Rapid Adaptive Evolution of the Tumor Suppressor Gene Pten in an Insect Lineage

The Pten gene was initially identified in humans as a tumor suppressor. It has since been shown to play important roles in the control of cell size, cell motility, apoptosis, and organ size, and it has also been implicated in aging. Pten is highly conserved among organisms as diverse as nematodes, insects, and vertebrates. In contrast, a phylogenetic analysis by maximum likelihood of a 133-amino acid region showed an average nonsynonymous-to-synonymous rate ratio of 10.4 for Pten in the lineage leading to parasitoid wasps of the Nasonia genus, indicating very strong positive selection. A previous study identified Pten as a potential QTL candidate gene for differences in male wing size in Nasonia. Most of the amino acid replacements that occurred in the Nasonia lineage cluster in a small region of the protein surface, suggesting that they might be involved in an interaction between Pten and another protein. The phenotypic changes due to Pten are not yet known, although it is not associated with known differences in male wing size. Introgression of Pten from one species to another does affect longevity, but a causal relationship is not established.

Characterization of a high-affinity complex between the bacterial outer membrane protein FhuA and the phage T5 protein pb5

Binding of bacteriophage T5 to Escherichia coli cells is mediated by specific interactions between the receptor-binding protein pb5 (67.8 kDa) and the outer membrane iron-transporter FhuA. A histidine-tagged form of pb5 was overproduced and purified. Isolated pb5 is monomeric and organized mostly as beta-sheets (51%). pb5 functionality was attested in vivo by its ability to impair infection of E. coli cells by phage T5 and Phi80, and to prevent growth of bacteria on iron-ferrichrome as unique iron source. pb5 was functional in vitro, since addition of an equimolar concentration of pb5 to purified FhuA prevented DNA release from phage T5. However, pb5 alone was not sufficient for the conversion of FhuA into an open channel. Direct interaction of pb5 with FhuA was demonstrated by isolating a pb5/FhuA complex using size-exclusion chromatography. The stoichiometry, 1 mol of pb5/1 mol of FhuA, was deduced from its molecular mass, established by analytical ultracentrifugation after determination of the amount of bound detergent. SDS-PAGE and differential scanning calorimetry experiments highlighted the great stability of the complex: (i) it was not dissociated by 2% SDS even when the temperature was raised to 70 degrees C; (ii) thermal denaturation of the complex occurred at 85 degrees C, while pb5 and FhuA were denatured at 45 degrees C and 74 degrees C, respectively. The stability of the complex renders it suitable for high-resolution structural studies, allowing future analysis of conformational changes into both FhuA and pb5 upon adsorption of the virus to its host.

Key interactions in the immunoglobulin-like structure of apo-neocarzinostatin: evidence from nuclear magnetic resonance relaxation data and molecular dynamics simulations

The three-dimensional structure of apo-neocarzinostatin (apo-NCS, MW: ca.11000, antitumoral chromophore carrier protein) is based on a seven-stranded antiparallel beta-sandwich, very similar to the immunoglobulin folding domain. We investigated the backbone dynamics of apo-NCS by (13)C-NMR relaxation measurements and molecular dynamics simulation. Model-free parameters determined from the experimental data are compared with a 1.5-nsec molecular simulation of apo-NCS in aqueous solution. This comparison provides an accurate description of both local and collective movements within the protein. This analysis enabled us to correlate dynamic processes with key interactions of this beta-protein. Local motions that could be relevant for the intermolecular association with the ligand are also described.

Role of loops in the folding and stability of yeast phosphoglycerate kinase

Yeast phosphoglycerate kinase (yPGK) is a monomeric two domain protein used as folding model representative of large proteins. We inserted short unstructured sequences (four Gly or four Thr) into the connections between secondary structure elements and studied the consequences of these insertions on the folding process and stability of yPGK. All the mutated proteins can refold efficiently. The effect per residue on stability is larger for the first inserted residue. Insertion in two long betaalpha loops (at residue positions 71 and 129) is more destabilizing than an insertion in a short alphabeta loop (at residue position 89) located on the opposite side of the N-terminal domain. The effect on stability is mainly due to a large increase of the unfolding rate rather than a decrease of the folding rate. This suggests that these connections between secondary structure elements do not play an active role in directing the folding process. Insertion into the short alphabeta loop (position 89) has limited effects on stability and results in the detection of a kinetic phase not previously seen with the wild-type protein, suggesting that insertions in this particular loop do qualitatively affect the folding process without a large effect on folding efficiency. For the two long betaalpha loops (positions 71 and 129) located in the inner surface of the N-terminal domain, the effects on stability are possibly associated with decoupling of the two domains as observed by differential scanning calorimetry during thermal unfolding.

