A new large form of transcarboxylase with six outer subunits and twelve biotinyl carboxyl carrier subunits.

A new form of transcarboxylase has been isolated which has a molecular weight of 1,200,000, an s20,w of 26 S, and contains 12 biotinyl groups. Transcarboxylase as isolated previously has a molecular weight of 790,000, an s20,w of 18 S, and contains six biotinyl groups. The larger species of enzyme consists of a central hexameric subunit with six dimeric outer subunits attached to it by biotinyl carboxyl carrier proteins, three each at the opposite faces of the central subunits. This larger species is stable at pH 5.5, but dissociates to the 18 S species at pH values near neutrality with loss of a set of three of the outer subunits with two of the biotinyl carboxyl carrier proteins still attached to each of these subunits. The dissociation to the 18 S form occurs by several rapidly reversible steps and under certain conditions of centrifugation multiple peaks are observed as a consequence of the occurrence of different forms of enzyme with variable numbers of the outer subunits attached to the 18 S enzyme. The s20,w value of the so-called 26 S enzyme varies with conditions. Isolated 18 S enzyme has been combined with isolated outer subunits to form active 26 S enzyme. The newly enzyme is a normal form but has not been isolated previously because of its dissociation to the 18 S form at neutral pH. A procedure is described for the isolation of the 26 S form in a highly purified state. The molecular weight of the enzyme has been determined by high speed meniscus depletion. In addition, a procedure is described for dissociation of the 26 S form of the enzyme and isolation of the resulting outer subunits with the biotinyl subunits still attached to it. Evidence is presented that all six outer subunits participate in the enzymatic reaction which includes the demonstration that; (a) all 12 biotins of the 26 S form of the enzyme can be carboxylated with [3-14C]methylmalonyl coenzyme A; (b) there is an increase in enzymatic activity when the outer subunits are combined with the normal 18 S enzyme with formation of the 26 S enzyme; and (c) a 26 S form of the enzyme is active which is prepared by combination of inactive 18 S trypsin-treated transcarboxylase with the outer subunits. The trypsin-treated 18 S enzyme is inactive because trypsin removes the biotin as biotinyl peptides and the 26 S enzyme is active because of the second set of active outer subunits.     

High resolution solution structure of the 1.3S subunit of transcarboxylase from Propionibacterium shermanii

Transcarboxylase (TC) from Propionibacterium shermanii, a biotin-dependent enzyme, catalyzes the transfer of a carboxyl group from methylmalonyl-CoA to pyruvate to form propionyl-CoA and oxalacetate. Within the multi-subunit enzyme complex, the 1.3S subunit functions as the carboxyl group carrier and also binds the other two subunits to assist in the overall assembly of the enzyme. The 1.3S subunit is a 123 amino acid polypeptide (12.6 kDa) to which biotin is covalently attached at Lys 89. The three-dimensional solution structure of the full-length holo-1.3S subunit of TC has been solved by multidimensional heteronuclear NMR spectroscopy. The C-terminal half of the protein (51-123) is folded into a compact all-beta-domain comprising of two four-stranded antiparallel beta-sheets connected by short loops and turns. The fold exhibits a high 2-fold internal symmetry and is similar to that of the biotin carboxyl carrier protein (BCCP) of acetyl-CoA carboxylase, but lacks an extension that has been termed "protruding thumb" in BCCP. The first 50 residues, which have been shown to be involved in intersubunit interactions in the intact enzyme, appear to be disordered in the isolated 1.3S subunit. The molecular surface of the folded domain has two distinct surfaces: one side is highly charged, while the other comprises mainly hydrophobic, highly conserved residues.     

Amino acid sequence of the biotinyl subunit from transcarboxylase.

