Characterization of the protrimer intermediate in the folding pathway of the interdigitated beta-helix tailspike protein

P22 tailspike is a homotrimeric, thermostable adhesin that recognizes the O-antigen lipopolysaccharide of Salmonella typhimurium. The 70 kDa subunits include long beta-helix domains. After residue 540, the polypeptide chains change their path and wrap around one another, with extensive interchain contacts. Formation of this interdigitated domain intimately couples the chain folding and assembly mechanisms. The earliest detectable trimeric intermediate in the tailspike folding and assembly pathway is the protrimer, suspected to be a precursor of the native trimer structure. We have directly analyzed the kinetics of in vitro protrimer formation and disappearance for wild type and mutant tailspike proteins. The results confirm that the protrimer intermediate is an on-pathway intermediate for tailspike folding. Protrimer was originally resolved during tailspike folding because its migration through nondenaturing polyacrylamide gels was significantly retarded with respect to the migration of the native tailspike trimer. By comparing protein mobility versus acrylamide concentration, we find that the retarded mobility of the protrimer is due exclusively to a larger overall size than the native trimer, rather than an altered net surface charge. Experiments with mutant tailspike proteins indicate that the conformation difference between protrimer and native tailspike trimer is localized toward the C-termini of the tailspike polypeptide chains. These results suggest that the transformation of the protrimer to the native tailspike trimer represents the C-terminal interdigitation of the three polypeptide chains. This late step may confer the detergent-resistance, protease-resistance, and thermostability of the native trimer.     

Stalled folding mutants in the triple beta-helix domain of the phage P22 tailspike adhesin

The trimeric bacteriophage P22 tailspike adhesin exhibits a domain in which three extended strands intertwine, forming a single turn of a triple beta-helix. This domain contains a single hydrophobic core composed of residues contributed by each of the three sister polypeptide chains. The triple beta-helix functions as a molecular clamp, increasing the stability of this elongated structural protein. During folding of the tailspike protein, the last precursor before the native state is a partially folded trimeric intermediate called the protrimer. The transition from the protrimer to the native state results in a structure that is resistant to denaturation by heat, chemical denaturants, and proteases. Random mutations were made in the region encoding residues 540-548, where the sister chains begin to wrap around each other. From a set of 26 unique single amino acid substitutions, we characterized mutations at G546, N547, and I548 that retarded or blocked the protrimer to native trimer transition. In contrast, many non-conservative substitutions were tolerated at residues 540-544. Sucrose gradient analysis showed that protrimer-like mutants had reduced sedimentation, 8.0 S to 8.3 S versus 9.3 S for the native trimer. Mutants affected in the protrimer to native trimer transition were also destabilized in their native state. These data suggest that the folding of the triple beta-helix domain drives transition of the protrimer to the native state and is accompanied by a major rearrangement of polypeptide chains.     

P22 tailspike trimer assembly is governed by interchain redox associations

Though disulfide bonds are absent from P22 tailspike protein in its native state, a disulfide-bonded trimeric intermediate has been identified in the tailspike folding and assembly pathway in vitro. The formation of disulfide bonds is critical to efficient assembly of native trimers as mutations at C-terminal cysteines reduce or inhibit trimer formation. We investigated the effect of different redox folding environments on tailspike formation to discover if simple changes in reducing potential would facilitate trimer formation. Expression of tailspike in trxB cell lines with more oxidizing cytoplasms led to lower trimer yields; however, observed assembly rates were unchanged. In vitro, the presence of any redox buffer decreased the overall yield compared to non-redox buffered controls; however, the greatest yields of the native trimer were obtained in reducing rather than oxidizing environments at pH 7. Slightly faster trimer formation rates were observed in the redox samples at pH 7, perhaps by accelerating the reduction of the disulfide-bonded protrimer to the native trimer. These rates and the effects of the redox system were found to depend greatly on the pH of the refolding reaction. Oxidized glutathione (GSSG) trapped a tailspike intermediate, likely as a mixed disulfide. This trapped intermediate was able to form native trimer upon addition of dithiothreitol (DTT), indicating that the trapped intermediate is on the assembly pathway, rather than the aggregation pathway. Thus, the presence of redox agents interfered with the ability of the tailspike monomers to associate, demonstrating that disulfide associations play an important role during the assembly of this cytoplasmic protein.     

