Cooperativity induced by a single mutation at the subunit interface of a dimeric enzyme: glutathione reductase.

When glycine418 of Escherichia coli glutathione reductase, which is in a closely packed region of the dimer interface, is replaced with a bulky tryptophan residue, the enzyme becomes highly cooperative (Hill coefficient 1.76) for glutathione binding. The cooperativity is lost when the mutant subunit is hybridized with a wild-type subunit to create a heterodimer. The mutation appears to disrupt atomic packing at the dimer interface, which induces a change of kinetic mechanism. A single mutation in a region of the protein remote from the active site can thus act as a molecular switch to confer cooperativity on an enzyme.

Phage display of peptide epitopes from HIV-1 elicits strong cytolytic responses.

Although much effort has been expended on evaluating recombinant proteins and synthetic peptides as immunogens, they have generally proved incapable of inducing an efficient cytotoxic T-cell (CTL) response. Filamentous bacteriophage fd can display multiple copies of foreign peptides in the N-terminal region of its major coat protein pVIII, 2,700 copies of which make up the virus capsid. Here we show that fd virions displaying peptide RT2 (ILKEPVHGV), corresponding to residues 309-317 of the reverse transcriptase (RTase) of HIV-1, are able to prime a CTL response specific for this HIV-1 epitope in human cell lines. Successful priming also requires a T-helper epitope, pep23 (KDSWTVNDIQKLVGK), corresponding to residues 249-263 of HIV-1 RTase. Supplying this by displaying it on either the same or a separate bacteriophage virion led to activation of antigen-specific CD4+ T cells. Likewise, HLA-A2 transgenic mice immunized with bacteriophage virions displaying peptide RT2 were shown to mount an effective, specific anti-HIV-RT2 CTL response. This unexpected ability to elicit a designated cytolytic T-cell response, in addition to a B-cell response, has important implications for access to the class I major histocompatibility complex (MHC) loading compartment and the development of recombinant vaccines.

Protein-protein interactions in the pyruvate dehydrogenase multienzyme complex: dihydrolipoamide dehydrogenase complexed with the binding domain of dihydrolipoamide acetyltransferase.

BACKGROUND: The ubiquitous pyruvate dehydrogenase multienzyme complex is built around an octahedral or icosahedral core of dihydrolipoamide acetyltransferase (E2) chains, to which multiple copies of pyruvate decarboxylase (E1) and dihydrolipoamide dehydrogenase (E3) bind tightly but non-covalently. E2 is a flexible multidomain protein that mediates interactions with E1 and E3 through a remarkably small binding domain (E2BD). RESULTS: In the Bacillus stearothermophilus complex, the E2 core is an icosahedral assembly of 60 E2 chains. The crystal structure of the E3 dimer (101 kDa) complexed with E2BD (4 kDa) has been solved to 2.6 A resolution. Interactions between E3 and E2BD are dominated by an electrostatic zipper formed by Arg135 and Arg139 in the N-terminal helix of E2BD and Asp344 and Glu431 of one of the monomers of E3. E2BD interacts with both E3 monomers, but the binding site is located close to the twofold axis. Thus, in agreement with earlier biochemical results, it is impossible for two molecules of E2BD to bind simultaneously to one E3 dimer. CONCLUSIONS: Combining this new structure for the E3-E2BD complex with previously determined structures of the E2 catalytic domain and the E2 lipoyl domain creates a model of the E2 core showing how the lipoyl domain can move between the active sites of E2 and E3 in the multienzyme complex.

Engineering a peptide epitope display system on filamentous bacteriophage.