The complete amino acid sequence of the biotinyl subunit from the enzyme transcarboxylase of Propionibacterium shermanii has been determined from the structures of overlapping tryptic and cyanogen bromide peptides together with sequenator analysis on the whole subunit. The subunit contains 123 amino acid residues. Eleven of nineteen residues in the region of biotin attachment, when compared to pyruvate carboxylase from avian liver (Rylatt, D. B., Keech, D. B., and Wallace, J. C. (1977) Arch. Biochem. Biophys. 183, 113-122), were found to be in identical positions relative to biocytin. There was less homology with acetyl-CoA carboxylase from Escherichia coli (Sutton, M. R., Fall, R. R., Nervi, A. M., Alberts, A. W., Vagelos, P. R., and Bradshaw, R. A. (1977) J. Biol. Chem. 252, 3934-3940), but in all of these biotin enzymes there was an alanylmethionyl-biocytinyl-methionine sequence. The secondary structure of the biotinyl subunit has been estimated using the method of Chou and Fasman (Chou, P. Y., and Fasman, G. D. (1978) Adv. Enzymol. 47, 45-148) and considered in relationship to the role of the biotinyl subunit in the structure and function in transcarboxylase.     

New and easy strategy for cloning, expression, purification, and characterization of the 5S subunit of transcarboxylase from Propionibacterium f. shermanii

Methylmalonyl CoA-oxalacetate transcarboxylase (EC 2. 1. 3. 1) from Propionibacterium f. shermanii is a biotin dependent enzyme which transfers CO2 from methylmalonyl-CoA (MMCoA) to pyruvate via a carboxylated biotin group to form oxalacetate. It is composed of three subunits, the central cylindrical hexameric 12S subunit, the outer six dimeric 5S subunit, and the twelve 1.3S linkers. We here report the cloning, sequencing, expression, and purification of the 5S subunit. The gene was identified by matching the amino acid sequence with that of deposited in the NCBI database. For cloned 5S subunit sequence shows regions of high homology with that of pyruvate carboxylase and oxaloacetate decarboxylase. The gene encoding the 5S subunit was cloned into the pTXB1 vector. The expressed 5S subunit was purified to apparent homogeneity by a single step process by using Intein mediated protein ligation (IPL) method. The cloned 5S gene encodes a protein of 505 amino acids and of M(r) 55,700.     

The biotin carboxylase-biotin carboxyl carrier protein complex of Escherichia coli acetyl-CoA carboxylase

Escherichia coli acetyl-CoA carboxylase (ACC) is composed of four different protein molecules. These proteins form a large but very unstable complex. Hints of a sub-complex between the biotin carboxylase (BC) and biotin carboxyl carrier protein (BCCP) subunits have been reported in the literature, but the complex was not isolated and thus the protein stoichiometry could not be determined. We report isolation of the BC.BCCP complex. By use of affinity chromatography using two different affinity tags it was shown that the complex consists of a two BCCP molecules per BC molecule. The molar ratio in the complex is the same as the ratio of the subunit proteins synthesized in vivo. We conclude that the complex consists of a dimer of BC plus four BCCP molecules instead of the 2BC.2BCCP complex previously assumed. This subunit ratio allows two conflicting models of the ACC mechanism to be rectified. We also report that the N-terminal 30 or so residues of BCCP are responsible for the interaction of BCCP with BC and that the BC.BCCP complex is a substrate for biotinylation in vitro.     

Interchangeable enzyme modules. Functional replacement of the essential linker of the biotinylated subunit of acetyl-CoA carboxylase with a linker from the lipoylated subunit of pyruvate dehydrogenase

Biotin carboxyl carrier protein (BCCP) is the small biotinylated subunit of Escherichia coli acetyl-CoA carboxylase, the enzyme that catalyzes the first committed step of fatty acid synthesis. E. coli BCCP is a member of a large family of protein domains modified by covalent attachment of biotin. In most biotinylated proteins, the biotin moiety is attached to a lysine residue located about 35 residues from the carboxyl terminus of the protein, which lies in the center of a strongly conserved sequence that forms a tightly folded anti-parallel beta-barrel structure. Located upstream of the conserved biotinoyl domain sequence are proline/alanine-rich sequences of varying lengths, which have been proposed to act as flexible linkers. In E. coli BCCP, this putative linker extends for about 42 residues with over half of the residues being proline or alanine. I report that deletion of the 30 linker residues located adjacent to the biotinoyl domain resulted in a BCCP species that was defective in function in vivo, although it was efficiently biotinylated. Expression of this BCCP species failed to restore normal growth and fatty acid synthesis to a temperature-sensitive E. coli strain that lacks BCCP when grown at nonpermissive temperatures. In contrast, replacement of the deleted BCCP linker with a linker derived from E. coli pyruvate dehydrogenase gave a chimeric BCCP species that had normal in vivo function. Expression of BCCPs having deletions of various segments of the linker region of the chimeric protein showed that some deletions of up to 24 residues had significant or full biological activity, whereas others had very weak or no activity. The inactive deletion proteins all lacked an APAAAAA sequence located adjacent to the tightly folded biotinyl domain, whereas deletions that removed only upstream linker sequences remained active. Deletions within the linker of the wild type BCCP protein also showed that the residues adjacent to the tightly folded domain play an essential role in protein function, although in this case some proteins with deletions within this region retained activity. Retention of activity was due to fusion of the domain to upstream sequences. These data provide new evidence for the functional and structural similarities of biotinylated and lipoylated proteins and strongly support a common evolutionary origin of these enzyme subunits.     

