Complex additivity of the effects of suppressor mutations in differing protein environments.

In the alpha-complementation of beta-galactosidase, a defective beta-galactosidase protein interacts with an autologous peptide fragment (alpha-peptide) to restore enzymatic activity. Within a specific site of a defective alpha-peptide we have previously isolated a large number of mutations, many of which suppress the functional defect. The alpha-peptide was originally defective due to both insertional and substitutional sequence alterations near its N-terminus, which provided an increase in the sensitivity of detection of (suppressor) secondary mutations which conferred improved function. We have now studied the effects of the suppressor mutations when the primary deleterious mutations are sequentially reversed. This was done in intact beta-galactosidase, as we have shown that mutations in the alpha-peptide have related functional effects in the whole protein. Evidence was obtained showing that the effects of at least some suppressor mutations were not simply additive when the mutations are placed into the original wild-type protein environment. One suppressor appeared to function less effectively in the normal environment, while another when tested in the same manner functioned at a relatively increased level. This failure to show simple additivity may be attributable to the physical proximity of the original defective mutations and the introduced suppressors. Nevertheless, even in such cases it may be feasible to use a defective protein as a sensitive starting point for the identification of mutations which improve the wild-type protein.     

Loop mutations can cause a substantial conformational change in the carboxy terminus of the ferritin protein.

Although some protein folding theories sustain that the peptides (loops) that connect elements of more compact secondary structure may be important in the folding process, most of the data accumulated until now seems to contradict this notion. To approach this problem we have isolated and characterized a number of mutants in which the amino acid sequence of the peptide that connects helix D and helix E in the H-chain of human ferritin has been randomized. Our results indicate that, though no single loop residue is absolutely required for ferritin to attain the native conformation, most of the mutants that we have obtained by random regional mutagenesis, affect its folding/assembly process. This conclusion was reached utilizing a sensitive test that associates the color formed by a colony synthesizing a hybrid ferritin-beta-galactosidase protein to the ability of the ferritin domain to fold and assemble as the native protein. The characterization of the folding/assembly properties of our collection of mutants and the comparison of the mutant loop sequences, have allowed us to draw the following conclusions. Mutants that have positively charged residues at position 159, 160 or 161 fail to assemble into the native protein shell and form an insoluble aggregate. Interestingly some loop amino acid sequences cause the E-helix to reverse direction and to expose its COOH group, normally hidden inside the protein cavity, to the solvent. The propensity of a given ferritin mutant to fold into this "non-native" conformation can be attenuated by the introduction of Gly at position 159 and 164, as in the natural ferritin.     

Refolding and assembly of penicillin acylase, an enzyme composed of two polypeptide chains that result from proteolytic activation

The in vitro folding and assembly of penicillin acylase (EC 3.5.1.11) (PA) to active enzyme has been studied. PA is a large bacterial protein (Mr = 86,000) comprising two peptides, alpha and beta, produced by proteolytic processing and activation of a 92-kDa precursor. Proteins that result from proteolytic processing are characteristically difficult if not impossible to refold. Different factors that affect folding and assembly of PA, including pH, ionic strength, and temperature, have been studied. Yields of 60% can be obtained, based on recovery of enzyme activity, together with another 20% of folded and associated monomer with conformation closely similar to that of the active enzyme but with the active site not formed. Evidence is presented for in vitro assembly proceeding via initial folding of the N-terminal alpha-peptide with subsequent collapse of the transiently folded beta-chain on to the surface of the former. A slow process of rearrangement follows association in vitro. Competition experiments support the proposal that the linker endopeptide in the precursor serves to increase the probability of productive collision between folded alpha- and beta-peptides. The effect of raised temperature is to interfere with the folding of the alpha-peptide, thus preventing proper folding of the precursor. This finding accounts for the basis of the temperature regulation of PA production in vivo.     