C-terminal hydrophobic interactions play a critical role in oligomeric assembly of the P22 tailspike trimer

The tailspike protein from the bacteriophage P22 is a well characterized model system for folding and assembly of multimeric proteins. Folding intermediates from both the in vivo and in vitro pathways have been identified, and both the initial folding steps and the protrimer-to-trimer transition have been well studied. In contrast, there has been little experimental evidence to describe the assembly of the protrimer. Previous results indicated that the C terminus plays a critical role in the overall stability of the P22 tailspike protein. Here, we present evidence that the C terminus is also the critical assembly point for trimer assembly. Three truncations of the full-length tailspike protein, TSPΔN, TSPΔC, and TSPΔNC, were generated and tested for their ability to form mixed trimer species. TSPΔN forms mixed trimers with full-length P22 tailspike, but TSPΔC and TSPΔNC are incapable of forming similar mixed trimer species. In addition, mutations in the hydrophobic core of the C terminus were unable to form trimer in vivo. Finally, the hydrophobic-binding dye ANS inhibits the formation of trimer by inhibiting progression through the folding pathway. Taken together, these results suggest that hydrophobic interactions between C-terminal regions of P22 tailspike monomers play a critical role in the assembly of the P22 tailspike trimer.     

Role for cysteine residues in the in vivo folding and assembly of the phage P22 tailspike

The predominantly beta-sheet phage P22 tailspike adhesin contains eight reduced cysteines per 666 residue chain, which are buried and unreactive in the native trimer. In the pathway to the native trimer, both in vivo and in vitro transient interchain disulfide bonds are formed and reduced. This occurs in the protrimer, an intermediate in the formation of the interdigitated beta-sheets of the trimeric tailspike. Each of the eight cysteines was replaced with serine by site-specific mutagenesis of the cloned P22 tailspike gene and the mutant genes expressed in Escherichia coli. Although the yields of native-like Cys>Ser proteins varied, sufficient soluble trimeric forms of each of the eight mutants accumulated to permit purification. All eight single Cys>Ser mature proteins maintained the high thermostability of the wild type, as well as the wild-type biological activity in forming infectious virions. Thus, these cysteine thiols are not required for the stability or activity of the native state. When their in vivo folding and assembly kinetics were examined, six of the mutant substitutions--C267S, C287S, C458S, C613S, and C635S--were significantly impaired at higher temperatures. Four--C290S, C496, C613S, and C635--showed significantly impaired kinetics even at lower temperatures. The in vivo folding of the C613S/C635S double mutant was severely defective independent of temperature. Since the trimeric states of the single Cys>Ser substituted chains were as stable and active as wild type, the impairment of tailspike maturation presumably reflects problems in the in vivo folding or assembly pathways. The formation or reduction of the transient interchain disulfide bonds in the protrimer may be the locus of these kinetic functions.     

Cold rescue of the thermolabile tailspike intermediate at the junction between productive folding and off-pathway aggregation.

