Subtle alteration of the active site of ribulose bisphosphate carboxylase/oxygenase by concerted site-directed mutagenesis and chemical modification

Switching DNA-binding specificity by unnatural amino acid substitution

The specificity of protein–nucleic acid recognition is believed to originate largely from hydrogen bonding between protein polar atoms, primarily side-chain and polar atoms of nucleic acid bases. One way to design new nucleic acid binding proteins of novel specificity is by structure-guided alterations of the hydrogen bonding patterns of a nucleic acid–protein complex. We have used cI repressor of bacteriophage λ as a model system. In the λ-repressor–DNA complex, the ɛ-NH₂ group (hydrogen bond donor) of lysine-4 of λ-repressor forms hydrogen bonds with the amide carbonyl atom of asparagine-55 (acceptor) and the O6 (acceptor) of CG6 of operator site O_L1. Substitution of lysine-4 (two donors) by iso-steric S-(2-hydroxyethyl)-cysteine (one donor and one acceptor), by site-directed mutagenesis and chemical modification, leads to switch of binding specificity of λ-repressor from C:G to T:A at position 6 of O_L1. This suggests that unnatural amino acid substitutions could be a simple way of generating nucleic acid binding proteins of altered specificity.

Activation of carbonic anhydrase II by active-site incorporation of histidine analogs

The hydration of CO2 catalyzed by human carbonic anhydrase II (HCA II) is accompanied by proton transfer from the zinc-bound water of the enzyme to solution. We have replaced the proton shuttling residue His 64 with Ala and placed cysteine residues within the active-site cavity by mutating sites Trp 5, Asn 62, Ile 91, and Phe 131. These mutants were modified at the single inserted cysteine with imidazole analogs to introduce new potential shuttle groups. Catalysis by these modified mutants was determined by stopped-flow and 18O-exchange methods. Specificity in proton transfer was demonstrated; only modifications of the Cys 131-containing mutant showed enhancement in the proton transfer step of catalysis compared with unmodified Cys 131-containing mutant. Modifications at other sites resulted in up to 3-fold enhancement in rates of CO2 hydration, with apparent second-order rate constants near 350 microM(-1) s(-1). These are among the largest values of kcat/Km observed for a carbonic anhydrase.

Proteomics of the chloroplast envelope membranes from Arabidopsis thaliana

The development of chloroplasts and the integration of their function within a plant cell rely on the presence of a complex biochemical machinery located within their limiting envelope membranes. To provide the most exhaustive view of the protein repertoire of chloroplast envelope membranes, we analyzed this membrane system using proteomics. To this purpose, we first developed a procedure to prepare highly purified envelope membranes from Arabidopsis chloroplasts. We then extracted envelope proteins using different methods, i.e. chloroform/methanol extraction and alkaline or saline treatments, in order to retrieve as many proteins as possible, from the most to least hydrophobic ones. Liquid chromatography tandem mass spectrometry analyses were then performed on each envelope membrane subfraction, leading to the identification of more than 100 proteins. About 80% of the identified proteins are known to be, or are very likely, located in the chloroplast envelope. The validation of localization in the envelope of two phosphate transporters exemplifies the need for a combination of strategies to perform the most exhaustive identification of genuine chloroplast envelope proteins. Interestingly, some of the identified proteins are found to be Nalpha-acetylated, which indicates the accurate location of the N terminus of the corresponding mature protein. With regard to function, more than 50% of the identified proteins have functions known or very likely to be associated with the chloroplast envelope. These proteins are a) involved in ion and metabolite transport, b) components of the protein import machinery, and c) involved in chloroplast lipid metabolism. Some soluble proteins, like proteases, proteins involved in carbon metabolism, or proteins involved in responses to oxidative stress, were associated with envelope membranes. Almost one-third of the proteins we identified have no known function. The present work helps understanding chloroplast envelope metabolism at the molecular level and provides a new overview of the biochemical machinery of the chloroplast envelope membranes.

Proteomics of the chloroplast: experimentation and prediction

New technologies, in combination with increasing amounts of plant genome sequence data, have opened up incredible experimental possibilities to identify the total set of chloroplast proteins (the chloroplast proteome) as well as their expression levels and post-translational modifications in a global manner. This is summarized under the term 'proteomics' and typically involves two-dimensional electrophoresis or chromatography, mass spectrometry and bioinformatics. Complemented with nucleotide-based global techniques, proteomics is expected to provide many new insights into chloroplast biogenesis, adaptation and function.

Chemical modification of enzymes for enhanced functionality

The explosion in commercial and synthetic applications of enzymes has stimulated much of the interest in enhancing enzyme functionality and stability. Covalent chemical modification, the original method available for altering protein properties, has now re-emerged as a powerful complementary approach to site-directed mutagenesis and directed evolution for tailoring proteins and enzymes. Glutaraldehyde crosslinking of enzyme crystals and polyethylene glycol (PEG) modification of enzyme surface amino groups are practical methods to enhance biocatalyst stability. Whereas crosslinking of enzyme crystals generates easily recoverable insoluble biocatalysts, PEGylation increases solubility in organic solvents. Chemical modification has been exploited for the incorporation of cofactors onto protein templates and for atom replacement in order to generate new functionality, such as the conversion of a hydrolase into a peroxidase. Despite the breadth of applicability of chemically modified enzymes, a difficulty that has previously impeded their implementation is the lack of chemo- or regio-specificity of chemical modifications, which can yield heterogeneous and irreproducible product mixtures. This challenge has recently been addressed by the introduction of a unique position for modification by a site-directed mutation that can subsequently be chemically modified to introduce an unnatural amino acid sidechain in a highly chemo- and regio-specific manner.

