Encapsulation into complex coacervate core micelles promotes EGFP dimerization.

Complex coacervate core micelles (C3Ms) are colloidal structures useful for encapsulation of biomacromolecules. We previously demonstrated that enhanced green fluorescent protein (EGFP) can be encapsulated into C3Ms using the diblock copolymer poly(2-methyl-vinyl-pyridinium)41-b-poly(ethylene-oxide)205. This packaging resulted in deviating spectroscopic features of the encapsulated EGFP molecules. Here we show that for monomeric EGFP variant (mEGFP) micellar encapsulation affects the absorption and fluorescence properties to a much lesser extent, and that changes in circular dichroism characteristics are specific for encapsulated EGFP. Time-resolved fluorescence anisotropy of encapsulated (m)EGFP established the occurrence of homo-FRET (Förster resonance energy transfer) with larger transfer correlation times in the case of EGFP. Together, these findings support that EGFP dimerizes whereas the mEGFP mainly remains as a monomer in the densely packed C3Ms. We propose that dimerization of encapsulated EGFP causes a reorientation of Glu222, resulting in a pKa shift of the chromophore, which is fully reversible after release of EGFP from the C3Ms at a high ionic strength.

5-fluorotryptophan as dual probe for ground-state heterogeneity and excited-state dynamics in apoflavodoxin.

The apoflavodoxin protein from Azotobacter vinelandii harboring three tryptophan (Trp) residues, was biosynthetically labeled with 5-fluorotryptophan (5-FTrp). 5-FTrp has the advantage that chemical differences in its microenvironment can be sensitively visualized via (19)F NMR. Moreover, it shows simpler fluorescence decay kinetics. The occurrence of FRET was earlier observed via the fluorescence anisotropy decay of WT apoflavodoxin and the anisotropy decay parameters are in excellent agreement with distances between and relative orientations of all Trp residues. The anisotropy decay in 5-FTrp apoflavodoxin demonstrates that the distances and orientations are identical for this protein. This work demonstrates the added value of replacing Trp by 5-FTrp to study structural features of proteins via (19)F NMR and fluorescence spectroscopy.

Structural changes of yellow Cameleon domains observed by quantitative FRET analysis and polarized fluorescence correlation spectroscopy.

Förster resonance energy transfer (FRET) is a widely used method for monitoring interactions between or within biological macromolecules conjugated with suitable donor-acceptor pairs. Donor fluorescence lifetimes in absence and presence of acceptor molecules are often measured for the observation of FRET. However, these lifetimes may originate from interacting and noninteracting molecules, which hampers quantitative interpretation of FRET data. We describe a methodology for the detection of FRET that monitors the rise time of acceptor fluorescence on donor excitation thereby detecting only those molecules undergoing FRET. The large advantage of this method, as compared to donor fluorescence quenching method used more commonly, is that the transfer rate of FRET can be determined accurately even in cases where the FRET efficiencies approach 100% yielding highly quenched donor fluorescence. Subsequently, the relative orientation between donor and acceptor chromophores is obtained from time-dependent fluorescence anisotropy measurements carried out under identical conditions of donor excitation and acceptor detection. The FRET based calcium sensor Yellow Cameleon 3.60 (YC3.60) was used because it changes its conformation on calcium binding, thereby increasing the FRET efficiency. After mapping distances and orientation angles between the FRET moieties in YC3.60, cartoon models of this FRET sensor with and without calcium could be created. Independent support for these representations came from experiments where the hydrodynamic properties of YC3.60 under ensemble and single-molecule conditions on selective excitation of the acceptor were determined. From rotational diffusion times as found by fluorescence correlation spectroscopy and consistently by fluorescence anisotropy decay analysis it could be concluded that the open structure (without calcium) is flexible as opposed to the rather rigid closed conformation. The combination of two independent methods gives consistent results and presents a rapid and specific methodology to analyze structural and dynamical changes in a protein on ligand binding.

Kinetic properties of the 2-oxoglutarate dehydrogenase complex from Azotobacter vinelandii evidence for the formation of a precatalytic complex with 2-oxoglutarate.

