Protein folding intermediates with rapidly exchangeable amide protons contain authentic hydrogen-bonded secondary structures

Separation of antigens and antibodies by immunoaffinity chromatography

CONTEXT

Affinity chromatography is an efficient antibody, antigen and protein separation method based on the interaction between specific immobilized ligands and target antibody, antigen, and so on. Populations of available ligands can be used to separate antibodies or their Fab fragments. Similarly, antigens can be isolated by immunoaffinity chromatography (IAC) on immobilized antibodies of low affinity.

OBJECTIVE

This review describes the advantages, the applications, as well as the drawbacks, of IAC in the separation and purification of antibodies and antigens.

METHODS

The present review discussed all types of purification and isolation of antibodies and antigens by IAC, including purification of antibodies using immobilized and synthetic mimic proteins A, G and L; isolation of Fab fragments of antibodies; separation of antibodies against different antigen forms; isolation of antigens by immobilized antibodies and so on. These methods come from over 60 references compiled from all major databases.

RESULTS

Purification of antigens with antibodies should choose low-affinity antibodies to avoid denaturation of most proteins. Concern for cost and safety, prompted research activities focused on novel synthetic ligands with improved properties such as lower cost, avoidance of the risk of contamination associated with natural ligands of human or animal origin to isolate antibodies and antigens.

CONCLUSION

It is anticipated that the improvements of IAC will have impact not only on large-scale production of antibodies but also on the generation of new affinity-based methods for the increasing number of proteins and antibody derivatives available by protein engineering and the proteomics revolution.

Structural malleability of plasticins: Preorganized conformations in solution and relevance for antimicrobial activity

Plasticins (23 long-residue glycine-leucine-rich dermaseptin-related peptides produced by the skin of South American hylids) have very similar amino acid sequences, hydrophobicities, and amphipathicities, but differ in their membrane-damaging properties and structurations (i.e. destabilized helix states, beta-hairpin, beta-sheet, and disordered states) at anionic and zwitterionic membrane interfaces. Structural malleability of plasticins in aqueous solutions together with parameters that may govern their ability to fold within beta-hairpin like structures were analyzed through circular dichroism and FTIR spectroscopic studies completed by molecular dynamics simulations in polar mimetic media. The goal of this study was to probe to which extent pre-existent peptide conformations, i.e. intrinsic "conformational landscape", may be responsible for variability in bioactive conformation and antimicrobial/hemolytic mechanisms of action of these peptides in relation with their various membrane disturbing properties. All plasticins present a turn region that does not always result in folding into a beta-hairpin shaped conformation. Residue at position 8 plays a major role in initiating the folding, while position 12 is not critical. Conformational stability has no major impact on antimicrobial efficacy. However, preformed beta-hairpin in solution may act as a conformational lock that prevents switch to alpha-helical structure. This lock lowers the antimicrobial efficiency and explains subtle differences in potencies of the most active antimicrobial plasticins.

Thermotoga maritima IscU. Structural characterization and dynamics of a new class of metallochaperone

Members of the IscU family of proteins are among the most conserved of all protein groups, extending across all three kingdoms of life. IscU serves as a scaffold for the assembly of intermediate iron-sulfur cluster centers and further mediates delivery to apo protein targets. Several proteins that mediate delivery of single metal ions to apo targets (termed metallochaperones) have recently been characterized structurally. Each displays a ferredoxin-like betaalphabetabetaalphabeta motif as a structural core. Assembly and delivery of a polynuclear iron-sulfur cluster is, however, a more complex pathway and presumably would demand a distinctive protein mediator. Here, we demonstrate Thermotoga maritima IscU (Tm IscU) to display unique structural and motional characteristics that distinguish it from other members of this class of proteins. In particular, IscU adopts a mobile, physiologically relevant, molten globule-like state that is vastly different from the previously identified ferredoxin-like fold that has thus far been characterized for other metallochaperones. The secondary structural content of Tm IscU is consistent with previous circular dichroism measurements on apo and holo protein, consisting of six alpha-helices and three beta-strands, the latter forming an anti-parallel beta-sheet. Extensive dynamics studies are consistent with a protein that has reasonably well defined secondary structural elements, but with a tertiary structure that is fluxional among widely different conformational arrangements. Analogous conformational flexibility does not exist in other structurally characterized metallochaperones; however, such a dynamic molecule may account for the lack of long-range NOEs, and allow both for the flexibility that is necessary for the multiple roles of Fe-S cluster assembly, and recognition and delivery of that cluster to a target protein. Additionally, the fluxionality of IscU is unique in that the protein appears to be more compact (based on 1H/2H exchange, R1, R2, and NOE data) but yet more fluid (lack of long-range NOEs) than typical molten globule proteins.

