A mechanistic link between oxidative stress and membrane mediated amyloidogenesis revealed by infrared spectroscopy

The fully developed lesion of Alzheimer's disease is a dense plaque composed of fibrillar amyloid beta-proteins (Abeta) with a characteristic and well-ordered beta-sheet secondary structure. Because the incipient lesion most likely develops when these proteins are first induced to form beta-sheet structure, it is important to understand factors that induced Abeta to adopt this conformation. In this review, we describe the application of polarized attenuated total internal reflection infrared FT-IR spectroscopy for characterizing the conformation, orientation, and rate of accumulation of Abeta on lipid membranes. We also describe the application and yield of linked analysis, whereby multiple spectra are fit simultaneously with component bands that are constrained to share common fitting parameters. Results have shown that membranes promote beta-sheet formation under a variety of circumstances that may be significant to the pathogenesis of Alzheimer's disease.     

Early synergy between Abeta42 and oxidatively damaged membranes in promoting amyloid fibril formation by Abeta40

Oxidative lipid membrane damage is known to promote the misfolding of Abeta42 into pathological beta structure. In fully developed senile plaques of Alzheimer's disease, however, it is the shorter and more soluble amyloid beta protein, Abeta40, that predominates. To investigate the role of oxidative membrane damage in the misfolding of Abeta40, we have examined its interaction with supported lipid monolayer membranes using internal reflection infrared spectroscopy. Oxidatively damaged lipids modestly increased Abeta40 accumulation, with adsorption kinetics and a conformation that are distinct from that of Abeta42. In stark contrast, pretreatment of oxidatively damaged monolayer membranes with Abeta42 vigorously promoted Abeta40 accumulation and misfolding. Pretreatment of saturated or undamaged membranes with Abeta42 had no such effect. Parallel studies of lipid bilayer vesicles using a dye binding assay to detect fibril formation and electron microscopy to examine morphology demonstrated that Abeta42 pretreatment of oxidatively damaged membranes promoted the formation of mature Abeta40 amyloid fibrils. We conclude that oxidative membrane damage and Abeta42 act synergistically at an early stage to promote fibril formation by Abeta40. This synergy could be detected within minutes using internal reflection spectroscopy, whereas a dye-binding assay required several days and much higher protein concentrations to demonstrate this synergy.     

Influence of hydrophobic Teflon particles on the structure of amyloid beta-peptide

The amyloid beta-protein (Abeta) constitutes the major peptide component of the amyloid plaque deposits of Alzheimer's disease in humans. The Abeta changes from a nonpathogenic to a pathogenic conformation resulting in self-aggregation and deposition of the peptide. It has been established that denaturing factors (such as the interaction with membranes) are involved in the structural transition. This work is aimed at determining the effect of hydrophobic Teflon on the conformation of the Abeta (1-40). Prior to adsorption, the secondary structure and self-aggregation state of the Abeta in solution were established as a function of pH. Three different species coexist: unordered monomers/dimers, small oligomers in mainly a regular beta-sheet structure, and bigger aggregates having a twisted beta-sheet conformation. Transferring the Abeta from the solution to the Teflon surface strongly promotes alpha-helix formation. Furthermore, increasing the degree of coverage of the Teflon by the Alphabeta protein leads to a conformational change toward a more enriched beta-sheet structure.     

Cross-seeding of wild-type and hereditary variant-type amyloid beta-proteins in the presence of gangliosides

We investigated the molecular mechanism underlying the ganglioside-induced initiation of the assembly of wild and hereditary variant-type amyloid beta-proteins, including Arctic-, Dutch-, and Flemish-type amyloid beta-proteins. We monitored the assembly of amyloid beta-protein by thioflavin-T assay, western blotting and electron microscopy. We also examined how externally added amyloid beta-protein assembles in a cell culture. The assembly of wild-, Arctic-, Dutch-, and Flemish-type amyloid beta-proteins were accelerated in the presence of GM1, GM1, GM3 and GD3 gangliosides. Notably, all of these amyloid beta-proteins accelerated the assembly of different type of amyloid beta-protein, following prior binding to a specific ganglioside. A specific-ganglioside-bound form of variant-type amyloid beta-protein was recognized by the antibody (4396C) specific to the GM1-ganglioside-induced altered conformation of wild-type amyloid beta-protein. Moreover, the assembly of these amyloid beta-proteins in the presence of a specific ganglioside was markedly suppressed by coincubation with 4396C. This study suggests that cross-seeding can occur between wild and hereditary variant-type amyloid beta-proteins despite differences in their amino acid sequences.     