Introduction of histidine analogs leads to enhanced proton transfer in carbonic anhydrase V

The rate-limiting step in the catalysis of the hydration of CO2 by carbonic anhydrase involves transfer of protons between zinc-bound water and solution. This proton transfer can be enhanced by proton shuttle residues within the active-site cavity of the enzyme. We have used chemical modulation to provide novel internal proton transfer groups that enhance catalysis by murine carbonic anhydrase V (mCA V). This approach involves the site-directed mutation of a targeted residue to a cysteine which is then subsequently reacted with an imidazole analog containing an appropriately positioned leaving group. Compounds examined include 4-bromoethylimidazole (4-BEI), 2-chloromethylimidazole (2-CMI), 4-chloromethylimidazole (4-CMI), and a triazole analog. Two sites in mCA V, Lys 91 and Tyr 131, located on the rim of the active-site cavity have been targeted for the introduction of these imidazole analogs. Modification of the introduced Cys 131 with 4-BEI and 4-CMI resulted in enhancements of up to threefold in catalytic activity. The pH profiles indicate the presence of a new proton shuttle residue of pKa near 5.8, consistent with the introduction of a functional proton transfer group into the active site. This is the first example of incorporation by chemical modification of an unnatural amino acid analog of histidine that can act as a proton shuttle in an enzyme.

Multiple catalytic roles of His 287 of Rhodospirillum rubrum ribulose 1,5-bisphosphate carboxylase/oxygenase

Active-site His 287 of Rhodospirillum rubrum ribulose 1,5-bisphosphate (RuBP) carboxylase/oxygenase interacts with the C3-hydroxyl of bound substrate or reaction-intermediate analogue (CABP), water molecules, and ligands for the activator metal-ion (Andersson I, 1996, J Mol Biol 259:160-174; Taylor TC, Andersson I, 1997, J Mol Biol 265:432-444). To test structure-based postulates of catalytic functionality, His 287 was replaced with Asn or Gln. The mutants are not affected adversely in subunit assembly, activation (binding of Mg2+ and carbamylation of Lys 191), or recognition of phosphorylated ligands; they bind CABP with even greater tenacity than does wild-type enzyme. H287N and H287Q are severely impaired in catalyzing overall carboxylation (approximately 10(3)-fold and > 10(5)-fold, respectively) and enolization (each mutant below threshold for detection) of RuBP. H287N preferentially catalyzes decarboxylation of carboxylated reaction intermediate instead of forward processing to phosphoglycerate. Analysis of RuBP turnover that occurs at high concentrations of mutants over extended time periods reveal > 10-fold reduced CO2/O2 specificities, elevated misprotonation of the enediol intermediate, and misprocessing of the oxygenated intermediate of the oxygenase pathway. These results are consistent with multifaceted roles for His 287 in promoting enediol formation, enediol tautomerization, and forward-processing of carboxylated intermediate.

Conversion of cysteinyl residues to unnatural amino acid analogs. Examination in a model system

Improved and efficient techniques have led to an explosive growth in the application of site-directed mutagenesis to the study of enzymes. However, the limited availability of only those 20 amino acids that are translated by the genetic code has prevented the systematic variation of an amino acid's properties in order to define more precisely its role in the catalytic mechanism of an enzyme. An approach is being examined that combines the high specificity of site-directed mutagenesis with the flexibility of chemical modification to overcome these limitations. A set of reagents has been synthesized and reacted with a cysteine model to produce a series of amino acid structural analogs at appreciable rates and in good overall yields. The selective incorporation of these analogs in place of important functional amino acids in a protein will allow a more detailed examination of the role of that amino acid.

Ribonuclease a: revealing structure-function relationships with semisynthesis

Bovine pancreatic ribonuclease A (RNase A) catalyzes the cleavage of P–O5′ bonds in RNA. Structural analyses had suggested that the active-site lysine residue (K41) may interact preferentially with the transition state for covalent bond cleavage, thus facilitating catalysis. Here, site-directed mutagenesis and semisynthesis were combined to probe the role of K41 in the catalysis of RNA cleavage. Recombinant DNA techniques were used to replace K41 with an arginine residue (K41R) and with a cysteine residue (K41C), which had the only sulfhydryl group in the native protein. The value of k cat/K m for cleavage of poly(C) by K41C RNase was 105-fold lower than that by the wild-type enzyme. The sulfhydryl group of K41C RNase A was alkylated with 5 different haloalkylamines. The value of k cat/K m for the resulting semisynthetic enzymes and K41R RNase A were correlated inversely with the values of pK a for the side chain of residue 41. Further, no significant catalytic advantage was gained by side chains that could donate a second hydrogen bond. These results indicate that residue 41 donates a single hydrogen bond to the rate-limiting transition state during catalysis.

