Nicked apomyoglobin: a noncovalent complex of two polypeptide fragments comprising the entire protein chain

Limited proteolysis of the 153-residue chain of horse apomyoglobin (apoMb) by thermolysin results in the selective cleavage of the peptide bond Pro88-Leu89. The N-terminal (residues 1-88) and C-terminal (residues 89-153) fragments of apoMb were isolated to homogeneity and their conformational and association properties investigated in detail. Far-UV circular dichroism (CD) measurements revealed that both fragments in isolation acquire a high content of helical secondary structure, while near-UV CD indicated the absence of tertiary structure. A 1:1 mixture of the fragments leads to a tight noncovalent protein complex (1-88/89-153, nicked apoMb), characterized by secondary and tertiary structures similar to those of intact apoMb. The apoMb complex binds heme in a nativelike manner, as given by CD measurements in the Soret region. Second-derivative absorption spectra in the 250-300 nm region provided evidence that the degree of exposure of Tyr residues in the nicked species is similar to that of the intact protein at neutral pH. Also, the microenvironment of Trp residues, located in positions 7 and 14 of the 153-residue chain of the protein, is similar in both protein species, as given by fluorescence emission data. Moreover, in analogy to intact apoMb, the nicked protein binds the hydrophobic dye 1-anilinonaphthalene-8-sulfonate (ANS). Taken together, our results indicate that the two proteolytic fragments 1-88 and 89-153 of apoMb adopt partly folded states characterized by sufficiently nativelike conformational features that promote their specific association and mutual stabilization into a nicked protein species much resembling in its structural features intact apoMb. It is suggested that the formation of a noncovalent complex upon fragment complementation can mimic the protein folding process of the entire protein chain, with the difference that the folding of the complementary fragments is an intermolecular process. In particular, this study emphasizes the importance of interactions between marginally stable elements of secondary structure in promoting the tertiary contacts of a native protein. Considering that apoMb has been extensively used as a paradigm in protein folding studies for the past few decades, the novel fragment complementing system of apoMb here described appears to be very useful for investigating the initial as well as late events in protein folding.     

Reconstitution of Fragmentary Form of Thermostable Alanine Racemase

The fragmentary form of alanine racemase from Bacillus stearothermophilus is composed of two sets of two different polypeptides corresponding to the two domains of the subunit of wild-type enzyme. It was denatured with 6 M guanidium hydrochloride to be separated into pieces, and renatured by dilution with about 50% recovery of the activity. The two kinds of polypeptides (i.e., large and a small fragments) were isolated by gel filtration in the presence of 4 M guanidium hydrochloride. The CD spectra obtained by summation of the spectra of the refolded fragments were closely similar to that of the native fragmentary enzyme. The lysine residue to which PLP is bound in the wild-type enzyme occurs in the large peptide of the fragmentary enzyme containing the amino terminus of the wild-type enzyme. The visible spectrum of the large peptide refolded, however, indicated that PLP was not bound to it. The large peptide alone had no significant activity, but it was activated by incubation with the small peptide. Accordingly, co-existene of both peptide fragments is necessary for folding of a complex of the two kinds of peptide to form an active structure.     

Molecular relationship between two types of phospholipase B from Penicillium notatum and reconstitution of active enzyme from its peptide fragments

Two types of phospholipase B of Penicillium notatum, the native type and the modified type that is thought to be generated by the introduction of some nicks into the native type of enzyme by the endogenous protease(s), were distinguished on a slab sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis under a nonreducing condition. The native form migrated with a rate corresponding to 95K Da, whereas the modified form migrated more slowly, corresponding to 106K Da, presumably because of its more extended conformation. That the "106K" protein was indeed a nicked product of the "95K" protein was confirmed by amino acid analysis, peptide mapping, N- and C-terminal sequence analyses, and immunoblotting. The peptide fragments (70K and 37K + 32K) comprising the modified protein were isolated by gel filtration in the presence of SDS and 2-mercaptoethanol (the 32K peptide was suggested to be a partial proteolytic product of the 37K peptide). When the "95K" protein was subjected to the same treatment under denaturing condition, it retained a low, but significant, enzymatic activity; in contrast, the separated peptide fragments did not show any significant activity. By a coincubation of these fragments, however, a restoration of enzymatic activity was observed through a reformation of the active complex, corresponding to the original modified protein. The enzymatic activity of this complex was further increased by a treatment with guanidine X HCl, followed by dialysis. The association of peptide fragments appears to occur through the formation of interpeptidal disulfide bonds.     