A mechanistic link between oxidative stress and membrane mediated amyloidogenesis revealed by infrared spectroscopy

The fully developed lesion of Alzheimer's disease is a dense plaque composed of fibrillar amyloid β-proteins (Aβ) with a characteristic and well-ordered β-sheet secondary structure. Because the incipient lesion most likely develops when these proteins are first induced to form β-sheet structure, it is important to understand factors that induced Aβ to adopt this conformation. In this review, we describe the application of polarized attenuated total internal reflection infrared FT-IR spectroscopy for characterizing the conformation, orientation, and rate of accumulation of Aβ on lipid membranes. We also describe the application and yield of linked analysis, whereby multiple spectra are fit simultaneously with component bands that are constrained to share common fitting parameters. Results have shown that membranes promote β-sheet formation under a variety of circumstances that may be significant to the pathogenesis of Alzheimer's disease.     

Apocytochrome c interaction with phospholipid membranes studied by Fourier-transform infrared spectroscopy.

Apocytochrome c, the heme-free precursor of cytochrome c, has been used extensively as a model to study molecular aspects of posttranslational translocation of proteins across membranes. In this report, we have used Fourier-transform infrared spectroscopy to gain further insight into the mechanism of apocytochrome c interaction with membrane phospholipids. Association of apocytochrome c with model membranes containing the acidic lipid dimyristoylphosphatidylglycerol (DMPG) as a single component results in a drastic perturbation of phospholipid structure, at the level of both the acyl chains and the interfacial carbonyl groups. However, in a binary mixture of DMPG with acyl chain perdeuterated dimyristoylphosphatidylcholine (DMPC-d54), the perturbing effect of the protein on the acidic phospholipid is greatly attenuated. In such a membrane with mixed lipids, the physical properties of the DMPG and DMPC components are affected in a similar fashion, indicating that apocytochrome c does not induce any significant segregation or lateral-phase separation of acidic and zwitterionic lipids. Analysis of the apocytochrome c spectrum in the amide I region reveals that binding to phospholipids causes considerable changes in the secondary structure of the protein, the final conformation of which depends on the lipid to protein ratio. In the presence of a large excess of DMPG, apocytochrome c undergoes a transition from an essentially unordered conformation in solution to an alpha-helical structure. However, in complexes of lower lipid to protein ratios (less than or equal to approximately 40:1), infrared spectra are indicative of an extended, intermolecularly hydrogen-bonded beta-sheet structure. The latter is suggestive of an extensive aggregation of the membrane-associated protein.     

The influence of phospholipid membranes on bovine calcitonin secondary structure and amyloid formation

Calcitonin, a peptide hormone associated with medullary carcinoma of the thyroid, has the potential to form amyloid fibrils and may be a valuable model for investigating the role of peptide-membrane interactions in beta-sheet and amyloid formation. Via a new model peptide system, bovine calcitonin, we found that the exposure of peptide to phospholipid membranes altered its structure relative to the structures formed in aqueous solutions. Of particular relevance to the amyloidoses, incubation of calcitonin with cholesterol-rich and ganglioside-containing membranes resulted in significant enrichment in the beta-sheet and amyloid content of the peptide. The formation of amyloid was also accelerated in these systems. A correlation between the phospholipid-induced structural alterations and calcitonin binding affinities to phospholipid membranes was evident. Bovine calcitonin has considerably higher binding affinity for the phospholipid systems that enhanced its beta-sheet and amyloid structure. Electrostatic forces were not the governing forces behind the observed behavior, as supported by the fact that the ionic strength did not affect the peptide structures or binding affinities. A Van't Hoff analysis of the temperature-dependent peptide binding affinities indicated that binding led to an increase in enthalpy and possibly an increase in entropy of the peptide-membrane systems. Experiments with other amyloid-forming peptides such as beta-amyloid of Alzheimer's disease have also shown similar results and may indicate the need to manipulate peptide-membrane interactions in order to control amyloid formation and its associated disease.     