The genome of bacteriophage fd has been engineered to allow foreign amino acid sequences to be displayed in the exposed N-terminal segment of the major coat protein in the virus particle: small peptides can be encoded directly; larger peptides are encoded in hybrid virions, in which wild-type coat protein subunits are interspersed with coat proteins displaying the foreign peptides. Biophysical techniques, such as X-ray diffraction, indicate that the inclusion of the peptides can be achieved without significant disturbance to the helical parameters that define the protein-protein interactions in the assembled virion and the exposure of the peptides can be verified by analysing the susceptibility to attack by proteolytic enzymes. Peptide sequences from the V3 loop of the surface glycoprotein gp120 of HIV-1 strain MN (HIV-1MN) displayed in this way are remarkably effective structural mimics of the natural epitope. They are recognised by human HIV antisera and evoke high titres of virus-neutralizing antibodies in mice. Antibody production is stimulated by simultaneous inoculation with T cell epitopes similarly displayed on filamentous bacteriophage. The bacteriophage display system offers a powerful means of studying the immunological recognition of proteins. The specificity of the immune response, the ability to recruit helper T cells, the lack of need for external adjuvants and the structural mimicry of defined peptide epitopes, suggest that it will also be an inexpensive and simple route to the production of effective vaccines.

A mutant pyruvate dehydrogenase complex of Escherichia coli deleted in the (alanine + proline)-rich region of the acetyltransferase component.

The acetyltransferase chains of the pyruvate dehydrogenase complex of Escherichia coli contain conformationally mobile (alanine + proline)-rich segments that link the lipoyl domains to each other and to the subunit-binding and catalytic domain, and facilitate the intramolecular coupling of active sites in the complex. A deletion of 12 of the 32 residues of the (Ala + Pro)-rich segment of an acetyltransferase containing only one lipoyl domain was made by deleting the corresponding segment of the aceF gene. A pyruvate dehydrogenase complex was still produced and the catalytic activity of the restructured complex, including active-site coupling, was not detectably impaired.

Structural dependence of post-translational modification and reductive acetylation of the lipoyl domain of the pyruvate dehydrogenase multienzyme complex.

The lipoyl domain of the dihydrolipoyl acetyltransferase (E2) component of the pyruvate dehydrogenase multienzyme complex is recognized specifically by the lipoylating enzyme(s) in the cell and by the pyruvate dehydrogenase (E1) component in the parent complex. Highly conserved aspartic acid and alanine residues flank the lipoyl-lysine residue, on the N and C-terminal sides, respectively, in the sharp beta-turn in which the lipoyl-lysine residue is prominently displayed. A sub-gene encoding the lipoyl domain of the Bacillus stearothermophilus pyruvate dehydrogenase complex was subjected to mutagenesis in the vector M13mp18. Aspartic acid 41 was changed to glutamic acid (D41E), alanine (D41A) and lysine (D41K), and alanine 43 was changed to methionine (A43M), lysine (A43K) and glutamic acid (A43E). The double mutations D41KK42A and D41MA43M were also made. All mutant domains were capable of being lipoylated, apart from the D41KK42A domain where the lipoyl-lysine had been moved round the beta-turn by one position towards the N terminus. Neither the D41K nor the A43K mutants showed any doubly lipoylated domain and the single lipoyl group was found attached only to the correct lysine residue. Accurate positioning of the lipoyl-lysine in the beta-turn is thus an essential cue for lipoylation, but the conserved aspartic acid and alanine residues are not necessary for the domain to be recognized by the lipoylating enzyme(s). No biotinylation of the D41MA43M mutant domain was observed, although the sequence motif MKM is highly conserved as the biotinylation site in the structurally homologous biotinyl domain of biotin-containing enzymes. The mutations at the aspartic acid 41 position all lowered the rate of reductive acetylation of the lipoyl domain by the E1 component of the pyruvate dehydrogenase complex, as did the mutations A43E and A43K. The A43M mutant was reductively acetylated at the same rate as the wild-type domain. Thus, both the alanine and aspartic acid residues are important for recognition of the domain by E1, but there is no absolute dependence on retention of the sequence surrounding the lipoyl-lysine residue.

Cloning and expression of the filamentous bacteriophage Pf1 major coat protein gene in Escherichia coli. Membrane protein processing and virus assembly.

