Secondary binding site of the potato carboxypeptidase inhibitor. Contribution to its structure, folding, and biological properties

The contribution of each residue of the potato carboxypeptidase inhibitor (PCI) secondary binding site to the overall properties of this protein has been examined using alanine-scanning mutagenesis. Structural and enzymatic studies, performed on a series of PCI mutants, demonstrate that the proper positioning of the primary site for efficient binding and inhibition of carboxypeptidase A is significantly dependent on such a secondary contact region. The aromatic residues in this region play a key role in the stabilization of the PCI-enzyme complex, whereas polar residues contribute little to this task. A comparative study of the oxidative folding of these PCI mutants has been carried out using the disulfide quenching approach. The data, together with the structural characterization of some of these mutants, clearly indicate that noncovalent forces drive the refolding of this small disulfide-rich protein at the reshuffling stage, the rate-limiting step of the process. Moreover, it reveals that by introducing new noncovalent intramolecular contacts in PCI, we may create more stable variants, which also show improved folding efficiency. Taken together, the collected results clarify the folding determinants of the primary and secondary binding sites of PCI and their contribution to the inhibition of the carboxypeptidase, providing clues about PCI evolution and knowledge for its biotechnological redesign.     

Vacuolar localization of wound-induced carboxypeptidase inhibitor in potato leaves

The wound-induced carboxypeptidase inhibitor in potato leaves was shown to be localized in the central vacuoles of the cells. The inhibitor was quantified by immunological assays (ELISA) in protoplasts and vacuoles isolated from upper unwounded leaves of 5- to 6-week old potato plants that had been wounded on their lower leaves 48 hours earlier to induce the accumulation of the carboxypeptidase inhibitor. The regulation of the synthesis and compartmentation of the inhibitor is similar to that of wound-induced serine proteinase Inhibitors I and II in potato and tomato leaves and appears to be part of an induced defense response against attacking pests.     

Contribution of ribosomal residues to P-site tRNA binding

Structural studies have revealed multiple contacts between the ribosomal P site and tRNA, but how these contacts contribute to P-tRNA binding remains unclear. In this study, the effects of ribosomal mutations on the dissociation rate (k_off) of various tRNAs from the P site were measured. Mutation of the 30S P site destabilized tRNAs to various degrees, depending on the mutation and the species of tRNA. These data support the idea that ribosome-tRNA interactions are idiosyncratically tuned to ensure stable binding of all tRNA species. Unlike deacylated elongator tRNAs, N-acetyl-aminoacyl-tRNAs and tRNA^fMet dissociated from the P site at a similar low rate, even in the presence of various P-site mutations. These data provide evidence for a stability threshold for P-tRNA binding and suggest that ribosome-tRNA^fMet interactions are uniquely tuned for tight binding. The effects of 16S rRNA mutation G1338U were suppressed by 50S E-site mutation C2394A, suggesting that G1338 is particularly important for stabilizing tRNA in the P/E site. Finally, mutation C2394A or the presence of an N-acetyl-aminoacyl group slowed the association rate (k_on) of tRNA dramatically, suggesting that deacylated tRNA binds the P site of the ribosome via the E site.     

The unfolding pathway and conformational stability of potato carboxypeptidase inhibitor

The unfolding and denaturation curves of potato carboxypeptidase inhibitor (PCI) were investigated using the technique of disulfide scrambling. In the presence of denaturant and thiol initiator, the native PCI denatures by shuffling its native disulfide bonds and converts to form a mixture of scrambled PCI that consists of 9 out of a possible 14 isomers. The denaturation curve is determined by the fraction of native PCI converted to scrambled isomers under increasing concentrations of denaturant. The concentration of guanidine thiocyanate, guanidine hydrochloride, and urea required to denature 50% of the native PCI was found to be 0.7, 1.45, and 8 m, respectively. The PCI unfolding curve was constructed through the analysis of structures of scrambled isomers that were denatured under increasing concentrations of denaturant. These results reveal the existence of structurally defined unfolding intermediates and a progressive expansion of the polypeptide chain. The yield of the beads-form isomer (Cys(8)-Cys(12), Cys(18)-Cys(24), and Cys(27)-Cys(34)) as a fraction of total denatured PCI was shown to be directly proportional to the strength of the denaturing condition. Furthermore, the PCI sequence was unable to fold quantitatively into a single native structure. Under physiological conditions, the scrambled isomers of PCI that constitute about 4% of the protein were in equilibrium with native PCI.     