Dense-core and diffuse Abeta plaques in TgCRND8 mice studied with synchrotron FTIR microspectroscopy

Plaques composed of the Abeta peptide are the main pathological feature of Alzheimer's disease. Dense-core plaques are fibrillar deposits of Abeta, showing all the classical properties of amyloid including beta-sheet secondary structure, while diffuse plaques are amorphous deposits. We studied both plaque types, using synchrotron infrared (IR) microspectroscopy, a technique that allows the chemical composition and average protein secondary structure to be investigated in situ. We examined plaques in hippocampal, cortical and caudal tissue from 5- to 21-month-old TgCRND8 mice, a transgenic model expressing doubly mutant amyloid precursor protein, and displaying impaired hippocampal function and robust pathology from an early age. Spectral analysis confirmed that the congophilic plaque cores were composed of protein in a beta-sheet conformation. The amide I maximum of plaque cores was at 1623 cm(-1), and unlike for in vitro Abeta fibrils, the high-frequency (1680-1690 cm(-1)) component attributed to antiparallel beta-sheet was not observed. A significant elevation in phospholipids was found around dense-core plaques in TgCRND8 mice ranging in age from 5 to 21 months. In contrast, diffuse plaques were not associated with IR detectable changes in protein secondary structure or relative concentrations of any other tissue components.     

The influence of phospholipid membranes on bovine calcitonin peptide's secondary structure and induced neurotoxic effects

The peptide hormone, calcitonin, which is associated with medullary carcinoma of the thyroid, has a marked tendency to form amyloid fibrils and may be a useful model in probing the role of peptide-membrane interactions in beta-sheet and amyloid formation and amyloid neurotoxicity. Using bovine calcitonin, we found that, like other amyloids, the peptide was toxic only when in a beta-sheet-rich, amyloid form, but was non-toxic, when it lacked an amyloid structure. We found that the peptide bound with significant affinity to membranes that contained either cholesterol and gangliosides. In addition, incubation of calcitonin with cholesterol-rich and ganglioside-containing membranes resulted in significant changes in peptide structure yielding a peptide enriched in beta-sheet and amyloid content. Because the cholesterol- and ganglioside-rich phospholipid systems enhanced the calcitonin beta-sheet and amyloid contents, and peptide amyloid content was associated with neurotoxicity, we then investigated whether depleting cellular cholesterol and gangliosides affected calcitonin neurotoxicity. We found that cholesterol and ganglioside removal significantly reduced the calcitonin-induced PC12 cell neurotoxicity. Similar results have been observed with other amyloid-forming peptides such as beta-amyloid (A beta) of Alzheimer's disease and suggest that modulation of membrane composition and peptide-membrane interactions may prove useful in the control of amyloid formation and amyloid neurotoxicity.     

Cholesterol and Clioquinol modulation of A beta(1-42) interaction with phospholipid bilayers and metals

The beta-sheet plaques that are the most obvious pathological feature of Alzheimer's disease are composed of amyloid-beta peptides and are highly enriched in the metal ions Zn, Fe and Cu. The interaction of the full-length amyloid peptide, A beta(1-42), with phospholipid lipid bilayers was studied in the presence of the metal-chelating drug, Clioquinol (CQ). The effect of cholesterol and metal ions was also determined using solid-state 31P and 2H NMR. CQ modulated the effect of metal ions on the integrity of the bilayer and although CQ perturbed the phospholipid membrane, the bilayer integrity was maintained. Model membranes enriched in cholesterol were studied under conditions of peptide association and incorporation. Solid-state NMR showed that the bilayer integrity was preserved in cholesterol-enriched membranes in comparison to phosphatidylcholine-phosphatidylserine bilayers. Changes in peptide structure, consistent with an increase in beta-sheet, were observed using specifically 13C-labelled A beta(1-42) by magic angle spinning NMR. Results using aligned phosphatidylcholine bilayers and completely 15N-labelled peptide indicated that the peptide aggregated. The results are consistent with oligomeric beta-sheet structured peptides only partially penetrating the bilayer and cholesterol reducing the membrane disruption.     

Study of the correlation of secondary structure of beta-amyloid peptide (Abeta40) with the hydrophobic exposure under different conditions

Abeta is the core protein of extracellular plaque of Alzheimer's disease, and its neurotoxicity is relative to its conformation. In the current work, the effects of various factors, such as pH, ionic strength and lipid membranes, on the secondary structure of Abeta were studied by circular dichroism. In addition, we detected the exposure of hydrophobic sites of Abeta under different conditions using ANS fluorescence. The results showed that the hydrophobic exposure of the protein was correlated with the content of 3betasheet conformation in the phospholipid-containing environment. The beta-sheet content and hydrophobic exposure of Abeta both increased when reacted with pure PC vesicles, while no beta-sheet content and very low hydrophobic exposure were detected after reaction with 30% cholesterol containing PC vesicles. Since beta-sheet conformation is considered as the toxic conformation of Afbeta such correlation may be important for the pathology of AD.     