Autolysis of thermolysin. Isolation and characterization of a folded three-fragment complex

Incubation of the neutral metalloendopeptidase thermolysin at pH 7.2 in the presence of EDTA and/or low concentrations of calcium ions produces fast enzyme inactivation as a result of autolysis. The 'nicked' protein is a folded species composed of three tightly associated protein fragments. Dissociation of this complex can be achieved under denaturing conditions, such as gel filtration on a column equilibrated with 5 M guanidine hydrochloride or reverse-phase high-performance liquid chromatography (HPLC) at acidic pH. The positions of the peptide bond cleavages were defined by isolation of the individual fragments by HPLC and their characterization by amino acid analysis after acid hydrolysis, end-group determination and partial amino acid sequencing. The results of these analyses indicated that the nicked protein is composed of fragments 1-196, 197-204 and 205-316 and thus that the corresponding sites of limited proteolysis occur at the polypeptide chain loop involved in the binding of Ca(4) in native thermolysin [Matthews, B. W., Weaver, L. H. and Kester, W. R. (1974) J. Biol. Chem. 249, 8030-8044]. The overall conformational properties of nicked thermolysin are quite similar to those of the intact protein, as judged by spectroscopic measurements and by the fact that rabbit antibodies against native thermolysin recognize and precipitate the nicked protein in immunodiffusion assays. The nicked protein was much less stable to heat and unfolding agents than intact thermolysin. These results contribute to a better knowledge of the molecular mechanism of stabilization of native thermolysin by the four bound calcium ions and demonstrate that the function of Ca(4) is to stabilize the loop 190-205 on the surface of the molecule against autolysis.     

Fluorescence-quenching studies on a conformational transition within a domain of the beta 2 subunit of Escherichia coli tryptophan synthase

The fluorescence quenching by acrylamide of the single tryptophan residue in the beta 2 subunit of tryptophan synthase from Escherichia coli K12 is studied for different states of the protein: the native apo-enzyme and holo-enzyme, the nicked apo-protein and holo-protein and the isolated proteolytic fragment F1 corresponding to the N-terminal two thirds of beta 2. The quenching constants measured are used to estimate the accessibility of the tryptophan residue in these different forms. The results are discussed in terms of conformational transition within the F1 domain, occurring in the presence of the cofactor, pyridoxal 5'-phosphate, in the native enzyme. The proteolytic cleavage of the native enzyme is shown to render the nicked protein unable to undergo this conformational change.     

Renaturation of recombinant Treponema pallidum rare outer membrane protein 1 into a trimeric, hydrophobic, and porin-active conformation