A restriction fragment carrying the major coat protein gene (gene VIII) was excised from the replicative form (RF) DNA of the class II filamentous bacteriophage Pf1, which infects Pseudomonas aeruginosa. This fragment was cloned into the expression plasmid pKK223-3, where it came under the control of the tac promoter. In transformed Escherichia coli JM101 cells, in the presence of the inducer isopropyl-beta-D-thiogalactoside, the bacteriophage Pf1 gene was strongly expressed. The bacteriophage Pf1 coat protein displays the same pattern of negatively charged N-terminal region, hydrophobic middle region and positively charged C-terminal region as that of its counterpart in the class I bacteriophage fd, which infects E. coli, but otherwise the two proteins have no sequence homology. However, the Pf1 procoat protein was found to undergo processing and insertion into the E. coli cell inner membrane, like its fd counterpart, demonstrating that this part of the assembly process is the same for these different bacteriophages. The complete transcriptional unit, incorporating the tac promoter and rrnB transcription terminators flanking the Pf1 coat protein gene, was excised from the expression plasmid and cloned into the intergenic space of bacteriophage R252, an fd bacteriophage that carries an amber mutation in its own major coat protein gene. The Pf1 coat protein gene was again well expressed in infected E. coli cells but the chimeric bacteriophage had growth properties identical to those of the parent bacteriophage R252 on suppressor and non-suppressor strains of E. coli. The class I bacteriophage Pf1 coat protein evidently cannot be recognized by the class I bacteriophage assembly complex at or in the E. coli cell inner membrane, either at the point of initiation of assembly or during the elongation process.

Regulation of filamentous bacteriophage length by modification of electrostatic interactions between coat protein and DNA.

Bacteriophage fd gene VIII, which encodes the major capsid protein, was mutated to convert the serine residue at position 47 to a lysine residue (S47K), thereby increasing the number of positively charged residues in the C-terminal region of the protein from four to five. The S47K coat protein underwent correct membrane insertion and processing but could not encapsidate the viral DNA, nor was it incorporated detectably with wild-type coat proteins into hybrid bacteriophage particles. However, hybrid virions could be constructed from the S47K coat protein and a second mutant coat protein, K48Q, the latter containing only three lysine residues in its C-terminal region. K48Q phage particles are approximately 35% longer than wild-type. Introducing the S47K protein shortened these particles, the S47K/K48Q hybrids exhibiting a range of lengths between those of K48Q and wild-type. These results indicate that filamentous bacteriophage length (and the DNA packaging underlying it) are regulated by unusually flexible electrostatic interactions between the C-terminal domain of the coat protein and the DNA. They strongly suggest that wild-type bacteriophage fd makes optimal use of the minimum number of coat protein subunits to package the DNA compactly.

Multiple display of foreign peptides on a filamentous bacteriophage. Peptides from Plasmodium falciparum circumsporozoite protein as antigens.

We describe here two systems for encoding foreign amino acid sequences in the exposed N-terminal segment of the major coat protein of bacteriophage fd. Small peptides can be encoded directly; larger peptides are encoded in hybrid bacteriophage particles, in which the capsid is formed from a mixture of wild-type and modified coat proteins. In both cases, the peptides are present in multiple copies per phage particle. Peptides that represent the circumsporozoite protein, the major surface antigen of the sporozoites of the malaria parasite, Plasmodium falciparum, were inserted in this way and found to be highly immunogenic. These systems should prove to be valuable in displaying specific or random peptides as antigens, and could lead to cheap and effective vaccines. They will also allow rapid screening of peptides as potential agents of other biological effects, with important applications in biomolecular design.

Multiple display of peptides and proteins on a macromolecular scaffold derived from a multienzyme complex.

The acyltransferase components (E2) from the family of 2-oxo acid dehydrogenase multienzyme complexes form large protein scaffolds, to which multiple copies of peripheral enzymes bind tightly but non-covalently. Sixty copies of the E2 polypeptide from the pyruvate dehydrogenase multienzyme complex of Bacillus stearothermophilus assemble to form a pentagonal dodecahedral scaffold with icosahedral symmetry. This protein scaffold can be modified to present foreign peptides and proteins on its surface. We show that it is possible to display two epitopes (MAL1 and MAL2) from the circumsporozoite CS proteins of Plasmodium falciparum and Plasmodium berghei, respectively, and a green fluorescent protein (EGFP), on the E2 surface. Immunization with an E2 scaffold displaying the MAL1 epitope elicited MAL1-specific antibodies in rabbits. EGFP (25 kDa) displayed as an N-terminal fusion in each of the 60 copies of the E2 chain folded into its active form, as judged by its fluorescence and detection in localized foci in Escherichia coli cells in vivo. Simultaneous display of a hexahistidine affinity tag, the MAL1 epitope and the green fluorescent protein, all on the same E2 scaffold, could be achieved by reversible denaturation and reassembly of mixtures of appropriately modified E2 chains. This new methodology offers several important advantages over other current display technologies, not least in the size of insert that can be accommodated and the multiplicity of display that can be achieved.

