The degradation of ␣II-and II-spectrin during apoptosis in cultured human neuroblastoma SH-SY5Y cells was investigated. Immunofluorescent staining showed that the collapse of the cortical spectrin cytoskeleton is an early event following staurosporine challenge. This collapse correlated with the generation of a series of prominent spectrin breakdown products (BDPs) derived from both ␣II-and II-subunits. Major C-terminal ␣II-spectrin BDPs were detected at Ϸ150, 145, and 120 kDa (␣II-BDP150, ␣II-BDP145, and ␣II-BDP120, respectively); major C-terminal II-spectrin BDPs were at Ϸ110 and 85 kDa (II-BDP110 and II-BDP85, respectively). N-terminal sequencing of the major fragments produced in vitro by caspase 3 revealed that ␣II-BDP150 and ␣II-BDP120 were generated by cleavages at DETD 1185 *S 1186 and DSLD 1478 *S 1479 , respectively. For II-spectrin, a major caspase site was detected at DEVD 1457 *S
1458, and both II-BDP110 and II-BDP85 shared a common N-terminal sequence starting with Ser 1458 . An additional cleavage site near the C terminus, at ETVD 2146 *S 2147 , was found to account for II-BDP85. Studies using specific caspase or calpain inhibitors indicate that the pattern of spectrin breakdown during apoptosis differs from that during non-apoptotic cell death. We postulate that in concert with calpain, caspase rapidly targets critical sites in both ␣II-and II-spectrin and thereby initiates a rapid dissolution of the spectrin-actin cortical cytoskeleton with apoptosis.The importance of proteases in the expression of mammalian apoptosis has been the subject of many recent studies. The mammalian interleukin-1-converting enzyme (ICE) 1 -like protease family (renamed caspase (1) (5), and its deletion by gene knockout blocks neuronal death during brain development with consequential lethality (6). Besides the caspases, a second family of proteases implicated in the initiation and control of apoptosis are the calpains (7, 8), especially in several hematopoietic and neuronal cells (9 -12). The relationship between these two protease families, the consequences of each on their respective substrates and on cellular physiology, or the conditions under which each is activated remain poorly understood. While many proteins are cleaved during apoptosis, a prominent target of both calpain and caspase action is ␣II-spectrin, the major component of the cortical membrane skeleton. In neurons, calcium-activated calpain cleavage of ␣II-spectrin (non-erythroid ␣-spectrin or ␣-fodrin) accompanies N-methyl-D-aspartic acid receptor activation (13), 2 does not directly cause neuronal toxicity (7,15), and is postulated to be necessary for synaptic and neuronal plasticity (16 -18). Indeed, ␣II-spectrin cleavage by calpain appears to be a molecular mechanism by which skeletal plasticity can be enhanced without complete dissolution of the spectrin skeleton since calpain-mediated cleavage of ␣II-spectrin bestows calmodulin regulation on oligomeric spectrin-actin complexes, but does not dissociate them (unless II-spectrin is also c...