We have previously observed that while native Treponema pallidum rare outer membrane protein 1 (Tromp1) is hydrophobic and has porin activity, recombinant forms of Tromp1 do not possess these properties. In this study we show that these properties are determined by conformation and can be replicated by proper renaturation of recombinant Tromp1. Native Tromp1, but not the 47-kDa lipoprotein, extracted from whole organisms by using Triton X-114, was found to lose hydrophobicity after treatment in 8 M urea, indicating that Tromp1's hydrophobicity is conformation dependent. Native Tromp1 was purified from 0.1% Triton X-100 extracts of whole organisms by fast-performance liquid chromatography (FPLC) and shown to have porin activity in planar lipid bilayers. Cross-linking studies of purified native Tromp1 with an 11 A cross-linking agent showed oligomeric forms consistent with dimers and trimers. For renaturation studies of recombinant Tromp1 (rTromp1), a 31,109-Da signal-less construct was expressed in Escherichia coli and purified by FPLC. FPLC-purified rTromp1 was denatured in 8 M urea and then renatured in the presence of 0.5% Zwittergent 3,14 during dialysis to remove the urea. Renatured rTromp1 was passed through a Sephacryl S-300 gel exclusion column previously calibrated with known molecular weight standards. While all nonrenatured rTromp1 eluted from the column at approximately the position of the carbonic anhydrase protein standard (29 kDa), all renatured rTromp1 eluted at the position of the phosphorylase b protein standard (97 kDa), suggesting a trimeric conformation. Trimerization was confirmed by using an 11 A cross-linking agent which showed both dimers and trimers similar to that of native Tromp1. Triton X-114 phase separations showed that all of renatured rTromp1, but none of nonrenatured rTromp1, phase separated exclusively into the hydrophobic detergent phase, similar to native Tromp1. Circular dichroism of nonrenatured and renatured rTromp1 showed a marked loss in alpha-helical secondary structure of renatured rTromp1 compared to the nonrenatured form. Finally, renatured rTromp1, but not the nonrenatured form, showed porin activity in planar liquid bilayers. These results demonstrate that proper folding of rTromp1 results in a trimeric, hydrophobic, and porin-active conformation similar to that of the native protein.     

Effect of glycosylation on the mechanism of renaturation of invertase from yeast

N-Glycosylation occurs cotranslationally as soon as the growing polypeptide chain enters the endoplasmic reticulum, before the final native-like folded state is reached. We examined the role of the carbohydrate chains in the mechanism of protein folding. The in vitro folding and association of yeast invertase are used as an experimental system. External invertase contains approximately 50% carbohydrate, whereas cytoplasmic invertase is not glycosylated. The functional native state of both proteins is a homodimer. At pH greater than or equal to 6.5 and at protein concentrations below 3 micrograms/ml, the kinetics of reactivation and the final yields are similar for the two invertases. For both proteins, reactivation is a sequential reaction with a lag phase at the beginning. The nonglycosylated protein tends to aggregate during reactivation at low pH and at protein concentrations above 3 micrograms/ml. After separation of inactive material, the renatured protein is indistinguishable from the original native state by a number of physicochemical and functional criteria. The results suggest that the carbohydrate moiety does not affect the mechanism of folding and association of invertase. However, glycosylation improves the solubility of unfolded or partially folded invertase molecules and hence leads to a suppression of irreversible aggregation. Such a protective effect may also be important for the in vivo maturation of nascent glycosylated protein chains.     

Kinetics and importance of the dimerization step in the folding pathway of the beta 2 subunit of Escherichia coli tryptophan synthase

During its folding, the polypeptide chain of the beta 2 subunit of Escherichia coli tryptophan synthase (L-serine hydrolyase (adding indole) EC 4.2.1.20) undergoes dimerization. To decide whether this dimerization precedes or follows the formation of the native, functional, tertiary structure of the polypeptide chain, the kinetics of renaturation of beta 2 are studied by monitoring both the regain of native conformation and the dimerization. Dimer formation is followed by the increase of the fluorescence polarization, or by energy transfer between a fluorescence donor and a fluorescence acceptor, which occur upon association of adequately labelled beta chains. Renaturation is followed by the regain of functional properties of beta 2, i.e. its ability to bind pyridoxal-5'-phosphate or to form a fluorescent ternary complex with this coenzyme and L-serine. It is shown that for beta 2 the dimerization obeys first-order kinetics, presumably because it occurs rapidly after a rate-limiting isomerization of the monomer. The dimerization is followed by another isomerization, taking place within the dimer, which leads to the formation of the pyridoxal-5'-phosphate binding site. Still another, slow, isomerization reaction involving the F1 (N-terminal) domain completes the renaturation. With a modified form of beta 2 (trypsin-nicked beta 2) where this isomerization of F1 can be made to occur before the dimerization, the dimer is also shown to appear before the functional properties. It is concluded that a non-native dimer indeed exists as an obligatory intermediate on the folding pathway of nicked beta 2 and of beta 2, and that interdomain interactions are needed to force the polypeptide chains into their native conformations.     