Three-dimensional structure of the lipoyl domain from Bacillus stearothermophilus pyruvate dehydrogenase multienzyme complex.

The structure of the lipoyl domain from the pyruvate dehydrogenase multienzyme complex of Bacillus stearothermophilus has been determined by means of nuclear magnetic resonance spectroscopy. A total of 452 nuclear Overhauser effect distance constraints and 76 dihedral angle restraints were employed as the input for the structure calculations, which were performed using a hybrid distance geometry-simulated annealing strategy and the programs DISGEO and X-PLOR. The overall structure of the lipoyl domain (residues 1 to 79 of the dihydrolipoamide acetyltransferase polypeptide chain) is that of a flattened eight-stranded beta-barrel folded around a core of well-defined hydrophobic residues. The lipoylation site, lysine 42, is located in the middle of a beta-turn, and the N and C-terminal residues of the domain are close together in adjacent beta-strands at the opposite end of the molecule. The polypeptide backbone exhibits a 2-fold axis of quasi-symmetry, with the C alpha atoms of residues 15 to 39 and 52 to 76 being almost superimposable on those of residues 52 to 76 and 15 to 39, respectively (root-mean-square deviation = 1.48 A). The amino acid residues at key positions in the structure are conserved among all the reported primary structures of lipoyl domains, suggesting that the domains all fold in a similar way.

Variable electrostatic interaction between DNA and coat protein in filamentous bacteriophage assembly.

A restriction fragment carrying the major coat protein gene (gene VIII) was excised from the DNA of the class I filamentous bacteriophage fd, which infects Escherichia coli. This fragment was cloned into the expression plasmid pKK223-3, where it came under the control of the tac promoter, generating plasmid pKf8P. Bacteriophage fd gene VIII was similarly cloned into the plasmid pEMBL9+, enabling it to be subjected to site-directed mutagenesis. By this means the positively charged lysine residue at position 48, one of four positively charged residues near the C terminus of the protein, was turned into a negatively charged glutamic acid residue. The mutated fd gene VIII was cloned back from the pEMBL plasmid into the expression plasmid pKK223-3, creating plasmid pKE48. In the presence of the inducer isopropyl-beta-D-thiogalactoside, the wild-type and mutated coat protein genes were strongly expressed in E. coli TG1 cells transformed with plasmids pKf8P and pKE48, respectively, and the product procoat proteins underwent processing and insertion into the E. coli cell inner membrane. A net positive charge of only 2 on the side-chains in the C-terminal region is evidently sufficient for this initial stage of the virus assembly process. However, the mutated coat protein could not encapsidate the DNA of bacteriophage R252, an fd bacteriophage carrying an amber mutation in its own gene VIII, when tested on non-suppressor strains of E. coli. On the other hand, elongated hybrid bacteriophage particles could be generated whose capsids contained mixtures of wild-type (K48) and mutant (E48) subunits. This suggests that the defect in assembly may occur at the initiation rather than the elongation step(s) in virus assembly. Other mutations of lysine-48 that removed or reversed the positive charge at this position in the C-terminal region of the coat protein were also found to lead to the production of commensurately longer bacteriophage particles. Taken together, these results indicate direct electrostatic interaction between the DNA and the coat protein in the capsid and support a model of non-specific binding between DNA and coat protein subunits with a stoicheiometry that can be varied during assembly.

Analysis of X-ray diffraction from fibres of Pf1 Inovirus (filamentous bacteriophage) shows that the DNA in the virion is not highly ordered.