Mutagenesis affecting the carboxyl terminus of the biotinyl subunit of transcarboxylase. Effects on biotination

Biotin is added to biotin-containing enzymes as a post-translational modification catalyzed by holoenzyme synthetase. This reaction is fairly general in that synthetase from one organism will modify enzymes from heterologous sources. This suggests that the polypeptides share some structural characteristic(s) that define(s) them as biotin enzymes. We have reported previously that when the gene coding for the 1.3 S biotinyl subunit of transcarboxylase is expressed in Escherichia coli, the polypeptide produced is biotinated by the cellular synthetase. Using in vitro mutagenesis of this gene, we have begun to define the primary structure involved in the enzymatic addition of biotin to a lysine residue. We show here that the carboxyl terminus of the 1.3 S subunit is critical in biotination. Mutations affecting the COOH-terminal residue do not influence the modification, but elimination of the hydrophobic side chain of the penultimate residue abolishes biotin addition.     

Involvement of tryptophans at the catalytic and subunit-binding domains of transcarboxylase

Transcarboxylase from Propionibacterium shermanii is a multisubunit enzyme. It consists of one central hexameric subunit to which six outer dimeric subunits are attached through twelve biotinyl subunits. Both the central and the outer subunits are multi-tryptophan (Trp) proteins, and each contains 5 Trps per monomer. The roles of the Trps during catalysis and assembly of the enzyme have been studied by using N-bromosuccinimide (NBS) oxidation as a probe. Modification of approximately 10 Trps of the total 90 Trps of the intact enzyme results in loss of activity. Both the substrates, viz., methylmalonyl-CoA and pyruvate, afford protection (approximately 50%) against inactivation caused by NBS. Analyses of tryptic peptide maps and intrinsic fluorescence studies have indicated that modification of 10 Trps of the whole enzyme does not cause extensive conformational changes. Therefore, the Trps appear to be essential for catalytic activity. NBS modification of the individual subunits at pH 6.5 has demonstrated differential reactivity of their Trps. Modification of the exposed/reactive Trps of either one of the subunits significantly affects the subunit assembly with the complementary unmodified subunits to form active enzyme. It is proposed that Trps are involved at the subunit-binding domains of either the central or the outer subunit of transcarboxylase, in addition to those critical for catalysis.     

In vivo biotinylation of fusion proteins expressed in Escherichia coli with a sequence of Propionibacterium freudenreichii transcarboxylase 1.3S biotin subunit.

Biotinylation of fusion proteins in E. coli was studied using a sequence of Propionibacterium freudenreichii transcarboxylase 1.3S biotin subunit. As the biotinylation sequence, we examined two sequences: one was of amino acid residues [84-123] of 1.3S, a partial sequence containing a region from a conserved tetrapeptide (Ala-Met-Bct-Met) around the biotinyl lysine (Bct) to the carboxyl terminal; the other was of an almost entire sequence [18-123]. We constructed recombinant plasmids for fusion proteins of beta-galactosidase, of chloramphenicol acetyltransferase, and of alkaline phosphatase. We found the biotinylation in the [18-123] sequence fused to alkaline phosphatase.     

The importance of methionine residues for the catalysis of the biotin enzyme, transcarboxylase. Analysis by site-directed mutagenesis.