The 2-oxoglutarate dehydrogenase complex was purified from Azotobacter vinelandii. The complex consists of three components, 2-oxoglutarate dehydrogenase/decarboxylase (E1o), lipoate succinyltransferase (E2o) and lipoamide dehydrogenase (E3). Upon purification, the E3 component dissociates partially from the complex. From reconstitution experiments, the Kd for E3 was found to be 26 nM, about 30 times higher than that for the pyruvate dehydrogenase complex. The Km values for the substrates 2-oxoglutarate, CoA and NAD+ were found to be 0.15, 0.014 and 0.17 mM, respectively. The system has a high specificity for 2-oxoglutarate, which is determined by the action of both E1o and E2o. Above 4 mM substrate inhibition is observed. From steady-state inhibition experiments with substrate analogs, two substrate-binding modes are revealed at different degrees of saturation of the enzyme with 2-oxoglutarate. At low substrate concentrations (10(-6) to 10(-5) M), the binding mainly depends on the interaction of the enzyme with the substrate carboxyl groups. At a higher degree of substrate saturation (10(-4) to 10(-3) M) the relative contribution of the 2-oxo group in the binding increases. A kinetic analysis points to a single binding site for a substrate analog under steady state conditions. Saturation of this site with an analog indicates that two kinetically different complexes are formed with 2-oxoglutarate in the course of catalysis. From competition studies with analogs it is concluded that one of these complexes is formed at the site that is sterically identical to the substrate inhibition site. The data obtained are represented by a minimal scheme that considers formation of a precatalytic complex SE between the substrate and E1o before the catalytic complex ES, in which the substrate is added to the thiamin diphosphate cofactor, is formed. The incorrect orientation of the substrate molecule in SE or the occupation of this site by analogs is supposed to cause substrate or analog inhibition, respectively.

Pyruvate dehydrogenase from Azotobacter vinelandii. Properties of the N-terminally truncated enzyme.

The pyruvate dehydrogenase multienzyme complex (PDHC) catalyses the oxidative decarboxylation of pyruvate and the subsequent acetylation of coenzyme A to acetyl-CoA. Previously, limited proteolysis experiments indicated that the N-terminal region of the homodimeric pyruvate dehydrogenase (E1p) from Azotobacter vinelandii could be involved in the binding of E1p to the core protein (E2p) [Hengeveld, A. F., Westphal, A. H. & de Kok, A. (1997) Eur J. Biochem. 250, 260-268]. To further investigate this hypothesis N-terminal deletion mutants of the E1p component of Azotobacter vinelandii pyruvate dehydrogenase complex were constructed and characterized. Up to nine N-terminal amino acids could be removed from E1p without effecting the properties of the enzyme. Truncation of up to 48 amino acids did not effect the expression or folding abilities of the enzyme, but the truncated enzymes could no longer interact with E2p. The 48 amino acid deletion mutant (E1pdelta48) is catalytically fully functional: it has a Vmax value identical to that of wild-type E1p, it can reductively acetylate the lipoamide group attached to the lipoyl domain of the core enzyme (E2p) and it forms a dimeric molecule. In contrast, the S0.5 for pyruvate is decreased. A heterodimer was constructed containing one subunit of wild-type E1p and one subunit of E1pdelta48. From the observation that the heterodimer was not able to bind to E2p, it is concluded that both N-terminal domains are needed for the binding of E1p to E2p. The interactions are thought to be mainly of an electrostatic nature involving negatively charged residues on the N-terminal domains of E1p and previously identified positively charged residues on the binding and catalytic domain of E2p.

Principles of quasi-equivalence and Euclidean geometry govern the assembly of cubic and dodecahedral cores of pyruvate dehydrogenase complexes.

The pyruvate dehydrogenase multienzyme complex (Mr of 5-10 million) is assembled around a structural core formed of multiple copies of dihydrolipoyl acetyltransferase (E2p), which exhibits the shape of either a cube or a dodecahedron, depending on the source. The crystal structures of the 60-meric dihydrolipoyl acyltransferase cores of Bacillus stearothermophilus and Enterococcus faecalis pyruvate dehydrogenase complexes were determined and revealed a remarkably hollow dodecahedron with an outer diameter of approximately 237 A, 12 large openings of approximately 52 A diameter across the fivefold axes, and an inner cavity with a diameter of approximately 118 A. Comparison of cubic and dodecahedral E2p assemblies shows that combining the principles of quasi-equivalence formulated by Caspar and Klug [Caspar, D. L. & Klug, A. (1962) Cold Spring Harbor Symp. Quant. Biol. 27, 1-4] with strict Euclidean geometric considerations results in predictions of the major features of the E2p dodecahedron matching the observed features almost exactly.

Purification and characterization of a flavoprotein involved in the degradation of epoxyalkanes by Xanthobacter Py2.