Membrane interactions and the effect of metal ions of the amyloidogenic fragment Abeta(25-35) in comparison to Abeta(1-42)

Abeta(1-42) peptide, found as aggregated species in Alzheimer's disease brain, is linked to the onset of Alzheimer's disease. Many reports have linked metals to inducing Abeta aggregation and amyloid plaque formation. Abeta(25-35), a fragment from the C-terminal end of Abeta(1-42), lacks the metal coordinating sites found in the full-length peptide and is neurotoxic to cortical cortex cell cultures. We report solid-state NMR studies of Abeta(25-35) in model lipid membrane systems of anionic phospholipids and cholesterol, and compare structural changes to those of Abeta(1-42). When added after vesicle formation, Abeta(25-35) was found to interact with the lipid headgroups and slightly perturb the lipid acyl-chain region; when Abeta(25-35) was included during vesicle formation, it inserted deeper into the bilayer. While Abeta(25-35) retained the same beta-sheet structure irrespective of the mode of addition, the longer Abeta(1-42) appeared to have an increase in beta-sheet structure at the C-terminus when added to phospholipid liposomes after vesicle formation. Since the Abeta(25-35) fragment is also neurotoxic, the full-length peptide may have more than one pathway for toxicity.     

Formation of a membrane-active form of amyloid beta-protein in raft-like model membranes

The conversion of soluble, nontoxic amyloid beta-protein (A beta) to aggregated, toxic A beta rich in beta-sheet structures is considered to be the key step in the development of Alzheimer's disease. We have proposed that the aggregation proceeds in the lipid raft containing a ganglioside cluster, the formation of which is facilitated by cholesterol and for which A beta shows a specific affinity. In this study, using fluorescence resonance energy transfer, we found that after A beta binds to raft-like membranes composed of monosialoganglioside GM1/cholesterol/sphingomyelin (1/1/1), the protein can translocate to the phosphatidylcholine membranes to which soluble A beta does not bind. Furthermore, self-quenching experiments using fluorescein-labeled A beta revealed that the translocation process competes with the oligomerization of the protein in the raft-like membranes. These results suggest that the lipid raft containing a ganglioside cluster serves as a conformational catalyst or a chaperon generating a membrane-active form of A beta with seeding ability.     

Apoptosis induced in neuronal cells by C-terminal amyloid beta-fragments is correlated with their aggregation properties in phospholipid membranes

A number of findings suggest that lipophilic monomeric Abeta peptides can interact with the cellular lipid membranes. These interactions can affect the membrane integrity and result in the initiation of apoptotic cell death. The secondary structure of C-terminal Abeta peptides (29-40) and the longer (29-42) variant have been investigated in solution by circular dichroism measurements. The secondary structure of lipid bound Abeta (29-40) and (29-42) peptides prepared at different lipid/peptide ratio's, was investigated by ATR-FTIR spectroscopy. Finally, the changes in secondary structure (i.e. the transition of alpha-helix to beta-sheet) of the lipid bound peptides were correlated with the induction of neurotoxic and apoptotic effects in neuronal cells. The data suggest that the C-terminal fragments of the Abeta peptide induce a significant apoptotic cell death, as demonstrated by caspase-3 measurements and DNA laddering, with consistently a stronger effect of the longer Abeta (29-42) variant. Moreover, the induction of apoptotic death induced by these peptides can be correlated with the secondary structure of the lipid bound amyloid beta peptides. Based on these observations, it is proposed that membrane bound aggregated Abeta peptides (produced locally as the result of gamma-secretase cleavage) can accumulate and aggregate in the membrane. These membrane bound beta-sheet aggregated amyloid peptides induce neuronal apoptotic cell death.     

Interactions of amyloid beta-peptide (1-40) with ganglioside-containing membranes

Interactions between amyloid beta-peptides (Abeta) and neuronal membranes have been postulated to play an important role in the neuropathology of Alzheimer's disease. To gain insight into the molecular details of this association, we investigated the interactions of Abeta (1-40) with ganglioside-containing membranes by circular dichroism (CD) and Fourier transform infrared-polarized attenuated total reflection (FTIR-PATR) spectroscopy. The CD study revealed that at physiological ionic strength Abeta (1-40) specifically binds to ganglioside-containing membranes inducing a two-state, unordered --> beta-sheet transition above a threshold intramembrane ganglioside concentration, which depends on the host lipid bilayers used. Furthermore, differences in the number and position of sialic acid residues of the carbohydrate backbone significantly affected the conformational transition of the peptide. FTIR-PATR spectroscopy experiments demonstrated that Abeta (1-40) forms an antiparallel beta-sheet, the plane of which lies parallel to the membrane surface, inducing dehydration of lipid interfacial groups and perturbation of acyl chain orientation. These results suggest that Abeta (1-40) imposes negative curvature strain on ganglioside-containing lipid bilayers, disturbing the structure and function of the membranes.     