Almost all biotin enzymes contain the conserved tetrapeptide Ala-Met-Bct-Met (Bct, N epsilon-biotinyl-L-lysine). In the 1.3 S biotinyl subunit of transcarboxylase (TC), this sequence is present between positions 87 and 90. The conserved nature of these amino acids implies a critical role in the function of biotin enzymes. In order to examine the role of these conserved amino acids, point mutations in the gene encoding the 1.3 S subunit have been made by site-directed mutagenesis to generate A87G, M88L, M90L, M88T, M88C, M88A, and a double mutant A87M, M88A in the 1.3 S subunit. TC, a multisubunit enzyme containing 12 S, 5 S, and 1.3 S subunits, catalyzes the transfer of a carboxyl group from methylmalonyl-CoA to pyruvate (overall reaction). TC can be dissociated into individual subunits and also reconstituted by assembling isolated subunits to a fully active form. The mutants of the 1.3 S subunit have been reconstituted with native 5 S and 12 S subunits from Propionibacterium shermanii. The effects of mutations on the activity of TC were compared with that of TC-1.3 S wild type (WT) prepared in a similar manner. The results show that any substitution of a residue in the conserved tetrapeptide causes impairment of the rate of TC activity. Comparison of gel filtration profiles, sodium dodecyl sulfate-polyacrylamide gel electrophoresis and electron micrographs of the TC assembled with mutant 1.3 S and with wild type 1.3 S subunits showed that the impairment of the overall activity was not due to a failure of the subunits to assemble into complexes. Steady state kinetic analysis using the mutant 1.3 S subunits indicated that the Km for methylmalonyl-CoA or pyruvate did not change significantly indicating that the binding of substrates is not altered. However, the kcat values were significantly lower for mutants at positions 87 and 88 than for those at position 90. The replacement of methionine at position 88 either by hydrophobic or hydrophilic residues significantly altered the activity in the overall reaction, while similar substitution at position 90 did not dramatically alter the kcat. These results suggest that Ala-87 and Met-88 are catalytically critical in the conserved tetrapeptide.     

Heteronuclear NMR studies of the specificity of the post-translational modification of biotinyl domains by biotinyl protein ligase

The lipoyl domains of 2-oxo acid dehydrogenase multienzyme complexes and the biotinyl domains of biotin-dependent enzymes have homologous structures, but the target lysine residue in each domain is correctly selected for posttranslational modification by lipoyl protein ligase and biotinyl protein ligase, respectively. We have applied two-dimensional heteronuclear NMR spectroscopy to investigate the interaction between the apo form of the biotinyl domain of the biotin carboxyl carrier protein of acetyl-CoA carboxylase and the biotinyl protein ligase (BPL) from Escherichia coli. Heteronuclear multiple quantum coherence NMR spectra of the 15N-labelled biotinyl domain were recorded in the presence and absence of the ligase and backbone amide 1H and 15N chemical shifts were evaluated. Small, but significant, changes in chemical shift were found in two regions, including the tight beta-turn that houses the lysine residue targetted for biotinylation, and the beta-strand 2 and the loop that precedes it in the domain. When compared with the three-dimensional structure, sequence alignments of other biotinyl and lipoyl domains, and mutagenesis data, these results give a clear indication of how the biotinyl domain is both recognised by BPL and distinguished from the structurally related lipoyl domain to ensure correct posttranslational modification.     

The genes encoding the biotin carboxyl carrier protein and biotin carboxylase subunits of Bacillus subtilis acetyl coenzyme A carboxylase, the first enzyme of fatty acid synthesis.

The genes encoding two subunits of acetyl coenzyme A carboxylase, biotin carboxyl carrier protein, and biotin carboxylase have been cloned from Bacillus subtilis. DNA sequencing and RNA blot hybridization studies indicated that the B. subtilis accB homolog which encodes biotin carboxyl carrier protein, is part of an operon that includes accC, the gene encoding the biotin carboxylase subunit of acetyl coenzyme A carboxylase.     