Recently a newly discovered pyridine nucleotide-disulfide oxidoreductase was reported to be essential for the degradation of epoxyalkanes by the Xanthobacter Py2 [Swaving, J., De Bont, J. A. M., Westphal, A. & De Kok, A. (1996) J. Bacteriol. 178, 6644-6646]. The disulfide oxidoreductase has now been purified from propene-grown Xanthobacter Py2. This enzyme (component II) is a NADPH-dependent FAD-containing homodimeric protein. The physiological substrate for this enzyme is unknown. The enzyme was active with the following dithiol substrates in decreasing order: 1,3-propanedithiol, reduced lipoamide and dithiothreitol, and inactive with glutathione and monothiols. In the reversed direction, only activity with 5,5'-dithiobis(2-nitrobenzoate) could be measured. Compared with other disulfide reductases it has a high activity with 5,5'-dithiobis(2-nitrobenzoate) and a low diaphorase and oxidase activity. Steady-state kinetic studies at pH 8.5 with 1,3-propanedithiol show that the enzyme operates by a ternary complex mechanism in the direction of NADP+ reduction. Anaerobic incubation of the enzyme with 1,3-propanedithiol resulted in slow reduction of the enzyme to yield the thiolate-FAD charge-transfer complex, the rate depending on the pH. At pH 7, where reduction was not detectable within 2 h, rapid mixing of NADP+ with the enzyme-propanedithiol mixture resulted in the formation of a complex between the reduced enzyme and NADP+ within the dead time of the instrument (5.6 ms). This is followed by slow formation of NADPH, concomitant with the appearance of the flavin C(4a)-thiol adduct, as judged from the spectral changes. This suggests that the rate-limiting step is the transfer of a hydride ion from the half-reduced enzyme to NADP+. Stopped-flow experiments involving reduction by NADPH show a biphasic behavior. The rapid formation (k(obs) = 40 s(-1)) of a transient intermediate with little absorption decrease at 460 nm and long wavelength absorption was followed by the slow formation (k(obs) = 4 s(-1)) of a species characterized as the thiolate-FAD charge-transfer complex with bound NADP+. Some formation of the FAD C(4a)-thiol adduct was also observed. Photoreduction in the presence of deazaflavin results in rapid bleaching at 450 nm, followed by the slow formation of a stable semiquinone. Full reduction could not be achieved, either by photoreduction or with NADPH, and was incomplete even with dithionite or NADPH in the presence of arsenite. The results indicate a low redox potential of the FAD and a slow rate of electron transfer from the pyridine nucleotide to the redox active disulfide and vice versa. From a sequence alignment with other disulfide reductases, it appears that the active site His-Glu diad is absent in this enzyme. The kinetic and spectral features described above will be discussed in this context.

The pyruvate dehydrogenase multi-enzyme complex from Gram-negative bacteria.

Pyruvate dehydrogenase multi-enzyme complexes from Gram-negative bacteria consists of three enzymes, pyruvate dehydrogenase/decarboxylase (E1p), dihydrolipoyl acetyltransferase (E2p) and dihydrolipoyl dehydrogenase (E3). The acetyltransferase harbors all properties required for multi-enzyme catalysis: it forms a large core of 24 subunits, it contains multiple binding sites for the E1p and E3 components, the acetyltransferase catalytic site and mobile substrate carrying lipoyl domains that visit the active sites. Today, the Azotobacter vinelandii complex is the best understood oxo acid dehydrogenase complex with respect to structural details. A description of multi-enzyme catalysis starts with the structural and catalytic properties of the individual components of the complex. Integration of the individual properties is obtained by a description of how the many copies of the individual enzymes are arranged in the complex and how the lipoyl domains couple the activities of the respective active sites by way of flexible linkers. These latter aspects are the most difficult to study and future research need to be aimed at these properties.

Kinetics and specificity of reductive acylation of wild-type and mutated lipoyl domains of 2-oxo-acid dehydrogenase complexes from Azotobacter vinelandii.