Membrane Lipid Co-Aggregation with α-Synuclein Fibrils

Amyloid deposits from several human diseases have been found to contain membrane lipids. Co-aggregation of lipids and amyloid proteins in amyloid aggregates, and the related extraction of lipids from cellular membranes, can influence structure and function in both the membrane and the formed amyloid deposit. Co-aggregation can therefore have important implications for the pathological consequences of amyloid formation. Still, very little is known about the mechanism behind co-aggregation and molecular structure in the formed aggregates. To address this, we study in vitro co-aggregation by incubating phospholipid model membranes with the Parkinson’s disease-associated protein, α-synuclein, in monomeric form. After aggregation, we find spontaneous uptake of phospholipids from anionic model membranes into the amyloid fibrils. Phospholipid quantification, polarization transfer solid-state NMR and cryo-TEM together reveal co-aggregation of phospholipids and α-synuclein in a saturable manner with a strong dependence on lipid composition. At low lipid to protein ratios, there is a close association of phospholipids to the fibril structure, which is apparent from reduced phospholipid mobility and morphological changes in fibril bundling. At higher lipid to protein ratios, additional vesicles adsorb along the fibrils. While interactions between lipids and amyloid-protein are generally discussed within the perspective of different protein species adsorbing to and perturbing the lipid membrane, the current work reveals amyloid formation in the presence of lipids as a co-aggregation process. The interaction leads to the formation of lipid-protein co-aggregates with distinct structure, dynamics and morphology compared to assemblies formed by either lipid or protein alone.     

Ion channel formation by Alzheimer's disease amyloid beta-peptide (Abeta40) in unilamellar liposomes is determined by anionic phospholipids

Incorporation of Alzheimer's disease amyloid beta-proteins (AbetaPs) across natural and artificial bilayer membranes leads to the formation of cation-selective channels. To study the peptide-membrane interactions involved in channel formation, we used cation reporter dyes to measure AbetaP-induced influx of Na+, Ca2+, and K+ into liposomes formed from phosphatidylserine (PS), phosphatidylinositol (PI) and phosphatidylcholine (PC). We found that Abeta40, but not Abeta40-1 or Abeta28, caused a dose-dependent increase in the concentration of each cation in the lumen of liposomes formed from the acidic phospholipids PS and PI. The Abeta40-induced changes in cation concentration, which we attribute to ion entry through Abeta40 channels, were not observed when using liposomes formed from the neutral phospholipid PC. Using mixtures of phospholipids, the magnitude of the AbetaP40-induced ion entry increased with the acidic phospholipid content of the liposomes, with entry being observed with as little as 5% PS or PI. Thus, while negatively charged phospholipids are required for formation of cation-permeable channels by Abeta40, a small amount is sufficient to support the process. These results have implications for the mechanisms of AbetaP cytotoxicity, suggesting that even a small amount of externalized negative charge could render cells susceptible to the deleterious effects of unregulated ion influx through AbetaP channels.     

Solution conformations and aggregational properties of synthetic amyloid beta-peptides of Alzheimer's disease. Analysis of circular dichroism spectra.