Phenylphosphate carboxylase: a new C-C lyase involved in anaerobic phenol metabolism in Thauera aromatica

The anaerobic metabolism of phenol in the beta-proteobacterium Thauera aromatica proceeds via carboxylation to 4-hydroxybenzoate and is initiated by the ATP-dependent conversion of phenol to phenylphosphate. The subsequent para carboxylation of phenylphosphate to 4-hydroxybenzoate is catalyzed by phenylphosphate carboxylase, which was purified and studied. This enzyme consists of four proteins with molecular masses of 54, 53, 18, and 10 kDa, whose genes are located adjacent to each other in the phenol gene cluster which codes for phenol-induced proteins. Three of the subunits (54, 53, and 10 kDa) were sufficient to catalyze the exchange of 14CO2 and the carboxyl group of 4-hydroxybenzoate but not phenylphosphate carboxylation. Phenylphosphate carboxylation was restored when the 18-kDa subunit was added. The following reaction model is proposed. The 14CO2 exchange reaction catalyzed by the three subunits of the core enzyme requires the fully reversible release of CO2 from 4-hydroxybenzoate with formation of a tightly enzyme-bound phenolate intermediate. Carboxylation of phenylphosphate requires in addition the 18-kDa subunit, which is thought to form the same enzyme-bound energized phenolate intermediate from phenylphosphate with virtually irreversible release of phosphate. The 54- and 53-kDa subunits show similarity to UbiD of Escherichia coli, which catalyzes the decarboxylation of a 4-hydroxybenzoate derivative in ubiquinone (ubi) biosynthesis. They also show similarity to components of various decarboxylases acting on aromatic carboxylic acids, such as 4-hydroxybenzoate or vanillate, whereas the 10-kDa subunit is unique. The 18-kDa subunit belongs to a hydratase/phosphatase protein family. Phenylphosphate carboxylase is a member of a new family of carboxylases/decarboxylases that act on phenolic compounds, use CO2 as a substrate, do not contain biotin or thiamine diphosphate, require K+ and a divalent metal cation (Mg2+or Mn2+) for activity, and are strongly inhibited by oxygen.     

Crystal structures of biotin protein ligase from Pyrococcus horikoshii OT3 and its complexes: structural basis of biotin activation

Biotin protein ligase (EC 6.3.4.15) catalyses the synthesis of an activated form of biotin, biotinyl-5'-AMP, from substrates biotin and ATP followed by biotinylation of the biotin carboxyl carrier protein subunit of acetyl-CoA carboxylase. The three-dimensional structure of biotin protein ligase from Pyrococcus horikoshii OT3 has been determined by X-ray diffraction at 1.6A resolution. The structure reveals a homodimer as the functional unit. Each subunit contains two domains, a larger N-terminal catalytic domain and a smaller C-terminal domain. The structural feature of the active site has been studied by determination of the crystal structures of complexes of the enzyme with biotin, ADP and the reaction intermediate biotinyl-5'-AMP at atomic resolution. This is the first report of the liganded structures of biotin protein ligase with nucleotide and biotinyl-5'-AMP. The structures of the unliganded and the liganded forms are isomorphous except for an ordering of the active site loop upon ligand binding. Catalytic binding sites are suitably arranged to minimize the conformational changes required during the reaction, as the pockets for biotin and nucleotide are located spatially adjacent to each other in a cleft of the catalytic domain and the pocket for biotinyl-5'-AMP binding mimics the combination of those of the substrates. The exact locations of the ligands and the active site residues allow us to propose a general scheme for the first step of the reaction carried out by biotin protein ligase in which the positively charged epsilon-amino group of Lys111 facilitates the nucleophilic attack on the ATP alpha-phosphate group by the biotin carboxyl oxygen atom and stabilizes the negatively charged intermediates.     