Off-pathway intermolecular interactions between partially folded polypeptide chains often compete with correct intramolecular interactions, resulting in self-association of folding intermediates into the inclusion body state. Intermediates for both productive folding and off-pathway aggregation of the parallel beta-coil tailspike trimer of phage P22 have been identified in vivo and in vitro using native gel electrophoresis in the cold. Aggregation of folding intermediates was suppressed when refolding was initiated and allowed to proceed for a short period at 0 degrees C prior to warming to 20 degrees C. Yields of refolded tailspike trimers exceeding 80% were obtained using this temperature-shift procedure, first described by Xie and Wetlaufer (1996, Protein Sci 5:517-523). We interpret this as due to stabilization of the thermolabile monomeric intermediate at the junction between productive folding and off-pathway aggregation. Partially folded monomers, a newly identified dimer, and the protrimer folding intermediates were populated in the cold. These species were electrophoretically distinguished from the multimeric intermediates populated on the aggregation pathway. The productive protrimer intermediate is disulfide bonded (Robinson AS, King J, 1997, Nat Struct Biol 4:450-455), while the multimeric aggregation intermediates are not disulfide bonded. The partially folded dimer appears to be a precursor to the disulfide-bonded protrimer. The results support a model in which the junctional partially folded monomeric intermediate acquires resistance to aggregation in the cold by folding further to a conformation that is activated for correct recognition and subunit assembly.     

Three amino acids that are critical to formation and stability of the P22 tailspike trimer

The P22 tailspike protein folds by forming a folding competent monomer species that forms a dimeric, then a non-native trimeric (protrimer) species by addition of folding competent monomers. We have found three residues, R549, R563, and D572, which play a critical role in both the stability of the native tailspike protein and assembly and maturation of the protrimer. King and colleagues reported previously that substitution of R563 to glutamine inhibited protrimer formation. We now show that the R549Q and R563K variants significantly delay the protrimer-to-trimer transition both in vivo and in vitro. Previously, variants that destabilize intermediates have shown wild-type chemical stability. Interestingly, both the R549Q and R563K variants destabilize the tailspike trimer in guanidine denaturation studies, indicating that they represent a new class of tailspike folding variants. R549Q has a midpoint of unfolding at 3.2M guanidine, compared to 5.6M for the wild-type tailspike protein, while R563K has a midpoint of unfolding of 1.8 M. R549Q and R563K also denature over a broader pH range than the wild-type tailspike protein and both proteins have increased sensitivity to pH during refolding, suggesting that both residues are involved in ionic interactions. Our model is that R563 and D572 interact to stabilize the adjacent turn, aiding the assembly of the dimer and protrimer species. We believe that the interaction between R563 and D572 is also critical following assembly of the protrimer to properly orient D572 in order to form a salt bridge with R549 during protrimer maturation.     

The interdigitated beta-helix domain of the P22 tailspike protein acts as a molecular clamp in trimer stabilization

The P22 tailspike adhesin is an elongated thermostable trimer resistant to protease digestion and to denaturation in sodium dodecyl sulfate. Monomeric, dimeric, and protrimeric folding and assembly intermediates lack this stability and are thermolabile. In the native trimer, three right-handed parallel beta-helices (residues 143-540), pack side-by-side around the three-fold axis. After residue 540, these single chain beta-helices terminate and residues 541-567 of the three polypeptide chains wrap around each other to form a three-stranded interdigitated beta-helix. Three mutants located in this region -- G546D, R563Q, and A575T -- blocked formation of native tailspike trimers, and accumulated soluble forms of the mutant polypeptide chains within cells. The substitutions R563Q and A575T appeared to prevent stable association of partially folded monomers. G546D, in the interdigitated region of the chain, blocked tailspike folding at the transition from the partially-folded protrimer to the native trimer. The protrimer-like species accumulating in the G546D mutant melted out at 42 degrees C and was trypsin and SDS sensitive. The G546D defect was not corrected by introduction of global suppressor mutations, which correct kinetic defects in beta-helix folding. The simplest interpretation of these results is that the very high thermostability (T(m) = 88 degrees C), protease and detergent resistance of the native tailspike acquired in the protrimer-to-trimer transition, depends on the formation of the three-stranded interdigitated region. This interdigitated beta-helix appears to function as a molecular clamp insuring thermostable subunit association in the native trimer.     

In vitro folding pathway of phage P22 tailspike protein.