Heat-induced unfolding of neocarzinostatin, a small all-β protein investigated by small-angle X-ray scattering 1 1Edited by M. F. Moody

Neocarzinostatin is an all-beta protein, 113 amino acid residues long, with an immunoglobulin-like fold. Its thermal unfolding has been studied by small-angle X-ray scattering. Preliminary differential scanning calorimetry and fluorescence measurements suggest that the transition is not a simple, two-state transition. The apparent radius of gyration is determined using three different approaches, the validity of which is critically assessed using our experimental data as well as a simple, two-state model. Similarly, each step of data analysis is evaluated and the underlying assumptions plainly stated. The existence of at least one intermediate state is formally demonstrated by a singular value decomposition of the set of scattering patterns. We assume that the pattern of the solution before the onset of the transition is that of the native protein, and that of the solution at the highest temperature is that of the completely unfolded protein. Given these, actually not very restrictive, boundary constraints, a least-squares procedure yields a scattering pattern of the intermediate state. However, this solution is not unique: a whole class of possible solutions is derived by adding to the previous linear combination of the native and completely unfolded states. Varying the initial conditions of the least-squares calculation leads to very similar solutions. Whatever member of the class is considered, the conformation of this intermediate state appears to be weakly structured, probably less than the transition state should be according to some proposals. Finally, we tried and used the classical model of three thermodynamically well-defined states to account for our data. The failure of the simple thermodynamic model suggests that there is more than the single intermediate structure required by singular value decomposition analysis. Formally, there could be several discrete intermediate species at equilibrium, or an ensemble of conformations differently populated according to the temperature. In the latter case, a third state would be a weighted average of all non native and not completely unfolded states of the protein but, since the weights change with temperature, no meaningful curve is likely to be derived by a global analysis using the simple model of three thermodynamically well-defined states.

Characterization of the denatured states distribution of neocarzinostatin by small-angle neutron scattering and differential scanning calorimetry

The denatured states of a small globular protein, apo-neocarzinostatin (NCS), have been characterized using several techniques. Structural properties were investigated by optical spectroscopy techniques and small-angle neutron scattering (SANS), as a function of guanidinium chloride (GdmCl) concentration. SANS experiments show that in heavy water, the protein keeps its native size at GdmCl concentrations below 2.5 M. A sharp transition occurs at about 3.6 M GdmCl, and NCS behaves like an excluded volume chain above 5 M. The same behavior is observed in deuterated buffer by fluorescence and circular dichroism measurements. For the H(2)O buffer, the transition occurs with lower concentration of denaturant, the shift being about 0.6 M. 8-Anilino-1-naphthalenesulfonate (ANS) was used as a hydrophobic fluorescent probe for studying the early stages of protein unfolding. Protein denaturation modifies the fluorescence intensity of ANS, a maximum of intensity being detected close to 2 M GdmCl in hydrogenated buffer, which shows the existence of at least one intermediate state populated at the beginning of the unfolding pathway. Differential scanning calorimetry (DSC) was used to obtain thermodynamic values for NCS denaturation. The melting curves recorded between 20 and 90 degrees C in the presence of various GdmCl concentrations (0-3 M) cannot be explained by a simple two-state model. Altogether, the data presented in this paper suggest that before unfolding the protein explores a distribution of states which is centered around compact states at denaturant concentrations below 2 M in H(2)O, and then shifts to less structured states by increasing denaturant concentrations.

Stability studies of FhuA, a two-domain outer membrane protein from Escherichia coli

FhuA (MM 78.9 kDa) is an Escherichia coli outer membrane protein that transports iron coupled to ferrichrome and is the receptor for a number of bacteriophages and protein antibiotics. Its three-dimensional structure consists of a 22-stranded beta-barrel lodged in the membrane, extracellular hydrophilic loops, and a globular domain (the "cork") located within the beta-barrel and occluding it. This unexpected structure raises questions about the connectivity of the different domains and their respective roles in the different functions of the protein. To address these questions, we have compared the properties of the wild-type receptor to those of a mutated FhuA (FhuA Delta) missing a large part of the cork. Differential scanning calorimetry experiments on wild-type FhuA indicated that the cork and the beta-barrel behave as autonomous domains that unfold at 65 and 75 degrees C, respectively. Ferrichrome had a strong stabilizing effect on the loops and cork since it shifted the first transition to 71.4 degrees C. Removal of the cork destabilized the protein since a unique transition at 61.6 degrees C was observed even in the presence of ferrichrome. FhuA Delta showed an increased sensitivity to proteolysis and to denaturant agents and an impairment in phage T5 and ferrichrome binding.