Environmental factors influencing the chaperone-like activity of α-crystallin

The effects of mild environmental changes (e.g. the addition of divalent cations or EDTA, as well as variations of buffer pH) on the heat stability and chaperone-like activity of native α-crystallin, and denatured–renatured α-crystallin in the native molar isoform ratio, have been investigated using circular dichroism (CD) spectropolarimetry and functional assays. The presence or absence of divalent cations has little or no effect on the secondary structure of renatured samples, although chaperone-like activity levels can vary widely; the only relevant spectral difference observed is a loss of some α-helical content in all the renatured samples relative to the native protein, but this change has no impact on function. The range of concentration over which the inhibitory Mg²⁺ effect is observed is 10-fold higher for dialyzed fresh protein than for protein renatured into buffers containing Mg²⁺, but for both sets of samples, the full effect is established below physiological Mg²⁺ concentrations. Renaturing into various pH buffers, in contrast, affects both heat stability and chaperone-like activity below pH 7.0, with essentially no functionality observed at pH 6.0. CD spectra of these samples indicate that acidic conditions lead to some degree of unfolding, and that this unfolding correlates directly with functionality. Similar results are obtained for fresh protein dialyzed against these pH levels. Overall, these results suggest that heat stability is a function of the protein's secondary structure and folding state, while chaperone-like activity is primarily a function of factors at the tertiary and quaternary levels of organization.     

Properties of monoclonal antibodies selected for probing the conformation of wild type and mutant forms of the P22 tailspike endorhamnosidase

Eleven species of monoclonal antibodies directed against the trimeric P22 tailspike endorhamnosidase have been selected and characterized. Seven of these antibodies recognize the native tailspike, both isolated and assembled onto the virion, and prevent phage infection. Four antibodies react with denatured forms of the tailspike as well as with the plastic absorbed tailspike. Three of these latter prevent the tailspike from assembling onto the phage head. The antibodies have been tested against tailspike proteins carrying single amino acid substitutions at 15 different sites on the protein. Two of these mutations interfere with binding by a set of the monoclonals, indicating that they disrupt the epitopes for these antibodies. Since amino acid replacements corresponding to the temperature-sensitive folding mutations do not change the conformation of the native protein, these mutant proteins may be particularly useful for mapping epitopes. Amber fragments of the tailspike chain are recognized predominantly by the anti-denatured antibodies suggesting either that they are conformationally closer to folding intermediates than to the native tailspike or that the epitopes recognized by anti-native antibodies are carried by the C-terminal end of the native protein. Immunochemical detection by an anti-denatured antibody, after sucrose gradient sedimentation of a large 55-kDa amber fragment, indicates a monomeric rather than a trimeric state. This suggests that the missing C-terminal region is important for the trimerization reaction. Such N-terminal amber fragments may be useful models for studying with the monoclonal antibodies the nascent chain emerging from the ribosome.     

Automated search of natively folded protein fragments for high-throughput structure determination in structural genomics

Structural genomic projects envision almost routine protein structure determinations, which are currently imaginable only for small proteins with molecular weights below 25,000 Da. For larger proteins, structural insight can be obtained by breaking them into small segments of amino acid sequences that can fold into native structures, even when isolated from the rest of the protein. Such segments are autonomously folding units (AFU) and have sizes suitable for fast structural analyses. Here, we propose to expand an intuitive procedure often employed for identifying biologically important domains to an automatic method for detecting putative folded protein fragments. The procedure is based on the recognition that large proteins can be regarded as a combination of independent domains conserved among diverse organisms. We thus have developed a program that reorganizes the output of BLAST searches and detects regions with a large number of similar sequences. To automate the detection process, it is reduced to a simple geometrical problem of recognizing rectangular shaped elevations in a graph that plots the number of similar sequences at each residue of a query sequence. We used our program to quantitatively corroborate the premise that segments with conserved sequences correspond to domains that fold into native structures. We applied our program to a test data set composed of 99 amino acid sequences containing 150 segments with structures listed in the Protein Data Bank, and thus known to fold into native structures. Overall, the fragments identified by our program have an almost 50% probability of forming a native structure, and comparable results are observed with sequences containing domain linkers classified in SCOP. Furthermore, we verified that our program identifies AFU in libraries from various organisms, and we found a significant number of AFU candidates for structural analysis, covering an estimated 5 to 20% of the genomic databases. Altogether, these results argue that methods based on sequence similarity can be useful for dissecting large proteins into small autonomously folding domains, and such methods may provide an efficient support to structural genomics projects.     

