Novel processing of Notch 1 within its intracellular domain by a cysteine protease

In order to study N1 processing, we expressed human N1 (hN1) in HEK293 cells (293-hN1). Following Western blot analysis of 293-hN1 extracts, we detected, in addition to full-length hN1 and the N1 extracellular domain truncated form (N1-TM), a novel extracellular domain truncated form of hN1 with a COOH-terminal deletion, designated hN1-TMΔCT. Treatment of cells with the γ-secretase inhibitor L-685,458 resulted in an accumulation of hN1-TMΔCT suggesting that this fragment is a γ-secretase substrate. To identify the proteolytic activity(ies) that generates hN1-TMΔCT, we treated 293-hN1 cells with inhibitors of proteasome, calpains, caspases, serine and cysteine proteases. Despite the presence of a caspase-3 cleavage site within hN1 intracellular domain, none of the caspase inhibitors inhibited hN1-TMΔCT production. The proteasomal inhibitors used had also no effect. Incubation of cells with the cysteine protease inhibitor E64d resulted in the accumulation of hN1-TM and the inhibition of hN1-TMΔCT production suggesting a precursor-product relationship and that a cysteine protease is involved. Similarly, treatment of cells expressing amyloid precursor protein or E-cadherin with E-64d resulted in the accumulation of COOH-terminal fragments suggesting that these proteins are also processed within their intracellular domain by a cysteine protease. Processing towards hN1-TMΔCT requires maturation and transport of hN1 to the cell surface since treatment with brefeldin A inhibited its production and resulted in accumulation of hN1. Processing of hN1 within its intracellular domain could generate fragments that can exert novel functions and/or interfere with the function of hN1 intracellular domain. Copyright © 2007 S. Karger AG

Release of nontransmembrane full-length Alzheimer's amyloid precursor protein from the lumenar surface of chromaffin granule membranes

We previously demonstrated the presence of a soluble form of full- length Alzheimer's amyloid precursor protein (APP) in the lumen of adrenal medullary chromaffin granules (CG). Furthermore, full-length APP is released from CG membranes in vitro at pH 9.0 by an enzymatic mechanism, sensitive to protease inhibitors [Vassilacopoulou et al. (1995) J. Neurochem. 64, 2140- 2146]. In this study, we found that when intact CG were subjected to exogenous trypsin, a fraction of APP was not digested, consistent with an intragranular population of APP. To examine the substrate-product relationship between membrane and soluble full-length APP, we labeled CG transmembrane APP with 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine ([125I]TID), a lipophilic probe, specific for membrane-spanning domains of proteins. APP released from the membranes at pH 9.0 was not labeled with [125I]TID. In addition, this APP was not biotinylated in intact CG. Combined, the results indicate that APP released from CG membranes derives from a unique nontransmembrane population of membrane-associated APP, located in the lumenal side of CG membranes. Dithiobis(succinimidylpropionate) (DSP) cross-linking indicated that APP in CG is situated in close proximity with other proteins, possibly with APP itself. APP complexes were also detected under nonreducing conditions, without DSP cross-linking. These results, combined with our previous studies, indicate that full-length APP within CG exists as three different populations: (I) transmembrane, (II) membrane- associated/nontransmembrane, and (III) soluble. The existence of nontransmembrane populations suggests that putative γ-secretase cleavage sites of APP, assumed to be buried within the lipid bilayer, could be accessible to proteolysis in a soluble intravesicular environment