The kinetics and specificity of reductive acylation of lipoyl domains derived from Azotobacter vinelandii 2-oxo-acid dehydrogenase complexes, catalysed by A. vinelandii and Escherichia coli complexes, have been investigated. With the wild-type pyruvate dehydrogenase complex from A. vinelandii the rate of reductive acetylation and deacetylation was studied by rapid mixing methods. The rate of reductive acetylation, 126 s(-1), corresponds well with the turnover rate derived from steady-state measurements. Deacetylation was rapid and specific for coenzyme A. No deacetylation was observed with reduced or oxidised lipoamide or with dithiothreitol. The rate of reductive acetylation of complex-bound lipoyl domains by pyruvate dehydrogenase (E1p) is at least 60 times higher than of free lipoyl domains under comparable conditions. This gain in catalytic rate indicates a large diffusion limitation of lipoyl domains when attached via the flexible linker segments to the complex, and illustrates the efficiency of substrate channeling in the multienzyme complex. The 2-oxo-acid dehydrogenases exhibit specificity for lipoyl domains in the reductive acylation reaction. The A. vinelandii lipoyl domain derived from the pyruvate dehydrogenase complex is a good substrate for A. vinelandii E1p, but not for A. vinelandii 2-oxoglutarate dehydrogenase (E1o), and vice versa. The A. vinelandii lipoyl domain of the pyruvate dehydrogenase complex is also, although at a lower rate, reductively acetylated by E. coli E1p and reductively succinylated by E. coli E1o. Likewise, the A. vinelandii lipoyl domain derived from the 2-oxoglutarate dehydrogenase complex is recognised by E. coli E1o, but not by E. coli E1p. This suggests that common determinants of the lipoyl domains exist that are responsible for recognition by the E1 components. On the basis of the observed specificity and lipoyl domain sequences and structures, an exposed loop of the A. vinelandii 2-oxoglutarate dehydrogenase complex lipoyl domain was subjected to mutagenesis. Although the reductive acylation experiments of mutants of the lipoyl domain indicate the importance of this loop for recognition, it is probably not the single determinant for specificity.

Expression and characterisation of the homodimeric E1 component of the Azotobacter vinelandii pyruvate dehydrogenase complex.

We have cloned and sequenced the gene encoding the homodimeric pyruvate dehydrogenase component (E1p) of the pyruvate dehydrogenase complex from Azotobacter vinelandii and expressed and purified the E1p component in Escherichia coli. Cloned E1p can be used to fully reconstitute complex activity. The enzyme was stable in high ionic strength buffers, but was irreversibly inactivated when incubated at high pH, which presumably was caused by its inability to redimerize correctly. This explains the previously found low stability of the wild-type E1p component after resolution from the complex at high pH. Cloned E1p showed a kinetic behaviour exactly like the wild-type complex-bound enzyme with respect to its substrate (pyruvate), its allosteric properties, and its effectors. These experiments show that acetyl coenzyme A acts as a feedback inhibitor by binding to the E1p component. Limited proteolysis experiments showed that the N-terminal region of E1p was easily removed. The resulting protein fragment was still active with artificial electron acceptors but had lost its ability to bind to the core component (E2p) and thus reconstitute complex activity. E1p was protected against proteolysis by E2p. The allosteric effector pyruvate changed E1p into a conformation that is more resistant to proteolysis.

Cloning, sequencing, characterisation and implications for vaccine design of the novel dihydrolipoyl acetyltransferase of Neisseria meningitidis.

A lambdaZap-II expression library of Neisseria meningitidis was screened with a rabbit polyclonal antiserum (R-70) raised against c. 70-kDa proteins purified from outer membrane vesicles by elution from preparative SDS-polyacrylamide gels. Selected clones were isolated, further purified, and their recombinant pBluescript SKII plasmids were excised. The cloned DNA insert was sequenced from positive clones and analysed. Four open reading frames (ORFs) were identified, three of which showed a high degree of homology with the pyruvate dehydrogenase (E1p), dihydrolipoyl acetyltransferase (E2p) and dihydrolipoyl dehydrogenase (E3) components of the pyruvate dehydrogenase complex (PDHC) of a number of prokaryotic and eukaryotic species. Sequence analysis indicated that the meningococcal E2p (Men-E2p) contains two N-terminal lipoyl domains, an E1/E3 binding domain and a catalytic domain. The domains are separated by hinge regions rich in alanine, proline and charged residues. Another lipoyl domain with high sequence similarity to the Men-E2p lipoyl domain was found at the N-terminal of the E3 component. A further ORF, coding for a 16.5-kDa protein, was found between the ORFs encoding the E2p and E3 components. The identity and functional characteristics of the expressed and purified heterologous Men-E2p were confirmed as dihydrolipoyl acetyltransferase by immunological and biochemical assays. N-terminal amino-acid analysis confirmed the sequence of the DNA-derived mature protein. Purified Men-E2p reacted with monospecific antisera raised against the whole E2p molecule and against the lipoyl domain of the Azotobacter vinelandii E2p. Conversely, rabbit antiserum raised against Men-E2p reacted with protein extracts of A. vinelandii, Escherichia coli and N. gonorrhoeae and with the lipoyl and catalytic domains of E2p obtained by limited proteolysis. In contrast, the original R-70 antiserum reacted almost exclusively with the lipoyl domain, indicating the strong immunogenicity of this domain. Antibodies to Men-E2p were detected in patients and animals (rabbits and mice) infected with homologous or heterologous meningococci or other neisserial species. These results have important implications for the understanding of PDHC and the design of future outer membrane vesicle-based vaccines.

