Mutations that stabilize folding intermediates of phage P22 tailspike protein: folding in vivo and in vitro, stability, and structural context

Fine Sampling of Sequence Space for Membrane Protein Structural Biology

We describe an enhancement of traditional genomics-based approaches to improve the success of structure determination of membrane proteins. Following a broad screen of sequence space to identify initial expression-positive targets, we employ a second step to select orthologs with closely related sequences to these hits. We demonstrate that a greater percentage of these latter targets express well and are stable in detergent, increasing the likelihood of identifying candidates that will ultimately yield structural information.

Self-Competitive Inhibition of the Bacteriophage P22 Tailspike Endorhamnosidase by O-Antigen Oligosaccharides

The P22 tailspike endorhamnosidase confers the high specificity of bacteriophage P22 for some serogroups of Salmonella differing only slightly in their O-antigen polysaccharide. We used several biophysical methods to study the binding and hydrolysis of O-antigen fragments of different lengths by P22 tailspike protein. O-Antigen saccharides of defined length labeled with fluorophors could be purified with higher resolution than previously possible. Small amounts of naturally occurring variations of O-antigen fragments missing the nonreducing terminal galactose could be used to determine the contribution of this part to the free energy of binding to be ∼7 kJ/mol. We were able to show via several independent lines of evidence that an unproductive binding mode is highly favored in binding over all other possible binding modes leading to hydrolysis. This is true even under circumstances under which the O-antigen fragment is long enough to be cleaved efficiently by the enzyme. The high-affinity unproductive binding mode results in a strong self-competitive inhibition in addition to product inhibition observed for this system. Self-competitive inhibition is observed for all substrates that have a free reducing end rhamnose. Naturally occurring O-antigen, while still attached to the bacterial outer membrane, does not have a free reducing end and therefore does not perform self-competitive inhibition.

Invivo folding efficiencies for mutants of the P22 tailspike beta-helix protein correlate with predicted stability changes

Parallel beta-helices are among the simplest repetitive structural elements in proteins. The folding behavior of beta-helix proteins has been studied intensively, also to gain insight on the formation of amyloid fibrils, which share the parallel beta-helix as a central structural motif. An important system for investigating beta-helix folding is the tailspike protein from the Salmonella bacteriophage P22. The central domain of this protein is a right-handed parallel beta-helix with 13 windings. Extensive mutational analyses of the P22 tailspike protein have revealed two main phenotypes: temperature-sensitive-folding (tsf) mutations that reduce the folding efficiency at elevated temperatures, and global suppressor (su) mutations that increase the tailspike folding efficiency. A central question is whether these phenotypes can be understood from changes in the protein stability induced by the mutations. Experimental determination of the protein stability is complicated by the nearly irreversible trimerization of the folded tailspike protein. Here, we present calculations of stability changes with the program FoldX, focusing on a recently published extensive data set of 145 singe-residue alanine mutants. We find that the calculated stability changes are correlated with the experimentally measured invivo folding efficiencies. In addition, we determine the free-energy landscape of the P22 tailspike protein in a nucleation-propagation model to explore the folding mechanism of this protein, and obtain a processive folding route on which the protein nucleates in the N-terminal region of the helix.

Polyhead formation in phage P22 pinpoints a region in coat protein required for conformational switching

Eighteen single amino acid substitutions in phage P22 coat protein cause temperature-sensitive folding defects (tsf). Three intragenic global suppressor (su) substitutions (D163G, T166I and F170L), localized to a flexible loop, rescue the folding of several tsf coat proteins. Here we investigate the su substitutions in the absence of the original tsf substitutions. None of the su variant coat proteins displayed protein folding defects. Individual su substitutions had little effect on phage production in vivo; yet double and triple combinations resulted in a cold-sensitive (cs) phenotype, consistent with a defect in assembly. During virus assembly and maturation, conformational switching of capsid subunits is required when chemically identical capsid subunits form an icosahedron. Analysis of double- and triple-su phage-infected cell lysates by negative-stain electron microscopy reveals an increase in aberrant structures at the cs temperature. In vitro assembly of F170L coat protein causes production of polyheads, never seen before in phage P22. Purified procapsids composed of all of the su coat proteins showed defects in expansion, which mimics maturation in vitro. Our results suggest that a previously identified surface-exposed loop in coat protein is critical in conformational switching of subunits during both procapsid assembly and maturation.