The intracellular chain folding and association pathway of the thermostable, trimeric phage P22 tailspike endorhamnosidase has been the subject of a previous detailed study employing temperature-sensitive folding mutants. Recently, reconstitution of native tailspikes from completely unfolded polypeptides has been accomplished, providing a model system to compare protein folding pathways in vivo and in vitro. The in vitro reconstitution pathway of the protein after dilution from guanidine hydrochloride or acid-urea solutions at 10 degrees C was characterized by spectroscopic and hydrodynamic techniques, and may be summarized as an ordered sequence of folding, association, and folding reactions. Multiphasic folding of monomers was indicated by changes in circular dichroism and fluorescence, with a rate constant of k = 1.6 X 10(-3) s-1 for the slowest phase observed spectroscopically. Trimerization of structured monomers was followed by size-exclusion HPLC and was completed within 1.5 h at a protein concentration of 20 micrograms/mL. Although at this time trimers did not exchange subunits, they were readily dissociable by dodecyl sulfate in the cold. Formation of native, detergent-resistant trimers was only completed after 3 days of reconstitution at 10 degrees C. The reconstitution pathway of the tailspike protein closely resembles its intracellular maturation path. Thus, the in vitro reconstitution system, as a valid model of chain folding and association in vivo, should provide the tools to localize the steps or intermediates on the pathway that are the targets of temperature-sensitive folding mutations.     

Temperature-sensitive mutants blocked in the folding or subunit assembly of the bacteriophage P22 tail spike protein: III. Inactive polypeptide chains synthesized at 39 °C

Salmonella typhimurium cells infected by temperature-sensitive mutants in gene 9 of bacteriophage P22 at the restrictive temperature (39 °C) fail to accumulate functional tail spike protein. We report here studies of the inactive mutant tail spike polypeptide chains synthesized at 39 °C by temperature-sensitive mutants at 15 different sites of gene 9. For all 15 mutants, the gene 9 polypeptide chains were synthesized at 39 °C at rates similar to wild type. The mutant polypeptide chains were stable within the infected cells.The inactive polypeptide chains were tested for three functions displayed by the mature tail spike protein: irreversible binding to phage heads, endorhamnosidase activity, and reaction with anti-tail antibody. The 15 mutant proteins that accumulated at 39 °C lacked all three functions. Since the amino acid substitutions do not affect these functions of the mature protein, the mutant polypeptide chains synthesized at 39 °C have a conformation very different from the wild type, and different from the same proteins when matured at 30 °C. The fact that amino acid substitutions throughout the 76,000 M_r polypeptide chain prevent all three functions suggests that the mutations prevent the correct folding of the gene 9 polypeptide chain at restrictive temperature. Thus, these mutations identify sites in the polypeptide chain critical for protein maturation.Many of the mutant proteins could be activated in the absence of new protein synthesis by shifting infected cells from restrictive to permissive temperature before cell lysis. For these mutants, the immature chains accumulating at high temperature must be reversibly related to intermediates in protein folding or subunit assembly.     

Temperature-sensitive mutants blocked in the folding or subunit assembly of the bacteriophage P22 tail spike protein: II. Active mutant proteins matured at 30 °C

