Construction and properties of pyruvate dehydrogenase complexes with up to nine lipoyl domains per lipoate acetyltransferase chain

The lipoate acetyltransferase (E2p) subunits of the pyruvate dehydrogenase (PDH) complex of Escherichia coli have three tandemly repeated lipoyl domains, although net deletions of one or two has no apparent effect on the activity of the purified complexes. Plasmids containing IPTG-inducible aceEF-lpd operons, which encode PDH complexes bearing from one to nine lipoyl domains per E2p chain (24-216 per complex), were constructed. They were all capable of restoring the nutritional lesion of a strain lacking PDH complex and they all expressed active sedimentable multienzyme complexes having a relatively normal range of subunit stoichiometries. The extra domains are presumed to protrude from the E2p core (24-mer) without significantly affecting the assembly of the E1p and E3 subunits on the respective edges and faces of the cubic core. However, the catalytic activities of the overproduced complexes containing four to nine lipoyl domains per E2p chain were lower than those with fewer lipoyl domains. This could be due to under-lipoylation of the domains participating in catalysis and interference from unlipoylated domains.     

Chain folding in the dihydrolipoyl acyltransferase components of the 2-oxo-acid dehydrogenase complexes from Escherichia coli. Identification of a segment involved in binding the E3 subunit

The state of assembly of the pyruvate and 2-oxoglutarate dehydrogenase multienzyme complexes was examined after the dihydrolipoyl acyltransferase (E2) component of each enzyme system had been subjected to varying degrees of limited proteolysis. Dissociation of the dihydrolipoyl dehydrogenase (E3) component accompanied specifically the excision of a homologous segment of each E2 chain that connects the N-terminal lipoyl domain(s) with a C-terminal catalytic domain. The latter remains aggregated as a 24-mer and retains its capacity to bind the 2-oxo-acid decarboxylase (E1) component. The relevant segment of the E2o chain from the 2-oxoglutarate dehydrogenase complex was isolated and shown to be a folded protein which still binds to E3.     

Molecular structure of a 9-MDa icosahedral pyruvate dehydrogenase subcomplex containing the E2 and E3 enzymes using cryoelectron microscopy

The pyruvate dehydrogenase multienzyme complexes are among the largest multifunctional catalytic machines in cells, catalyzing the production of acetyl CoA from pyruvate. We have previously reported the molecular architecture of an 11-MDa subcomplex comprising the 60-mer icosahedral dihydrolipoyl acetyltransferase (E2) decorated with 60 copies of the heterotetrameric (alpha(2)beta(2)) 153-kDa pyruvate decarboxylase (E1) from Bacillus stearothermophilus (Milne, J. L. S., Shi, D., Rosenthal, P. B., Sunshine, J. S., Domingo, G. J., Wu, X., Brooks, B. R., Perham, R. N., Henderson, R., and Subramaniam, S. (2002) EMBO J. 21, 5587-5598). An annular gap of approximately 90 A separates the acetyltransferase catalytic domains of the E2 from an outer shell formed of E1 tetramers. Using cryoelectron microscopy, we present here a three-dimensional reconstruction of the E2 core decorated with 60 copies of the homodimeric 100-kDa dihydrolipoyl dehydrogenase (E3). The E2E3 complex has a similar annular gap of approximately 75 A between the inner icosahedral assembly of acetyltransferase domains and the outer shell of E3 homodimers. Automated fitting of the E3 coordinates into the map suggests excellent correspondence between the density of the outer shell map and the positions of the two best fitting orientations of E3. As in the case of E1 in the E1E2 complex, the central 2-fold axis of the E3 homodimer is roughly oriented along the periphery of the shell, making the active sites of the enzyme accessible from the annular gap between the E2 core and the outer shell. The similarities in architecture of the E1E2 and E2E3 complexes indicate fundamental similarities in the mechanism of active site coupling involved in the two key stages requiring motion of the swinging lipoyl domain across the annular gap, namely the synthesis of acetyl CoA and regeneration of the dithiolane ring of the lipoyl domain.     