Gamma radiation effects on alpha-lactalbumin: structural modifications

Alpha-lactalbumin was irradiated in the lyophilized state in air at ambient temperature. The irradiated protein was examined by size exclusion chromatography, sodium dodecyl sulfate polyacrylamide gel electrophoresis, circular dichroism, and microcalorimetry. Irradiation induced the loss of aromatic amino acids and of helicity so that fragmentation and aggregation products were obtained. The thermodynamic properties of the protein were also modified. The irradiated protein had lower stability, however, the temperature at which denaturation occurred process remained constant.

Gamma radiation effects on α-lactalbumin: structural modifications

α-Lactalbumin was irradiated in the lyophilized state in air at ambient temperature. The irradiated protein was examined by size exclusion chromatography, sodium dodecyl sulfate polyacrylamide gel electrophoresis, circular dichroism, and microcalorimetry. Irradiation induced the loss of aromatic amino acids and of helicity so that fragmentation and aggregation products were obtained. The thermodynamic properties of the protein were also modified. The irradiated protein had lower stability, however, the temperature at which denaturation occurred process remained constant.Key words: ionizing radiation, radiation-induced conformational changes, protein structural modifications, protein thermodynamic properties.

Functionally accepted insertions of proteins within protein domains

Experiments were designed to explore the tolerance of protein structure and folding to very large insertions of folded protein within a structural domain. Dihydrofolate reductase and beta-lactamase have been inserted in four different positions of phosphoglycerate kinase. The resultant chimeric proteins are all overexpressed, and the host as well as the inserted partners are functional. Although not explicitly designed, functional coupling between the two fused partners was observed in some of the chimeras. These results show that the tolerance of protein structures to very large structured insertions is more general than previously expected and supports the idea that the natural sequence continuity of a structural domain is not required for the folding process. These results directly suggest a new experimental approach to screen, for example, for folded protein in randomized polypeptide sequences.

Reinvestigation of the proteolytic activity of neocarzinostatin

Neocarzinostatin (NCS) is the most studied member of a family of chromoproteins secreted by a range of actinomycetes species. It has been proposed that in addition to their antitumoral activity related to the bound chromophores, this group of related proteins could be a secreted proteases superfamily. With the aim of dissecting the molecular basis of the proteolytic activity of NCS, an expression system allowing efficient expression of apo-NCS in Escherichia coli was constructed. The recombinant protein was properly folded and functional. Its histone-specific proteolytic activity was similar to the activity described for the natural protein. Further analyses unambiguously demonstrated that the proteolytic activity could be physically separated from NCS. This activity is therefore due not to NCS itself but to minor contaminating proteases, the nature of which differed in the recombinant and natural NCS preparations. The histone degradation test commonly used to monitor proteolytic activity is extremely sensitive and may easily generate false-positive results. These results strongly suggest that the possible proteolytic activity of the proteins of this family should be critically reconsidered.

Role of hydrophobic interactions in yeast phosphoglycerate kinase stability

Cold denaturation of yeast phosphoglycerate kinase (yPGK) was investigated by a combination of far UV circular dichroism (CD), steady-state and time-resolved fluorescence, and small angle X-ray scattering. It was shown that cold denaturation of yPGK cannot be accounted for by a simple two-state process and that an intermediate state can be stabilized under mild denaturing conditions. Comparison between far UV CD and fluorescence shows that in this state the protein displays a fluorescence signal corresponding mainly to exposed tryptophans, whereas its CD signal is only partially modified. Comparison with spectroscopic data obtained from a mutant missing the last 12 amino-acids (yPGK delta404) suggests that lowering the temperature mainly results in a destabilization of hydrophobic interactions between the two domains. Small angle X-ray scattering measurements give further information about this stabilized intermediate. At 4 degrees C and in the presence of 0.45 M Gdn-HCl, the main species corresponds to a protein as compact as native yPGK, whereas a significant proportion of ellipticity has been lost. Although various techniques have shown the existence of residual structures in denatured proteins, this is one example of a compact denatured state devoid of its main content in alpha helices.