Directed evolution of single-chain Fv for cytoplasmic expression using the beta-galactosidase complementation assay results in proteins highly susceptible to protease degradation and aggregation

BACKGROUND: Antibody fragments are molecules widely used for diagnosis and therapy. A large amount of protein is frequently required for such applications. New approaches using folding reporter enzymes have recently been proposed to increase soluble expression of foreign proteins in Escherichia coli. To date, these methods have only been used to screen for proteins with better folding properties but have never been used to select from a large library of mutants. In this paper we apply one of these methods to select mutations that increase the soluble expression of two antibody fragments in the cytoplasm of E. coli. RESULTS: We used the beta-galactosidase alpha-complementation system to monitor and evolve two antibody fragments for high expression levels in E. coli cytoplasm. After four rounds of mutagenesis and selection from large library repertoires (>107 clones), clones exhibiting high levels of beta-galactosidase activity were isolated. These clones expressed a higher amount of soluble fusion protein than the wild type in the cytoplasm, particularly in a strain deficient in the cytoplasmic Lon protease. The increase in the soluble expression level of the unfused scFv was, however, much less pronounced, and the unfused proteins proved to be more aggregation prone than the wild type. In addition, the soluble expression levels were not correlated with the beta-galactosidase activity present in the cells. CONCLUSION: This is the first report of a selection for soluble protein expression using a fusion reporter method. Contrary to anticipated results, high enzymatic activity did not correlate with the soluble protein expression level. This was presumably due to free alpha-peptide released from the protein fusion by the host proteases. This means that the alpha-complementation assay does not sense the fusion expression level, as hypothesized, but rather the amount of free released alpha-peptide. Thus, the system does not select, in our case, for higher soluble protein expression level but rather for higher protease susceptibility of the fusion protein.     

Expression and purification of intact and functional soybean (Glycine max) seed ferritin complex in Escherichia coli

Soybean seed ferritin is essential for human iron supplementation and iron deficiency anemia prevention because it contains abundant bioavailable iron and is frequently consumed in the human diet. However, it is poorly understood in regards its several properties, such as iron mineralization, subunit assembly, and protein folding. To address these issues, we decided to prepare the soybean seed ferritin complex via a recombinant DNA approach. In this paper, we report a rapid and simple Escherichia coli expression system to produce the soybean seed ferritin complex. In this system, two subunits of soybean seed ferritin, H-2 and H-1, were encoded in a single plasmid, and optimal expression was achieved by additionally coexpressing a team of molecular chaperones, trigger factor and GroEL-GroES. The His-tagged ferritin complex was purified by Ni2+ affinity chromatography, and an intact ferritin complex was obtained following His-tagged enterokinase (His-EK) digestion. The purified ferritin complex synthesized in E. coli demonstrated some reported features of its native counterpart from soybean seed, including an apparent molecular weight, multimeric assembly, and iron uptake activity. We believe that the strategy described in this paper may be of general utility in producing other recombinant plant ferritins built up from two types of subunits.     

Active human ferritin H/L-hybrid and sequence effect on folding efficiency in Escherichia coli

In Escherichia coli, the recombinant human L-chain ferritin was synthesized in the form of inclusion bodies under the control of T7 promoter system. We developed a recombinant ferritin H/L-hybrid by a direct gene fusion between H- and L-chain subunits. Surprisingly, the presence of heavy-chain polypeptide at the amino terminus of light chain significantly increased the cytoplasmic solubility of the recombinant ferritin hybrid, i.e., more than 80% of synthesized ferritin hybrid was soluble in intracellular region regardless of the changes in cell growth and gene expression conditions such as type of inducer, growth media, culture scale, etc. The soluble ferritin H/L-hybrid was biologically active with the iron storage capacity (295mol Fe(+3) per mol H/L-hybrid) equivalent to ferritin standard. Different types of hybrid mutants were also developed using various H-chain derivatives. Comparison of the intracellular solubilities of the synthesized hybrid mutants showed that the N-terminus four helices of heavy subunit were of crucial importance in maintaining the high solubility in E. coli cytoplasm. Consequently, the increased solubility of the ferritin hybrid seems to be related to such H-chain sequence that forms ferroxidase center and promotes effective intra-molecular interaction with L-chain domain of H/L-hybrid for enhancing the folding efficiency.     

Ferritin from the spleen of the Antarctic teleost Trematomus bernacchii is an M-type homopolymer.