X-ray fibre diffraction patterns of well-aligned Pf1 filamentous bacteriophage show sharp layer-lines attributable to an ordered helical array of protein subunits. Electron density maps calculated from the intensity on these layer-lines show no evidence for DNA following the symmetry of the protein, nor is there evidence on the diffraction patterns for the additional layer-lines expected if ordered DNA follows a symmetry different from that of the protein. We conclude that the interactions between DNA and protein in the Pf1 virion, like those in the Ff virion, are delocalized rather than specific, and the DNA structure in the virion is less regular than the protein structure. This conclusion has implications for the process of virion assembly, and we suggest a possible model for the change in the viral DNA symmetry as the DNA is passed to the virion from the intracellular complex with the viral gene 5 single-stranded DNA-binding protein.

Recognition of the lipoyl domain is the ultimate determinant of substrate channelling in the pyruvate dehydrogenase multienzyme complex.

Reductive acetylation of the lipoyl domain (E2plip) of the dihydrolipoyl acetyltransferase component of the pyruvate dehydrogenase multienzyme complex of Escherichia coli is catalysed specifically by its partner pyruvate decarboxylase (E1p), and no productive interaction occurs with the analogous 2-oxoglutarate decarboxylase (E1o) of the 2-oxoglutarate dehydrogenase complex. Residues in the lipoyl-lysine beta-turn region of the unlipoylated E2plip domain (E2plip(apo)) undergo significant changes in both chemical shift and transverse relaxation time (T(2)) in the presence of E1p but not E1o. Residue Gly11, in a prominent surface loop between beta-strands 1 and 2 in the E2plip domain, was also observed to undergo a significant change in chemical shift. Addition of pyruvate to the mixture of E2plip(apo) and E1p caused larger changes in chemical shift and the appearance of multiple cross-peaks for certain residues, suggesting that the domain was experiencing more than one type of interaction. Residues in both beta-strands 4 and 5, together with those in the prominent surface loop and the following beta-strand 2, appeared to be interacting with E1p, as did a small patch of residues centred around Glu31. The values of T(2) across the polypeptide chain backbone were also lower than in the presence of E1p alone, suggesting that E2plip(apo) binds more tightly after the addition of pyruvate. The lipoylated domain (E2plip(holo)) also exhibited significant changes in chemical shift and decreases in the overall T(2) relaxation times in the presence of E1p, the residues principally affected being restricted to the half of the domain that contains the lipoyl-lysine (Lys41) residue. In addition, small chemical shift changes and a general drop in T(2) times in the presence of E1o were observed, indicating that E2plip(holo) can interact, weakly but non-productively, with E1o. It is evident that recognition of the protein domain is the ultimate determinant of whether reductive acetylation of the lipoyl group occurs, and that this is ensured by a mosaic of interactions with the Elp.

Structural differences between wild-type NADP-dependent glutathione reductase from Escherichia coli and a redesigned NAD-dependent mutant.

NAD and NADP are ubiquitous coenzymes in biological redox reactions. They have distinct metabolic functions, yet they differ only by an additional phosphate group esterified at the 2'-hydroxyl group of the AMP moiety of NADP. The natural specificity of Escherichia coli glutathione reductase for NADP has previously been converted into a marked preference for NAD by introducing seven point mutations into the beta alpha beta-fold of the NADP-binding domain of the protein based on the known structure of the human enzyme. Among them was the replacement of Ala179 by glycine (A179G) in the alpha-helix of the fold, a change suggested by a difference in a sequence fingerprint previously found in the dinucleotide-binding domains of a number of dehydrogenases. Although this position is at a distance of 10 A from the bound 2'-phosphate group of NADP in glutathione reductase, the A179G mutation was found to be synergistic and beneficial. We have now carried out X-ray crystallographic analyses of the NAD-dependent mutant without and with bound NADH. A comparison of the structures of the mutant and wild-type enzymes reveals a flip of the peptide bond between Gly174 and Ala175 such that the side-chain of another introduced amino acid, Glu197, is fixed and can participate in binding the adenine ribose of NAD, thereby contributing to the ability of the mutated enzyme to exert its selectivity for the "wrong" coenzyme.

The high-resolution structure of the peripheral subunit-binding domain of dihydrolipoamide acetyltransferase from the pyruvate dehydrogenase multienzyme complex of Bacillus stearothermophilus.