Chemical chaperone-mediated protein folding: stabilization of P22 tailspike folding intermediates by glycerol

Polyol co-solvents such as glycerol increase the thermal stability of proteins. This has been explained by preferential hydration favoring the more compact native over the denatured state. Although polyols are also expected to favor aggregation by the same mechanism, they have been found to increase the folding yields of some large, aggregation-prone proteins. We have used the homotrimeric phage P22 tailspike protein to investigate the origin of this effect. The folding of this protein is temperature-sensitive and limited by the stability of monomeric folding intermediates. At non-permissive temperature (≥35°C), tailspike refolding yields were increased significantly in the presence of 1–4 mglycerol. At low temperature, tailspike refolding is prevented when folding intermediates are destabilized by the addition of urea. Glycerol could offset the urea effect, suggesting that the polyol acts by stabilizing crucial folding intermediates and not by increasing solvent viscosity. The stabilization effect of glycerol on tailspike folding intermediates was confirmed in experiments using a temperature-sensitive folding mutant protein, by fluorescence measurements of subunit folding kinetics, and by temperature up-shift experiments. Our results suggest that the chemical chaperone effect of polyols observed in the folding of large proteins is due to preferential hydration favoring structure formation in folding intermediates.

GroEL/S substrate specificity based on substrate unfolding propensity

Phage P22 wild-type (WT) coat protein does not require GroEL/S to fold but temperature-sensitive-folding (tsf) coat proteins need the chaperone complex for correct folding. WT coat protein and all variants absolutely require P22 scaffolding protein, an assembly chaperone, to assemble into precursor structures termed procapsids. Previously, we showed that a global suppressor (su) substitution, T1661, which rescues several tsf coat protein variants, functioned by inducing GroEL/S. This led to an increased formation of tsf:T1661 coat protein:GroEL complexes compared with the tsf parents. The increased concentration of complexes resulted in more assembly-competent coat proteins because of a shift in the chaperone-driven kinetic partitioning between aggregation-prone intermediates toward correct folding and assembly. We have now investigated the folding and assembly of coat protein variants that carry a different global su substitution, F170L. By monitoring levels of phage production in the presence of a dysfunctional GroEL we found that tsf:F170L proteins demonstrate a less stringent requirement for GroEL. Tsf:F170L proteins also did not cause induction of the chaperones. Circular dichroism and tryptophan fluorescence indicate that the native state of the tsf: F170L coat proteins is restored to WT-like values. In addition, native acrylamide gel electrophoresis shows a stabilized native state for tsf:F170L coat proteins. The F170L su substitution also increases procapsid production compared with their tsf parents. We propose that the F170L su substitution has a decreased requirement for the chaperones GroEL and GroES as a result of restoring the tsf coat proteins to a WT-like state. Our data also suggest that GroEL/S can be induced by increasing the population of unfolding intermediates.

A second-site suppressor of a folding defect functions via interactions with a chaperone network to improve folding and assembly in vivo

Single amino acid substitutions in a protein can cause misfolding and aggregation to occur. Protein misfolding can be rescued by second-site amino acid substitutions called suppressor substitutions (su), commonly through stabilizing the native state of the protein or by increasing the rate of folding. Here we report evidence that su substitutions that rescue bacteriophage P22 temperature-sensitive-folding (tsf) coat protein variants function in a novel way. The ability of tsf:su coat proteins to fold and assemble under a variety of cellular conditions was determined by monitoring levels of phage production. The tsf:su coat proteins were found to more effectively utilize P22 scaffolding protein, an assembly chaperone, as compared with their tsf parents. Phage-infected cells were radioactively labelled to quantify the associations between coat protein variants and folding and assembly chaperones. Phage carrying the tsf:su coat proteins induced more GroEL and GroES, and increased formation of protein:chaperone complexes as compared with their tsf parents. We propose that the su substitutions result in coat proteins that are more assembly competent in vivo because of a chaperone-driven kinetic partitioning between aggregation-prone intermediates and the final assembled state. Through more proficient use of this chaperone network, the su substitutions exhibit a novel means of suppression of a folding defect.

