Requirement of PEN-2 for stabilization of the presenilin N-/C-terminal fragment heterodimer within the gamma-secretase complex

Gamma-secretase is a protease complex composed of presenilin (PS), nicastrin (NCT), APH-1, and PEN-2, which catalyzes intramembrane cleavage of several type I transmembrane proteins including the Alzheimer's disease-associated beta-amyloid precursor protein. We generated stable RNA interference-mediated PEN-2 knockdown cells to probe mutant PEN-2 variants for functional activity. Knockdown of PEN-2 was associated with impaired NCT maturation and deficient PS1 endoproteolysis, which was efficiently rescued by wild type or N-terminally tagged PEN-2 but not by C-terminally tagged PEN-2 or by the C-terminally truncated PEN-2-DeltaC mutant. Although the latter mutants rescued the PS1 holoprotein accumulation associated with the PEN-2 knockdown, they failed to restore normal levels of the PS1 N- and C-terminal fragments and to maturate NCT. PEN-2-DeltaC was highly unstable and rapidly turned over by proteasomal degradation consistent with its failure to become stably incorporated into the gamma-secretase complex. In addition, expression of PEN-2-DeltaC caused a selective instability of the PS1 N-/C-terminal fragment heterodimer that underwent proteasomal degradation, whereas NCT and APH-1 were stable. Interestingly, when we knocked down PEN-2 in the background of the endoproteolysis-deficient PS1 Deltaexon9 mutant, immature NCT still accumulated, demonstrating that PEN-2 is also required for gamma-secretase complex maturation when PS endoproteolysis cannot occur. Taken together, our data suggest that PEN-2 is required for the stabilization of the PS fragment heterodimer within the gamma-secretase complex following PS endoproteolysis. This function critically depends on the PEN-2 C terminus. Moreover, our data show that PEN-2 is generally required for gamma-secretase complex maturation independent of its activity in PS1 endoproteolysis.     

Functional domains in presenilin 1: the Tyr-288 residue controls gamma-secretase activity and endoproteolysis

Processing of the Alzheimer amyloid precursor protein (APP) into the amyloid beta-protein and the APP intracellular domain is a proteolysis event mediated by the gamma-secretase complex where presenilin (PS) proteins are key constituents. PS is subjected to an endoproteolytic cleavage, generating a stable heterodimer composed of an N-terminal and a C-terminal fragment. Here we aimed at further understanding the role of PS in endoproteolysis, in proteolytic processing of APP and Notch, and in assembly of the gamma-secretase complex. By using a truncation protocol and alanine scanning, we identified Tyr-288 in the PS1 N-terminal fragment as critical for PS-dependent intramembrane proteolysis. Further mutagenesis of the 288 site identified mutants differentially affecting endoproteolysis and gamma-secretase activity. The Y288F mutant was endoproteolyzed to the same extent as wild type PS but increased the amyloid beta-protein 42/40 ratio by approximately 75%. In contrast, the Y288N mutant was also endoproteolytically processed but was inactive in reconstituting gamma-secretase in PS null cells. The Y288D mutant was deficient in both endoproteolysis and gamma-secretase activity. All three mutant PS1 molecules were incorporated into gamma-secretase complexes and stabilized Pen-2 in PS null cells. Thus, mutations at Tyr-288 do not affect gamma-secretase complex assembly but can differentially control endoproteolysis and gamma-secretase activity.     

gamma-Secretase complexes containing N- and C-terminal fragments of different presenilin origin retain normal gamma-secretase activity

The gamma-secretase complex processes substrate proteins within membranes and consists of four proteins: presenilin (PS), nicastrin, Aph-1 and Pen-2. PS harbours the enzymatic activity of the complex, and there are two mammalian PS homologues: PS1 and PS2. PS undergoes endoproteolysis, generating the N- and C-terminal fragments, NTF and CTF, which represent the active species of PS. To characterize the functional similarity between complexes of various PS composition, we analysed PS1, PS2, and chimeric PS composed of the NTF from PS1 and CTF from PS2, or vice versa, in assembly and function of the gamma-secretase complex. Chimeric PSs, like PS1 and PS2, undergo normal endoproteolysis when introduced into cells devoid of endogenous PS. Furthermore, PS2 CTF can, at least partially, restore processing in a truncated PS1, which cannot undergo endoproteolysis. All PS forms enable maturation of nicastrin and cleave full length Notch receptors, indicating that both PS1 and PS2 are present at the cell surface. Finally, when co-introduced as separate molecules, NTF and CTF of different PS origin reconstitute gamma-secretase activity. In conclusion, these data show that endoproteolysis, NTF-CTF interactions, and the assembly and activity of gamma-secretase complexes are very conserved between PS1 and PS2.     