Isolation of antigens and antibodies by affinity chromatography

Antibody-antigen binding constants are commonly strong enough for an effective affinity purification of antibodies (by immobilized antigens) or antigens (by immobilized antibodies) to work out a straightforward purification method. A drawback is that antibodies are large protein molecules and subject to denaturation under conditions required for the elution from the complex. Structures of antigens can vary but usually antigens are also equally subject to similar problems. The lability of the components can sometimes make the procedure sophisticated, but usually in all cases it is possible to find a satisfactory approach. In certain cases, specific interactions of the Fc part of antibodies are more facile to exploit for their purification.

Beta-turn formation by a six-residue linear peptide in solution

A model peptide AAGDYY-NH2 (B1), which is found to adopt a beta-turn conformation in the TEM-1 beta-lactamase inhibitor protein (BLIP) in the TEM-1/BLIP co-crystal, was synthesized to elucidate the mechanism of its beta-turn formation and stability. Its structural preferences in solution were comprehensively characterized using CD, FT-IR and 1H NMR spectroscopy, respectively. The set of observed diagnostic NOEs, the restrained molecular dynamics simulation, CD and FT-IR spectroscopy confirmed the formation of a beta-turn in solution by the model peptide. The dihedral angles [(phi3, phi3) (phi4, phi4)] of [(-52 degrees, -32 degrees ) (-38 degrees, -44 degrees )] of Gly-Asp fragment in the model peptide are consistent with those of a type III beta-turn. In a conclusion, the conformational preference of the linear hexapeptide B1 in solution was determined, and it would provide a simple template to study the mechanism of beta-turn formation and stability.

Chaperone function of FkpA, a heat shock prolyl isomerase, in the periplasm of Escherichia coli

The nature of molecular chaperones in the periplasm of Escherichia coli that assist newly translocated proteins to reach their native state has remained poorly defined. Here, we show that FkpA, a heat shock periplasmic peptidyl-prolyl cis/trans isomerase (PPIase), suppresses the formation of inclusion bodies from a defective-folding variant of the maltose-binding protein, MalE31. This chaperone-like activity of FkpA, which is independent of its PPIase activity, requires a full-length structure of the protein. In vitro, FkpA does not catalyse a slow rate-limiting step in the refolding of MalE31, but prevents its aggregation at stoichiometric amounts and promotes the reactivation of denaturated citrate synthase. We propose that FkpA functions as a chaperone for envelope proteins in the bacterial periplasm.

Direct evidence for the cooperative unfolding of cytochrome c in lipid membranes from H-(2)H exchange kinetics

The interaction of cytochrome c (cyt c) with anionic lipid membranes is known to disrupt the tightly packed native structure of the protein. This process leads to a lipid-inserted denatured state, which retains a native-like alpha-helical structure but lacks any specific tertiary interactions. The structural and dynamic properties of cyt c bound to vesicles containing an anionic phospholipid (DOPS) were investigated by amide H-(2)H exchange using two-dimensional NMR spectroscopy and electrospray ionisation mass spectrometry. The H-(2)H exchange kinetics of the core amide protons in cyt c, which in the native protein undergo exchange via an uncorrelated EX2 mechanism, exchange in the lipid vesicles via a highly concerted global transition that exposes these protected amide groups to solvent. The lack of pH dependence and the observation of distinct populations of deuterated and protonated species by mass spectrometry confirms that exchange occurs via an EX1 mechanism with a common rate of 1(+/-0.5) h(-1), which reflects the rate of transition from the lipid-inserted state, H(l), to an unprotected conformation, D(i), associated with the lipid interface.

A rapid test for identification of autonomous folding units in proteins

The structure of a protein is dictated by a large number of weak interactions that cooperatively stabilize the native state. Usually, excised fragments smaller than a domain have little if any residual structure. When autonomous units of structure are found within domains, this challenges common assumptions about the cooperativity of protein structure. Such autonomous folding units (AFUs) are of wide interest and have applications in protein engineering and as simple model systems for studying the determinants of stability and specificity. A new method of identifying AFUs within proteins is presented here. The rapid autonomous fragment test (RAFT) identifies AFUs based on analysis of inter-residue contacts present in the three-dimensional structure of a protein. RAFT is fast enough to mine the entire PDB for AFUs and provide a library of potential small stable folds. We show that RAFT is able to predict whether a protein fragment will be structured if isolated from its parent domain.