Characterization of a bifunctional archaeal acyl coenzyme A carboxylase

Acyl coenzyme A carboxylase (acyl-CoA carboxylase) was purified from Acidianus brierleyi. The purified enzyme showed a unique subunit structure (three subunits with apparent molecular masses of 62, 59, and 20 kDa) and a molecular mass of approximately 540 kDa, indicating an alpha(4)beta(4)gamma(4) subunit structure. The optimum temperature for the enzyme was 60 to 70 degrees C, and the optimum pH was around 6.4 to 6.9. Interestingly, the purified enzyme also had propionyl-CoA carboxylase activity. The apparent K(m) for acetyl-CoA was 0.17 +/- 0.03 mM, with a V(max) of 43.3 +/- 2.8 U mg(-1), and the K(m) for propionyl-CoA was 0.10 +/- 0.008 mM, with a V(max) of 40.8 +/- 1.0 U mg(-1). This result showed that A. brierleyi acyl-CoA carboxylase is a bifunctional enzyme in the modified 3-hydroxypropionate cycle. Both enzymatic activities were inhibited by malonyl-CoA, methymalonyl-CoA, succinyl-CoA, or CoA but not by palmitoyl-CoA. The gene encoding acyl-CoA carboxylase was cloned and characterized. Homology searches of the deduced amino acid sequences of the 62-, 59-, and 20-kDa subunits indicated the presence of functional domains for carboxyltransferase, biotin carboxylase, and biotin carboxyl carrier protein, respectively. Amino acid sequence alignment of acetyl-CoA carboxylases revealed that archaeal acyl-CoA carboxylases are closer to those of Bacteria than to those of Eucarya. The substrate-binding motifs of the enzymes are highly conserved among the three domains. The ATP-binding residues were found in the biotin carboxylase subunit, whereas the conserved biotin-binding site was located on the biotin carboxyl carrier protein. The acyl-CoA-binding site and the carboxybiotin-binding site were found in the carboxyltransferase subunit.     

The biotinyl domain of Escherichia coli acetyl-CoA carboxylase. Evidence that the "thumb" structure id essential and that the domain functions as a dimer

Biotin carboxyl carrier protein (BCCP) is the small biotinylated subunit of Escherichia coli acetyl-CoA carboxylase (ACC), the enzyme that catalyzes the first committed step of fatty acid synthesis. Similar proteins are found in other bacteria and in chloroplasts. E. coli BCCP is a member of a large family of protein domains modified by covalent attachment of biotin to a specific lysine residue. However, the BCCP biotinyl domain differs from many of these proteins in that an eight-amino acid residue insertion is present upstream of the biotinylated lysine. X-ray crystallographic and multidimensional NMR studies show that these residues constitute a structure that has the appearance of an extended thumb that protrudes from the otherwise highly symmetrical domain structure. I report that expression of two mutant BCCPs lacking the thumb residues fails to restore growth and fatty acid synthesis to a temperature-sensitive E. coli strain that lacks BCCP when grown at nonpermissive temperature. Alignment of BCCPs from various organisms shows that only two of the eight thumb residues are strictly conserved, and amino acid substitution of either residue results in proteins giving only weak growth of the temperature-sensitive E. coli strain. Therefore, the thumb structure is essential for the function of BCCP in the ACC reaction and provides a useful motif for distinguishing the biotinylated proteins of multisubunit ACCs from those of enzymes catalyzing other biotin-dependent reactions. An unexpected result was that expression of a mutant BCCP in which the biotinylated lysine residue was substituted with cysteine was able to partially restore growth and fatty acid synthesis to the temperature-sensitive E. coli strain. This complementation was shown to be specific to BCCPs having native structure (excepting the biotinylated lysine) and is interpreted in terms of dimerization of the BCCP biotinyl domain during the ACC reaction.     

Role of the small subunit in ribulose-1,5-bisphosphate carboxylase/oxygenase

Ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) catalyzes the rate-limiting step of CO2 fixation in photosynthesis, but O2 competes with CO2 for substrate ribulose 1,5-bisphosphate, leading to the loss of fixed carbon. Interest in genetically engineering improvements in carboxylation catalytic efficiency and CO2/O2 specificity has focused on the chloroplast-encoded large subunit because it contains the active site. However, there is another type of subunit in the holoenzyme of plants, which, like the large subunit, is present in eight copies. The role of these nuclear-encoded small subunits in Rubisco structure and function is poorly understood. Small subunits may have originated during evolution to concentrate large-subunit active sites, but the extensive divergence of structures among prokaryotes, algae, and land plants seems to indicate that small subunits have more-specialized functions. Furthermore, plants and green algae contain families of differentially expressed small subunits, raising the possibility that these subunits may regulate the structure or function of Rubisco. Studies of interspecific hybrid enzymes have indicated that small subunits are required for maximal catalysis and, in several cases, contribute to CO2/O2 specificity. Although small-subunit genetic engineering remains difficult in land plants, directed mutagenesis of cyanobacterial and green-algal genes has identified specific structural regions that influence catalytic efficiency and CO2/O2 specificity. It is thus apparent that small subunits will need to be taken into account as strategies are developed for creating better Rubisco enzymes.     