Crystal structure of 2-oxoisovalerate and dehydrogenase and the architecture of 2-oxo acid dehydrogenase multienzyme complexes.

The family of giant multienzyme complexes metabolizing pyruvate, 2-oxoglutarate, branched-chain 2-oxo acids or acetoin contains several of the largest and most sophisticated protein assemblies known, with molecular masses between 4 and 10 million Da. The principal enzyme components, E1, E2 and E3, are present in numerous copies and utilize multiple cofactors to catalyze a directed sequence of reactions via substrate channeling. The crystal structure of a heterotetrameric (alpha2beta2) E1, 2-oxoisovalerate dehydrogenase from Pseudomonas putida, reveals a tightly packed arrangement of the four subunits with the beta2-dimer held between the jaws of a 'vise' formed by the alpha2-dimer. A long hydrophobic channel, suitable to accommodate the E2 lipoyl-lysine arm, leads to the active site, which contains the cofactor thiamin diphosphate (ThDP) and an inhibitor-derived covalent modification of a histidine side chain. The E1 structure, together with previous structural information on E2 and E3, completes the picture of the shared architectural features of these enormous macromolecular assemblies.     

Self-assembly and catalytic activity of the pyruvate dehydrogenase multienzyme complex from Bacillus stearothermophilus.

The pyruvate dehydrogenase multienzyme complex from Bacillus stearothermophilus was reconstituted in vitro from recombinant proteins derived from genes over-expressed in Escherichia coli. Titrations of the icosahedral (60-mer) dihydrolipoyl acetyltransferase (E2) core component with the pyruvate decarboxylase (E1, alpha2beta2) and dihydrolipoyl dehydrogenase (E3, alpha2) peripheral components indicated a variable composition defined predominantly by tight and mutually exclusive binding of E1 and E3 with the peripheral subunit-binding domain of each E2 chain. However, both analysis of the polypeptide chain ratios in complexes generated from various mixtures of E1 and E3, and displacement of E1 or E3 from E1-E2 or E3-E2 subcomplexes by E3 or E1, respectively, showed that the multienzyme complex does not behave as a simple competitive binding system. This implies the existence of secondary interactions between the E1 and E3 subunits and E2 that only become apparent on assembly. Exact geometrical distribution of E1 and E3 is unlikely and the results are best explained by preferential arrangements of E1 and E3 on the surface of the E2 core, superimposed on their mutually exclusive binding to the peripheral subunit-binding domain of the E2 chain. Correlation of the subunit composition with the overall catalytic activity of the enzyme complex confirmed the lack of any requirement for precise stoichiometry or strict geometric arrangement of the three catalytic sites and emphasized the crucial importance of the flexibility associated with the lipoyl domains and intramolecular acetyl group transfer in the mechanism of active-site coupling.     

Structure, stability and dynamics of norovirus P domain derived protein complexes studied by native mass spectrometry

Expression of the protruding (P) domain of the norovirus capsid protein, in vitro, results in the formation of P dimers and larger oligomers, 12-mer and 24-mer P particles. All these P complexes retain the authentic antigenicity and carbohydrate-binding function of the norovirus capsid. They have been used as tools to study norovirus-host interactions, and the 24-mer P particle has been proposed as a vaccine and vaccine platform against norovirus and other pathogens. In view of their pharmaceutical interest it is important to characterise the structure, stability and dynamics of these protein complexes. Here we use a native mass spectrometric approach. We analyse the P particles under both non-reducing and reducing conditions, as it is known that the macromolecular assemblies are stabilised by inter-subunit disulphide bonding. A novel 18-mer complex is identified, and we show that under reducing conditions the 24-mer dissociates into P dimers that reassemble into the 12-mer small P particle and another novel 36-mer complex. The collisional cross-sections of the 12-mer and 24-mer P particles determined by ion mobility MS are in good agreement with theoretical predictions and electron microscopy data. We propose a model structure for the 18-mer based on ion mobility experiments. Our results demonstrate the interchangeable nature and dynamic relationship of all P domain complexes and confirm their binding activity to the host receptors - human histo blood group antigens (HBGAs). These findings, together with the identification of the 18-mer and 36-mer P complexes add new information to the intriguing interactions of the norovirus P domain.     