The interaction between lipoamide dehydrogenase and the peripheral-component-binding domain from the Azotobacter vinelandii pyruvate dehydrogenase complex.

The sensitivity of lipoamide dehydrogenase (dihydrolipoamide:NAD+ oxidoreductase E3) from Azotobacter vinelandii to inhibition by NADH requires measurement of the activity in the initial phase of the reaction. Stopped-flow turnover experiments show that kcat is 830 s-1 compared with 420 s-1 found in standard steady-state experiments. Mutations at the si-side of the flavin prosthetic group that cause severe inhibition by NADH were studied. Tyr16 was replaced by phenylalanine and serine, which causes the loss of two intersubunit H-bonds. [F16]E3 shows only 5.7% of wild-type activity in the standard assay procedure, but analyzed by stopped-flow the activity is 70% of the wild-type enzyme. The NADH-->Cl2Ind (dichloroindophenol) activity was normal or slightly increased. The inhibition by NADH is competitive with respect to NAD+, Ki = 50 microM. Spectral analysis show that electrons readily pass over from the disulfide to the FAD, indicating an increase in the redox potential of the flavin. It is concluded that subunit interaction plays an important role in the protection of the enzyme against over-reduction by decreasing the redox potential of the flavin. The interaction of wild-type or mutant enzymes with the core component of the pyruvate (E2p) or oxoglutarate (E2o) dehydrogenase multienzyme complex relieves the inhibition to a large extent. In the mutant enzymes, the mechanism of inhibition changes from competitive to the mixed-type inhibition observed for the wild-type enzyme. The stabilizing effect of E2 on [F16]E3 was used as an assay to analyze the stoichiometry of interaction of E3 with E2p as well as E2o. 1 mol E2p monomer was sufficient to saturate 1 mol E3 dimer with a Kd of about 1 nM. Similarly, 1 mol E2o saturated the E3 dimer with a Kd of 30 nM. From these experiments it is concluded that the E3-binding domain of E2 interacts with the subunit interface of E3 near the dyad axis, thus preventing sterically the interaction with a second molecule of the binding domain. This mode of interaction, which causes asymmetry in the complex, explains the stabilization against over-reduction by tightening the subunit interaction. Subgene cloning of the E2p component of the pyruvate dehydrogenase complex is described in order to obtain a complex between the lipoamide dehydrogenase component (E3) and the binding domain of E2p. A unique restriction site in the DNA encoding the flexible linker between the third lipoyl domain and the binding domain combined with timed digestion with exonuclease Bal31 was used to create a set of deletion mutants in the N-terminal region of the binding-catalytic didomain, fused to six N-terminal amino acids from beta-galactosidase. The expressed proteins, selected for E2p activity, were analyzed for binding of E3 and E1p. The shortest fusion protein containing a functional binding domain was expressed and purified. [F16]E3 was combined with this fusion protein in a stoichiometric ratio and the resulting complex was subjected to limited proteolysis to remove the catalytic domain. The resulting [F16]E3-binding domain preparation was purified to homogeneity.

Crystallographic and enzymatic investigations on the role of Ser558, His610, and Asn614 in the catalytic mechanism of Azotobacter vinelandii dihydrolipoamide acetyltransferase (E2p).