Co-expressed presenilin 1 NTF and CTF form functional gamma-secretase complexes in cells devoid of full-length protein

The enzyme gamma-secretase catalyzes the intramembrane proteolytic cleavage that generates the amyloid beta-peptide from the beta-amyloid precursor protein. The presenilin (PS) protein is one of the four integral membrane protein components of the mature gamma-secretase complex. The PS protein is itself subjected to endoproteolytic processing, generating stable N- and C-terminal fragment (NTF and CTF, respectively) heterodimers. Here we demonstrate that coexpression of PS1 NTF and CTF functionally mimics expression of the full-length PS1 protein and restores gamma-secretase activity in PS-deficient mammalian cells. The coexpressed fragments re-associate with each other inside the cell, where they also interact with nicastrin, another gamma-secretase complex component. Analysis of gamma-secretase activity following the expression of mutant forms of NTF and CTF, under conditions bypassing endoproteolysis, indicated that the putatively catalytic Asp257 and Asp385 residues have a direct effect on gamma-secretase activity. Moreover, we demonstrate that expression of the wild-type CTF rescues endoproteolytic cleavage of C-terminally truncated PS1 molecules that are otherwise uncleaved and inactive. Recovery of cleavage is critically dependent on the integrity of Asp385. Taken together, our findings indicate that ectopically expressed NTF and CTF restore functional gamma-secretase complexes and that the presence of full-length PS1 is not a requirement for proper complex assembly.     

C-terminal fragment of presenilin is the molecular target of a dipeptidic gamma-secretase-specific inhibitor DAPT (N-[N-(3,5-difluorophenacetyl)-L-alanyl]-S-phenylglycine t-butyl ester)

Gamma-secretase is a multimeric membrane protein complex composed of presenilin (PS), nicastrin, Aph-1 and, Pen-2 that is responsible for the intramembrane proteolysis of various type I transmembrane proteins, including amyloid beta-precursor protein and Notch. The direct labeling of PS polypeptides by transition-state analogue gamma-secretase inhibitors suggested that PS represents the catalytic center of gamma-secretase. Here we show that one of the major gamma-secretase inhibitors of dipeptidic type, N-[N-(3,5-difluorophenacetyl)-l-alanyl]-S-phenylglycine t-butyl ester (DAPT), targets the C-terminal fragment of PS, especially the transmembrane domain 7 or more C-terminal region, by designing and synthesizing DAP-BpB (N-[N-(3,5-difluorophenacetyl)-l-alanyl]-(S)-phenylglycine-4-(4-(8-biotinamido)octylamino)benzoyl)benzyl)methylamide), a photoactivable DAPT derivative. We also found that DAP-BpB selectively binds to the high molecular weight gamma-secretase complex in an activity-dependent manner. Photolabeling of PS by DAP-BpB is completely blocked by DAPT or its structural relatives (e.g. Compound E) as well as by arylsulfonamides. In contrast, transition-state analogue inhibitor L-685,458 or alpha-helical peptidic inhibitor attenuated the photolabeling of PS1 only at higher concentrations. These data illustrate the DAPT binding site as a novel functional domain within the PS C-terminal fragment that is distinct from the catalytic site or the substrate binding site.     

