Presenilins are integral membrane protein involved in the production of amyloid -protein. Mutations of the presenilin-1 and -2 gene are associated with familial Alzheimer's disease and are thought to alter ␥-secretase cleavage of the -amyloid precursor protein, leading to increased production of longer and more amyloidogenic forms of A, the 4-kDa -peptide. Here, we show that radiolabeled ␥-secretase inhibitors bind to mammalian cell membranes, and a benzophenone analog specifically photocross-links three major membrane polypeptides. A positive correlation is observed among these compounds for inhibition of cellular A formation, inhibition of membrane binding and cross-linking. Immunological techniques establish N-and C-terminal fragments of presenilin-1 as specifically cross-linked polypeptides. Furthermore, binding of ␥-secretase inhibitors to embryonic membranes derived from presenilin-1 knockout embryos is reduced in a gene dose-dependent manner. In addition, C-terminal fragments of presenilin-2 are specifically cross-linked. Taken together, these results indicate that potent and selective ␥-secretase inhibitors block A formation by binding to presenilin-1 and -2.-Amyloid precursor protein (APP) 1 is a transmembrane protein that undergoes processing to A by proteolytic activities known as -and ␥-secretases (for review, see Refs. 1-3). The -secretase cleavage occurs in the extracellular domain by a recently identified aspartyl protease variously termed BACE, memapsin, and Asp2 (4 -9), whereas the heterogeneous ␥-secretase cleavage occurs in the transmembrane domain (2, 10). Dominant mutations in either of the two human presenilin (PS-1 and PS-2) genes lead to familial Alzheimer's disease (AD). PS-1 and -2 are polytopic membrane proteins (for review, see Refs. 11-13). Presenilins are proteolytic processed. In vivo, only small amounts of the holoprotein can be detected, primarily in the nuclear envelope, whereas 30-kDa N-terminal and 20-kDa C-terminal fragments of presenilin are observed in all mammalian tissues and cell lines analyzed so far. Coimmunoprecipitation experiments revealed that presenilin fragments are assembled into a high molecular weight complex together with other proteins (for review see 11-13). The proposed mechanism through which the presenilin mutations cause AD is an alteration in the predominant ␥-secretase cleavage site which increases the amount of the longer, more amyloidogenic A 1-42(43) fragments produced (11-13). A null mutation of the mouse PS-1 selectively reduces ␥-secretase activity (14), and site-directed mutagenesis of PS-1 and PS-2 at two conserved aspartyl residues, which resemble the catalytic center of aspartyl proteases, also reduces ␥-secretase activity (15, 16). These observations indicate that PS-1 and PS-2 either stimulate the activity of ␥-secretase by trafficking to appropriate cellular compartments, serve as cofactors of the ␥-secretase, or are ␥-secretase themselves.Here, we report that a series of potent and selective ␥-secretase inhibitors bind to mam...
Molecular cloning efforts have provided primary amino acid sequence and signal transduction data for a large collection of serotonin receptor subtypes. These include five 5‐HT1‐like receptors, three 5‐HT2 receptors, one 5‐HT3 receptor, two 5‐HT5 receptors, one 5‐HT6 receptor and one 5‐HT7 receptor. Molecular biological information on the 5‐HT4 receptor is notably absent from this list. We now report the cloning of the pharmacologically defined 5‐HT4 receptor. Using degenerate oligonucleotide primers, we identified a rat brain PCR fragment which encoded a ‘5‐HT receptor‐like’ amino acid sequence. The corresponding full length cDNA was isolated from a rat brain cDNA library. Transiently expressed in COS‐7 cells, this receptor stimulates adenylyl cyclase activity and is sensitive to the benzamide derivative cisapride. The response is also blocked by ICS‐205930. Interestingly, we isolated two splice variants of the receptor, 5‐HT4L and 5‐HT4S, differing in the length and sequence of their C‐termini. In rat brain, the 5‐HT4S transcripts are restricted to the striatum, but the 5‐HT4L transcripts are expressed throughout the brain, except in the cerebellum where it was barely detectable. In peripheral tissues, differential expression was also observed in the atrium of the heart where only the 5‐HT4S isoform was detectable.
A rapid methof for preparation of membrane fractions highly enriched in nicotinic acetylcholine receptor from Torpedo californica electroplax is described. The major step in this purification involves sucrose-density-gradient centrifugation in a reorienting rotor. Further purification of these membranes can be achieved by selective extraction of proteins by use of alkaline pH or by treatment with solutions of lithium di-idosalicylate. The alkali-treated membranes retain functional characteristics of the untreated membranes and in addition contain essentially only the four polypeptides (mol.wts. 40000, 50000, 60000 and 65000) characteristic of the receptor purified by affinity chromatography. Dissolution of the purified membranes or of the alkali-treated purified membranes in sodium cholate solution followed by sucrose-density-gradient centrifugation in the same detergent solution yields solubilized receptor preparations comparable with the most highly purified protein obtained by affinity-chromatographic procedures.
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