Folding of the nascent peptide chain into a biologically active protein

The refolding of denatured proteins with complete sequences may not be fast enough to account for the in vivo folding of growing peptide chains during biosynthesis. As some peptide fragments have secondary structures not unlike those of the corresponding segments in the intact molecules and native disulfide bonds of some proteins can form cotranslationally, it is suggested that the folding of the nascent chain begins early during synthesis. However, further adjustments may be necessary during chain elongation and after posttranslational modifications of the completed peptide chain to generate the native conformation of a biologically active protein.     

Interaction between two discontiguous chain segments from the beta-sheet of Escherichia coli thioredoxin suggests an initiation site for folding

The approach of comparing folding and folding/binding processes is exquisitely poised to narrow down the regions of the sequence that drive protein folding. We have dissected the small single alpha/beta domain of oxidized Escherichia coli thioredoxin (Trx) into three complementary fragments (N, residues 1-37; M, residues 38-73; and C, residues 74-108) to study them in isolation and upon recombination by far-UV CD and NMR spectroscopy. The isolated fragments show a minimum of ellipticity of ca. 197 nm in their far-UV CD spectra without concentration dependence, chemical shifts of H(alpha) that are close to the random coil values, and no medium- and long-range NOE connectivities in their three-dimensional NMR spectra. These fragments behave as disordered monomers. Only the far-UV CD spectra of binary or ternary mixtures that contain N- and C-fragments are different from the sum of their individual spectra, which is indicative of folding and/or binding of these fragments. Indeed, the cross-peaks corresponding to the rather hydrophobic beta(2) and beta(4) regions of the beta-sheet of Trx disappear from the (1)H-(15)N HSQC spectra of isolated labeled N- and C-fragments, respectively, upon addition of the unlabeled complementary fragments. The disappearing cross-peaks indicate interactions between the beta(2) and beta(4) regions, and their reappearance at lower temperatures indicates unfolding and/or dissociation of heteromers that are predominantly held by hydrophobic forces. Our results argue that the folding of Trx begins by zippering two discontiguous and rather hydrophobic chain segments (beta(2) and beta(4)) corresponding to neighboring strands of the native beta-sheet.     

GroEL channels the folding of thioredoxin along one kinetic route.

Many proteins display complex folding kinetics, which represent multiple parallel folding pathways emanating from multiple unfolded forms and converging to the unique native form. The small protein thioredoxin from Escherichia coli is one such protein. The effect of the chaperonin GroEL on modulating the complex energy landscape that separates the unfolded ensemble from the native state of thioredoxin has been studied. It is shown that while the fluorescence change accompanying folding occurs in five kinetic phases in the absence of GroEL, only the two slowest kinetic phases are discernible in the presence of saturating concentrations of GroEL. This result is shown to be consistent with only one out of several available folding routes being operational in the presence of GroEL. It is shown that native protein, which forms via fast as well as slow routes in the absence of GroEL, forms only via a slow route in its presence. The effect of GroEL on the folding of thioredoxin is shown to be the consequence of it binding differentially to the many folding-competent forms. While some of these forms can continue folding when bound to GroEL, others cannot. All molecules are then drawn into the operational folding route by the law of mass action. This observation indicates a new role for GroEL, which is to bias the energy landscape of a folding polypeptide towards fewer available pathways. It is suggested that such channeling might be a mechanism to avoid possible aggregation-prone routes available to a refolding polypeptide in vivo.     