Ferritin from the spleen of the Antarctic teleost Trematomus bernacchii is composed of a single subunit that contains both the ferroxidase center residues, typical of mammalian H chains, and the carboxylate residues forming the micelle nucleation site, typical of mammalian L chains. Comparison of the amino-acid sequence with those available from lower vertebrates indicates that T. bernacchii ferritin can be classified as an M-type homopolymer. Interestingly, the T. bernacchii ferritin chain shows 85.7% identity with a cold-inducible ferritin chain of the rainbow trout Salmo gairdneri. The structural and functional properties indicate that cold acclimation and functional adaptation to low temperatures are achieved without significant modification of the protein stability. In fact, the stability of T. bernacchii ferritin to denaturation induced by acid or temperature closely resembles that of mesophilic mammalian ferritins. Moreover iron is taken up efficiently and the activation energy of the reaction is 74.9 kJ.mol(-1), a value slightly lower than that measured for the human recombinant H ferritin (80.8 kJ.mol(-1)).     

A portable allosteric mechanism

The allosteric mechanism by which the gene expression regulatory protein AraC regulates its DNA-binding activity is shown to be portable by grafting it to beta-galactosidase, generating an arabinose-regulated beta-galactosidase. A portion of the alpha-peptide sequence that complements the activity of alpha-acceptor beta-galactosidase was inserted into a nonessential region of the regulatory peptidyl arm of AraC protein. Arabinose, which regulates the position of the arm in AraC protein now regulates the availability of the alpha-peptide to alpha-acceptor beta-galactosidase, thereby modulating its activity in response to arabinose.     

Effect of the N-terminal hydrophobic sequence of hepatitis B virus surface antigen on the folding and assembly of hybrid beta-galactosidase in Escherichia coli

To investigate the mechanism of inclusion body formation and the effect of a hydrophobic sequence on the in vivo polypeptide folding, the aggregation caused by recombinant fusion beta-galactosidase in Escherichia coli was examined. Two plasmids were constructed: pTBG(H-) carried only the preS2 sequence of the hepatitis B virus surface antigen (HBsAg) in front of the beta-galactosidase gene (lacZ) while pTBG(H+) carried an additional sequence encoding the amino-terminal hydrophobic sequence of the S region of HBsAg between preS2 and lacZ. Unlike cells expressing the fusion protein not containing the hydrophobic sequence, E. coli JM109/pTBG(H+) exhibited temperature-sensitive production of beta-galactosidase. As the culture temperature increased the activity decreased dramatically. This decrease in activity was not due to a decrease in fusion polypeptide production, but rather the fusion polypeptides containing the hydrophobic sequence aggregated within the cells at high temperature. However once the fusion polypeptides folded into proper conformation at low temperature, they maintained the activity even at high temperature. The results indicate that aggregation is a consequence of incorrect folding and assembly of the polypeptides, and is not derived from the native structure. The aggregates of the pTBG(H+)-encoded fusion polypeptides did not revert to active form when the culture temperature was lowered.     

Identification of sites influencing the folding and subunit assembly of the P22 tailspike polypeptide chain using nonsense mutations

Amber mutations have been isolated and mapped to more than 60 sites in gene 9 of P22 encoding the thermostable phage tailspike protein. Gene 9 is the locus of over 30 sites of temperature sensitive folding (tsf) mutations, which affect intermediates in the chain folding and subunit association pathway. The phenotypes of the amber missense proteins produced on tRNA suppressor hosts inserting serine, glutamine, tryosine and leucine have been determined at different temperatures. Thirty-three of the sites are tolerant, producing functional proteins with any of the four amino acids inserted at the sites, independent of temperature. Tolerant sites are concentrated at the N-terminal end of the protein indicating that this region is not critical for conformation or function. Sixteen of the sites yield temperature sensitive missense proteins on at least one nonsense suppressing host. Most of the sites with ts phenotypes map to the central region of the gene which is also the region where most of the tsf mutations map. Mutations at 15 of the sites have a lethal phenotype on at least one tRNA suppressor host. For nine out of ten sites tested with at least one lethal phenotype, the primary defect was in the folding or subunit association of the missense polypeptide chain. This analysis of the tailspike missense proteins distinguishes three classes of amino acid sites in the polypeptide chain; residues whose side chains contribute little to folding, subunit assembly or function; residues critical for maintaining the folding and subunit assembly pathway at the high end of the temperature range of phage growth; and residues critical over the entire temperature range of growth.     