Circular dichroism study of ribonuclease A mutants containing the minimal structural requirements for dimerization and swapping

Four residues Pro19. Leu28, Cys31 and Cys32 proved to be the minimal structural requirements in determining the dimeric structure and the N-terminal segment swapping of bovine seminal ribonuclease, BS-RNase. We analyzed the content of secondary and tertiary structures in RNase A, P-RNase A, PL-RNase A, MCAM-PLCC-RNase A and MCAM-BS-RNase, performing near and far-UV CD spectra. It results that the five proteins have very similar native conformations. Thermal denaturation at pH 5.0 of the proteins. studied by means of CD measurements. proved reversible and well represented by the two-state N<==>D transition model. Thermodynamic data are discussed in the light of the structural information available for RNase A and BS-RNase.

Two-dimensional mid-IR and near-IR correlation spectra of ribonuclease A: using overtones and combination modes to monitor changes in secondary structure

We introduce near-IR spectroscopy as an ancillary tool for monitoring structural changes of proteins in aqueous solution using ribonuclease A (RNase A) as a model protein. The thermal unfolding of RNase A results in clear spectral changes in the near-IR and the mid-IR regions. In the near-IR the most pronounced changes are observed in the spectral region between 4820 and 4940 cm-1. The strong N-H combination band found at 4867 cm-1 in the spectrum of native RNase A shifts to 4878 cm-1 upon thermal unfolding. Hydrogen-deuterium exchange experiments that validate the N-H character of this mode can also be used to estimate the number of unexchanged amide protons after exposure to D2O. The transition profiles and temperatures derived from the temperature dependence of the N-H combination mode were found to be practically identical with those derived from the temperature dependence of the C = O amide I band in the mid-IR region, demonstrating that the near-IR region can be used as a conformation-sensitive monitor for the thermally induced unfolding of proteins in H2O solution. A 2-dimensional correlation analysis was applied to the mid-IR and near-IR spectra of RNase A to establish correlations between IR bands in both regions. The correlation analysis demonstrates that the thermal unfolding of RNase A is not a completely cooperative process; rather it begins with some changes in beta-sheet structure, followed by the loss of alpha-helical structures, and then ending with the unfolding of the remaining beta-sheets.

Initial hydrophobic collapse is not necessary for folding RNase A

BACKGROUND

One of the main distinctions between different theories describing protein folding is the predicted sequence of secondary structure formation and compaction during the folding process. Whether secondary structure formation precedes compaction of the protein molecules or secondary structure formation is driven by a hydrophobic collapse cannot be decided unequivocally on the basis of existing experimental data.

RESULTS

In this study, we investigate the refolding of chemically denatured, disulfide-intact ribonuclease A (RNase A) by monitoring compaction and secondary structure formation using stopped-flow dynamic light scattering and stopped-flow CD, respectively. Our data reveal the formation of a considerable amount of secondary structure early in the refolding of the slow folding species of RNase A without a significant compaction of the molecules. A simultaneous formation of secondary structure and compaction is observed in the subsequent rate-limiting step of folding.

CONCLUSIONS

During folding of RNase A an initial global hydrophobicity is not observed, which contradicts the view that this is a general requirement for protein folding. This folding behavior could be typical of similar, moderately hydrophobic proteins.