Refolding of bacteriorhodopsin in lipid bilayers. A thermodynamically controlled two-stage process

Possible steps in the folding of bacteriorhodopsin are revealed by studying the refolding and interaction of two fragments of the molecule reconstituted in lipid vesicles. (1) Two denatured bacteriorhodopsin fragments have been purified starting from chymotryptically cleaved bacteriorhodopsin. Cleaved bacteriorhodopsin has been renatured from a mixture of the fragments in Halobacterium lipids/retinal/dodecyl sulfate solution following removal of dodecyl sulfate by precipitation with potassium. The renatured molecules have the same absorption spectrum and extinction coefficient as native cleaved bacteriorhodopsin. They are integrated into small lipid vesicles as a mixture of monomers and aggregates. Extended lattices form during the partial dehydration process used to orient samples for X-ray and neutron crystallography. (2) Correct refolding of cleaved bacterioopsin occurs upon renaturation in the absence of retinal. Regeneration of the chromophore and reformation of the purple membrane lattice are observed following subsequent addition of all-trans retinal. (3) The two chymotryptic fragments have been reinserted separately into lipid vesicles and refolded in the absence of retinal. Circular dichroism spectra of the polypeptide backbone transitions indicate that they have regained a highly alpha-helical structure. The kinetics of chromophore regeneration following reassociation have been studied by absorption spectroscopy. Upon vesicle fusion, the refolded fragments first reassociate, then bind retinal and finally regenerate cleaved bacteriorhodopsin. The complex formed in the absence of retinal is kinetically indistinguishable from cleaved bacterioopsin. The refolded fragments in lipid vesicles are stable for months, both as separate entities and after reassociation. These observations provide further evidence that the native folded structure of bacteriorhodopsin lies at a free energy minimum. They are interpreted in terms of a two-stage folding mechanism for membrane proteins in which stable transmembrane helices are first formed. They subsequently pack without major rearrangement to produce the tertiary structure.     

Limited tryptic proteolysis of pig kidney 3,4-dihydroxyphenylalanine decarboxylase

Pig kidney 3,4-dihydroxyphenylalanine (Dopa) decarboxylase can be nicked by trypsin with complete loss of its catalytic activity. The original dimer of subunit molecular weight of about 52,000 yields fragments of Mr 38,000 and 14,000, as seen on sodium dodecyl sulfate-gel electrophoresis. Though inactive, the nicked protein retains its native molecular weight and its capacity to bind pyridoxal-5'-phosphate (pyridoxal-P), is recognized by an antiserum raised against the native enzyme, and forms Schiff's base intermediates with aromatic amino acids in L and D forms. Thus, the nicked protein appears to be in a conformation--closely resembling that of the original enzyme--which consists of a tight association of the two tryptic fragments. Dissociation and separation of the two fragments can be achieved under denaturing conditions on a reverse-phase HPLC column. The pyridoxal-P binding site is located on the larger fragment. No NH2-terminal residue is detected in either the intact enzyme or the larger fragment, whereas analysis of the smaller fragment yields a sequence of the first 50 amino acid residues. These data indicate that the smaller fragment is located at about one-third from the COOH terminus of Dopa decarboxylase, while the larger fragment constitutes the aminic portion of the molecule. The site of trypsin cleavage seems to be in a region of the enzyme particularly susceptible to proteolysis. The results of these studies contribute to a better understanding of the structural properties of pig kidney Dopa decarboxylase and may constitute an important step toward the elucidation of the enzyme's primary structure.     

Autonomous folding of the excised coenzyme-binding domain of D-glyceraldehyde 3-phosphate dehydrogenase from Thermotoga maritima.