Different cofactor activities in gamma-secretase assembly: evidence for a nicastrin-Aph-1 subcomplex

The gamma-secretase complex is required for intramembrane cleavage of several integral membrane proteins, including the Notch receptor, where it generates an active signaling fragment. Four putative gamma-secretase components have been identified-presenilin (Psn), nicastrin (Nct), Aph-1, and Pen-2. Here, we use a stepwise coexpression approach to investigate the role of each new component in gamma-secretase assembly and activation. Coexpression of all four proteins leads to high level accumulation of mature Psn and increased proteolysis of Notch. Aph-1 and Nct may form a subcomplex that stabilizes the Psn holoprotein at an early step in gamma-secretase assembly. Subcomplex levels of Aph-1 are down-regulated by stepwise addition of Psn, suggesting that Aph-1 might not enter the mature complex. In contrast, Pen-2 accumulates proportionally with Psn, and is associated with Psn endoproteolysis during gamma-secretase assembly. These results demonstrate that Aph-1 and Pen-2 are essential cofactors for Psn, but that they play different roles in gamma-secretase assembly and activation.     

Detergent-dependent dissociation of active gamma-secretase reveals an interaction between Pen-2 and PS1-NTF and offers a model for subunit organization within the complex

Gamma-secretase is a member of a new class of proteases with an intramembrane catalytic site and cleaves numerous type I membrane proteins, including the amyloid beta-protein precursor (APP) and the Notch receptor. Biochemical and genetic studies have identified four membrane proteins as components of gamma-secretase: a heterodimeric form of presenilin (PS), composed of its N- and C-terminal fragments (PS-NTF and PS-CTF, respectively), a highly glycosylated, mature form of nicastrin (NCT), Aph-1, and Pen-2. However, it is unclear how these components interact physically with each other and assemble into functional complexes. We and others recently found that Aph-1 interacts with a less glycosylated, immature form of nicastrin as an intermediate toward full assembly of gamma-secretase. Here we show that (1) the detergent dodecyl beta-d-maltoside (DDM) mediates the dissociation and inactivation of active gamma-secretase in a concentration-dependent manner, (2) DDM-dependent dissociation of the active gamma-secretase complex generates two major inactive complexes (Pen-2-PS1-NTF and mNCT-Aph-1) and two minor inactive complexes (mNCT-Aph1-PS1-CTF and PS1-NTF-PS1-CTF), and (3) Pen-2 can also associate with the PS holoprotein in complexes devoid of NCT and Aph-1. Taken together, our results demonstrate that Pen-2 interacts with PS-NTF within active gamma-secretase and offer a model for how the components of active gamma-secretase interact physically with each other.     

Length and overall sequence of the PEN-2 C-terminal domain determines its function in the stabilization of presenilin fragments

Gamma-secretase is an aspartyl protease complex that catalyzes the intramembrane cleavage of a subset of type I transmembrane proteins including the beta-amyloid precursor protein (APP) implicated in Alzheimer's disease. Presenilin (PS), nicastrin (NCT), anterior pharynx defective (APH-1) and presenilin enhancer-2 (PEN-2) constitute the active gamma-secretase complex. PEN-2, the smallest subunit, is required for triggering PS endoproteolysis. Stabilization of the resultant N- and C-terminal fragments, which carry the catalytically active site aspartates, but not endoproteolysis itself, requires the C-terminal domain of PEN-2. To functionally dissect the C-terminal domain we created C-terminal deletion mutants and mutagenized several evolutionary highly conserved residues. The PEN-2 mutants were then probed for functional complementation of a PEN-2 knockdown, which displays deficient PS1 endoproteolysis and impaired NCT maturation. Progressive truncation of the C-terminus caused increasing loss of function. This was also observed for an internal deletion mutant as well as for C-terminally tagged PEN-2 with a twofold elongated C-terminal domain. Interestingly, only simultaneous, but not individual substitution of the highly conserved D90, F94, P97 and G99 residues with alanine interfered with PEN-2 function. All loss of function mutants identified allowed PS1 endoproteolysis, but failed to stably associate with the resultant PS1 fragments, which like the PEN-2 loss of function mutants underwent proteasomal degradation. However, complex formation of the PEN-2 mutants with PS1 fragments could be recovered when proteasomal degradation was blocked. Taken together, our data suggest that the PS-subunit stabilizing function of PEN-2 depends on length and overall sequence of its C-terminal domain.     