Reversible unfolding of sheep liver tetrameric serine hydroxymethyltransferase

Equilibrium unfolding studies of the tetrameric serine hydroxymethyltransferase from sheep liver (SHMT, E.C.2.1.2.1) revealed that the holoenzyme, apoenzyme and the sodium borohydride-reduced holoenzyme had random coil structures in 8 M urea. In the presence of a non-ionic detergent, Brij-35, and polyethylene glycol, the 8 M urea unfolded protein could be completely (> 95%) refolded by a 20-fold dilution. The refolded enzyme was completely active and kinetically similar to the native enzyme. The midpoint of inactivation of the enzyme occurred at a urea concentration that was much below the urea concentration required to bring about a substantial loss of secondary structure. This observation suggested the occurrence of a 'predenaturation transition' in the unfolding pathway. The equilibrium urea-induced denaturation curve of holoSHMT showed two transitions. The midpoint of the first transition was 1.2 M, which was comparable to that required for 50% decrease in enzyme activity. Further, 50% release of the pyridoxal-5'-phosphate (PLP) from the active site, as monitored by decrease in absorbance at 425 nm, also occurred at about 1.2 M urea. Size exclusion chromatography showed that the tetrameric SHMT unfolds via the intermediate formation of dimers. This dissociation occurred at a much lower urea concentration (0.15 M) in the unfolding of the apoenzyme, and at a higher urea concentration (1.2 M) in the unfolding of holoenzyme, thereby demonstrating the involvement of PLP in stabilizing the quaternary structure of the enzyme. Size exclusion chromatography of the refolding intermediates demonstrated that the cofactor shifts the equilibrium towards the formation of the active tetramer. The reduced holoenzyme could also be refolded to its native structure, as observed by fluorescence and CD measurements, indicating that the presence of covalently linked PLP does not affect refolding. The results demonstrate clearly that the dimer is an intermediate in the urea-induced equilibrium unfolding/refolding of sheep liver SHMT; and PLP, in addition to its role in catalysis, is required for the stabilization of the tetrameric structure of the enzyme.

Folding kinetics of the SH3 domain of PI3 kinase by real-time NMR combined with optical spectroscopy

The refolding kinetics of the chemically denatured SH3 domain of phosphatidylinositol 3'-kinase (PI3-SH3) have been monitored by real-time one-dimensional 1H NMR coupled with a variety of other biophysical techniques. These experiments indicate that the refolding kinetics of PI3-SH3 are biphasic. The slow phase (27 (+/- 8)% amplitude) is due to a population of substantially unfolded molecules with an incorrectly configured cis proline residue. The fast phase (73 (+/- 8)% amplitude) corresponds to the folding of protein molecules with proline residues in a trans configuration in the unfolded state. NMR experiments indicate that the first species populated after the initiation of folding exhibit poor chemical shift dispersion and have spectra very similar to that of the denatured protein in 8 M guanidine hydrochloride. Linear combinations of the first spectrum and of the spectrum of the native protein accurately reconstruct all of the spectra acquired during refolding. Consistent with this, native side-chain and backbone H alpha atom packing (NMR), secondary structure (far-UV circular dichroism), burial of aromatic residues (near-UV circular dichroism), intrinsic fluorescence and peptide binding activity are all recovered with effectively identical kinetics. Equilibrium unfolding and folding/unfolding kinetics yield, within experimental error, identical values for the free energy of unfolding (delta Gu-H2O = 3.38 kcal mol-1) and for the slope of the free energy of unfolding versus denaturant concentration (meq = 2.33 kcal mol-1 M-1). Together, these data provide strong evidence that PI3-SH3 folds without significant population of kinetic well-structured intermediates. That PI3-SH3 folds slowly (time constant 2.8 seconds in H2O at 20 degrees C) indicates that slow refolding is not always a consequence of kinetic traps but may be observed even when a protein appears to fold via a simple, two-state mechanism.

Kinetics of lysozyme refolding: structural characterization of a non-specifically collapsed state using time-resolved X-ray scattering

We report time-resolved small angle X-ray scattering (SAXS) studies of the structural characteristics of the collapsed state of lysozyme from henegg white (HEL) obtained on initiating refolding by rapidly changing solvent conditions from 8 M to 1.1 M urea at pH 2.9. At this reduced pH the lifetime, of about one second, of the non-specifically collapsed ensemble is considerably prolonged relative to its value at pH 5.2. The SAXS studies are combined with time resolved measurements of tryptophan fluorescence and of the rate of formation of native molecules using interrupted refolding experiments. We observe large burst phase changes in intrinsic tryptophan fluorescence and in the radius of gyration (Rg) which is reduced from 22 A in the fully unfolded state to approximately 19 to 20 A. Subsequent decrease of the Rg to the value for native lysozyme (15 A) follows the time course of formation of native molecules. Single exponential fits to the singular value decomposition (SVD) components of the SAXS data allow reconstruction of the SAXS profile at early time points of refolding. The results of this analysis suggest a globular shape of the collapsed state. A similar fit to the forward scattering amplitude, I(0), suggests that the collapsed state has a solvent accessible surface area which is considerably increased relative to that of the native protein. These results show directly that the non-specifically collapsed state formed during the burst phase in lysozyme refolding indeed represents a molecular compaction and a change in shape from a fully denatured random coil state (albeit restricted by disulfide bonds) to an ensemble of globular conformations which, however, have not yet formed a solvent-protected hydrophobic core.