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.

Buried hydrophobic side-chains essential for the folding of the parallel beta-helix domains of the P22 tailspike

The processive beta-strands and turns of a polypeptide parallel beta-helix represent one of the topologically simplest beta-sheet folds. The three subunits of the tailspike adhesin of phage P22 each contain 13 rungs of a parallel beta-helix followed by an interdigitated section of triple-stranded beta-helix. Long stacks of hydrophobic residues dominate the elongated buried core of these two beta-helix domains and extend into the core of the contiguous triple beta-prism domain. To test whether these side-chain stacks represent essential residues for driving the chain into the correct fold, each of three stacked phenylalanine residues within the buried core were substituted with less bulky amino acids. The mutant chains with alanine in place of phenylalanine were defective in intracellular folding. The chains accumulated exclusively in the aggregated inclusion body state regardless of temperature of folding. These severe folding defects indicate that the stacked phenylalanine residues are essential for correct parallel beta-helix folding. Replacement of the same phenylalanine residues with valine or leucine also impaired folding in vivo, but with less severity. Mutants were also constructed in a second buried stack that extends into the intertwined triple-stranded beta-helix and contiguous beta-prism regions of the protein. These mutants exhibited severe defects in later stages of chain folding or assembly, accumulating as misfolded but soluble multimeric species. The results indicate that the formation of the buried hydrophobic stacks is critical for the correct folding of the parallel beta-helix, triple-stranded beta-helix, and beta-prism domains in the tailspike protein.

A concerted mechanism for the suppression of a folding defect through interactions with chaperones

Specific amino acid substitutions confer a temperature-sensitive-folding (tsf) phenotype to bacteriophage P22 coat protein. Additional amino acid substitutions, called suppressor substitutions (su), relieve the tsf phenotype. These su substitutions are proposed to increase the efficiency of procapsid assembly, favoring correct folding over improper aggregation. Our recent studies indicate that the molecular chaperones GroEL/ES are more effectively recruited in vivo for the folding of tsf:su coat proteins than their tsf parents. Here, the tsf:su coat proteins are studied with in vitro equilibrium and kinetic techniques to establish a molecular basis for suppression. The tsf:su coat proteins were monomeric, as determined by velocity sedimentation analytical ultracentrifugation. The stability of the tsf:su coat proteins was ascertained by equilibrium urea titrations, which were best described by a three-state folding model, N <--> I <--> U. The tsf:su coat proteins either had stabilized native or intermediate states as compared with their tsf coat protein parents. The kinetics of the I <--> U transition showed a decrease in the rate of unfolding and a small increase in the rate of refolding, thereby increasing the population of the intermediate state. The increased intermediate population may be the reason the tsf:su coat proteins are aggregation-prone and likely enhances GroEL-ES interactions. The N --> I unfolding rate was slower for the tsf:su proteins than their tsf coat parents, resulting in an increase in the native state population, which may allow more competent interactions with scaffolding protein, an assembly chaperone. Thus, the suppressor substitution likely improves folding in vivo through increased efficiency of coat protein-chaperone interactions.

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, TSPDeltaN, TSPDeltaC, and TSPDeltaNC, were generated and tested for their ability to form mixed trimer species. TSPDeltaN forms mixed trimers with full-length P22 tailspike, but TSPDeltaC and TSPDeltaNC 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.

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.