Little is known of the molecular mechanisms by which temperature-sensitive mutations interfere with the formation of biologically active proteins. We have studied the effects of such mutations at 13 different sites on the properties of the multifunctional tail spike protein of bacteriophage P22, a thermostable structural protein composed of 76,000 M_r chains.Using multiple mutant strains blocked in capsid assembly, we have examined the free mutant tail spikes that accumulate in active form at permissive temperature. When assayed for the ability to bind to phage heads at the restrictive temperature, the mutant proteins were as active as the wild type. Similarly, when assayed for the ability to adsorb to bacteria at restrictive temperature, the mutant proteins were as active as the wild type. Thus the temperature-sensitive phenotypes of the mutants are not due to the thermolability of these functions in the mature mutant protein.The wild-type protein is heat-resistant, requiring incubation at 90 °C, to give a half-time of inactivation of ten minutes. The 13 ts mutant proteins, once matured at 30 °C, were as resistant as the wild-type protein to inactivation at elevated temperatures.Though the mature wild-type protein is heat stable, its maturation is heat-sensitive; the number of polypeptide chains synthesized at 30 °C and 39 °C is the same, but the yield of active tail spikes at 39 °C is only 25% of the yield at 30 °C.The results show that the amino acid substitutions in the mutant proteins, though lethal for the formation of the virus at 39 °C, do not affect the thermostability of the mature tail spike protein formed at 30 °C. They may act by destabilizing thermolabile intermediates in the folding or subunit assembly of the tail spike protein.     

Pressure dissociation studies provide insight into oligomerization competence of temperature-sensitive folding mutants of P22 tailspike

Several temperature-sensitive folding (tsf) mutants of the tailspike protein from bacteriophage P22 have been found to fold with lower efficiency than the wild-type sequence, even at lowered temperatures. Previous refolding studies initiated from the unfolded monomer have indicated that the tsf mutations decrease the rate of structured monomer formation. We demonstrate that pressure treatment of the tailspike aggregates provides a useful tool to explore the effects of tsf mutants on the assembly pathway of the P22 tailspike trimer. The effects of pressure on two different tsf mutants, G244R and E196K, were explored. Pressure treatment of both G244R and E196K aggregates produced a folded trimer. E196K forms almost no native trimer in in vitro refolding experiments, yet it forms a trimer following pressure in a manner similar to the native tailspike protein. In contrast, trimer formation from pressure-treated G244R aggregates was not rapid, despite the presence of a G244R dimer after pressure treatment. The center-of-mass shifts of the fluorescence spectra under pressure are nearly identical for both tsf aggregates, indicating that pressure generates similar intermediates. Taken together, these results suggest that E196K has a primary defect in formation of the beta-helix during monomer collapse, while G244R is primarily an assembly defect.     

Thermal unfolding pathway for the thermostable P22 tailspike endorhamnosidase

The conditions in which protein stability is biologically or industrially relevant frequently differ from those in which reversible denaturation is studied. The trimeric tailspike endorhamnosidase of phage P22 is a viral structural protein which exhibits high stability to heat, proteases, and detergents under a range of environmental conditions. Its intracellular folding pathway includes monomeric and trimeric folding intermediates and has been the subject of detailed genetic analysis. To understand the basis of tailspike thermostability, we have examined the kinetics of thermal and detergent unfolding. During thermal unfolding of the tailspike, a metastable unfolding intermediate accumulates which can be trapped in the cold or in the presence of SDS. This species is still trimeric, but has lost the ability to bind to virus capsids and, unlike the native trimer, is partially susceptible to protease digestion. Its N-terminal regions, containing about 110 residues, are unfolded whereas the central regions and the C-termini of the polypeptide chains are still in the folded state. Thus, the initiation step in thermal denaturation is the unfolding of the N-termini, but melting of the intermediate represents a second kinetic barrier in the denaturation process. This two-step unfolding is unusually slow at elevated temperature; for instance, in 2% SDS at 65 degrees C, the unfolding rate constant is 1.1 x 10(-3) s-1 for the transition from the native to the unfolding intermediate and 4.0 x 10(-5) s-1 for the transition from the intermediate to the unfolded chains. The sequential unfolding pathway explains the insensitivity of the apparent Tm to the presence of temperature-sensitive folding mutations [Sturtevant, J. M., Yu, M.-H., Haase-Pettingell, C., & King, J. (1989) J. Biol. Chem. 264, 10693-10698] which are located in the central region of the chain. The metastable unfolding intermediate has not been detected in the forward folding pathway occurring at lower temperatures. The early stage of the high-temperature thermal unfolding pathway is not the reverse of the late stage of the low-temperature folding pathway.     