Purification and spectroscopic characterization of beta-amyloid precursor protein from porcine brains

Soluble and membrane-bound isoforms of beta-amyloid protein precursor (APP) of Alzheimer's disease were extracted and purified from porcine brains. At least three types of soluble APP and membrane-bound APP with different molecular masses, ranging from 86 kDa to 116 kDa, were obtained. CD and infrared spectroscopies were used to determine the overall secondary-structure content of APP. The infrared spectra of soluble and membrane-bound APP (in dry and hydrated states) were similar in the amide-I and amide-II regions, suggesting that the overall secondary structures of the soluble and membrane isoforms were roughly identical. The amide-I band is composed of at least five component bands, located at 1694, 1674, 1652, 1637 and 1618 cm(-1) for soluble APP, and located at 1687, 1674, 1651, 1637 and 1614-1606 cm(-1) for membrane-bound APP, as evidenced by their respective second-derivative infrared spectra. The 1651-1652-cm(-1) band was associated with alpha-helix structures, while two types of beta-sheet structures are evidenced by two characteristic pairs of component bands. The 1674-cm(-1) and 1637-cm(-1) bands for soluble APP and membrane-bound APP were tentatively associated to beta-sheet structures. The second pair of bands, located at 1694 cm(-1) and at 1618 cm(-1) for soluble APP and at 1687 cm(-1) and 1614-1606 cm(-1) for membrane-bound APP, were associated with intermolecular beta-sheet structures or aggregated strands, as confirmed by heat denaturation. CD spectra indicated the presence of alpha-helix structures in soluble and membrane-bound APP. The secondary-structure content, estimated from CD spectra, was about 40-45% alpha-helix and 15-20% beta-sheet structures for soluble and membrane-bound APP.

Lack of coupling between secondary structure formation and collapse in a model polypeptide that mimics early folding intermediates, the F2 fragment of the Escherichia coli tryptophan-synthase beta chain

The isolated, 101-residue long C-terminal (so called F2) fragment of the beta chain from Escherichia coli tryptophan synthase was shown previously to fold into an ensemble of conformations that are condensed, to contain large amounts of highly dynamic secondary structures, and to behave as a good model of structured intermediates that form at the very early stages of protein folding. Here, solvent perturbations were used to investigate the forces that are involved in stabilizing the secondary structure (monitored by far-UV CD) and the condensation of the polypeptide chain (monitored by dynamic light scattering) in isolated F2. It was observed that neither the ionic strength, nor the pH (between 7 and 10), nor salts of the Hofmeister series affected the global secondary structure contents of F2, whereas some of these salts affected the collapse slightly. Addition of trifluoroethanol resulted in a large increase in both the amount of secondary structure and the Stokes radius of F2. Conversely, F2 became more condensed upon raising the temperature from 4 to 60 degrees C, whereas in this temperature range, the secondary structure undergoes significant melting. These observations lead to the conclusion that, in isolated F2, there is no coupling between the hydrophobic collapse and the secondary structure. This finding will be discussed in terms of early events in protein folding.

Kinetics of secondary structure recovery during the refolding of reduced hen egg white lysozyme

We have shown previously that, in less than 4 ms, the unfolded/oxidized hen lysozyme recovered its native secondary structure, while the reduced protein remained fully unfolded. To investigate the role played by disulfide bridges in the acquisition of the secondary structure at later stages of the renaturation/oxidation, the complete refolding of reduced lysozyme was studied. This was done in a renaturation buffer containing 0.5 M guanidinium chloride, 60 microM oxidized glutathione, and 20 microM reduced dithiothreitol, in which the aggregation of lysozyme was minimized and where a renaturation yield of 80% was obtained. The refolded protein could not be distinguished from the native lysozyme by activity, compactness, stability, and several spectroscopic measurements. The kinetics of renaturation were then studied by following the reactivation and the changes in fluorescence and circular dichroism signals. When bi- or triphasic sequential models were fitted to the experimental data, the first two phases had the same calculated rate constants for all the signals showing that, within the time resolution of these experiments, the folding/oxidation of hen lysozyme is highly cooperative, with the secondary structure, the tertiary structure, and the integrity of the active site appearing simultaneously.

