Virtudes Villegas

Favourable native-like helical local interactions can accelerate protein folding

BACKGROUND Extensive studies of peptide conformation have provided reasonable knowledge of the rules determining helix stability. This knowledge can be used to stabilize proteins against chemical and thermal denaturation. This has been done in two proteins: the chemotactic protein from Escherichia coli, Che Y (a 129 aa alpha/beta parallel protein with five alpha-helices, which shows an accumulating intermediate during refolding) and the activation domain of human procarboxypeptidase A2, ADA2h (a 81 aa alpha + beta protein domain, with two alpha-helices, which follows a two-state mechanism). As the introduced stabilizing interactions are local in nature, the energy balance between the contribution of local and nonlocal interactions changes considerably. Recent theoretical analyses of protein folding using simplified models have indicated that optimization of folding speed requires this balance to be biased towards nonlocal interactions. To determine whether this is the case, we study here the folding kinetics of two ADA2h mutants in which alpha-helix 1 (mutant M1) or 2 (mutant M2) has been stabilized through local interactions, as well as the equilibrium and kinetic behaviour of a double mutant (DM) in which both helices have been stabilized. RESULTS The stability of DM is considerably enhanced with respect to wild type (WI) and this mutant can be considered as a thermoresistant protein (Tm > 363 K). The thermodynamic parameters obtained by chemical denaturation (urea and GdnHCl) show that DM is approximately 2.6 kcal mol-1 more stable than WT. The effects on folding kinetics are different in each of the single mutants. M1 shows very little effect in refolding, while its unfolding is greatly decelerated with respect to WT. M2 shows, together with a deceleration in unfolding, a significant acceleration in refolding. As with equilibrium parameters, the kinetics of the double mutant can be explained by the simple addition of the effects found in each single mutant. Interestingly enough, the refolding slope mkf in mutants M2 and DM is smaller than in the wild-type and M1 mutant. CONCLUSIONS Thermoresistance can be achieved, in some cases, by increasing favourable native local interactions. The balance between local and nonlocal interactions can be significantly changed in some proteins and still keep a cooperative unfolding transition similar to that of the wild type. The introduction of favourable local interactions by mutational redesign can also be used to increase the folding speed of certain proteins, showing that not all proteins in nature have been optimized for rapid folding, contrary to what has been theoretically indicated. This behaviour is probably also shared by other polypeptides with highly unstructured denatured states. All these phenomena have been shown experimentally in ADA2h by mutations that increase helix stability. However, the effects promoted for such an approach in proteins with residual structure and/or intermediates in the denatured ensemble could be different. This has been shown by experiments performed on CheY in which the cooperativity of the folding process was greatly affected.

Stabilization of proteins by rational design of α-helix stability using helix/coil transition theory

Backgound. Increasing protein stability is a major goal of protein engineering because of its potential industrial and pharmacological applications. Several different rule-of-thumb strategies have been employed for such a purpose, but a general rational method is still lacking. Recently, there has been significant progress in our understanding of the interactions responsible for helix stability in monomeric peptides and this information has been included in algorithms based on the helix/coil transition theory. We set out to investigate whether it is possible to use these algorithms to rationally increase protein stability. Results. Using a helix/coil transition algorithm, AGADIRms, we have designed mutations affecting solvent-exposed residues which, as predicted, significantly increase the helical stability in aqueous solution of peptides corresponding to the two alpha-helices of the activation domain of procarboxipeptidase A. Introduction of the same mutations in the protein results in proteins more resistant to urea or temperature denaturation, and there is a qualitative agreement between the expected and observed increases in stability. Conclusion. In this work we demonstrate that by using a helix/coil algorithm to design helix-stabilizing mutations on the solvent-exposed face of helices, it is possible to rationally increase the stability of proteins.

Hydrogen exchange monitored by MALDI-TOF mass spectrometry for rapid characterization of the stability and conformation of proteins

Matrix‐assisted laser desorption/ionization time‐of‐flight mass spectrometry (MALDI‐TOF MS) has been used to monitor hydrogen exchange on entire proteins. Two alternative methods have been used to carry out the hydrogen exchange studies, exchanging deuteron (H to D experiments) or proton (D to H experiments). In the former case, the use of a deuterated matrix has made possible to overcome back‐exchange problems and attain reproducible results. The methods presented have been used to determine the slow exchange core of the potato carboxypeptidase inhibitor in different folding states, and to differentially compare the activation domain of human procarboxypeptidase A2 versus three site‐directed mutants of different conformational stability. In this work, we show that by using MALDI‐TOF MS to monitor hydrogen exchange in entire proteins, it is possible to rapidly check the folding state of a protein and characterize mutational effects on protein conformation and stability, while requiring minimal amounts of sample.