Structure and atomic fluctuation patterns of potato carboxypeptidase a inhibitor protein

Molecular dynamics (MD) simulation methods were applied to the study of the structural and dynamic fluctuation properties of the potato carboxypeptidase A inhibitor protein (PCI) immersed in a bath of 1259 water molecules. A trajectory of 200 ps was generated at constant temperature and pressure. The crystallographic structure of PCI, as found in its complex with bovine carboxy-peptidase A (CPA), was used to seed the MD simulation. Analyses show that the structure of the PCI core is fairly rigid and stable in itself, and that little deformation is caused by the protein-protein interactions found in the PCI-CPA complex. The N-terminal tail fluctuates to approach the core structure and appears as a relatively disordered region. In contrast, the conformations of the C-terminal tail, which is involved in the inhibitory mechanism, fluctuates in the neighborhood of the X-ray structure in orientations which facilitate CPA binding. Comparison with the structural entries for PCI in water obtained from both 2D-NMR experiments and X-ray data shows that important features of the MD structural results fluctuates between the initial crystal values and those obtained from the NMR solution structure. This fluctuation is not uniform; minor regions move away from the X-ray conformation while they do not approach the NMR conformation. The results reported suggest that the trajectory is long enough to show a behavior that is consistent with the conformational space available to the protein in solution.Abbreviations CPA Carboxypeptidase - DG Distance Geometry - NMR Nuclear Magnetic Resonance - NIS Non Inertial Solvent - MD Molecular Dynamics - PBC Periodic Boundary Conditions - PCI Potato Carboxypeptidase Inhibitor - RMSD Root Mean Square Deviation - a.m.u. Atomic mass unitsCorrespondence to: O. Tapia     

Analysis of the effect of potato carboxypeptidase inhibitor pro-sequence on the folding of the mature protein.

Protein folding can be modulated in vivo by many factors. While chaperones act as folding catalysts and show broad substrate specificity, some pro-peptides specifically facilitate the folding of the mature protein to which they are bound. Potato carboxypeptidase inhibitor (PCI), a 39-residue protein carboxypeptidase inhibitor, is synthesized in vivo as a precursor protein that includes a 27-residue N-terminal and a seven-residue C-terminal pro-regions. In this work the disulfide-coupled folding of mature PCI in vitro has been compared with that of the same protein extended with either the N-terminal pro-sequence (ProNtPCI) or both N- and C-terminal pro-sequences (ProPCI), and also with the N-terminal pro-sequence in trans (ProNt + PCI). No significant differences can be observed in the folding kinetics or efficiencies of all these molecules. In addition, in vivo folding studies in Escherichia coli have been performed using wild-type PCI and three PCI mutant forms with and without the N-terminal pro-sequence, the mutations had been previously reported to affect folding of the PCI mature form. The extent to which the 'native-like' form was secreted to the media by each construction was not affected by the presence of the N-terminal pro-sequence. These results indicate that PCI does not depend on the N-terminal pro-sequence for its folding in both, in vitro and in vivo in E. coli. However, structural analysis by spectroscopy, hydrogen exchange and limited proteolysis by mass spectrometry, indicate the capability of such N-terminal pro-sequence to fold within the precursor form.     

Contribution of monosaccharide residues in heparin binding to antithrombin III

The importance of 3-O- and 6-O-sulfated glucosamine residues within the heparin octasaccharide iduronic acid(1)----N-acetylglucosamine 6-O-sulfate(2)----glucuronic acid(3)----N-sulfated glucosamine 3,6-di-O-sulfate(4)----iduronic acid 2-O-sulfate(5)----N-sulfated glucosamine 6-O-sulfate(6)----iduronic acid 2-O-sulfate(7)----anhydromannitol 6-O-sulfate(8) was determined by comparing with synthetic tetra- and penta-saccharides its ability to bind human antithrombin. The octasaccharide had an affinity for antithrombin of 1 X 10(-8) M (10.2 kcal/mol) measured by intrinsic fluorescence enhancement at 6 degrees C. The synthetic pentasaccharide, consisting of residues 2-6, had an affinity of 3 X 10(-8) M (9.6 kcal/mol). The same pentasaccharide, except lacking the 3-O-sulfate on residue 4, had an affinity of 5 X 10(-4) M (4.5 kcal/mol) measured by equilibrium dialysis. The tetrasaccharide, consisting of residues 2-5, bound antithrombin with an affinity of 5 X 10(-6) M (6.8 kcal/mol). The tetrasaccharide, consisting of residues 3-6, had an affinity of 5 X 10(-5) M (5.5 kcal/mol). Since the loss of either the 6-O-sulfated residue 2 or the 3-O-sulfate of residue 4 results in a 4-5 kcal/mol or a 40-50% loss in binding energy of the pentasaccharide, these two residues must be the major contributors to the binding and must be linked to the biologic activity of the octasaccharide.     