Improvement of diffraction quality upon rehydration of dehydrated icosahedral Enterococcus faecalis pyruvate dehydrogenase core crystals.

Members of the family of 2-oxoacid dehydrogenase multienzyme complexes catalyze the oxidative decarboxylation of alpha-keto acids and are among the most remarkable enzymatic machineries in the living cell. These multienzyme complexes combine a highly symmetric (cubic or icosahedral) core with a dynamic and flexible arrangement of numerous subunits and domains surrounding the core. The center of the complex is formed by either 24 or 60 copies of dihydrolipoamide acetyltransferase (E2)-a multidomain enzyme. The hollow icosahedral cores are composed of 60 identical subunits of the catalytic domain of E2 with a molecular weight of about 1.8 million Da. Bipyramidal crystals suitable for X-ray diffraction of the icosahedral core of the pyruvate dehydrogenase multienzyme complex from Enterococcus faecalis were grown up to 0.7 mm in each dimension. The crystals belong to space group R32 with a = b = 244.3 A (hexagonal setting), and have a solvent content of 73%. The asymmetric unit contains one-third of the molecule, i.e., 20 of the 60 subunits. Initial X-ray crystallographic data to 7 A resolution were collected at cryotemperatures at synchrotron facilities. Interestingly, the diffraction was improved significantly upon rehydrating dehydrated crystals and extended to 4.2 A.     

Identification of a protein mediating respiratory supercomplex stability

The complexes of the electron transport chain associate into large macromolecular assemblies, which are believed to facilitate efficient electron flow. We have identified a conserved mitochondrial protein, named respiratory supercomplex factor 1 (Rcf1-Yml030w), that is required for the normal assembly of respiratory supercomplexes. We demonstrate that Rcf1 stably and independently associates with both Complex III and Complex IV of the electron transport chain. Deletion of the RCF1 gene caused impaired respiration, probably as a result of destabilization of respiratory supercomplexes. Consistent with the hypothetical function of these respiratory assemblies, loss of RCF1 caused elevated mitochondrial oxidative stress and damage. Finally, we show that knockdown of HIG2A, a mammalian homolog of RCF1, causes impaired supercomplex formation. We suggest that Rcf1 is a member of an evolutionarily conserved protein family that acts to promote respiratory supercomplex assembly and activity.     

"Macromolecular crowding": thermodynamic consequences for protein-protein interactions within the T4 DNA replication complex

In vitro biochemical assays are typically performed using very dilute solutions of macromolecular components. On the other hand, total intracellular concentrations of macromolecular solutes are very high, resulting in an in vivo environment that is significantly "volume-occupied." In vitro studies with the DNA replication proteins of bacteriophage T4 have revealed anomalously weak binding of T4 gene 45 protein to the rest of the replication complex. We have used inert macromolecular solutes to mimic typical intracellular solution conditions of high volume occupancy to investigate the effects of "macromolecular crowding" on the binding equilibria involved in the assembly of the T4 polymerase accessory proteins complex. The same approach was also used to study the assembly of this complex with T4 DNA polymerase (gene 43 protein) and T4 single-stranded DNA binding protein (gene 32 protein) to form the five protein "holoenzyme". We find that the apparent association constant (Ka) of gene 45 for gene 44/62 proteins in forming both the accessory protein complex and the holoenzyme increases markedly (from approximately 7 x 10(6) to approximately 3.5 x 10(8) M-1) as a consequence of adding polymers such as polyethylene glycol and dextran. Although the processivity of the polymerase alone is not directly effected by the addition of such polymers to the solution, macromolecular crowding does significantly stabilize the holoenzyme and thus indirectly increases the observed processivity of the holoenzyme complex. The use of macromolecular crowding to increase the stability of multienzyme complexes in general is discussed, as is the relevance of these results to DNA replication in vivo.     