Reversible dissociation and conformational stability of dimeric ribulose bisphosphate carboxylase

Dimer-monomer dissociation of ribulosebisphosphate carboxylase/oxygenase from Rhodospirillum rubrum was investigated using hydrostatic pressure in the range 1-2 kbar to promote dissociation. Intrinsic fluorescence emission and polarization, along with the polarization of the fluorescence of single-labeled AEDANS conjugates, were used to follow the dissociation. Full reversibility after dissociation was observed to depend on the presence of small ligands: glycerol, Mg2+, and NaHCO3, the last two being required to activate the enzyme. The free energy of association at 15 degrees C, -12.9 kcal mol-1, was made up of a positive change in enthalpy on association of 6.0 kcal mol-1 and an entropic contribution (T delta S) of 18.9 kcal mol-1; thus the monomer association is entropy driven. No dissociation of the quaternary complex formed by the dimer, 2-carboxy-D-arabinitol 1,5-diphosphate (CADP), Mg2+, and NaHCO3 was observed at pressures up to 2.0 kbar; the magnitude of stabilization by the inhibitor binding was estimated as 2.3 kcal mol-1. Pressurization in the presence of bis-ANS results in a time-dependent increase in fluorophore emission, indicating changes in monomer conformation with exposure of hydrophobic surfaces upon dissociation. Reactivity against the fluorescent probe 1,5-I-AEDANS was also used as a conformational probe: HPLC of a trypsin digest of rubisco labeled at atmospheric pressure revealed a single fluorescent peptide, whereas more extensive labeling was observed when the reaction was carried out at 2.0 kbar, indicative of exposure of internal cysteines.(ABSTRACT TRUNCATED AT 250 WORDS)

Reengineering the catalytic lysine of aspartate aminotransferase by chemical elaboration of a genetically introduced cysteine

The active-site essential catalytic residue of aspartate aminotransferase, Lys 258, has been converted to Cys (K258C) by site-directed mutagenesis. This mutant retains less than 10(-6) of the wild-type activity with L-aspartate. The deleted general base was functionally replaced by selective (with respect to the other five cysteines in wild type) aminoethylation of the introduced Cys 258 with (2-bromoethyl)amine following reversible protection of the nontarget sulfhydryl groups at different stages of unfolding. The chemically elaborated mutant (K258C-EA) is 10(5) times more reactive than is K258C and has a kcat value of approximately 7% of that of wild type (WT). Km and KI values are similar to those for WT. The acidic pKa controlling V/KAsp is shifted from 7.3 (WT) to 6.0 (mutant). V/K values for amino acids are approximately 3% of those found for WT, whereas they are approximately 20% for keto acids. The value of DV increases from 1.6 for WT to 3.4 for the mutant, indicating that C alpha proton abstraction constitutes a more significant kinetic barrier for the latter enzyme. A smaller, but still significant, increase in D(V/KAsp) from 1.9 in WT to 3.0 in the mutant shows that the forward and reverse commitment factors are inverted by the mutation. The acidic limb of the V/KAsp versus pH profile, is lowered by 1.3 pH units, probably reflecting the similar difference in the basicity of the epsilon-NH2 group in gamma-thialysine versus that in lysine.(ABSTRACT TRUNCATED AT 250 WORDS)

Sequence and expression of genes encoding the large and small subunits of ribulose 1,5-bisphosphate carboxylase/oxygenase from Chromatium vinosum

A DNA fragment bearing genes for the large (rbcL) and small (rbcS) subunits of ribulose 1,5-bisphosphate carboxylase/oxygenase (RuBisCO) was cloned from the photosynthetic purple sulfur bacterium Chromatium vinosum. Enzymatically fully active RuBisCO was synthesized in Escherichia coli cells when the cloned DNA was placed downstream of tac promoter. Nucleotide (nt) sequences of rbcL-rbcS were more homologous to cyanobacterial counterparts than to those from Alcaligenes eutrophus or higher plants. However, the amino acid (aa) sequence in a domain responsible for CO2 activation in the C. vinosum rbcL product resembled the corresponding aa sequence in higher plant RuBisCos, but not in the cyanobacterial enzymes. Chemically determined aa sequences at the N terminals of both subunits of RuBisCO purified from C. vinosum were not identical to those deduced from the nt sequences, although they were completely the same as aa sequences deduced from rbcA-rbcB, another locus encoding RuBisCO in C. vinosum. Therefore, the rbcL-rbcS locus seems to be barely expressed under a standard condition for photoautotrophic growth. The homology of the nt sequences between rbcL and rbcA was 82%, and that between rbcS and rbcB was 63%, whereas the codon usages of these genes were basically identical. The rbcL-rbcS and rbcA-rbcB loci therefore must have evolved from a common ancestral set of genes after duplication, instead of lateral gene transfer.