An important question in protein folding is whether compact substructures or domains are autonomous units of folding and assembly. The protomer of the tetrameric D-glyceraldehyde-3-phosphate dehydrogenase from the hyperthermophilic bacterium Thermotoga maritima has a complex coenzyme-binding domain, in which residues 1-146 form a compact substructure with the last 31 residues (313-333). Here it is shown that the gene of a single-chain protein can be expressed in Escherichia coli after deleting the 163 codons corresponding to the interspersed catalytic domain (150-312). The purified gene product is a soluble, monomeric protein that binds both NAD+ and NADH strongly and possesses the same unfolding transition induced by guanidinium chloride as the native tetramer. The autonomous folding of the coenzyme-binding domain has interesting implications for the folding, assembly, function, and evolution of the native enzyme.     

Binding and folding: in search of intramolecular chaperone-like building block fragments

We propose an intramolecular chaperone which catalyzes folding and neither dissociates nor is cleaved. This uncleaved foldase is an intramolecular chain-linked chaperone, which constitutes a critical building block of the structure. Macroscopically, all molecular chaperones facilitate folding reactions and manifest similar energy landscapes. However, microscopically they differ. While intermolecular chaperones catalyze folding by unfolding misfolded conformations or prevent misfolding, the chain-linked cleaved (proregion) and uncleaved intramolecular chaperone-like building blocks suggested here, catalyze folding by binding to, stabilizing and increasing the populations of native conformations of adjacent building block fragments. In both, the more stable the intramolecular chaperone fragment region, the faster is the folding rate. Hence, mechanistically, intramolecular chaperones and chaperone-like segments are similar. Both play a dual role, in folding and in protein function. However, while the functional role of the proregions is inhibitory, necessitating their cleavage, the function of the uncleaved intramolecular chaperone-like building blocks does not require their subsequent removal. On the contrary, it requires that they remain in the structure. This may lead to the difference in the type of control they are under: proteins folding with the assistance of the proregion have been shown to be under kinetic control. It has been suggested that kinetically controlled folding reactions, with the proregion catalyst removed, lend longevity under harsh conditions. On the other hand, proteins with uncleaved intramolecular chaperone-like building blocks, with their 'foldases' still attached, are largely under thermodynamic control, consistent with the control observed in most protein folding reactions. We propose that an uncleaved intramolecular chaperone-like fragment occurs frequently in proteins. We further propose that such proteins would be prone to changing conditions and in particular, to mutations in this critical building block region. We describe the features qualifying it for its proposed chaperone-like role, compare it with inter- and intramolecular chaperones and review current literature in this light. We further propose a mechanism showing how it lowers the barrier heights, leading to faster folding reaction rates. Since these fragments constitute an intergal part of the protein structure, we call these critical building blocks intramolecular, chaperone-like fragments, to clarify, distinguish and adhere to the definition of the transiently associating chaperones. The new mechanism presented here differs from the concept of 'folding nuclei'. While the concept of folding nuclei focuses on a non-sequential distribution of the folding information along the entire protein chain, the chaperone-like building block fragments proposition focuses on a segmental distribution of the folding information. This segmental distribution controls the distributions of the populations throughout the hierarchical folding processes.     

In silico protein fragmentation reveals the importance of critical nuclei on domain reassembly

Protein complementation assays (PCAs) based on split protein fragments have become powerful tools that facilitate the study and engineering of intracellular protein-protein interactions. These assays are based on the observation that a given protein can be split into two inactive fragments and these fragments can reassemble into the original properly folded and functional structure. However, one experimentally observed limitation of PCA systems is that the folding of a protein from its fragments is dramatically slower relative to that of the unsplit parent protein. This is due in part to a poor understanding of how PCA design parameters such as split site position in the primary sequence and size of the resulting fragments contribute to the efficiency of protein reassembly. We used a minimalist on-lattice model to analyze how the dynamics of the reassembly process for two model proteins was affected by the location of the split site. Our results demonstrate that the balanced distribution of the “folding nucleus,” a subset of residues that are critical to the formation of the transition state leading to productive folding, between protein fragments is key to their reassembly.