Maturation of phage T7 involves structural modification of both shell and inner core components

The double-stranded DNA bacteriophages are good model systems to understand basic biological processes such as the macromolecular interactions that take place during the virus assembly and maturation, or the behavior of molecular motors that function during the DNA packaging process. Using cryoelectron microscopy and single-particle methodology, we have determined the structures of two phage T7 assemblies produced during its morphogenetic process, the DNA-free prohead and the mature virion. The first structure reveals a complex assembly in the interior of the capsid, which involves the scaffolding, and the core complex, which plays an important role in DNA packaging and is located in one of the phage vertices. The reconstruction of the mature virion reveals important changes in the shell, now much larger and thinner, the disappearance of the scaffolding structure, and important rearrangements of the core complex, which now protrudes the shell and interacts with the tail. Some of these changes must originate by the pressure exerted by the DNA in the interior of the head.     

Structural features and oligomeric nature of human podocin domain

Podocytes are crucial cells of the glomerular filtration unit and plays a vital role at the interface of the blood-urine barrier. Podocyte slit-diaphragm is a modified tight junction that facilitates size and charge-dependent permselectivity. Several proteins including podocin, nephrin, CD2AP, and TRPC6 form a macromolecular assembly and constitute the slit-diaphragm. Podocin is an integral membrane protein attached to the inner membrane of the podocyte via a short transmembrane region (101–125). The cytosolic N- and C-terminus help podocin to attain a hook-like structure. Podocin shares 44% homology with stomatin family proteins and similar to the stomatin proteins, podocin was shown to associate into higher-order oligomers at the site of slit-diaphragm. However, the stoichiometry of the homo-oligomers and how it partakes in the macromolecular assemblies with other slit-diaphragm proteins remains elusive. Here we investigated the oligomeric propensity of a truncated podocin construct (residues:126–350). We show that the podocin domain majorly homo-oligomerizes into a 16-mer. Circular dichroism and fluorescence spectroscopy suggest that the 16-mer oligomer has considerable secondary structure and moderate tertiary packing.     

Novel Binding Motif and New Flexibility Revealed by Structural Analyses of a Pyruvate Dehydrogenase-Dihydrolipoyl Acetyltransferase Subcomplex from the Escherichia coli Pyruvate Dehydrogenase Multienzyme Complex

The Escherichia coli pyruvate dehydrogenase multienzyme complex contains multiple copies of three enzymatic components, E1p, E2p, and E3, that sequentially carry out distinct steps in the overall reaction converting pyruvate to acetyl-CoA. Efficient functioning requires the enzymatic components to assemble into a large complex, the integrity of which is maintained by tethering of the displaced, peripheral E1p and E3 components to the E2p core through non-covalent binding. We here report the crystal structure of a subcomplex between E1p and an E2p didomain containing a hybrid lipoyl domain along with the peripheral subunit-binding domain responsible for tethering to the core. In the structure, a region at the N terminus of each subunit in the E1p homodimer previously unseen due to crystallographic disorder was observed, revealing a new folding motif involved in E1p-E2p didomain interactions, and an additional, unexpected, flexibility was discovered in the E1p-E2p didomain subcomplex, both of which probably have consequences in the overall multienzyme complex assembly. This represents the first structure of an E1p-E2p didomain subcomplex involving a homodimeric E1p, and the results may be applicable to a large range of complexes with homodimeric E1 components. Results of HD exchange mass spectrometric experiments using the intact, wild type 3-lipoyl E2p and E1p are consistent with the crystallographic data obtained from the E1p-E2p didomain subcomplex as well as with other biochemical and NMR data reported from our groups, confirming that our findings are applicable to the entire E1p-E2p assembly.     