Dihydrolipoamide acetyltransferase (E2p) is the structural and catalytic core of the pyruvate dehydrogenase multienzyme complex. In Azotobacter vinelandii E2p, residues Ser558, His610', and Asn614' are potentially involved in transition state stabilization, proton transfer, and activation of proton transfer, respectively. Three active site mutants, S558A, H610C, and N614D, of the catalytic domain of A. vinelandii E2p were prepared by site-directed mutagenesis and enzymatically characterized. The crystal structures of the three mutants have been determined at 2.7, 2.5, and 2.6 A resolution, respectively. The S558A and H610C mutants exhibit a strongly (200-fold and 500-fold, respectively) reduced enzymatic activity whereas the substitution of Asn614' by aspartate results in a moderate (9-fold) reduced activity. The decrease in enzymatic activity of the S558A and H610C mutants is solely due to the absence of the hydroxyl and imidazole side chains, respectively, and not due to major conformational rearrangements of the protein. Furthermore the sulfhydryl group of Cys610' is reoriented, resulting in a completely buried side chain which is quite different from the solvent-exposed imidazole group of His610' in the wild-type enzyme. The presence of Asn614' in A. vinelandii E2p is exceptional since all other 18 known dihydrolipoamide acyltransferase sequences contain an aspartate in this position. We observe no difference in conformation of Asp614' in the N614D mutant structure compared with the conformation of Asn614' in the wild-type enzyme. Detailed analysis of all available structures and sequences suggests two classes of acetyltransferases: one class with a catalytically essential His-Asn pair and one with a His-Asp-Arg triad as present in chloramphenicol acetyltransferase [Leslie, A. G. W. (1990) J. Mol. Biol. 213, 167-186] and in the proposed active site models of Escherichia coli and yeast E2p.

Differences in sensitivity to NADH of purified pyruvate dehydrogenase complexes of Enterococcus faecalis, Lactococcus lactis, Azotobacter vinelandii and Escherichia coli: implications for their activity in vivo.

The effect of NADH on the activity of the purified pyruvate dehydrogenase complexes (PDHc) of Enterococcus (Ec.) faecalis, Lactococcus lactis, Azotobacter vinelandii and Escherichia coli was determined in vitro. It was found that the PDHc of E. coli and L. lactis was active only at relatively low NADH/NAD ratios, whereas the PDHc of Ec. faecalis was inhibited only at high NADH/NAD ratios. The PDHc of Azotobacter vinelandii showed an intermediate sensitivity. The organisms were grown in chemostat culture under conditions that led to different intracellular NADH/NAD ratios and the PDHc activities in vivo could be calculated from the specific rates of product formation. Under anaerobic growth conditions, only Ec. faecalis expressed PDHc activity in vivo. The activities in vivo of the complexes of the different organisms were in good agreement with their properties determined in vitro. The physiological consequences of these results are discussed.

Refined crystal structure of the catalytic domain of dihydrolipoyl transacetylase (E2p) from Azotobacter vinelandii at 2.6 A resolution.

Dihydrolipoyl transacetylase (E2p) is both structurally and functionally the central enzyme of the pyruvate dehydrogenase multienzyme complex. The crystal structure of the catalytic domain, i.e. residues 382 to 637, of Azotobacter vinelandii E2p (E2pCD) was solved by multiple isomorphous replacement and refined by energy minimization procedures. The final model contains 2182 protein atoms and 37 ordered water molecules. The R-factor is 18.7% for 10,344 reflections between 10.0 and 2.6 A resolution. The root-mean-square shift deviation from the ideal values is 0.017 A for bond lengths and 3.3 degrees for bond angles. The N-terminal residues 382 to 394 are disordered and not visible in the electron density map, otherwise all residues have well-defined density. The catalytic domain forms an oligomer of 24 subunits, having octahedral 432 symmetry. In the E2pCD crystals, the 24 subunits are related by the crystallographic symmetry. The cubic arrangement of subunits gives rise to a large hollow cube with edges of 120 A. The faces of the cube have pores of diameter of 30 A. The true building block of the cube is the E2p trimer, eight of which occupy the corners of the cube. Two levels of intermolecular contacts can be distinguished: (1) the extensive interactions between 3-fold related subunits leading to a tightly associated trimer; and (2) the interactions along the 2-fold axis leading to the assembly of the trimers into the cubic 24-mer. Each subunit has a topology similar to chloramphenicol acetyltransferase (CAT) and comprises a central beta-sheet surrounded by five alpha-helices. The comparison of the two proteins indicates a large rotation of the N-terminal residues 395 to 426 of E2pCD, which reshapes the substrate binding site and extends the interaction between threefold related subunits. The catalytic centre consists of a 30 A long channel extending from the "inner" side of the trimer to the "outer" side, where inner and outer refer to the position in the 24-meric cubic core of the pyruvate dehydrogenase complex and correspond with CoA and lipoamide binding sites, respectively. The active site is formed by the residues with the lowest mobility as indicated by the atomic B-factors. Five proline residues surround the active site.(ABSTRACT TRUNCATED AT 400 WORDS)

Structure/function relationships in the pyruvate dehydrogenase complex from Azotobacter vinelandii. Role of the linker region between the binding and catalytic domain of the dihydrolipoyl transacetylase component.