Stability and fluctuations of the potato carboxypeptidase A protein inhibitor fold: a molecular dynamics study

A 120ps non-inertial solvent (NIS) molecular dynamics (MD) trajectory of the potato carboxypeptidase A protein inhibitor (PCI) was calculated and analyzed. It is shown that, in spite of a very low content of regular secondary structure, the PCI fold has a large degree of stability, judged from the fairly good agreement between the average MD and X-ray structures. The N-terminal and C-terminal regions behave differently, both in their isoatomic positional shifts with respect to the X-ray structure, and in atomic fluctuation pattern. Positional shifts up to 9A are detected in the exposed N-terminal region as it folds back on the inhibitor's core. This large deviation is most likely caused by the absence of the receptor protein or by the lack of supporting solvent molecules. In contrast, the C-terminal region, which is the primary contact site with the enzyme, has an average structure similar to the X-ray conformation; this feature is probably due to a hydrogen bond network to the central core of PCI. The C-terminal tail shows larger fluctuations than the core. The secondary contact site retains its structure in this simulation. The results evidence an intrinsically stable PCI fold which favors a spatially well defined, fairly flexible, structuration of the primary and secondary contact sites that optimizes PCI's interaction with its target enzyme.     

A mutagenesis study of the putative luciferin binding site residues of firefly luciferase

Firefly luciferase catalyzes the highly efficient emission of yellow-green light from substrate firefly luciferin by a sequence of reactions that require Mg-ATP and molecular oxygen. We had previously developed [Branchini, B. R., Magyar, R. A., Murtiashaw, M. H., Anderson, S. M., and Zimmer, M. (1998) Biochemistry 37, 15311-15319] a molecular graphics-based working model of the luciferase active site starting with the first X-ray structure [Conti, E., Franks, N. P., and Brick, P. (1996) Structure 4, 287-298] of the enzyme without bound substrates. In our model, the luciferin binding site contains 15 residues that are within 5 A of the substrate. Using site-directed mutagenesis, we made changes at all of these residues and report here the characterization of the corresponding expressed and purified proteins. Of the 15 residues studied, 12 had a significantly (>or=4-fold K(m) difference) altered binding affinity for luciferin and seven residues, spanning the primary sequence region Arg218-Ala348, had substantially (>or=30 nm) red-shifted bioluminescence emission maxima when mutated. We report here an interpretation of the roles of the mutated residues in substrate binding and bioluminescence color determination. The results of this study generally substantiate the accuracy of our model and provide the foundation for future experiments designed to alter the substrate specificity of firefly luciferase.     

Expression of a synthetic gene encoding potato carboxypeptidase inhibitor using a bacterial secretion vector.

A synthetic gene encoding the 39-amino-acid (aa) potato carboxypeptidase inhibitor IIa (PCI-IIa) has been constructed and expressed using the secretion vector, pIN-III-ompA-3, fused in frame to the OmpA signal peptide-encoding sequence. Recombinant Escherichia coli secreted a PCI with 10 additional aa at the N terminus (rePCI + 10). These extra aa were removed by site-directed mutagenesis giving a PCI with no additional aa (rePCI), as shown by fast atom bombardment mass spectrometry (M(r) 4295). The two forms of rePCI were found almost exclusively in the culture medium, not in the periplasmic space, as would be expected from OmpA signal peptide fusions. Both rePCI + 10 and rePCI are biologically active and react strongly with serum raised against PCI from potato. A method for the purification of rePCI to homogeneity has been developed. The purified rePCI shows a Ki for carboxypeptidase A within the range of the natural PCI-IIa (1.5-2.7 nM). These results indicate that both rePCI + 10 and rePCI are properly folded and that their three disulfide bridges are correctly formed. Together with previous reports, our results show that fusion to a secretion signal peptide is an effective way of producing small proteins containing disulfide bridges in a biologically active form.     

