Thomas F, Wu J, Contreras J L, Smyth C, Bilbao G, He J, Thomas J
Division of Transplantation, Department of Surgery, University of Alabama Medical Center, Birmingham, AL 35294-0012, USA.
Surgery. 2001 Aug;130(2):333-8. doi: 10.1067/msy.2001.116413.
This study examines the mechanisms of early isolated islet apoptosis (II-APO) and loss of functional islet mass.
Rhesus islets were isolated for transplantation, and an aliquot was used for in vitro molecular studies of II-APO. These studies used Western blotting to examine caspase activation and perinuclear envelope protein cleavage that are associated with II-APO and used immunofluorescence analysis of Annexin V and mitochondrial permeability index to examine spontaneous and tripartite anoikis-like (TRAIL) mechanism--induced II-APO.
Caspase 6 was prominently activated in association with spontaneous II-APO, which occurred after overnight culture. In contrast, caspase 7, 8, and 9 were not activated. Cleavage of focal adhesion kinase and Lamin, substrates of caspase 6, was also evident in spontaneous II-APO. II-APO was exaggerated by the addition of the TRAIL mechanism. The TRAIL mechanism--induced II-APO was blocked by the caspase 6 inhibitor, VEID, and by the soluble fusion proteins, DR4 or DR5, which act as decoy receptors. In vivo studies in diabetic severe combined immunodeficiency disease mice showed that rhesus islets were cytoprotected by either ex vivo gene transfer of Bcl-2 or treatment of the isolated islet with VEID.
These studies suggest 3 major mechanisms involved in II-APO: caspase 6 activation, a TRAIL-induced apoptosis pathway, and the mitochondrial-associated apoptosis pathway. Inhibition of these II-APO pathways may improve isolated islet survival and reduce functional islet mass loss, which compromises the stable reversal of diabetes.
本研究探讨早期孤立胰岛凋亡(II-APO)及功能性胰岛团块丢失的机制。
分离恒河猴胰岛用于移植,取一份用于II-APO的体外分子研究。这些研究采用蛋白质免疫印迹法检测与II-APO相关的半胱天冬酶激活及核周包膜蛋白裂解,并采用膜联蛋白V免疫荧光分析和线粒体通透性指数检测自发性及三方失巢凋亡样(TRAIL)机制诱导的II-APO。
半胱天冬酶6在过夜培养后发生的自发性II-APO中显著激活。相比之下,半胱天冬酶7、8和9未被激活。在自发性II-APO中,粘着斑激酶和层粘连蛋白(半胱天冬酶6的底物)的裂解也很明显。添加TRAIL机制会加剧II-APO。TRAIL机制诱导的II-APO被半胱天冬酶6抑制剂VEID以及作为诱饵受体的可溶性融合蛋白DR4或DR5阻断。对糖尿病重症联合免疫缺陷病小鼠的体内研究表明,恒河猴胰岛通过Bcl-2的体外基因转移或用VEID处理分离的胰岛而得到细胞保护。
这些研究提示II-APO涉及3种主要机制:半胱天冬酶6激活、TRAIL诱导的凋亡途径和线粒体相关凋亡途径。抑制这些II-APO途径可能会提高孤立胰岛的存活率并减少功能性胰岛团块丢失,而功能性胰岛团块丢失会损害糖尿病的稳定逆转。