The architecture of parallel beta-helices and related folds

Three-dimensional structures have been determined of a large number of proteins characterized by a repetitive fold where each of the repeats (coils) supplies a strand to one or more parallel beta-sheets. Some of these proteins form superfamilies of proteins, which have probably arisen by divergent evolution from a common ancestor. The classical example is the family including four families of pectinases without obviously related primary sequences, the phage P22 tailspike endorhamnosidase, chrondroitinase B and possibly pertactin from Bordetella pertusis. These show extensive stacking of similar residues to give aliphatic, aromatic and polar stacks such as the asparagine ladder. This suggests that coils can be added or removed by duplication or deletion of the DNA corresponding to one or more coils and explains how homologous proteins can have different numbers of coils. This process can also account for the evolution of other families of proteins such as the beta-rolls, the leucine-rich repeat proteins, the hexapeptide repeat family, two separate families of beta-helical antifreeze proteins and the spiral folds. These families need not be related to each other but will share features such as relative untwisted beta-sheets, stacking of similar residues and turns between beta-strands of approximately 90 degrees often stabilized by hydrogen bonding along the direction of the parallel beta-helix.Repetitive folds present special problems in the comparison of structures but offer attractive targets for structure prediction. The stacking of similar residues on a flat parallel beta-sheet may account for the formation of amyloid with beta-strands at right-angles to the fibril axis from many unrelated peptides.

Mutations improving the folding of phage P22 tailspike protein affect its receptor binding activity

Four previously isolated mutations in Salmonella phage P22 tailspike protein were used to study the relationship between protein stability, folding, and function. Tailspike protein binds and hydrolyzes the repetitive O-antigen structure in Salmonella lipopolysaccharide. Four mutations (V331G, V331A, A334V, A334I) are known to increase the folding efficiency, and two of them (at position 331) also increase the thermal stability of the protein. Octasaccharides comprising two repeating units of the O-antigens from two different Salmonella strains were employed to analyze the receptor binding function of the mutant proteins. Their endorhamnosidase enzymatic activity was assayed with the aid of a fluorescence-labeled dodecasaccharide. Both V331A and V331G were found to strongly affect O-antigen binding. Octasaccharide binding affinities of the mutant proteins are reduced tenfold and 200-fold, corresponding to a loss of 17% and 36% of the standard free energy of binding, respectively. Both mutations at position 334 affected O-antigen binding only slightly (DeltaDeltaG(0)B approximately 1 kJ/mol), but these mutations reduce the thermal stability of the protein. The observed effects on the endoglycosidase activity are fully explained by the changes in substrate binding, suggesting that neither of the mutations affect the catalytic rate. Crystal structures of all four mutants were determined to a resolution of 2.0 A. Except for the partly or completely missing side-chain, no significant changes compared to the wild-type protein structure were found for the mutants at position 331, whereas a small but significant backbone displacement around the mutation site in A334V and A334I may explain the observed thermal destabilization.

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.

Folding and function of repetitive structure in the homotrimeric phage P22 tailspike protein

The Salmonella bacteriophage P22 recognizes its host cell receptor, lipopolysaccharide, by means of six tailspikes, thermostable homotrimers of 72-kDa polypeptides. Biophysical results on the binding reaction, together with high-resolution structural information from X-ray crystallography, have shed light on the interactions determining the viral host range. Folding and assembly of the tailspike protein in vitro have been analyzed in detail, and the data have been compared with observations on the in vivo assembly pathway. Repetitive structural elements in the tailspike protein, like a side-by-side trimer of parallel beta-helices, a parallel alpha-helical bundle, a triangular prism made up from antiparallel beta-sheets, and a short segment of a triple beta-helix can be considered building blocks for larger structural proteins, and thus, the results on P22 tailspike may have implications for fibrous protein structure and folding.