Human lysosomal protective protein. Glycosylation, intracellular transport, and association with beta-galactosidase in the endoplasmic reticulum.

In lysosomes beta-galactosidase and neuraminidase acquire a stable and active conformation through their association with the protective protein. The latter is homologous to serine carboxypeptidases and has cathepsin A-like activity which is distinct from its protective function towards the two glycosidases. To define signals in the human protective protein important for its intracellular transport, and to determine the site of its association with beta-galactosidase, we have generated a set of mutated protective protein cDNAs carrying targeted base substitutions. These mutants were either singly transfected into COS-1 cells or cotransfected together with wild type human beta-galactosidase. We show that all point mutations cause either a complete or partial retention of the protective protein precursor in the endoplasmic reticulum. This abnormal accumulation leads to degradation of the mutant proteins probably in this compartment. Only the oligosaccharide chain on the 32-kDa subunit acquires the mannose 6-phosphate recognition marker, the one on the 20-kDa subunit seems to be merely essential for the stability of the mature protein. In cotransfection experiments, wild type beta-galactosidase and protective protein appear to assemble already as precursors, soon after synthesis, in the endoplasmic reticulum. Mutated protective protein precursors that are retained in the endoplasmic reticulum or pre-Golgi complex interact with and withhold normal beta-galactosidase molecules in the same compartments, thereby preventing their normal routing.     

Impaired elastic-fiber assembly by fibroblasts from patients with either Morquio B disease or infantile GM1-gangliosidosis is linked to deficiency in the 67-kD spliced variant of beta-galactosidase

We have previously shown that intracellular trafficking and extracellular assembly of tropoelastin into elastic fibers is facilitated by the 67-kD elastin-binding protein identical to an enzymatically inactive, alternatively spliced variant of beta-galactosidase (S-Gal). In the present study, we investigated elastic-fiber assembly in cultures of dermal fibroblasts from patients with either Morquio B disease or GM1-gangliosidosis who bore different mutations of the beta-galactosidase gene. We found that fibroblasts taken from patients with an adult form of GM1-gangliosidosis and from patients with an infantile form, carrying a missense mutations in the beta-galactosidase gene-mutations that caused deficiency in lysosomal beta-galactosidase but not in S-Gal-assembled normal elastic fibers. In contrast, fibroblasts from two cases of infantile GM1-gangliosidosis that bear nonsense mutations of the beta-galactosidase gene, as well as fibroblasts from four patients with Morquio B who had mutations causing deficiency in both forms of beta-galactosidase, did not assemble elastic fibers. We also demonstrated that S-Gal-deficient fibroblasts from patients with either GM1-gangliosidosis or Morquio B can acquire the S-Gal protein, produced by coculturing of Chinese hamster ovary cells permanently transected with S-Gal cDNA, resulting in improved deposition of elastic fibers. The present study provides a novel and natural model validating functional roles of S-Gal in elastogenesis and elucidates an association between impaired elastogenesis and the development of connective-tissue disorders in patients with Morquio B disease and in patients with an infantile form of GM1-gangliosidosis.     

Matching simulation and experiment: a new simplified model for simulating protein folding.

Simulations of simplified protein folding models have provided much insight into solving the protein folding problem. We propose here a new off-lattice bead model, capable of simulating several different fold classes of small proteins. We present the sequence for an alpha/beta protein resembling the IgG-binding proteins L and G. The thermodynamics of the folding process for this model are characterized using the multiple multihistogram method combined with constant-temperature Langevin simulations. The folding is shown to be highly cooperative, with chain collapse nearly accompanying folding. Two parallel folding pathways are shown to exist on the folding free energy landscape. One pathway contains an intermediate--similar to experiments on protein G, and one pathway contains no intermediates-similar to experiments on protein L. The folding kinetics are characterized by tabulating mean-first passage times, and we show that the onset of glasslike kinetics occurs at much lower temperatures than the folding temperature. This model is expected to be useful in many future contexts: investigating questions of the role of local versus nonlocal interactions in various fold classes, addressing the effect of sequence mutations affecting secondary structure propensities, and providing a computationally feasible model for studying the role of solvation forces in protein folding.     