A three-dimensional working model of the multienzyme complex of aminoacyl-tRNA synthetases based on electron microscopic placements of tRNA and proteins

It has become evident that the process of protein synthesis is performed by many cellular polypeptides acting in concert within the structural confines of protein complexes. In multicellular eukaryotes, one of these assemblies is a multienzyme complex composed of eight proteins that have aminoacyl-tRNA synthetase activities as well as three non-synthetase proteins (p43, p38, and p18) with diverse functions. This study uses electron microscopy and three-dimensional reconstruction to explore the arrangement of proteins and tRNA substrates within this "core" multisynthetase complex. Binding of unfractionated tRNA establishes that these molecules are widely distributed on the exterior of the structure. Binding of gold-labeled tRNA(Leu) places leucyl-tRNA synthetase and the bifunctional glutamyl-/prolyl-tRNA synthetase at the base of this asymmetric "V"-shaped particle. A stable cell line has been produced that incorporates hexahistidine-labeled p43 into the multisynthetase complex. Using a gold-labeled nickel-nitrilotriacetic acid probe, the polypeptides of the p43 dimer have been located along one face of the particle. The results of this and previous studies are combined into an initial three-dimensional working model of the multisynthetase complex. This is the first conceptualization of how the protein constituents and tRNA substrates are arrayed within the structural confines of this multiprotein assembly.     

Structure, dynamics and function of nuclear pore complexes

Nuclear pore complexes are large aqueous channels that penetrate the nuclear envelope, thereby connecting the nuclear interior with the cytoplasm. Until recently, these macromolecular complexes were viewed as static structures, the only function of which was to control the molecular trafficking between the two compartments. It has now become evident that this simplistic scenario is inaccurate and that nuclear pore complexes are highly dynamic multiprotein assemblies involved in diverse cellular processes ranging from the organization of the cytoskeleton to gene expression. In this review, we discuss the most recent developments in the nuclear-pore-complex field, focusing on the assembly, disassembly, maintenance and function of this macromolecular structure.     

Cooperative organization in a macromolecular complex

The mechanism of assembly of multiprotein complexes and the subsequent organization of activity are not well understood. Here we report the application of biophysical tools to investigate the relationship between structure and function in protein assemblies. We used as a model system the SCF(Skp2) complex that targets p27(Kip1) for ubiquitination and subsequent degradation; this process requires an adapter protein, Cks1. By dissecting the interactions between the different subunits we show that the properties of Cks1 are highly context dependent, and its activity is acquired only when the complex is fully assembled. The results provide insights into the central role of small adapters in macromolecular assembly and explain their high sequence conservation. Simultaneous and synergistic binding of multiple subunits in a complex provides the specificity and control required before the key cell-cycle regulator p27 is committed to degradation.     

Component X of mammalian pyruvate dehydrogenase complex: structural and functional relationship to the lipoate acetyltransferase (E2) component

The lipoate acetyltransferase (E2, Mr 70,000) and protein X (Mr 51,000) subunits of the bovine pyruvate dehydrogenase multienzyme complex (PDC) core assembly are antigenically distinct polypeptides. However comparison of the N-terminal amino acid sequence of the E2 and X polypeptides reveals significant homology between the two components. Selective tryptic release of the 14C-labelled acetylated lipoyl domains of E2 and protein X from native PDC generates stable, radiolabelled 34 and 15 kDa fragments, respectively. Thus, in contrast to E2 which contains two tandemly-arranged lipoyl domains, protein X appears to contain only a single lipoyl domain located at its N-terminus.     

Biomolecular analysis of elastic fibre molecules

Elastic fibres are macromolecular extracellular matrix assemblies that endow dynamic connective tissues such as arteries, lungs and skin with the property of elastic recoil. Here, we describe how we have purified elastic fibre molecules and then analysed them using a range of biochemical and biomolecular approaches. Such approaches have provided powerful insights into the complex hierarchical processes of extracellular matrix assembly. We outline molecular interaction and kinetics assays using Biacore, biophysical approaches such as multi-angle laser light scattering and analytical ultracentrifugation which provide information on molecular and macromolecular shape and mass in solution, the visualisation of molecules and assemblies using microscopy approaches such as atomic force microscopy and environmental scanning electron microscopy, and compositional analysis of macromolecular complexes using mass spectrometry. Data from these in vitro analytical approaches can be combined to develop powerful new models of elastic fibre assembly.     