Structure and evolution of parallel beta-helix proteins

Three bacterial pectate lyases, a pectin lyase from Aspergillus niger, the structures of rhamnogalacturonase A from Aspergillus aculeatus, RGase A, and the P22-phage tailspike protein, TSP, display the right-handed parallel beta-helix architecture first seen in pectate lyase. The lyases have 7 complete coils while RGase A and TSP have 11 and 12, respectively. Each coil contains three beta-strands and three turn regions named PB1, T1, PB2, T2, PB3, and T3 in their order of occurrence. The lyases have homologous sequences but RGase A and TSP do not show obvious sequence homology either to the lyases or to each other. However, the structural similarities between all these molecules are so extensive that divergence from a common ancestor is much more probable than convergence to the same fold. The region PB2-T2-PB3 is the best conserved region in the lyases and shows the clearest structural similarity. Not only is the pleating and the direction of the hydrogen bonding in the sheets conserved, but so is the unusual alphaL-conformation turn between the two sheets. However, the overall shape, the position of long loops, a conserved alpha-helix that covers the amino-terminal end of the parallel beta-helix and stacks of residues in alphaR-conformation at the start of PB1 all suggest a common ancestor. The functional similarity, that the enzymes all bind alpha-galactose containing polymers at an equivalent site involving PB1 and its two flanking turn regions, further supports divergent evolution. We suggest that the stacking of the coils and the unusual near perpendicular junction of PB2 and PB3 make the parallel beta-helix fold especially likely to maintain similar main chain conformations during divergent evolution even after all vestige of similarity in primary structure has vanished.

P22 tailspike folding mutants revisited: effects on the thermodynamic stability of the isolated beta-helix domain

The folding of the trimeric phage P22 tailspike protein is influenced by amino acid substitutions of two types, virtually all of which affect residues in the central domain, a large parallel beta-helix. Temperature sensitive folding (tsf) mutations lead to drastically decreased folding yields at elevated temperature. Their phenotype can be alleviated by global suppressor (su) mutations. Both types of mutations appeared to have no influence on the stability of the native protein at the time of their first isolation and were thus suggested to carry information needed for the folding pathway exclusively. The monomeric beta-helix of tailspike, expressed as an isolated domain, exhibits freely reversible unfolding and refolding transitions, allowing us to analyse the effects of two well-characterised tsf and all four known su mutations on its thermodynamic stability. We find a marked decrease in stability for the tsf mutants and a striking increase in stability for all su mutants. This leads to the conception that the isolated beta-helix domain, although active in receptor-binding and native-like in its spectroscopic properties, is close in conformation to a crucial monomeric folding intermediate whose thermolability is responsible for the kinetic partitioning between productive folding and irreversible aggregation during the maturation process of P22 tailspike protein.

Unfolding of bacteriophage P22 tailspike protein: enhanced thermal stability of an N-terminal fusion mutant

The tailspike protein (TSP) of bacteriophage P22 is a homotrimeric multifunctional protein responsible for cell attachment and hydrolysis of the Salmonella typhimurium host cell receptor. Despite the folding of TSP involves the formation of thermolabile intermediates, the mature protein is extremely resistant to heat and detergent denaturation. We have analyzed the thermal resistance and unfolding pathway of two mutant, functional TSPs carrying end-terminal peptide fusions. Whereas the C-terminal fusion has minor effects on the TSP stability, the presence of a 23-mer foreign peptide at the N terminus (protein ATSP) results in a significant enhancement of the thermal resistance by retarding the first transition step of the unfolding process. At 65 degrees C and in 2% SDS, the unfolding rate constant for the transition from the native to the unfolding intermediate is 9.3 x 10(-4) s(-1) for ATSP versus 1.7 x 10(-3) s(-1) for wild-type TSP. On the other hand, the electrophoretic mobility of ATSP intermediates is greatly affected, proving structural modifications induced by the fused peptide. These results suggest a critical participation of the N-terminal domain in the unfolding kinetic barriers generated during the TSP denaturation pathway.

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.

