Influence of the familial Alzheimer's disease-associated T43I mutation on the transmembrane structure and γ-secretase processing of the C99 peptide.

Extracellular deposition of ß-amyloid (Aß) peptides in the brain is a hallmark of Alzheimer's disease (AD). Upon ß-secretase-mediated cleavage of the ß C-terminal fragment (ß-CTF) from the Aß precursor protein, the γ-secretase complex produces the Aß peptides associated with AD. The familial T43I mutation within the transmembrane domain of the ß-CTF (also referred to as C99) increases the ratio between the Aß42 and Aß40 peptides largely due to a decrease in Aß40 formation. Aß42 is the principal component of amyloid deposits within the brain parenchyma, and an increase in the Aß42/Aß40 ratio is correlated with early-onset AD. Using NMR and FTIR spectroscopy, here we addressed how the T43I substitution influences the structure of C55, the minimal sequence containing the entire extracellular and transmembrane (TM) domains of C99 needed for γ-secretase processing. 13C NMR chemical shifts indicated that the T43I substitution increases helical structure within the TM domain of C55. These structural changes were associated with a shift of the C55 dimer to the monomer and an increase in the tilt of the TM helix relative to the membrane normal in the T43I mutant compared with that of WT C55. The A21G (Flemish) mutation was previously found to increase secreted Aß40 levels; here, we combined this mutation in the extracellular domain of C99 with T43I and observed that the T43I/A21G double mutant decreases Aß40 formation. We discuss how the observed structural changes in the T43I mutant may decrease Aß40 formation and increase the Aß42/Aß40 ratio.

ß-Sheet Structure within the Extracellular Domain of C99 Regulates Amyloidogenic Processing.

Familial mutations in C99 can increase the total level of the soluble Aß peptides produced by proteolysis, as well as the Aß42/Aß40 ratio, both of which are linked to the progression of Alzheimer's disease. We show that the extracellular sequence of C99 forms ß-sheet structure upon interaction with membrane bilayers. Mutations that disrupt this structure result in a significant increase in Aß production and, in specific cases, result in an increase in the amount of Aß42 relative to Aß40. Fourier transform infrared and solid-state NMR spectroscopic studies reveal a central ß-hairpin within the extracellular sequence comprising Y10-E11-V12 and L17-V18-F19 connected by a loop involving H13-H14-Q15. These results suggest how familial mutations in the extracellular sequence influence C99 processing and provide a structural basis for the development of small molecule modulators that would reduce Aß production.

Conformational changes induced by the A21G Flemish mutation in the amyloid precursor protein lead to increased Aß production.

Proteolysis of the ß C-terminal fragment (ß-CTF) of the amyloid precursor protein generates the Aß peptides associated with Alzheimer's disease. Familial mutations in the ß-CTF, such as the A21G Flemish mutation, can increase Aß secretion. We establish how the Flemish mutation alters the structure of C55, the first 55 residues of the ß-CTF, using FTIR and solid-state NMR spectroscopy. We show that the A21G mutation reduces ß sheet structure of C55 from Leu17 to Ala21, an inhibitory region near the site of the mutation, and increases α-helical structure from Gly25 to Gly29, in a region near the membrane surface and thought to interact with cholesterol. Cholesterol also increases Aß peptide secretion, and we show that the incorporation of cholesterol into model membranes enhances the structural changes induced by the Flemish mutant, suggesting a common link between familial mutations and the cellular environment.

A helix-to-coil transition at the epsilon-cut site in the transmembrane dimer of the amyloid precursor protein is required for proteolysis.

Processing of amyloid precursor protein (APP) by gamma-secretase is the last step in the formation of the Abeta peptides associated Alzheimer's disease. Solid-state NMR spectroscopy is used to establish the structural features of the transmembrane (TM) and juxtamembrane (JM) domains of APP that facilitate proteolysis. Using peptides corresponding to the APP TM and JM regions (residues 618-660), we show that the TM domain forms an alpha-helical homodimer mediated by consecutive GxxxG motifs. We find that the APP TM helix is disrupted at the intracellular membrane boundary near the epsilon-cleavage site. This helix-to-coil transition is required for gamma-secretase processing; mutations that extend the TM alpha-helix inhibit epsilon cleavage, leading to a low production of Abeta peptides and an accumulation of the alpha- and beta-C-terminal fragments. Our data support a progressive cleavage mechanism for APP proteolysis that depends on the helix-to-coil transition at the TM-JM boundary and unraveling of the TM alpha-helix.

Phosphorylation by glycogen synthase kinase of inhibitor-2 does not change its structure in free state.

Inhibitor-2 (I2) is a thermostable protein that specifically binds to the catalytic subunit of protein phosphatase-1 (PP1), resulting in the formation of the inactive holoenzyme, ATP-Mg-dependent phosphatase. Phosphorylation of I2 at Thr-72 by glycogen synthase kinase-3 (GSK-3) results in activation of the phosphatase, suggesting that kinase action triggers conformational change in the complex. In this paper, we characterize the effect of GSK-3 phosphorylation on the structure of free state I2[1-172] by nuclear magnetic resonance and circular dichroism spectroscopy, and show that phosphorylation has no significant effect on its conformation. We conclude that the conformational changes of ATP-Mg-dependent phosphatase induced by GSK-3 phosphorylation must depend on the interactions between PP1 and I2.