The three-dimensional structure of a 43-residue active, synthetic peptide encompassing the peripheral subunit-binding domain of dihydrolipoamide acetyltransferase from the pyruvate dehydrogenase multienzyme complex of Bacillus stearothermophilus has been determined by means of a multi-cooling dynamical simulated annealing protocol using restraints derived from 1H nuclear magnetic resonance spectroscopy. A total of 442 experimentally derived restraints including 13 dihedral angle (phi, chi 1) restraints were used. A final set of 35 structures was calculated with a root-mean-square deviation from the mean co-ordinates of 0.36 A for the backbone atoms and 0.96 A when side-chain heavy atoms were included for the well-defined region comprising residues Val7 to Leu39. Although assignments were made and sequential connectivities observed for the N-terminal six and C-terminal four residues, the absence of long-range NOEs suggests that the terminal regions are largely unstructured. The binding domain contains two short parallel alpha-helices (residues Val7 to Lys14 and Lys32 to Leu39), a3(10)-helix (residues Asp17 to Val21) and a structured loop made up of overlapping beta-turns (residues Gln22 to Leu31), which enclose a close-packed hydrophobic core. The loop is stabilized to a large extent by Asp34. This residue is conserved in all peripheral subunit-binding domains and its carboxylate side-chain forms a set of side-chain-main-chain hydrogen bonds with the main-chain amide protons of Gly23, Thr24, Gly25 and Leu31 and a side-chain-side-chain hydrogen bond with the hydroxyl group of Thr24. We propose that a peripheral subunit-binding site may be located in the loop region, which contains a series of highly conserved residues and provides a number of potential recognition sites. The structured region of the binding domain, comprising 33 residues, represents an exceptionally short amino acid sequence with defined tertiary structure that has no disulphide bond, ligand or cofactor to stabilize the fold. It may be approaching the lower size limit for a three-dimensional structure possessing features characteristic of larger structures, including a close-packed, non-polar interior. The organization of the side-chains in the hydrophobic core may have implications for de novo protein design.

Matching electrostatic charge between DNA and coat protein in filamentous bacteriophage. Fibre diffraction of charge-deletion mutants.

The virion of Ff (fd, f1, M13) filamentous bacteriophage consists of a long tube of coat protein subunits in a shingled, helical array, surrounding a genome of circular single-stranded DNA. Modified fd virions have been generated by a mutation (K48A) that removes one positive charge from each coat protein subunit in the C-terminal region of the polypeptide chain facing the DNA. The number of nucleotides in the mutant DNA is unchanged, but the K48A virions are 35% longer than wild-type. We have measured the X-ray diffraction attributable to single virions in hydrated gels of wild-type and K48A bacteriophages. Most of the diffraction pattern shows no significant difference between wild-type and K48A. Since the DNA is only about 12% by weight of the wild-type virion, the diffraction pattern is dominated by the protein contribution, and the absence of significant differences indicates that there are no significant changes in the symmetry or structure of the protein coat. But there is a change in the diffraction pattern in a region where the DNA and protein contributions are comparable. The diffraction pattern of the K48A mutant shows an increase in intensity of one of the weaker equatorial peaks, relative to wild-type, in a region where the protein contribution has negative sign but the DNA contribution has positive sign. This is consistent with a decrease in the ratio of DNA:protein per unit length of the K48A mutant. The results support the view that the protein forms a sheath lined with positive charges interacting electrostatically and non-specifically with a negatively charged DNA core of matching charge density. The lower positive charge density lining the capsid in the K48A mutant means that correspondingly fewer nucleotides can be packaged per coat protein subunit, which in turn requires an elongation of the DNA inside the virion. A longer virion is thus required to package the same amount of DNA. Within the error of measurement, the number of positive charges on the protein interacting with the DNA is the same in K48A as in the wild-type, despite the fact that the mutant is 35% longer than the wild-type.

DNA sequence of the filamentous bacteriophage Pf1.