A reversibly unfolding fragment of P22 tailspike protein with native structure: the isolated beta-helix domain

The homotrimeric tailspike endorhamnosidase of phage P22 has been used to compare in vivo and in vitro folding pathways and the influence of single amino acid substitutions thereon. Its main structural motif, which contains the known folding mutation sites, consists of three large right-handed parallel beta-helices. A thermodynamic analysis of the stability of tailspike is prevented by the irreversibility of unfolding at high temperatures or high concentrations of denaturant, probably due to interdigitation of the domains neighboring the beta-helix. We therefore expressed and isolated a tailspike fragment comprising only its central beta-helix domain (residues 109-544). As shown by equilibrium ultracentrifugation, the isolated beta-helix is a monomer at concentrations below 1 microM and trimerizes reversibly at higher protein concentrations. Both the similarity of fluorescence and CD spectra, compared to the complete protein, and the specific binding and hydrolysis of substrate suggest a nativelike structure. Moreover, urea denaturation transitions of the beta-helix domain are freely reversible, providing the basis for a future quantitative analysis of the effects of the folding mutations on the thermodynamic stability of the domain and of structural features responsible for folding and stability of the parallel beta-helix motif in general.

Side-chain specificity at three temperature-sensitive folding mutation sites of P22 tailspike protein

The phage P22 tailspike protein is one of the few proteins for which both in vivo and in vitro folding pathways have been thoroughly characterized. Many temperature-sensitive folding (tsf) mutations that cause the mutant tailspike polypeptides not to be folded at high restrictive temperatures have been identified. One-third of the tsf mutation sites are located in one domain called the dorsal fin domain (residues 197-259), which protrudes on the solvent-exposed side of the main beta helix. In the present study, we introduced various amino acid substitutions at three tsf mutation sites (residue numbers 235, 238, and 244) in this domain to elucidate the mechanism of these tsf mutations in detail. The side-chain specificity at these tsf sites, together with structural examination in the tertiary fold, strongly suggests that destabilization of folding intermediates by loss of specific interactions is likely to be the major cause of the tsf defect in the dorsal fin domain.

Prevalence of temperature sensitive folding mutations in the parallel beta coil domain of the phage P22 tailspike endorhamnosidase

Temperature sensitive mutations fall into two general classes: tl mutations, which render the mature protein thermolabile, and tsf (temperature sensitive folding) mutations, which destabilize an intermediate in the folding pathway without altering the functions of the folded state. The molecular defects caused by tsf mutations have been intensively studied for the elongated tailspike endorhamnosidase of Salmonella phage P22. The tailspike, responsible for host cell recognition and attachment, contains a 13 strand parallel beta coil domain. A set of tsf mutants located in the beta coil domain have been shown to cause folding defects in the in vivo folding pathway for the tailspike. We report here additional data on 17 other temperature sensitive mutants which are in the beta coil domain. Using mutant proteins formed at low temperature, the essential functions of assembling on the phage head, and binding to the O-antigen lipopolysaccharide (LPS) receptor of Salmonella were examined at high temperatures. All of the mutant proteins once folded at permissive temperature, were functional at restrictive temperatures. When synthesized at restrictive temperature the mutant chains formed an early folding intermediate, but failed to reach the mature conformation, accumulating instead in the aggregated inclusion body state. Thus this set of mutants all have the temperature sensitive folding phenotype. The prevalence of tsf mutants in the parallel beta coil domain presumably reflects properties of its folding intermediates. The key property may be the tendency of the intermediate to associate off pathway to the kinetically trapped inclusion body state.

Interaction of Salmonella phage P22 with its O-antigen receptor studied by X-ray crystallography

The O-antigenic repeating units of the Salmonella cell surface lipopolysaccharides (serotypes A, B and D1) serve as receptors for phage P22. This initial binding step is mediated by the tailspike protein (TSP), which is present in six copies on the base plate of the phage. In addition to the binding activity, TSP also displays a low endoglycolytic activity, cleaving the alpha(1,3)-O-glycosidic bond between rhamnose and galactose of the O-antigenic repeats. The crystal structure of TSP in complex with receptor fragments allowed to identify the receptor binding site for the octasaccharide product of the enzymatic action of TSP on delipidated LPS and the active site consisting of Asp392, Asp395 and Glu359. The structure comprises a large right-handed parallel beta-helix of 13 turns. These fold independently in the trimer, whereas the N-terminus forms a cap-like structure and the C-terminal parts of the three polypeptide strands merge to a single common domain. In addition, TSP has served as model system for the folding of large, multisubunit proteins. Its folding pathway is influenced by a large number of point mutations, classified as lethal, temperature sensitive or general suppressor mutations, which influence the partitioning between aggregation and the productive folding pathway.