The gamma-secretase complex: machinery for intramembrane proteolysis

Gamma-secretase is a membrane protease complex that possesses presenilin as a catalytic subunit. Presenilin generates amyloid beta peptides in the brains of Alzheimer's patients and is indispensable to Notch signaling in tissue development and renewal. Recent studies have revealed how presenilin is assembled with its cofactor proteins and acquires the gamma-secretase activity: Aph-1 and nicastrin initially form a subcomplex to bind and stabilize presenilin, and then Pen-2 confers the gamma-secretase activity and facilitates endoproteolysis of presenilin. Understanding the mechanism of gamma-secretase cleavage will help to clarify how intercellular cell signaling through transmembrane proteins is regulated by intramembrane proteolysis, and will hopefully eventually lead to a cure for Alzheimer's disease.     

Reconstitution of gamma-secretase activity

gamma-Secretase is a membrane protein complex with an unusual aspartyl protease activity that catalyses the regulated intramembranous cleavage of the beta-amyloid precursor protein (APP) to release the Alzheimer's disease (AD)-associated amyloid beta-peptide (Abeta) and the APP intracellular domain (AICD). Here we show the reconstitution of gamma-secretase activity in the yeast Saccharomyces cerevisiae, which lacks endogenous gamma-secretase activity. Reconstituted gamma-secretase activity depends on the presence of four complex components including presenilin (PS), nicastrin (Nct), APH-1 (refs 3-6) and PEN-2 (refs 4, 7), is associated with endoproteolysis of PS, and produces Abeta and AICD in vitro. Thus, the biological activity of gamma-secretase is reconstituted by the co-expression of human PS, Nct, APH-1 and PEN-2 in yeast.     

Abeta42 overproduction associated with structural changes in the catalytic pore of gamma-secretase: common effects of Pen-2 N-terminal elongation and fenofibrate

gamma-Secretase is an atypical aspartyl protease that cleaves amyloid beta-precursor protein to generate Abeta peptides that are causative for Alzheimer disease. gamma-Secretase is a multimeric membrane protein complex composed of presenilin (PS), nicastrin, Aph-1, and Pen-2. Pen-2 directly binds to transmembrane domain 4 of PS and confers proteolytic activity on gamma-secretase, although the mechanism of activation and its role in catalysis remain unknown. Here we show that an addition of amino acid residues to the N terminus of Pen-2 specifically increases the generation of Abeta42, the longer and more aggregable species of Abeta. The effect of the N-terminal elongation of Pen-2 on Abeta42 generation was independent of the amino acid sequences, the expression system and the presenilin species. In vitro gamma-secretase assay revealed that Pen-2 directly affects the Abeta42-generating activity of gamma-secretase. The elongation of Pen-2 N terminus caused a reduction in the water accessibility of the luminal side of the catalytic pore of PS1 in a similar manner to that caused by an Abeta42-raising gamma-secretase modulator, fenofibrate, as determined by substituted cysteine accessibility method. These data suggest a unique mechanism of Abeta42 overproduction associated with structural changes in the catalytic pore of presenilins caused commonly by the N-terminal elongation of Pen-2 and fenofibrate.     

Mutation analysis of the presenilin 1 N-terminal domain reveals a broad spectrum of gamma-secretase activity toward amyloid precursor protein and other substrates

The γ-secretase protein complex executes the intramembrane proteolysis of amyloid precursor protein (APP), which releases Alzheimer disease β-amyloid peptide. In addition to APP, γ-secretase also cleaves several other type I membrane protein substrates including Notch1 and N-cadherin. γ-Secretase is made of four integral transmembrane protein subunits: presenilin (PS), nicastrin, APH1, and PEN2. Multiple lines of evidence indicate that a heteromer of PS-derived N- and C-terminal fragments functions as the catalytic subunit of γ-secretase. Only limited information is available on the domains within each subunit involved in the recognition and recruitment of diverse substrates and the transfer of substrates to the catalytic site. Here, we performed mutagenesis of two domains of PS1, namely the first luminal loop domain (LL1) and the second transmembrane domain (TM2), and analyzed PS1 endoproteolysis as well as the catalytic activities of PS1 toward APP, Notch, and N-cadherin. Our results show that distinct residues within LL1 and TM2 domains as well as the length of the LL1 domain are critical for PS1 endoproteolysis, but not for PS1 complex formation with nicastrin, APH1, and PEN2. Furthermore, our experimental PS1 mutants formed γ-secretase complexes with distinct catalytic properties toward the three substrates examined in this study; however, the mutations did not affect PS1 interaction with the substrates. We conclude that the N-terminal LL1 and TM2 domains are critical for PS1 endoproteolysis and the coordination between the putative substrate-docking site and the catalytic core of the γ-secretase.     