The genome of the class II filamentous bacteriophage Pf1 has been sequenced by a combination of the chain termination and chemical degradation methods. It consists of 7349 nucleotides in a closed, circular loop of single-stranded DNA. The size and position of its open reading frames (ORFs) in general resemble those of other filamentous bacteriophage genomes. The size and position of the spaces between the ORFs have not been conserved, however, and six short reading frames (2 of which overlap) occupy a region corresponding to that filled by genes 2 and 10 in the Ff genome. Most of the ORFs are preceded by sequences resembling ribosome binding sites from the phage's host. Pseudomonas aeruginosa, that appear to differ somewhat from their counterparts in Escherichia coli. A search for sequences related to known pseudomonad promoters suggests that the promoters in this bacteriophage may well be ntr-dependent, with the two strongest preceding the gene for the major coat protein (gene 8) and another ORF (430). Gene 8 is followed by a sequence with the properties of a rho-independent terminator of transcription, like that at the same position in the genome of Ff. The Pf1 genome contains no collection of potential stem-and-loop structures corresponding to those that initiate replication of Ff DNA and assembly of the Ff virion, although isolated structures of this kind are present. The available evidence suggests that at least 13 of the 14 major ORFs are expressed. Overall, the organization of the Pf1 genome differs from that of the other class II filamentous phage whose genome has been sequenced, Pf3, as much as it does from that of the class I phages Ff and IKe.

Reductive acetylation of tandemly repeated lipoyl domains in the pyruvate dehydrogenase multienzyme complex of Escherichia coli is random order.

In vitro deletion and site-directed mutagenesis of the aceF gene of Escherichia coli was used to generate dihydrolipoamide acetyltransferase (E2p) polypeptide chains containing various permutations and combinations of functional and non-functional lipoyl domains. A lipoyl domain was rendered non-functional by converting the lipoylatable lysine residue to glutamine. Two- and three-lipoyl domain E2p chains, with lipoyl-lysine (Lys244) substituted by glutamine in the innermost lipoyl domains (designated +/- and +/+/-, respectively), and similar chains with lipoyl-lysine (Lys143) substituted by glutamine in the outer lipoyl domains (designated -/+ and -/-/+), were constructed. In all instances, pyruvate dehydrogenase complexes were assembled in vivo around E2p cores composed of the modified peptide chains. All the complexes were essentially fully active in catalysis, although the complex containing the -/-/+ version of the E2p polypeptide chain showed a 50% reduction in specific catalytic activity. Similarly, active-site coupling in the complexes containing the +/-, +/+/- and -/+ constructions of the E2p chains was not significantly different from that achieved by the wild-type complex. However, active-site coupling in the complex containing the -/-/+ version of the E2p chain was slightly impaired, consistent with the reduced overall complex activity. These results indicate that during oxidative decarboxylation there is no mandatory order of reductive acetylation of repeated lipoyl domains within E2p polypeptide chains, and strongly suggest that the three tandemly repeated lipoyl domains in the wild-type E2p chain function independently in the pyruvate dehydrogenase complex.

Three-dimensional structure of a lipoyl domain from the dihydrolipoyl acetyltransferase component of the pyruvate dehydrogenase multienzyme complex of Escherichia coli.

The structure of a lipoyl domain from the pyruvate dehydrogenase multienzyme complex of Escherichia coli has been determined by means of nuclear magnetic resonance spectroscopy. A total of 549 nuclear Overhauser effect distance restraints, 52 phi torsion angle restraints and 16 slowly exchanging amide protons were employed as input for the structure calculations. These were performed using a combined distance geometry-simulated annealing strategy. The domain is a hybrid between the N and C-terminal halves of the first and third lipoyl domains, respectively, of the dihydrolipoyl acetyltransferase component of the E. coli multienzyme complex, representing residues 1 to 33 and 238 to 289 (wild-type numbering). The lipoyl-lysine residue was also replaced by glutamine. Nonetheless, its structure, two four-stranded beta-sheets forming a flattened beta-barrel, closely resembles that of the lipoyl domain from the pyruvate dehydrogenase multienzyme complex from Bacillus stearothermophilus determined previously. As before, the lipoylation site is physically exposed in a tight turn in one of the beta-sheets, and the N and C-terminal residues are close together at the other end of the molecule in adjacent strands of the other beta-sheet. Another prominently conserved feature of the structure is the 2-fold axis of quasi-symmetry relating the N and C-terminal halves of the domain. Consistent with the high level of sequence similarity between lipoyl domains of 2-oxo acid dehydrogenase multienzyme complexes from many different sources, these results confirm that all lipoyl domains are likely to have closely related structures.