Role of the C-terminal extremities of the smooth muscle myosin heavy chains: implication for assembly properties

The two light meromyosin isoforms from rabbit smooth muscle were prepared as recombinant proteins in Escherichia coli. These species which differed only by their C-terminal extremity showed the same circular dichroism spectra and endotherms in measurements of differential scanning calorimetry. Their solubility properties were different at pH 7.0 in the absence of monovalent salts. Their paracrystals formed at low pH differed by their aspect and number. These data suggest a role for the C-terminal extremity of myosin heavy chains in the assembly of myosin molecules in filaments and consequently in the contractility of smooth muscles.

Kinetic evidence for the formation of a Michaelis-Menten-like complex between horseradish peroxidase compound II and di-(N-acetyl-L-tyrosine)

The formation of a reversible adsorption complex between a dimer of N-acetyl-L-tyrosine [di-(N-acetyl-L-tyrosine), (NAT)2] and horseradish peroxidase (HRP) compound II (CII) was demonstrated using a kinetic approach. A specific KIIm value (0.58 mM) was deduced for this step from stopped-flow measurements. The dimerization of the dipeptide Gly-Tyr was analysed at the steady state and compared with (NAT)2 dimerization [(NAT)2-->(NAT)4]. A saturation of the enzyme was observed for both substrates within their range of solubility. In each case the rate of dimerization reflected the rate-limiting step of compound II reduction to the native HRP (E) (kappcat/Kappm approximately kII-->E). The kappcat values for (Gly-Tyr)2 and (NAT)4 formation were 254 s-1 and 3.6 s-1 respectively. The KappM value of Gly-Tyr was 24 mM. It was observed that the value (0.7 mM) for (NAT)2 was close both to its specific KIIm value for the second step of reduction (CII-->E) and to its thermodynamic dissociation constant (Kd=0.7 mM) with the resting form of the enzyme. As (NAT)2 was a tighter ligand but a poorer substrate than Gly-Tyr, a steady-state kinetic study was performed in the presence of both substrates. A kinetic model which includes an enzyme-substrate adsorption prior to each of the two steps of reduction was derived. This one agreed reasonably well with the experimental data.

Steady state and time-resolved fluorescence study of residual structures in an unfolded form of yeast phosphoglycerate kinase

A previous study performed using steady state fluorescence has revealed the existence of residual structures surrounding the two tryptophan residues in an unfolded form of yeast phosphoglycerate kinase [Garcia, P., et al. (1995) Biochemistry 34, 397-404]. In this paper, we present a more detailed characterization of these residual structures, through the study of two single tryptophan-containing mutants of yPGK, W333F and W308Y. Denaturation experiments have first been performed at low temperatures to assess the nature of the interactions stabilizing these residual structures. On the other hand, the compactness and dynamics of the protein matrix were probed using tryptophan fluorescence quenching by acrylamide at various denaturant concentrations. Taking into consideration the changes in sample viscosity induced by addition of guanidinium chloride made feasible the use of this technique during the denaturation process. These different approaches have shown that the residual structures around tryptophan 308 are mainly stabilized by hydrophobic interactions and are more compact and less fluctuant than the ones surrounding tryptophan 333. Native and denatured yPGK have also been studied by time-resolved fluorescence spectroscopy. In the native protein, tryptophan buried in the core, W333, is mainly associated with a lifetime close to 0.1 ns, whereas tryptophan that is partially accessible to the solvent, W308, has a lifetime close to 0. 5 ns. The time-resolved tryptophan fluorescence emission of wild-type yPGK can be accounted for quantitatively by the summed emissions of its two single tryptophan mutants. The significance of minor long lifetime components is discussed for the two tryptophan residues. This new assignment of fluorescent decay times has allowed for the detection of a folding intermediate in which the environment of tryptophan 333 is modified for denaturant concentrations lower than those for tryptophan 308.