The "pre-molten globule," a new intermediate in protein folding

In vitro folding studies of several proteins revealed the formation, within 2-4 msec, of transient intermediates with a large far-UV ellipticity but no amide proton protection. To solve the contradiction between the secondary structure contents estimated by these two methods, we characterized the isolated C-terminal fragment F2 of the tryptophan synthase beta 2 subunit. In beta 2, F2 forms its tertiary interactions with the F1 N-terminal region. Hence, in the absence of F1, isolated F2 should remain at an early folding stage with no long-range interactions. We shall show that isolated F2 folds into, and remains in, a "state" called the pre-molten globule, that indeed corresponds to a 2- to 4-msec intermediate. This condensed, but not compact, "state" corresponds to an array of conformations in rapid equilibrium comprising native as well as nonnative secondary structures. It fits the "new view" on the folding process.

Conformational changes of arginine kinase induced by photochemical release of nucleotides from caged nucleotides--an infrared difference-spectroscopy investigation

The conformations of arginine kinase (AK) in AK x Mg x ADP, AK x Mg x ATP, AK x Mg x ADP x NO3-, AK x Mg x ADP x Arg and AK x Mg x ADP x NO3- x Arg complexes were investigated by measuring their reaction-induced infrared difference spectra (RIDS). The photochemical release of ATP from ATP[Et(PhNO2)] and of ADP from ADP[Et(PhNO2)] produced distinct RIDS of AK complexes, suggesting that binding of ADP and ATP promoted different structural alterations of the enzyme active-site. Small infrared changes in the amide-I region were observed, indicating that about 5-10 amino acid residues were involved in the nucleotide-binding site. These infrared changes were due to the structural alteration of the peptide backbone caused by the nucleotide-binding and to the coupling effects between the nucleotide-binding site and the other substrate (Arg or NO3-)-binding site. ATP binding to AK (as well as ADP-binding to AK in the presence of NO3-) induced protonation of a carboxylate group of Asp or Glu, as evidenced by the appearance of the 1733-cm(-1) band, which was not observed with the AK x Mg x ADP, AK x Mg x ADP x Arg and AK x Mg x ADP x NO3- x Arg complexes. The RIDS of the AK x Mg x ADP x NO3- x Arg complex showed new infrared bands at 1622 cm(-1) (negative) and at 1613 cm(-1) (positive), which were not seen in the RIDS of other complexes (without NO3- or/and Arg). In the transition-state-analog complex of AK, no protonation of the carboxylate residue (Asp or Glu) was observed, and the binding site of NO3- or the gamma-phosphate group of nucleotide was altered.

Kinetic role of early intermediates in protein folding

The traditional view that partly folded intermediates are important for directing a protein toward the native state has been challenged by the notion that proteins can intrinsically fold rapidly in a single step if kinetic complications due to slow conformational events are avoided. Intermediates that accumulate within the first few milliseconds of folding are, however, a common observation even for small single-domain proteins. Recent spectroscopic studies, coupled with quantitative kinetic analysis, suggest that folding is facilitated by the rapid formation of compact intermediates with some native-like structural features.

Nereis sarcoplasmic Ca2+-binding protein has a highly unstructured apo state which is switched to the native state upon binding of the first Ca2+ ion

NSCP, a sarcoplasmic Ca2+/Mg2+-binding protein from Nereis diversicolor, shows an allosteric change during Ca2+ binding and a high positive cooperativity for Mg2+ binding. Here we report the results of CD and NMR experiments aiming to characterize the apo state and the Ca2+-induced conformational changes in this protein. Circular dichroism spectra of the apo form are indicative of a reduced helical structure. In contrast, NMR spectra show no element of regular secondary or tertiary structure. Addition of one Ca2+ determines large spectral changes bringing the molecule in a conformation which is very close to the native three Ca2+ state. Addition of the second and third Ca2+ shifts this equilibrium progressively towards the liganded conformation but affects only minimally the spectrum of the liganded species.