Presenilins mediate a dual intramembranous gamma-secretase cleavage of Notch-1

Following ectodomain shedding, Notch-1 undergoes presenilin (PS)-dependent constitutive intramembranous endoproteolysis at site-3. This cleavage is similar to the PS-dependent gamma-secretase cleavage of the beta-amyloid precursor protein (betaAPP). However, topological differences in cleavage resulting in amyloid beta-peptide (Abeta) or the Notch-1 intracellular domain (NICD) indicated independent mechanisms of proteolytic cleavage. We now demonstrate the secretion of an N-terminal Notch-1 Abeta-like fragment (Nbeta). Analysis of Nbeta by MALDI-TOF MS revealed that Nbeta is cleaved at a novel site (site-4, S4) near the middle of the transmembrane domain. Like the corresponding cleavage of betaAPP at position 40 and 42 of the Abeta domain, S4 cleavage is PS dependent. The precision of this cleavage is affected by familial Alzheimer's disease-associated PS1 mutations similar to the pathological endoproteolysis of betaAPP. Considering these similarities between intramembranous processing of Notch and betaAPP, we conclude that these proteins are cleaved by a common mechanism utilizing the same protease, i.e. PS/gamma-secretase.     

Purification and characterization of the human gamma-secretase complex

Gamma-secretase is a member of an unusual class of proteases with intramembrane catalytic sites. This enzyme cleaves many type I membrane proteins, including the amyloid beta-protein (Abeta) precursor (APP) and the Notch receptor. Biochemical and genetic studies have identified four membrane proteins as components of gamma-secretase: heterodimeric presenilin (PS) composed of its N- and C-terminal fragments (PS-NTF/CTF), a mature glycosylated form of nicastrin (NCT), Aph-1, and Pen-2. Recent data from studies in Drosophila, mammalian, and yeast cells suggest that PS, NCT, Aph-1, and Pen-2 are necessary and sufficient to reconstitute gamma-secretase activity. However, many unresolved issues, in particular the possibility of other structural or regulatory components, would be resolved by actually purifying the enzyme. Here, we report a detailed, multistep purification procedure for active gamma-secretase and an initial characterization of the purified protease. Extensive mass spectrometry of the purified proteins strongly suggests that PS-NTF/CTF, mNCT, Aph-1, and Pen-2 are the components of active gamma-secretase. Using the purified gamma-secretase, we describe factors that modulate the production of specific Abeta species: (1) phosphatidylcholine and sphingomyelin dramatically improve activity without changing cleavage specificity within an APP substrate; (2) increasing CHAPSO concentrations from 0.1 to 0.25% yields a approximately 100% increase in Abeta42 production; (3) exposure of an APP-based recombinant substrate to 0.5% SDS modulates cleavage specificity from a disease-mimicking pattern (high Abeta42/43) to a physiological pattern (high Abeta40); and (4) sulindac sulfide directly and preferentially decreases Abeta42 cleavage within the purified complex. Taken together, our results define a procedure for purifying active gamma-secretase and suggest that the lipid-mediated conformation of both enzyme and substrate regulate the production of the potentially neurotoxic Abeta42 and Abeta43 peptides.     