The role of the hinge region between the binding domain and the catalytic domain in dihydrolipoyl transacetylase (E2p) from Azotobacter vinelandii was addressed by deletion mutagenesis. Mutated dihydrolipoyl transacetylase proteins were constructed with a deletion of 11 amino acids in the hinge region between the binding domain and the N-terminal part of the catalytic domain of E2p [E2p(pAPE1)] and with a further deletion of 9 amino acids into the N-terminal sequence protruding from the globular structure of the catalytic domain [E2p(pAPE2)] and found to take part in the intratrimer interaction. Both proteins behaved as wild-type E2p with respect to catalytic activity and quaternary structure. The interaction of the peripheral components pyruvate dehydrogenase (E1p) and lipoamide dehydrogenase (E3) with the mutated E2p proteins was studied. E2p(pAPE1) assembles to a trimeric pyruvate dehydrogenase complex (PDC) with 15% decreased complex activity. No difference in affinity towards the peripheral components was detected. Upon binding of E3, E2p(pAPE2) dissociates into trimers and monomers. At saturation, two dimers of E3 were bound/E2p monomer instead of one dimer/E2p chain in trimeric wild-type E2p or E2p (pAPE1). The monomeric E2p species was catalytically inactive. Upon binding of excess E1p, some monomer formation of the E2p mutant took place. E1p however can prevent monomerization by E3. It is concluded that E1p is bound between two different E2p chains in the trimer. The substrates CoA and acetyl-CoA also prevent monomerization because they are bound by amino acid residues of two different E2p chains. In the presence of CoA no difference in affinity with respect to E1p and E3 binding was observed. CoA (and acetylCoA) also prevent dissociation of the 24-subunit core structure of wild-type E2p when added before addition of E1p or E3. Therefore, it seems likely that in vivo A. vinelandii PDC is based on a 24-subunit E2p core, like Escherichia coli PDC. A functional difference between complexes based on a trimer or a 24-subunit core has not been observed. A role of the hinge region as a spacer to allow binding of E1p or E3 seems unlikely. The results are discussed on the basis of the three-dimensional structure of the catalytic domain.

Reconstitution of pyruvate dehydrogenase multienzyme complexes based on chimeric core structures from Azotobacter vinelandii and Escherichia coli.

Two unique restriction sites were introduced by site-directed mutagenesis at identical positions in the DNA encoding the dihydrolipoyltransacetylase (E2p) components of the pyruvate dehydrogenase complex from Azotobacter vinelandii and from Escherichia coli. In this manner each DNA chain could be cut into three parts, coding for the lipoyl domain, which consists of three lipoyl subdomains, the binding domain and the core-forming catalytic domain, respectively. Chimeric E2p components were constructed by exchanging the three domains between E2p from A. vinelandii and E. coli on gene level. The six chimeric E2p proteins were expressed and purified from E. coli TG2. All chimeras were catalytically active, 24-subunit E2p proteins. Interactions of the peripheral components E1p and E3 with the wild-type enzymes from A. vinelandii and E. coli and with the chimeric proteins were studied by gel-filtration experiments, analytical ultracentrifugation and reconstitution of the overall activity of the complex. A. vinelandii E3 interacts only with those chimeras that contain the A. vinelandii binding domain, whereas E. coli E3 interacts with all chimeras. Exchange of the lipoyl or catalytic domain did not influence the binding properties of E3. Recognition of E1p depends on the origin of both the binding domain and the catalytic domain. E. coli E1p interacts strongly with those chimeras in which both the binding domain and the catalytic domain were derived from E. coli E2p and weakly with chimeras that contained either the binding domain or the catalytic domain from E. coli E2p. No binding of E. coli E1p was observed when both domains were of A. vinelandii origin. A. vinelandii E1p recognizes E2p from A. vinelandii and E. coli, but strong interaction required that the binding and catalytic domain were of the same origin. Exchange of lipoyl domains had no effect on the binding properties of the E1p component. These observations confirm previous conclusions, based on site-directed mutagenesis of A. vinelandii E2p [Schulze, E., Westphal, A. H., Boumans, H., and de Kok, A. (1991) Eur. J. Biochem. 202, 841-848], that the binding site for E1p consists of amino acid residues derived from both the binding and the catalytic domain and extend these conclusions to E. coli E2p. Dissociation of the 24 subunit E2p core was only detected when the chimeric E2p proteins contained the catalytic domain from A. vinelandii E2p. Dissociation depends on the binding of peripheral components to the E1p-binding sites, pointing to differences in the inter-trimer contacts between the E2p proteins from both species.(ABSTRACT TRUNCATED AT 400 WORDS)

