to insulin. Incubation of islets with chloroquine or zinc enhances and diminishes accessibility of insulin disulfides, respectively. We hypothesize that two major conformational changes culminating in granule core formation, proinsulin hexamerization and insulin condensation, are sensitive to zinc and occur upon ER exit and arrival in immature secretory granules, respectively. In pancreatic islets, formation of β-secretory granule cores involves early proinsulin homohexamerization and subsequent insulin condensation. We examined proinsulin conformational maturation by monitoring accessibility of protein disulfide bonds. Proinsulin disulfides are intact immediately upon synthesis, but are ≥90% sensitive to in vivo reduction with 2 mM dithiothreitol; wash out of dithiothreitol leads to reoxidation, proinsulin transport, and conversion to insulin. With t ∼10 min, newly synthesized proinsulin becomes resistant to disulfide reduction, correlating with endoplasmic reticulum (ER) export. However, inhibition of ER export with brefeldin A blocks acquisition of resistance to reduction, and once proinsulin arrives in the Golgi, it resists reduction despite brefeldin treatment. Moreover, in vivo, resistance of proinsulin disulfides is overcome after increasing dithiothreitol > 10-fold, or in vitro, in islets lysed in a zinc-free, but not a zinc-containing, medium. Employing 30 mM dithiothreitol in vivo, a further decrease in disulfide accessibility is observed following proinsulin conversion to insulin. Incubation of islets with chloroquine or zinc enhances and diminishes accessibility of insulin disulfides, respectively. We hypothesize that two major conformational changes culminating in granule core formation, proinsulin hexamerization and insulin condensation, are sensitive to zinc and occur upon ER exit and arrival in immature secretory granules, respectively.
Huang et al. (Fri,) studied this question.
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