Reconstitution of the thermostable trimeric phage P22 tailspike protein from denatured chains in vitro

Intermediates in the intracellular chain folding and association pathway of the P22 tailspike endorhamnosidase have been identified previously by physiological and genetic methods. Conditions have now been found for the in vitro refolding of this large (Mr = 215,000) oligomeric protein. Purified Salmonella phage P22 tailspikes, while very stable to urea in neutral solution, were dissociated by moderate concentrations of urea at acidic pH. The tailspike protein was denatured to unfolded polypeptide chains in 6 M urea, pH 3, as disclosed by analytical ultracentrifugation, fluorescence, and circular dichroism. Upon dilution into neutral buffer at 10 degrees C, the polypeptides fold spontaneously and associate to form trimeric tailspikes with high yield. Like native phage P22 tailspikes, the reconstitution product is resistant to denaturation by dodecyl sulfate in the cold and displays endorhamnosidase activity. Sedimentation coefficients, electrophoretic mobility, and fluorescence emission maxima of native and reconstituted tailspikes are identical within experimental error. By characterization of intermediates, localization of temperature-sensitive steps, and analysis of the effect of previously identified folding mutations, the reconstitution system described should allow comparison of in vivo and in vitro folding pathways of this large protein oligomer.     

Denaturation of an extremely stable hyperthermophilic protein occurs via a dimeric intermediate

To elucidate determinants of thermostability and folding pathways of the intrinsically stable proteins from extremophilic organisms, we are studying β-glucosidase from Pyrococcus furiosus. Using fluorescence and circular dichroism spectroscopy, we have characterized the thermostability of β-glucosidase at 90°C, the lowest temperature where full unfolding is achieved with urea. The chemical denaturation profile reveals that this homotetrameric protein unfolds at 90°C with an overall ΔG° of ∼ 20 kcal mol⁻¹. The high temperatures needed to chemically denature P. furiosus β-glucosidase and the large ΔG° of unfolding at high temperatures shows this to be one of the most stable proteins yet characterized. Unfolding proceeds via a three-state pathway that includes a stable intermediate species. Stability of the native and intermediate forms is concentration dependent, and we have identified a dimeric assembly intermediate using high temperature native gel electrophoresis. Based on this data, we have developed a model for the denaturation of β-glucosidase in which the tetramer dissociates to partially folded dimers, followed by the coupled dissociation and denaturation of the dimers to unfolded monomers. The extremely high stability is thus derived from a combination of oligomeric interactions and subunit folding.     

Phage P22 tailspike protein: removal of head-binding domain unmasks effects of folding mutations on native-state thermal stability.

A shortened, recombinant protein comprising residues 109-666 of the tailspike endorhamnosidase of Salmonella phage P22 was purified from Escherichia coli and crystallized. Like the full-length tailspike, the protein lacking the amino-terminal head-binding domain is an SDS-resistant, thermostable trimer. Its fluorescence and circular dichroism spectra indicate native structure. Oligosaccharide binding and endoglycosidase activities of both proteins are identical. A number of tailspike folding mutants have been obtained previously in a genetic approach to protein folding. Two temperature-sensitive-folding (tsf) mutations and the four known global second-site suppressor (su) mutations were introduced into the shortened protein and found to reduce or increase folding yields at high temperature. The mutational effects on folding yields and subunit folding kinetics parallel those observed with the full-length protein. They mirror the in vivo phenotypes and are consistent with the substitutions altering the stability of thermolabile folding intermediates. Because full-length and shortened tailspikes aggregate upon thermal denaturation, and their denaturant-induced unfolding displays hysteresis, kinetics of thermal unfolding were measured to assess the stability of the native proteins. Unfolding of the shortened wild-type protein in the presence of 2% SDS at 71 degrees C occurs at a rate of 9.2 x 10(-4) s(-1). It reflects the second kinetic phase of unfolding of the full-length protein. All six mutations were found to affect the thermal stability of the native protein. Both tsf mutations accelerate thermal unfolding about 10-fold. Two of the su mutations retard thermal unfolding up to 5-fold, while the remaining two mutations accelerate unfolding up to 5-fold. The mutational effects can be rationalized on the background of the recently determined crystal structure of the protein.     