Atomic structure of the cubic core of the pyruvate dehydrogenase multienzyme complex.

The highly symmetric pyruvate dehydrogenase multienzyme complexes have molecular masses ranging from 5 to 10 million daltons. They consist of numerous copies of three different enzymes: pyruvate dehydrogenase, dihydrolipoyl transacetylase, and lipoamide dehydrogenase. The three-dimensional crystal structure of the catalytic domain of Azotobacter vinelandii dihydrolipoyl transacetylase has been determined at 2.6 angstrom (A) resolution. Eight trimers assemble as a hollow truncated cube with an edge of 125 A, forming the core of the multienzyme complex. Coenzyme A must enter the 29 A long active site channel from the inside of the cube, and lipoamide must enter from the outside. The trimer of the catalytic domain of dihydrolipoyl transacetylase has a topology identical to chloramphenicol acetyl transferase. The atomic structure of the 24-subunit cube core provides a framework for understanding all pyruvate dehydrogenase and related multienzyme complexes.

Purification and cellular localization of wild type and mutated dihydrolipoyltransacetylases from Azotobacter vinelandii and Escherichia coli expressed in E. coli.

Wild type dihydrolipoyltransacetylase(E2p)-components from the pyruvate dehydrogenase complex of A. vinelandii or E. coli, and mutants of A. vinelandii E2p with stepwise deletions of the lipoyl domains or the alanine- and proline-rich region between the binding and the catalytic domain have been overexpressed in E. coli TG2. The high expression of A. vinelandii wild type E2p (20% of cellular protein) and of a mutant enzyme with two lipoyl domains changed the properties of the inner bacterial membrane. This resulted in a solubilization of A. vinelandii E2p after degradation of the outer membrane by lysozyme without any contamination by E. coli pyruvate dehydrogenase complex (PDC) or other high-molecular-weight contaminants. The same effect could be detected for A. vinelandii E2o, an E2 which contains only one lipoyl domain, whereas almost no solubilization of A. vinelandii E2p with one lipoyl domain or of E2p consisting only of the binding and catalytic domain was found. Partial or complete deletion of the alanine- and proline-rich sequence between the binding and the catalytic domain did also decrease the solubilization of the E2p-mutants after lysozyme treatment. Immunocytochemical experiments on E. coli TG2 cells expressing A. vinelandii wild type E2p indicated that the enzyme was present as a soluble protein in the cytoplasm. In contrast, overexpressed A. vinelandii E2p with deletion of all three lipoyl domains and E. coli wild type E2p aggregated intracellularly. The solubilization by lysozyme is therefore ascribed to excluded volume effects leading to changes in the properties of the inner bacterial membrane.

Isolation and characterisation of the pyruvate dehydrogenase complex of anaerobically grown Enterococcus faecalis NCTC 775.

In this contribution the isolation and some of the structural and kinetic properties of the pyruvate dehydrogenase complex (PDC) of anaerobically grown Enterococcus faecalis are described. The complex closely resembles the PDC of other Gram-positive bacteria and eukaryotes. It consists of four polypeptide chains with apparent molecular masses on SDS/PAGE of 97, 55, 42 and 36 kDa, and these polypeptides could be assigned to dihydrolipoyl transacetylase (E2), lipoamide dehydrogenase (E3) and the two subunits of pyruvate dehydrogenase (E1 alpha and E1 beta), respectively. The E2 core has an icosahedral symmetry. The apparent molecular mass on SDS/PAGE of 97 kDa of the E2 chain is extremely high in comparison with other Gram-positive organisms (and eukaryotes) and probably due to several lipoyl domains associated with the E2 chain. NADH inhibition is mediated via E3. The mechanism of inhibition is discussed in view of the high PDC activities in vivo that are found in E. faecalis, grown under anaerobic conditions.