Identification of residues essential for progesterone binding to uteroglobin by site-directed mutagenesis

In order to identify amino acids directly involved in progesterone binding to rabbit uteroglobin we have mutated Phe 6, Tyr 21 and Thr 60 by site-directed mutagenesis of the uteroglobin cDNA. These residues have been postulated previously to participate in progesterone binding. High-level expression of the mutated uteroglobin cDNAs in Escherichia coli yields recombinant protein mutants that, like natural uteroglobin, form stable dimers, suggesting that the tertiary structure of the protein has not been altered. Substitution of Phe 6 by Ser or Ala does not change the progesterone binding characteristics. In contrast, replacement of Tyr 21 by Phe or Ala, drastically decreases progesterone binding. In addition, replacement of Thr 60 by Ala reduces the affinity for progesterone by a factor of three. These data suggest a direct interaction of progesterone with these two amino acids and support the idea of direct hydrogen bonding of the carbonyl (C3 and C20) of progesterone with the hydroxyl groups of Tyr 21 and Thr 60, respectively.     

Chlorophyll binding to monomeric light-harvesting complex. A mutation analysis of chromophore-binding residues

The chromophore binding properties of the higher plant light-harvesting complex II have been studied by site-directed mutagenesis of pigment-binding residues. Mutant apoproteins were overexpressed in Escherichia coli and then refolded in vitro with purified chromophores to yield holoproteins selectively affected in chlorophyll-binding sites. Biochemical and spectroscopic characterization showed a specific loss of pigments and absorption spectral forms for each mutant, thus allowing identification of the chromophores bound to most of the binding sites. On these bases a map for the occupancy of individual sites by chlorophyll a and chlorophyll b is proposed. In some cases a single mutation led to the loss of more than one chromophore indicating that four chlorophylls and one xanthophyll could be bound by pigment-pigment interactions. Differential absorption spectroscopy allowed identification of the Q(y) transition energy level for each chlorophyll within the complex. It is shown that not only site selectivity is largely conserved between light-harvesting complex II and CP29 but also the distribution of absorption forms among different protein domains, suggesting conservation of energy transfer pathways within the protein and outward to neighbor subunits of the photosystem.     

Enhanced Co2+ activation and inhibitor binding of carboxypeptidase M at low pH. Similarity to carboxypeptidase H (enkephalin convertase).

Carboxypeptidases H and M differ in their distribution and other properties, but both are activated by Co2+ and inhibited by guanidinoethylmercaptosuccinic acid. The higher degree of activation or inhibition of carboxypeptidase H by these agents at acid pH has been employed to identify this enzyme in tissues. We found that the activation or inhibition of both purified and plasma-membrane-bound human carboxy-peptidase M depends on the pH of the medium. CoCl2 activated over 6-fold at pH 5.5, but less than 2-fold at pH 7.5. Guanidinoethylmercaptosuccinic acid inhibited the membrane-bound carboxypeptidase M more effectively than the purified enzyme, and the IC50 was about 25-30 times lower at pH 5.5. As purified human plasma carboxypeptidase N and pancreatic carboxypeptidase B were also activated more at pH 5.5, we conclude that the increased activation by CoCl2 is due to the enhanced dissociation of Zn2+ below the pKa of the ligands that co-ordinate the cofactor in the protein. Thus increased activation or inhibition at acid pH would not differentiate basic carboxypeptidases.     

Characterization of inhibitor binding to human kinesin spindle protein by site-directed mutagenesis

A number of inhibitors of kinesin spindle protein (KSP) have been described, which are known from X-ray crystallography studies to bind to an induced fit pocket defined by the L5 loop. We describe the characterization of eight mutant forms of KSP in which six residues that line this pocket have been altered. Mutants were analyzed by measuring rates of enzyme catalysis, in the presence and absence of six KSP inhibitors of four diverse structural classes and of varied ATP-competition status. Our analysis was in agreement with the model of binding established by the structural studies and suggests that binding energy is well distributed across functional groups in these molecules. The majority of the mutants retained significant enzymatic activity while diminishing inhibitor binding, indicating potential for the development of drug resistance. These data provide detailed information on interactions between inhibitor and binding pocket at the functional group level and enable the development of novel KSP inhibitors.