Transient non-native interactions in early folding intermediates do not influence the folding kinetics of Escherichia coli tryptophan synthase beta 2 subunits

Local structures formed in early intermediates are thought to play a key role in orientating the protein folding pathway. Here, we test whether non-native interactions formed by eight N-terminal residues in early folding intermediates of tryptophan synthase beta chains [Navon, A., Schulze, A. J., Guillou, Y., Zylinksii, C. A., Baleux, F., Expert-Bezançon, N., Friguet, B., Djavadi-Ohaniance, L. & Goldberg, M. E. (1995) J. Biol. Chem. 270, 4255-4261] influence the folding kinetics. The kinetics of in vitro renaturation of wild-type beta chains and truncated beta chains lacking residues 2-9 were compared. Each step analyzed (molten globule formation, tryptophan shielding, closing up of distant residues, and complete renaturation) occurred with similar kinetics in the normal and truncated proteins. Thus, non-native interactions formed early during the folding of beta chains seem to influence neither the rate and efficiency of the complete renaturation, nor the kinetics of the early folding steps, which suggests that such non-native early intermediates are poorly stable and highly dynamic. This observation is consistent with the current view that productive folding should avoid the formation of stable intermediates.

A fragment of staphylococcal nuclease with an OB-fold structure shows hydrogen-exchange protection factors in the range reported for "molten globules"

Hydrogen-exchange rates for an OB-fold subdomain fragment of staphylococcal nuclease have been measured at pH 4.7 and 4 degrees C, conditions close to the minimum of acid/base catalyzed exchange. The strongest protection from solvent exchange is observed for residues from a five-stranded beta-barrel in the NMR structure of the protein. Protection factors, calculated from the experimental hydrogen-exchange rates, range between 1 and 190. Similarly small protection factors have in many cases been attributed to "molten globule" conformations that are supposed to lack a specific tertiary structure. The present results suggest that marginal protection from solvent exchange does not exclude well-defined structure.

Infrared evidence of a beta-hairpin peptide structure in solution

The IR spectrum of an 16-amino acid peptide corresponding, according to NMR studies, to a beta-hairpin has been analysed. Two characteristic features distinguish its spectrum from that of an antiparallel beta-sheet: the low-frequency band that in a beta-sheet structure is located at approximately 1632 cm-1 appears here at approximately 1620 cm-1, and the high-frequency component does not undergo the isotopic shift typical of beta-sheet from 1690 to 1675 cm-1 when transferred to D2O. The infrared characteristics associated with beta-hairpins have been described so far in two proteins, in one of which, whose three-dimensional structure is known from X-ray diffraction, a beta-hairpin has actually been detected.

The pH dependence of hydrogen-deuterium exchange in trp repressor: the exchange rate of amide protons in proteins reflects tertiary interactions, not only secondary structure

The pH dependence of amide proton exchange rates have been measured for trp-repressor. One class of protons exchanges too fast to be measured in these experiments. Among the protons that have measurable hydrogen-deuterium exchange rates, two additional classes may be distinguished. The second class of protons are in elements of secondary structure that are mostly on the surface of the protein, and exchange linearly with increasing base concentration (log kex versus pH). The third class of amide protons is characterized by much higher protection against exchange at higher pH. These protons are located in the core of the protein, in helices B and C. The exchange rate in the core region does not increase linearly with pH, but rather goes through a minimum around pH 6. The mechanism of exchange for the slowly exchanging core protons is interpreted in terms of the two-process model of Hilton and Woodward (1979, Biochemistry 18:5834-5841), i.e., exchange through both a local mechanism that does not require unfolding of the protein, and a mechanism involving global unfolding of the protein. The increase in exchange rates at low pH is attributed to a partial unfolding of the repressor. It is concluded that the formation of secondary structure alone is insufficient to account for the high protection factors seen in the core of native proteins at higher pH, and that tertiary interactions are essential to stabilize the structure.

Structural analysis of non-native states of proteins by NMR methods

Established NMR methods are increasingly being applied to the non-native states of proteins. For small denatured proteins, full assignment of proton, 15N and 13C resonances is often straightforward. Sensitive methods exist for detecting fractionally populated alpha helices and beta strands, but defining transient interactions among side chains is proving more problematic. The non-native states of several small proteins are being intensively investigated to address a number of questions about protein folding.