Three binding sites in protein-disulfide isomerase cooperate in collagen prolyl 4-hydroxylase tetramer assembly

Protein-disulfide isomerase (PDI) is a modular polypeptide consisting of four domains, a, b, b', and a'. It is a ubiquitous protein folding catalyst that in addition functions as the beta-subunit in vertebrate collagen prolyl 4-hydroxylase (C-P4H) alpha(2)beta(2) tetramers. We report here that point mutations in the primary peptide substrate binding site in the b' domain of PDI did not inhibit C-P4H assembly. Based on sequence conservation, additional putative binding sites were identified in the a and a' domains. Mutations in these sites significantly reduced C-P4H tetramer assembly, with the a domain mutations generally having the greater effect. When the a or a' domain mutations were combined with the b' domain mutation I272W tetramer assembly was further reduced, and more than 95% of the assembly was abolished when mutations in the three domains were combined. The data indicate that binding sites in three PDI domains, a, b', and a', contribute to efficient C-P4H tetramer assembly. The relative contributions of these sites were found to differ between Caenorhabditis elegans C-P4H alphabeta dimer and human alpha(2)beta(2) tetramer formation.     

Insight into Schmid metaphyseal chondrodysplasia from the crystal structure of the collagen X NC1 domain trimer

Collagen X is expressed specifically in the growth plate of long bones. Its C1q-like C-terminal NC1 domain forms a stable homotrimer and is crucial for collagen X assembly. Mutations in the NC1 domain cause Schmid metaphyseal chondrodysplasia (SMCD). The crystal structure at 2.0 A resolution of the human collagen X NC1 domain reveals an intimate trimeric assembly strengthened by a buried cluster of calcium ions. Three strips of exposed aromatic residues on the surface of NC1 trimer are likely to be involved in the supramolecular assembly of collagen X. Most internal SMCD mutations probably prevent protein folding, whereas mutations of surface residues may affect the collagen X suprastructure in a dominant-negative manner.     

Hierarchical formation of disulfide bonds in the immunoglobulin Fc fragment is assisted by protein-disulfide isomerase

Antibodies provide an excellent system to study the folding and assembly of all beta-sheet proteins and to elucidate the hierarchy of intra/inter chain disulfide bonds formation during the folding process of multimeric and multidomain proteins. Here, the folding process of the Fc fragment of the heavy chain of the antibody MAK33 was investigated. The Fc fragment consists of the C(H)3 and C(H)2 domains of the immunoglobulin heavy chain, both containing a single S-S bond. The folding process was investigated both in the absence and presence of the folding catalyst protein-disulfide isomerase (PDI), monitoring the evolution of intermediates by electrospray mass spectrometry. Moreover, the disulfide bonds present at different times in the folding mixture were identified by mass mapping to determine the hierarchy of disulfide bond formation. The analysis of the uncatalyzed folding showed that the species containing one intramolecular disulfide predominated throughout the entire process, whereas the fully oxidized Fc fragment never accumulated in significant amounts. This result suggests the presence of a kinetic trap during the Fc folding, preventing the one-disulfide-containing species (1S2H) to reach the fully oxidized protein (2S). The assignment of disulfide bonds revealed that 1S2H is a homogeneous species characterized by the presence of a single disulfide bond (Cys-130-Cys-188) belonging to the C(H)3 domain. When the folding experiments were carried out in the presence of PDI, the completely oxidized species accumulated and predominated at later stages of the process. This species contained the two native S-S bonds of the Fc protein. Our results indicate that the two domains of the Fc fragment fold independently, with a precise hierarchy of disulfide formation in which the disulfide bond, especially, of the C(H)2 domain requires catalysis by PDI.     