Comparative Analysis of the Sequences and Three-Dimensional Models of Human Procarboxypeptidases A1, A2 and B

A full-length cDNA clone for preprocarboxypeptidase B from human pancreas has been isolated and sequenced. The open reading frame is 1254 bp in length, encoding a protein of 417 amino acids that includes a leader signal peptide of 15 amino acids and a 95-amino acid-long pro-segment. It contains two differences when compared to the sequence reported for pancreas-specific protein, a human serum marker for acute pancreatitis identified as procarboxypeptidase B. The main difference is a previously unreported Cys at position 138, which is needed for the formation of one of the three disulphide bridges. Sequence alignments between human procarboxypeptidases A1, A2 and B and other known forms show that the most conserved region is the enzyme moiety followed by the globular domain of the pro-segment. The maximum variability is found in the connecting region between moieties. The known three-dimensional structures of procarboxypeptidases from bovine and porcine species have been used to model all three human procarboxypeptidases and also to estimatethe interaction energies between the different parts of the molecules, in an attempt to gain insight into the structural features responsible for the differences observed in the functionality of the proenzymes, particularly in their proteolytic activation pathways. Taken together, the results obtained confirm that the main determinant for the rate and mode of activation of procarboxypeptidases is the strength of the interaction between the enzyme and the globular domain of the pro-segment, the connecting segment playing a complementary role.

Expression of heat-labile enterotoxin genes is under cyclic AMP control inEscherichia coli

The expression of the linkedtoxA andtoxB genes coding for the A and B subunits of the heat-labile enterotoxin ofEscherichia coli, respectively, has been studied. For this reason,toxA-lacZ andtoxB-lacZ fusions were constructed through a promoter-probe vector. Results obtained show that thetoxB gene has a promoter from which it may be transcribed independently from thetoxA gene. Nevertheless, the expression oftoxB gene is about 25-fold higher from thetoxA promoter than from its own promoter. Furthermore, the presence of glucose in the culture medium decreased the transcription from bothtoxA andtoxB promoters. Likewise,cya andcrp mutants exhibited a lower level oftox gene expression than did the wild-type strain. The addition of cyclic AMP increased the expression fromtoxA andtoxB promoters in bothcya and wild-type strains, but not in acrp mutant. All these data suggest that the cyclic AMP receptor protein-cyclic AMP complex positively modulatestoxA andtoxB gene transcription inE. coli.

NMR solution structure of the activation domain of human procarboxypeptidase A2

The activation domain of human procarboxypeptidase A2, ADA2h, is an 81‐residue globular domain released during the proteolytic activation of the proenzyme. The role of this and other similar domains as assistants of the correct folding of the enzyme is not fully understood. The folding pathway of ADA2h was characterized previously, and it was also observed that under certain conditions it may convert into amyloid fibrils in vitro. To gain insight into these processes, a detailed description of its three‐dimensional structure in aqueous solution is required so that eventual changes could be properly monitored. A complete assignment of the 1H and 15N resonances of ADA2h was performed, and the solution structure, as derived from a set of 1688 nonredundant constraints, is very well defined (pairwise backbone RMSD = 0.67 ± 0.17 Å for residues 10–80). The structure is composed of two antiparallel α‐helices comprising residues 19–32 and 58–69 packed on the same side of a three‐stranded β‐sheet spanning residues 10–15, 50–55, and 73–75. The global fold for the isolated human A2 activation domain is very similar to that of porcine carboxypeptidase B, as well as to the structure of the domain in the crystal of the intact human proenzyme. The observed structural differences relative to the intact human proenzyme are located at the interface between the activation domain and the enzyme and can be related with the activation mechanism. The backbone amide proton exchange behavior of ADA2h was also examined. The global free energy of unfolding obtained from exchange data of the most protected amide protons at pH 7.0 and 298K is 4.9 ± 0.3 kcal.mole−1, in good agreement with the values determined by thermal or denaturant unfolding studies.