Repulsive interparticle interactions in a denatured protein solution revealed by small angle neutron scattering

In order to investigate the effect of concentration in biological processes such as protein folding, small angle neutron scattering measurements were used to determine the second virial coefficient of solutions of both native and strongly denatured phosphoglycerate kinase and the radius of gyration of the protein at zero concentration. The value of the second virial coefficient is a good probe of the non-ideality of a solution. The present results show that the unfolding of the protein leads to a drastic change in the repulsive intermolecular interactions. We conclude that these interactions are due mainly to the behaviour of the denatured polypeptide chain as an excluded volume polymer.

Horseradish peroxidase oxidation of tyrosine-containing peptides and their subsequent polymerization: a kinetic study

Tyrosine-containing model peptides were oxidized by horseradish peroxidase (HRP). This led to a peptide polymerization via condensation of the aromatic rings. Dimers, trimers, and tetramers (depending on the peptide length and on the position of the tyrosine in the sequence) were identified by electron spray mass spectroscopy. The second-order rate constants of the second step of the HRP reduction (CII --> E) was decreased by the presence of a positively charged amino group in the vicinity of the aromatic ring as determined by stopped flow measurements [k3 = 19 398 M-1 s-1 and k3 = 1016 M-1 s-1 for N-acetyltyrosine (NAT) and l-Tyr oxidations, respectively]. High-performance liquid chromatography was used to follow the kinetics of polymerization of some model peptides after their enzymatic oxidation. The first polymerization products exhibited a strong inhibitory effect toward further oxidation by HRP. This effect was not observed when using manganese-dependent peroxidase (MnP) which does not bind directly to the tyrosine residue but rather acts as a "distant catalyst". Saturation of the HRP was achieved with Pro-Gln-Gln-Pro-Tyr (kcat = 58 s-1, = 2.1 mM), NAT (kcat = 94 s-1, = 5.6 mM), and Gly-Tyr (kcat = 175 s-1, = 10.8 mM). Analysis of steady state kinetics of the reaction showed that the dimers formed initially behaved like competitive inhibitors. The value of the dissociation constant between HRP and dimers was 20 microM. A simplified model which accounts for these observations, including the formation of a Michaelis-Menten-like complex involving the donor and enzyme, is proposed and discussed.

Picosecond dynamical changes on denaturation of yeast phosphoglycerate kinase revealed by quasielastic neutron scattering

Quasielastic neutron scattering experiments performed on yeast phosphoglycerate kinase in the native form and denatured in 1.5 M guanidinium chloride reveal a change in the fast (picosecond time scale) diffusive internal dynamics of the protein. The momentum and energy transfer dependences of the scattering for both states are fitted by an analytical model in which, on the experimentally accessible picosecond time scale and angstrom length scale, the dynamics of a fraction of the nonexchangeable hydrogens in the protein is described as a superposition of vibrations with uniform diffusion in a sphere, the rest of the hydrogens undergoing only vibrational motion. The fraction diffusing changes, from approximately 60% in the native protein to approximately 82% in the denatured protein. The radius of the sphere also changes slightly, from approximately 1.8 A in the native protein to approximately 2.2 A in the denatured protein. Possible implications of these results for the general protein folding problem are discussed.

Small-angle neutron scattering by a strongly denatured protein: analysis using random polymer theory

Small-angle neutron scattering profiles are presented from phosphoglycerate kinase, in the native form and strongly denatured in 4 M guanidinium chloride (GdnHCl) solution. The data are interpreted using a model in which the excess scattering density associated with the protein is represented as a finite freely jointed chain of spheres. The similarity of the model-derived scattering function to experiment increases asymptotically with the number of spheres. The improvement of the fit obtained with more than approximately 200 spheres (i.e., two residues per sphere) is insignificant. The effects of finite size of the scattering units and of scattering length variation along the polypeptide chain are examined. Improved agreement with experiment is obtained when these effects are taken into account. A method for rapid calculation of the scattering profile of a full, all-atom configuration is examined. It is found that a representation of the chain containing two scattering units per residue, placed at the backbone and side-chain scattering length centroids, reproduces the full, all-atom profile to within 2%.