Presenilin endoproteolysis mediated by an aspartyl protease activity pharmacologically distinct from gamma-secretase

Presenilin (PS)-dependent gamma-secretase cleavage is the final proteolytic step in generating amyloid beta protein (A beta), a key peptide involved in the pathogenesis of Alzheimer's disease. PS undergoes endoproteolysis by an unidentified 'presenilinase' to generate the functional N-terminal and C-terminal fragment heterodimers (NTF/CTF) that may harbor the gamma-secretase active site. To better understand the relationship between presenilinase and gamma-secretase, we characterized the biochemical properties of presenilinase and compared them with those of gamma-secretase. Similar to gamma-secretase, presenilinase was most active at acidic pH 6.3. Aspartyl protease inhibitor pepstatin A blocked presenilinase activity with an IC50 of approximately 1 microM. Difluoroketone aspartyl protease transition state analogue MW167 was relatively selective for presenilinase (IC50 < 1 microM) over gamma-secretase (IC50-16 microM). Importantly, removing the transition state mimicking moiety simultaneously abolished both presenilinase and gamma-secretase inhibition, suggesting that presenilinase, like gamma-secretase, is an aspartyl protease. Interestingly, several of the most potent gamma-secretase inhibitors (IC50 = 0.3 or 20 nM) failed to block presenilinase activity. Although de novo generation of PS1 fragments coincided with production of A beta in vitro, blocking presenilinase activity without reducing pre-existing fragment levels permitted normal de novo generation of A beta and amyloid intracellular domain. Therefore, presenilinase has characteristics of an aspartyl protease, but this activity is distinct from gamma-secretase.     

Membrane topology and nicastrin-enhanced endoproteolysis of APH-1, a component of the gamma-secretase complex

APH-1, presenilin, nicastrin, and Pen-2 are proteins with varying membrane topologies that compose the gamma-secretase complex, which is responsible for the intramembrane proteolysis of several substrates including the amyloid precursor protein. APH-1 is known to be necessary for gamma-secretase activity, but its precise function in the complex is not fully understood, and its membrane topology has not been described, although it is predicted to traverse the membrane seven times. To investigate this, we used selective permeabilization of the plasma membrane and immunofluorescence microscopy to show that the C terminus of the APH-1 resides in the cytosolic space. Insertion of N-linked glycosylation sites into each of the hydrophilic loop domains and the N terminus of APH-1 showed that the N-terminal domain as well as loops 2, 4, and 6 could be glycosylated, whereas loops 1, 3, and 5 were not. Thus, APH-1 topologically resembles a seven-transmembrane domain receptor with the N terminus and even-numbered loops facing the endoplasmic reticulum lumen, and the C terminus and odd-numbered loops reside in the cytosolic space. By using these glycosylation mutants, we provide evidence that the association between nicastrin and APH-1 may occur very soon after APH-1 synthesis and that the interaction between these two proteins may rely more heavily on the transmembrane domains of APH-1 than on the loop domains. Furthermore, we found that APH-1 can be processed by several endoproteolytic events. One of these cleavages is strongly up-regulated by co-expression of nicastrin and generates a stable C-terminal fragment that associates with nicastrin.     

PEN-2 enhances gamma-cleavage after presenilin heterodimer formation

The presenilin (PS) complex, including PS, nicastrin, APH-1 and PEN-2, is essential for gamma-secretase activity, which is required for amyloid beta-protein (Abeta) generation. However, the precise individual roles of the three cofactors in the PS complex in Abeta generation remain to be clarified. Here, to distinguish the roles of PS cofactors in gamma-secretase activity from those in PS endoproteolysis, we investigated their roles in the gamma-secretase activity reconstituted by the coexpression of PS N- and C-terminal fragments (NTF and CTF) in PS-null cells. We demonstrate that the coexpression of PS1 NTF and CTF forms the heterodimer and restores Abeta generation in PS-null cells. The generation of Abeta was saturable at a certain expression level of PS1 NTF/CTF, while the overexpression of PEN-2 alone resulted in a further increase in Abeta generation. Although PEN-2 did not enhance PS1 NTF/CTF heterodimer formation, PEN-2 expression reduced the IC50 of a specific gamma-secretase inhibitor, a transition state analogue, for Abeta generation, suggesting that PEN-2 expression enhances the affinity or the accessibility of the substrate to the catalytic site. Thus, our results strongly suggest that PEN-2 is not only an essential component of the gamma-secretase complex but also an enhancer of gamma-cleavage after PS heterodimer formation.     