Conformation of P22 tailspike folding and aggregation intermediates probed by monoclonal antibodies

The partitioning of partially folded polypeptide chains between correctly folded native states and off-pathway inclusion bodies is a critical reaction in biotechnology. Multimeric partially folded intermediates, representing early stages of the aggregation pathway for the P22 tailspike protein, have been trapped in the cold and isolated by nondenaturing polyacrylamide gel electrophoresis (PAGE) (speed MA, Wang DIC, King J. 1995. Protein Sci 4:900-908). Monoclonal antibodies against tailspike chains discriminate between folding intermediates and native states (Friguet B, Djavadi-Ohaniance L, King J, Goldberg ME. 1994. J Biol Chem 269:15945-15949). Here we describe a nondenaturing Western blot procedure to probe the conformation of productive folding intermediates and off-pathway aggregation intermediates. The aggregation intermediates displayed epitopes in common with productive folding intermediates but were not recognized by antibodies against native epitopes. The nonnative epitope on the folding and aggregation intermediates was located on the partially folded N-terminus, indicating that the N-terminus remained accessible and nonnative in the aggregated state. Antibodies against native epitopes blocked folding, but the monoclonal directed against the N-terminal epitope did not, indicating that the conformation of the N-terminus is not a key determinant of the productive folding and chain association pathway.

How do proteins acquire their three-dimensional structure and stability?

Proteins are multifunctional in the sense that their specific amino acid sequence simultaneously determines self-organization, function and turnover. Correspondingly, evolution has to compromise between rigidity (stability) and flexibility (function/degradation) to the effect that the free energy of stabilization of proteins is the equivalent of only a few weak interactions (delta Gstab = 45 +/- 15 kJ.mol-1). Molecular adaptation of thermophiles, psychrophiles and other extremophiles is accomplished by extrinsic factors that are not encoded in the amino acid sequence, or by minute local structural changes involving mainly ion pairs and hydrophobic side chains. The acquisition of the native three-dimensional structure may be described by single- or multiple-pathway folding and association, where the fast collapse of the polypeptide chain leads to molten-globule-like states; subsequent shuffling reactions yield structured monomers which, in the case of oligomers, undergo specific association to form the native functional state. The rate-limiting steps (cysteine oxidation, proline isomerization, subunit assembly) are catalyzed or directed by enzymes or chaperones.

Cold-sensitive assembly of a mutant manganese-stabilizing protein caused by a Val to Ala replacement

Photosystem II (PSII) is a multisubunit transmembrane protein complex that oxidizes water and evolves O2. A tetranuclear manganese cluster associated with integral membrane subunits of PSII catalyzes water oxidation. The 33-kDa water-soluble PSII subunit, or manganese-stabilizing protein (MSP), stabilizes the O2-evolving manganese cluster and accelerates O2 evolution. Spinach PSII can be depleted of native MSP under conditions which retain a functional manganese cluster. Reconstition of MSP-depleted PSII with recombinant MSP was equally efficient at 4 and 22 degrees C. Replacement of Val235 (a conserved residue near the C-terminus of MSP) with Ala inhibited assembly of MSP at 4 degrees C, but not at 22 degrees C. Once assembled, [V235A]MSP remained bound to PSII even at 4 degrees C and in the presence of low concentrations of urea. Results from far-UV circular dichroism spectrometry indicated that [V235A]-MSP was destabilized by low temperature to a greater extent than the wild-type protein. However, the effect of temperature on the secondary structure of both the mutant and wild-type proteins was small compared to the temperature-independent destabilization of secondary structure induced by the mutation. These results demonstrate that the V235A mutation introduces an activation energy barrier for assembly of MSP into PSII, and it is suggested that the mutation acts by inhibiting isomerization of one or more prolyl peptide bonds required for assembly.