Primary structure of the biotin-binding site of chicken liver acetyl-CoA carboxylase

Limited proteolysis of chicken liver acetyl-CoA carboxylase by staphylococcal serine proteinase yielded a fragment of 31 kDa which contained the biotinyl active site. This polypeptide was purified by preparative polyacrylamide gel electrophoresis and characterized. The complete amino acid sequence of this polypeptide has been deduced from the nucleotide sequence of cloned DNA complementary to the chicken liver acetyl-CoA carboxylase mRNA. A highly conserved sequence of Met-Lys-Met was found in the biotin-binding site. Appreciable homology was observed among the sequences in close vicinity of the biotin sites of chicken liver acetyl-CoA carboxylase and other biotin-dependent carboxylases including biotin carboxyl carrier protein of Escherichia coli acetyl-CoA carboxylase.     

Intersubunit location of the active site of farnesyl diphosphate synthase: reconstruction of active enzymes by hybrid-type heteromeric dimers of site-directed mutants

Farnesyl diphosphate synthase is a homodimer of subunits having typically two aspartate-rich motifs with two sets of substrate binding sites for an allylic diphosphate and isopentenyl diphosphate per molecule of a homodimeric enzyme. To determine whether each subunit contains an independent active site or whether the active sites are created by intersubunit interaction, we constructed several expression plasmids that overproduce hybrid-type heterodimers of Bacillus stearothermophilus FPP synthases constituting different types of mutated monomers, which exhibit little catalytic activity as homodimers, by combining two tandem fps genes for the manipulated monomer subunit with a highly efficient promoter trc within an overexpression pTrc99A plasmid. A heterodimer of a combination of subunits of the wild type and of R98E, a mutant subunit which exhibits little enzymatic activity as a dimer form (R98E)(2), exhibited 78% of the activity of the wild-type homodimer enzyme, (WT)(2). Moreover, when a hybrid-type heterodimeric dimer of FPP synthase mutant subunits (R98E/F220A) was prepared, the FPP synthase activity was 18- and 390-fold of that of each of the almost inactive mutants as a dimeric enzymes, (R98E)(2) and (F220A)(2) [Koyama, T., et al. (1995) Biochem. Biophys. Res. Commun. 212, 681-686], respectively. These results suggest that the subunits of the FPP synthase interact with each other to form a shared active site in the homodimer structure rather than an independent active site in each subunit.     

Crystal structure of the (R)-specific enoyl-CoA hydratase from Aeromonas caviae involved in polyhydroxyalkanoate biosynthesis

The (R)-specific enoyl coenzyme A hydratase ((R)-hydratase) from Aeromonas caviae catalyzes the addition of a water molecule to trans-2-enoyl coenzyme A (CoA), with a chain-length of 4-6 carbons, to produce the corresponding (R)-3-hydroxyacyl-CoA. It forms a dimer of identical subunits with a molecular weight of about 14,000 and is involved in polyhydroxyalkanoate (PHA) biosynthesis. The crystal structure of the enzyme has been determined at 1.5-A resolution. The structure of the monomer consists of a five-stranded antiparallel beta-sheet and a central alpha-helix, folded into a so-called "hot dog" fold, with an overhanging segment. This overhang contains the conserved residues including the hydratase 2 motif residues. In dimeric form, two beta-sheets are associated to form an extended 10-stranded beta-sheet, and the overhangs obscure the putative active sites at the subunit interface. The active site is located deep within the substrate-binding tunnel, where Asp(31) and His(36) form a catalytic dyad. These residues are catalytically important as confirmed by site-directed mutagenesis and are possibly responsible for the activation of a water molecule and the protonation of a substrate molecule, respectively. Residues such as Leu(65) and Val(130) are situated at the bottom of the substrate-binding tunnel, defining the preference of the enzyme for the chain length of the substrate. These results provide target residues for protein engineering, which will enhance the significance of this enzyme in the production of novel PHA polymers. In addition, this study provides the first structural information of the (R)-hydratase family and may facilitate further functional studies for members of the family.