Equilibrium folding and unfolding pathways for a model protein

The folding–unfolding process of reduced bovine pancreatic trypsin inhibitor was investigated with an idealized model employing approximate free energies. The protein is regarded to consist of only C^α and C^β atoms. The backbone dihedral angles are the only conformational variables and are permitted to take discrete values at every 10°. Intraresidue energies consist of two terms: an empirical part taken from the observed frequency distributions of (?,ψ) and an additional favorable energy assigned to the native conformation of each residue. Interresidue interactions are simplified by assuming that there is an attractive energy operative only between residue pairs in close contact in the native structure. A total of 230,000 molecular conformations, with no atomic overlaps, ranging from the native state to the denatured state, are randomly generated by changing the sampling bias. Each conformation is classified according to its conformational energy, F; a conformational entropy, S(F) is estimated for each value of F from the number of samples. The dependence of S(F) on energy reveals that the folding–unfolding transition for this idealized model is an “all-or-none” type; this is attributable to the specific long-range interactions. Interresidue contact probabilities, averaged over samples representing various stages of folding, serve to characterize folding intermediates. Most probable equilibrium pathways for the folding–unfolding transition are constructed by connecting conformationally similar intermediates. The specific details obtained for bovine pancreatic trypsin inhibitor are as follows: (1) Folding begins with the appearance of nativelike medium-range contacts at a β-turn and at the α-helix. (2) These grow to include the native pair of interacting β-strands. This state includes intact regular secondary conformations, as well as the interstrand sheet contacts, and corresponds to an activated state with the highest free energy on the pathway. (3) Additional native long-range contacts are completely formed either toward the amino terminus or toward the carboxyl terminus. (4) In a final step, the missing contacts appear. Although these folding pathways for this model are not consistent with experimental reports, it does indicate multiple folding pathways. The method is general and can be applied to any set of calculated conformational energies and furthermore permits investigation of gross folding features.     

Kinetics of protein folding: Nucleation mechanism,time scales,and pathways

The kinetics and thermodynamics of protein folding is investigated using low friction Langevin simulation of minimal continuum mode of proteins. We show that the model protein has two characteristic temperatures: (a) T_θ, at which the chain undergoes a collapse transition from an extended conformation; (b) T_f(< T_θ), at which a finite size first-order transition to the folded state takes place. The kinetics of approach to the native state from initially denatured conformations is probed by several novel correlation functions. We find that the overall kinetics of approach to the native conformation occurs via a three-stage multiple pathway mechanism. The initial stage, characterized by a series of local dihedral angle transitions, eventually results in the compaction of the protein. Subsequently, the molecule acquires native-like structures during the second stage of folding. The final stage of folding involves activated transitions from one of the native-like structures to the native conformation. The first two stages are characterized by a multiplicity of pathways while relatively few paths are involved in the final stage. A detailed analysis of the dynamics of individual trajectories reveals a novel picture of protein folding. We find that afraction of the initial population reaches the native conformation without the formation of any detectable intermediates. This pathway is associated with a nucleation mechanism, i.e., once a critical number of tertiary contacts are established then the native state is reached rapidly. The remaining fraction of molecules become trapped in misfolded structures (stabilized by incorrect tertiary contacts). The slow folding involves transitions over barriers from these structures to the native conformation. The theoretical predictions are compared with recent experiments that probe protein folding kinetics by hydrogen exchange labeling technique. © 1995 John Wiley & Sons, Inc.