Analysis of the structural organization and thermal stability of two spermadhesins. Calorimetric, circular dichroic and Fourier-transform infrared spectroscopic studies

The CUB domain is a widespread 110-amino-acid module found in functionally diverse, often developmentally regulated proteins, for which an antiparallel beta-barrel topology similar to that in immunoglobulin V domains has been predicted. Spermadhesins have been proposed as a subgroup of this protein family built up by a single CUB domain architecture. To test the proposed structural model, we have analyzed the structural organization of two members of the spermadhesin protein family, porcine seminal plasma proteins I/II (PSP-I/PSP-II) heterodimer and bovine acidic seminal fluid protein (aSFP) homodimer, using differential scanning calorimetry, far-ultraviolet circular dichroism and Fourier-transform infrared spectroscopy. Thermal unfolding of PSP-I/PSP-II and aSFP were irreversible and followed a one-step process with transition temperatures (Tm) of 60.5 degrees C and 78.6 degrees C, respectively. The calorimetric enthalpy changes (delta Hcat) of thermal denaturation were 439 kJ/mol for PSP-I/PSP-II and 660 kJ/mol for aSFP dimer. Analysis of the calorimetric curves of PSP-I/PSP-II showed that the entire dimer constituted the cooperative unfolding unit. Fourier-transform infrared spectroscopy and deconvolution of circular dichroic spectra using a convex constraint analysis indicated that beta-structure and turns are the major structural element of both PSP-I/PSP-II (53% of beta-sheet, 21% of turns) and aSFP (44% of beta-sheet, 36% of turns), and that the porcine and the bovine proteins contain little, if any, alpha-helical structure. Taken together, our results indicate that the porcine and the bovine spermadhesin molecules are probably all-beta-structure proteins, and would support a beta-barrel topology like that predicted for the CUB domain. Other beta-structure folds, such as the Greek-key pattern characteristic of many carbohydrate-binding protein domains cannot be eliminated. Finally, the same combination of biophysical techniques was used to characterize the residual secondary structure of thermally denatured forms of PSP-I/PSP-II and aSFP, and to emphasize the aggregation tendency of these forms.

Effects of pH and KCl on the conformations of creatine kinase from rabbit muscle. Infrared, circular dichroic and fluorescence studies

The activity loss of creatine kinase (CK), observed at low pH (midpoint was 4.8) corresponded to the monomerization of the dimeric protein and was correlated with structural changes. The acid-induced unfolding was not complete at this pH, as probed by circular dichroic (CD) and fluorescence methods. Further decrease of pH, led to a second transition (midpoint was pH 3.5). The loss of activity was irreversible at pH 4.8 (< 20% native activity was recovered) while it was almost fully reversible (> 90% of native activity was recovered) for the enzyme incubated at pH 0.9-2.5. The amount of intermolecular beta-sheets (monitored with the 1620 cm-1 infrared component band) was maximal when the enzyme was incubated at pH 4.8, as a consequence of protein aggregation, while it was minimal at extremes of pH and at low ionic strength. Acid-induced and alkaline-induced denaturations promoted different structural changes, leading to distinct partially unfolded conformational states. The addition of KCl (from 0.05 M to 0.5 M) to an acidic solution of monomeric creatine kinase (pH 1.6) resulted in a highly cooperative transition from the partially unfolded conformation (UA) to the more compact conformation (A) with the properties of a molten globule, as probed by CD spectra and by fluorescence. The formation of intermolecular beta-sheets in the compact conformation was observed by infrared spectroscopy, indicating formation of unstable aggregates.

Initial hydrophobic collapse in the folding of barstar

Two models are commonly used to describe the poorly understood earliest steps of protein folding. The framework model stresses very early formation of nascent secondary structures, which coalesce into a compact, molten, globule-like form from which tertiary structure slowly develops. The hydrophobic collapse model gives overriding precedence to a nonspecific collapse of the polypeptide chain which facilitates subsequent formation of specific secondary and tertiary structure. Here we report our analysis of the earliest observable events of the major folding pathway of barstar, a small protein. We compare the kinetics of folding using circular dichroism at 222 nm and 270 nm, intrinsic tryptophan fluorescence, fluorescence of the hydrophobic dye 8-anilino-1-naphthalene-sulphonic acid on binding, and restoration of tryptophan-dansyl fluorescence energy transfer as structure-monitoring probes. We show that the polypeptide chain rapidly collapses (within 4 ms) to a compact globule with a solvent-accessible hydrophobic core, but with no optically active secondary or tertiary structure. Thus the earliest event of the major folding pathway of barstar is a nonspecific hydrophobic collapse that does not involve concomitant secondary structure formation.

Folding of beta-sheet proteins

In the past year, interesting new information concerning various aspects of the folding process of beta-sheet proteins has been gleaned. Kinetic and equilibrium folding intermediates have been characterized. Studies of extensively denatured states and of model peptide fragments have enabled important steps to be taken towards an understanding of the initiation of the folding process of beta-sheet proteins. Site-directed mutagenesis has been used in combination with various probes to monitor folding events.