The A4 or beta-peptide (39 to 43 amino acid residues) is the principal proteinaceous component of amyloid deposits in Alzheimer's disease. Using circular dichroism (c.d.), we have studied the secondary structures and aggregational properties in solution of 4 synthetic amyloid beta-peptides: beta-(1-28), beta-(1-39), beta-(1-42) and beta-(29-42). The natural components of cerebrovascular deposits and extracellular amyloid plaques are beta-(1-39) and beta-(1-42), while beta-(1-28) and beta-(29-42) are unnatural fragments. The beta-(1-28), beta-(1-39) and beta-(1-42) peptides adopt mixtures of beta-sheet, alpha-helix and random coil structures, with the relative proportions of each secondary structure being strongly dependent upon the solution conditions. In aqueous solution, beta-sheet structure is favored for the beta-(1-39) and beta-(1-42) peptides, while in aqueous solution containing trifluoroethanol (TFE) or hexafluoroisopropanol (HFIP), alpha-helical structure is favored for all 3 peptides. The alpha-helical structure unfolds with increasing temperature and is favored at pH 1 to 4 and pH 7 to 10; the beta-sheet conformation is temperature insensitive and is favored at pH 4 to 7. Peptide concentration studies showed that the beta-sheet conformation is oligomeric (intermolecular), whereas the alpha-helical conformation is monomeric (intramolecular). The rate of aggregation to the oligomeric beta-sheet structure (alpha-helix----random coil----beta-sheet) is also dependent upon the solution conditions such as the pH and peptide concentration; maximum beta-sheet formation occurs at pH 5.4. These results suggest that beta-peptide is not an intrinsically insoluble peptide. Thus, solution abnormalities, together with localized high peptide concentrations, which may occur in Alzheimer's disease, may contribute to the formation of amyloid plaques. The hydrophobic beta-(29-42) peptide adopts exclusively an intermolecular beta-sheet conformation in aqueous solution despite changes in temperature or pH. Therefore, this segment may be the first region of the beta-peptide to aggregate and may direct the folding of the complete beta-peptide to produce the beta-pleated sheet structure found in amyloid deposits. Differences between the solution conformations of the beta-(1-39) and beta-(1-42) peptides suggests that the last 3 C-terminal amino acids are crucial to amyloid deposition.     

Molecular determinants of amyloid deposition in Alzheimer's disease: conformational studies of synthetic beta-protein fragments

The amyloid beta-protein (1-42) is a major constituent of the abnormal extracellular amyloid plaque that characterizes the brains of victims of Alzheimer's disease. Two peptides, with sequences derived from the previously unexplored C-terminal region of the beta-protein, beta 26-33 (H2N-SNKGAIIG-CO2H) and beta 34-42 (H2N-LMVGGVVIA-CO2H), were synthesized and purified, and their solubility and conformational properties were analyzed. Peptide beta 26-33 was found to be freely soluble in water; however, peptide beta 34-42 was virtually insoluble in aqueous media, including 6 M guanidinium thiocyanate. The peptides formed assemblies having distinct fibrillar morphologies and different dimensions as observed by electron microscopy of negatively stained samples. X-ray diffraction revealed that the peptide conformation in the fibrils was cross-beta. A correlation between solubility and beta-structure formation was inferred from FTIR studies: beta 26-33, when dissolved in water, existed as a random coil, whereas the water-insoluble peptide beta 34-42 possessed antiparallel beta-sheet structure in the solid state. Solubilization of beta 34-42 in organic media resulted in the disappearance of beta-structure. These data suggest that the sequence 34-42, by virtue of its ability to form unusually stable beta-structure, is a major contributor to the insolubility of the beta-protein and may nucleate the formation of the fibrils that constitute amyloid plaque.     

Dynamic Monte Carlo simulations of a new lattice model of globular protein folding, structure and dynamics

A long-standing problem of molecular biology is the prediction of globular protein tertiary structure from the primary sequence. In the context of a new, 24-nearest-neighbor lattice model of proteins that includes both alpha and beta-carbon atoms, the requirements for folding to a unique four-member beta-barrel, four-helix bundles and a model alpha/beta-bundle have been explored. A number of distinct situations are examined, but the common requirements for the formation of a unique native conformation are tertiary interactions plus the presence of relatively small (but not irrelevant) intrinsic turn preferences that select out the native conformer from a manifold of compact states. When side-chains are explicitly included, there are many conformations having the same or a slightly greater number of side-chain contacts as in the native conformation, and it is the local intrinsic turn preferences that produce the conformational selectivity on collapse. The local preference for helix or beta-sheet secondary structure may be at odds with the secondary structure ultimately found in the native conformation. The requisite intrinsic turn populations are about 0.3% for beta-proteins, 2% for mixed alpha/beta-proteins and 6% for helix bundles. In addition, an idealized model of an allosteric conformational transition has been examined. Folding occurs predominantly by a sequential on-site assembly mechanism with folding initiating either at a turn or from an isolated helix or beta-strand (where appropriate). For helical and beta-protein models, similar folding pathways were obtained in diamond lattice simulations, using an entirely different set of local Monte Carlo moves. This argues strongly that the results are universal; that is, they are independent of lattice, protein model or the particular realization of Monte Carlo dynamics. Overall, these simulations demonstrate that the folding of all known protein motifs can be achieved in the context of a single class of lattice models that includes realistic backbone structures and idealized side-chains.