Mutations that destabilize the a' domain of human protein-disulfide isomerase indirectly affect peptide binding

Protein-disulfide isomerase (PDI) is a catalyst of folding of disulfide-bonded proteins and also a multifunctional polypeptide that acts as the beta-subunit in the prolyl 4-hydroxylase alpha(2)beta(2)-tetramer (P4H) and the microsomal triglyceride transfer protein alphabeta-dimer. The principal peptide-binding site of PDI is located in the b' domain, but all domains contribute to the binding of misfolded proteins. Mutations in the C-terminal part of the a' domain have significant effects on the assembly of the P4H tetramer and other functions of PDI. In this study we have addressed the question of whether these mutations in the C-terminal part of the a' domain, which affect P4H assembly, also affect peptide binding to PDI. We observed a strong correlation between P4H assembly competence and peptide binding; mutants of PDI that failed to form a functional P4H tetramer were also inactive in peptide binding. However, there was also a correlation between inactivity in these assays and indicators of conformational disruption, such as protease sensitivity. Peptide binding activity could be restored in inactive, protease-sensitive mutants by selective proteolytic removal of the mutated a' domain. Hence we propose that structural changes in the a' domain indirectly affect peptide binding to the b' domain.     

The molecular cloning and characterization of murine ferritin heavy chain, a tumor necrosis factor-inducible gene

Ferritin is a ubiquitous and highly conserved protein which plays a major role in iron homeostasis. We have identified and sequenced a full-length cDNA for murine ferritin heavy chain. The isolated cDNA is 819 nucleotides in length. It includes 546 nucleotides which encode a protein of 182 amino acids, a 5' noncoding sequence of 120 nucleotides, and a 3'-noncoding region of 153 nucleotides. The sequence displays a high degree of homology to human ferritin H, and includes a portion of the iron-responsive element conserved in chick, frog, and human ferritin. Tumor necrosis factor (TNF), a cytokine which mediates elements of the stress response, induces expression of ferritin H mRNA. Both mouse TA1 adipocytes and human muscle cells increase expression of ferritin H mRNA 4-6-fold after 48 h exposure to TNF. This increase occurs both prior and subsequent to differentiation of adipocytes and muscle cells, and is accompanied by an increase in the synthesis of the ferritin H subunit. These findings suggest a novel role for TNF in iron metabolism.     

BiP and Immunoglobulin Light Chain Cooperate to Control the Folding of Heavy Chain and Ensure the Fidelity of Immunoglobulin Assembly

The immunoglobulin (Ig) molecule is composed of two identical heavy chains and two identical light chains (H2L2). Transport of this heteromeric complex is dependent on the correct assembly of the component parts, which is controlled, in part, by the association of incompletely assembled Ig heavy chains with the endoplasmic reticulum (ER) chaperone, BiP. Although other heavy chain-constant domains interact transiently with BiP, in the absence of light chain synthesis, BiP binds stably to the first constant domain (CH1) of the heavy chain, causing it to be retained in the ER. Using a simplified two-domain Ig heavy chain (VH-CH1), we have determined why BiP remains bound to free heavy chains and how light chains facilitate their transport. We found that in the absence of light chain expression, the CH1 domain neither folds nor forms its intradomain disulfide bond and therefore remains a substrate for BiP. In vivo, light chains are required to facilitate both the folding of the CH1 domain and the release of BiP. In contrast, the addition of ATP to isolated BiP-heavy chain complexes in vitro causes the release of BiP and allows the CH1 domain to fold in the absence of light chains. Therefore, light chains are not intrinsically essential for CH1 domain folding, but play a critical role in removing BiP from the CH1 domain, thereby allowing it to fold and Ig assembly to proceed. These data suggest that the assembly of multimeric protein complexes in the ER is not strictly dependent on the proper folding of individual subunits; rather, assembly can drive the complete folding of protein subunits.     

Optimal combination of theory and experiment for the characterization of the protein folding landscape of S6: how far can a minimalist model go?

The detailed characterization of the overall free energy landscape associated with the folding process of a protein is the ultimate goal in protein folding studies. Modern experimental techniques provide accurate thermodynamic and kinetic measurements on restricted regions of a protein landscape. Although simplified protein models can access larger regions of the landscape, they are oftentimes built on assumptions and approximations that affect the accuracy of the results. We present a new methodology that allows to combine the complementary strengths of theory and experiment for a more complete characterization of a protein folding landscape. We prove that this new procedure allows a simplified protein model to reproduce remarkably well (correlation coefficient > 0.9) all experimental data available on free energies differences upon single mutations for S6 ribosomal protein and two circular permutants. Our results confirm and quantify the hypothesis, recently formulated on the basis of experimental data, that the folding landscape of protein S6 is strongly affected by an atypical distribution of contact energies.