Phosphorylation of nucleoside diphosphate kinase at the active site studied by steady-state and time-resolved fluorescence

Nucleoside diphosphate (NDP) kinase is the enzyme responsible in the cell for the phosphorylation of nucleoside or deoxynucleoside diphosphates into the corresponding triphosphates at the expense of ATP. Transfer of the gamma-phosphate is very fast (turnover number above 1000 s-1) and involves the phosphorylation of a histidine residue at the active site of the enzyme. We have used intrinsic protein fluorescence of the single tryptophan of Dictyostelium discoideum NDP kinase as a sensitive probe for monitoring the interaction of the enzyme with its substrates. We demonstrate that the 20% quenching of steady-state fluorescence observed upon addition of ATP is due to formation of the phosphorylated intermediate. Time-resolved fluorescence indicates that the Trp-137 side chain is rigidly bound to the protein core with a unique lifetime of 4.5 ns for the free enzyme at 20 degrees C and that it remains tightly immobilized during the time course of the reaction. Phosphorylation of this catalytic residue (His-122) in the presence of ATP induces a similar decrease in mean lifetime, due to the splitting of the signal and the appearance of a shorter decay. This splitting is discussed in terms of a slow conformational equilibrium. We demonstrate that, in the wild-type enzyme, the conserved His-55 quenches the fluorescence of Trp-137 as the H55A mutant protein fluorescence displays an increase in quantum yield. Even though H55A mutant enzyme is active, the absence of the imidazole ring prevents the detection of the phosphorylated state of His-122 by Trp-137. We conclude that His-55 serves as a relay between His-122 and Trp-137.

Purification and structural and functional characterization of FhuA, a transporter of the Escherichia coli outer membrane

The Escherichia coli outer membrane ferrichrome transporter FhuA was purified chromatographically in a neutral detergent (octyl glucoside or dodecyl maltoside). The amount of dodecyl maltoside bound to the protein (1.2 +/- 0.15 g/g of FhuA) and the Stokes radius of the FhuA-dodecyl maltoside complex (Rs = 4.2 nm) were determined using size exclusion chromatography. Sedimentation equilibrium and velocity experiments indicated that the FhuA preparation was monodisperse and that the protein was monomeric. The value found for the frictional coefficient of the protein-detergent complex (1.18) suggested a globular shape for the complex. Sedimentation experiments gave values for the molecular mass of the FhuA-dodecyl maltoside complex (180 kDa) and for the Stokes radius in complete agreement with those calculated from size exclusion chromatography. The circular dichroism spectrum indicated a 51% beta-sheet content. Functionality of the purified protein was assessed from fluorescence measurements using the DNA probe YO-PRO-1. Interaction of nM concentrations of FhuA with bacteriophage T5 resulted in the release of 90 +/- 8% of the phage DNA. The limiting step in DNA ejection was binding of the phage to its receptor. Release of DNA took place in a few seconds. Ferrichrome (0.8 microM) competed with the phage for binding to FhuA and prevented DNA ejection.

Folding and functional complementation of engineered fragments from yeast phosphoglycerate kinase

A set of protein fragments was produced by site-directed mutagenesis followed by chemical cleavage of phosphoglycerate kinase according to a previously described method [Pecorari et al. (1993) Protein Eng. 6, 313-325]. The cleavage positions were chosen in order to correspond to limits between structural subdomains. These isolated fragments were studied by circular dichroism, folding transitions, and cross-linking analyses. It appears that fragments corresponding to globular subdomains in the protein can recover the expected helix content. However, the cooperativity classically observed in the folding transitions of natural proteins is only observed for fragments larger than a domain. Previous studies have shown that the isolated C-terminal domain is an autonomous folding unit which displays a single cooperatine transition [Missiakas et al. (1990) Biochemistry 29, 8683-8689]. The results presented here show that the presence in a fragment of a sequence overpassing that of the C-terminal domain modifies its folding process. Reassociation experiments suggest that the efficiency of the complementation process is not related to the folding autonomy of the isolated fragments.

Occurrence of transient multimeric species during the refolding of a monomeric protein

A set of protein fragments from yeast phosphoglycerate kinase were produced by chemical cleavage at a unique cysteinyl residue previously introduced by site-directed mutagenesis. Cross-linking experiments showed that the fragments corresponding to incomplete N-terminal domain form stable oligomeric species. Transient oligomeric species were also observed by both cross-linking and light scattering experiments during the folding process of the whole protein. These transient oligomeric species are formed during the fast folding phase and dissociate during the slow folding phase to produce the monomeric active protein. The multimeric species are not required for the protein to fold correctly. Unexpectedly, the distribution of oligomeric species is not dependent on protein concentration during the folding process. A kinetic competition mechanism is proposed as a possible solution to this paradox. These results provide direct evidence that the polypeptide chain can explore nonnative interactions during the folding process.