gamma-Secretase substrate selectivity can be modulated directly via interaction with a nucleotide-binding site

gamma-Secretase is an unusual protease with an intramembrane catalytic site that cleaves many type I membrane proteins, including the amyloid beta-protein (Abeta) precursor (APP) and the Notch receptor. Genetic and biochemical studies have identified four membrane proteins as components of gamma-secretase: heterodimeric presenilin composed of its N- and C-terminal fragments, nicastrin, Aph-1, and Pen-2. Here we demonstrated that certain compounds, including protein kinase inhibitors and their derivatives, act directly on purified gamma-secretase to selectively block cleavage of APP- but not Notch-based substrates. Moreover, ATP activated the generation of the APP intracellular domain and Abeta, but not the generation of the Notch intracellular domain by the purified protease complex, and was a direct competitor of the APP-selective inhibitors, as were other nucleotides. In accord, purified gamma-secretase bound specifically to an ATP-linked resin. Finally, a photoactivable ATP analog specifically labeled presenilin 1-C-terminal fragments in purified gamma-secretase preparations; the labeling was blocked by ATP itself and APP-selective gamma-secretase inhibitors. We concluded that a nucleotide-binding site exists within gamma-secretase, and certain compounds that bind to this site can specifically modulate the generation of Abeta while sparing Notch. Drugs targeting the gamma-secretase nucleotide-binding site represent an attractive strategy for safely treating Alzheimer disease.     

Partial purification and characterization of gamma-secretase from post-mortem human brain

One characteristic feature of Alzheimer's disease is the deposition of amyloid beta-peptide (Abeta) as amyloid plaques within specific regions of the human brain. Abeta is derived from the amyloid beta-peptide precursor protein (beta-APP) by the intramembranous cleavage activity of gamma-secretase. Studies in cells have revealed that gamma-secretase is a large multimeric membrane-bound protein complex that is functionally dependent on several proteins, including presenilin, nicastrin, Aph-1, and Pen-2. However, the precise biochemical and molecular nature of gamma-secretase is as yet to be fully elucidated, and no investigations have analyzed gamma-secretase in human brain. To address this we have developed a novel in vitro gamma-secretase activity assay using detergent-solubilized cell membranes and a beta-APP-derived fluorescent probe. We report that human brain-derived gamma-secretase activity co-purifies with a high molecular weight protein complex comprising presenilin, nicastrin, Aph-1, and Pen-2. The inhibitor profile and solubility characteristics of brain-derived gamma-secretase are similar to those described in cells, and proteolysis occurs at the Abeta40- and Abeta42-generating cleavage sites. The ability to isolate gamma-secretase from post-mortem human brain may facilitate the identification of brain-specific modulators of beta-APP processing and provide new insights into the biology of this important factor in the pathogenesis of Alzheimer's disease.     

Pen-2 is incorporated into the gamma-secretase complex through binding to transmembrane domain 4 of presenilin 1

gamma-Secretase is a multimeric membrane protein complex comprised of presenilin (PS), nicastrin (Nct), Aph-1, and Pen-2. It is a member of an atypical class of aspartic proteases that hydrolyzes peptide bonds within the membrane. During the biosynthetic process of the gamma-secretase complex, Nct and Aph-1 form a heterodimeric intermediate complex and bind to the C-terminal region of PS, serving as a stabilizing scaffold for the complex. Pen-2 is then recruited into this trimeric complex and triggers endoproteolysis of PS, conferring gamma-secretase activity. Although the Pen-2 accumulation depends on PS, the binding partner of Pen-2 within the gamma-secretase complex remains unknown. We reconstituted PS1 in Psen1/Psen2 deficient cells by expressing a series of PS1 mutants in which one of the N-terminal six transmembrane domains (TMDs) was swapped with those of CD4 (a type I transmembrane protein) or CLAC-P (a type II transmembrane protein). We report that the proximal two-thirds of TMD4 of PS1, including the conserved Trp-Asn-Phe sequence, are required for its interaction with Pen-2. Using a chimeric CD4 molecule harboring PS1 TMD4, we further demonstrate that the PS1 TMD4 bears a direct binding motif to Pen-2. Pen-2 may contribute to the activation of the gamma-secretase complex by directly binding to the TMD4 of PS1.