Hepatitis C virus NS2 coordinates virus particle assembly through physical interactions with the E1-E2 glycoprotein and NS3-NS4A enzyme complexes

The hepatitis C virus (HCV) NS2 protein is essential for particle assembly, but its function in this process is unknown. We previously identified critical genetic interactions between NS2 and the viral E1-E2 glycoprotein and NS3-NS4A enzyme complexes. Based on these data, we hypothesized that interactions between these viral proteins are essential for HCV particle assembly. To identify interaction partners of NS2, we developed methods to site-specifically biotinylate NS2 in vivo and affinity capture NS2-containing protein complexes from virus-producing cells with streptavidin magnetic beads. By using these methods, we confirmed that NS2 physically interacts with E1, E2, and NS3 but did not stably interact with viral core or NS5A proteins. We further characterized these protein complexes by blue native polyacrylamide gel electrophoresis and identified ≈ 520-kDa and ≈ 680-kDa complexes containing E2, NS2, and NS3. The formation of NS2 protein complexes was dependent on coexpression of the viral p7 protein and enhanced by cotranslation of viral proteins as a polyprotein. Further characterization indicated that the glycoprotein complex interacts with NS2 via E2, and the pattern of N-linked glycosylation on E1 and E2 suggested that these interactions occur in the early secretory pathway. Importantly, several mutations that inhibited virus assembly were shown to inhibit NS2 protein complex formation, and NS2 was essential for mediating the interaction between E2 and NS3. These studies demonstrate that NS2 plays a central organizing role in HCV particle assembly by bringing together viral structural and nonstructural proteins.     

Macromolecular organization of the Yersinia pestis capsular F1 antigen: insights from time-of-flight mass spectrometry

Mass spectrometry has been used to examine the subunit interactions in the capsular F1 antigen from Yersinia pestis, the causative agent of the plague. Introducing the sample using nanoflow electrospray from solution conditions in which the protein remains in its native state and applying collisional cooling to minimize the internal energy of the ions, multiple subunit interactions have been maintained. This methodology revealed assemblies of the F1 antigen that correspond in mass to both 7-mers and 14-mers, consistent with interaction of two seven-membered units. The difference between the calculated masses and those measured experimentally for these higher-order oligomers was found to increase proportionately with the size of the complex. This is consistent with a solvent-filled central cavity maintained on association of the 7-mer to the 14-mer. The charge states of the ions show that an average of one and four surface accessible basic side-chains are involved in maintaining the interactions between the 7-mer units and neighboring subunits, respectively. Taken together, these findings provide new information about the stoichiometry and packing of the subunits involved in the assembly of the capsular antigen structure. More generally, the data show that the symmetry and packing of macromolecular complexes can be determined solely from mass spectrometry, without any prior knowledge of higher order structure     

Potential Regulatory Interactions of Escherichia coli RraA Protein with DEAD-box Helicases

Members of the DEAD-box family of RNA helicases contribute to virtually every aspect of RNA metabolism, in organisms from all domains of life. Many of these helicases are constituents of multicomponent assemblies, and their interactions with partner proteins within the complexes underpin their activities and biological function. In Escherichia coli the DEAD-box helicase RhlB is a component of the multienzyme RNA degradosome assembly, and its interaction with the core ribonuclease RNase E boosts the ATP-dependent activity of the helicase. Earlier studies have identified the regulator of ribonuclease activity A (RraA) as a potential interaction partner of both RNase E and RhlB. We present structural and biochemical evidence showing how RraA can bind to, and modulate the activity of RhlB and another E. coli DEAD-box enzyme, SrmB. Crystallographic structures are presented of RraA in complex with a portion of the natively unstructured C-terminal tail of RhlB at 2.8-Å resolution, and in complex with the C-terminal RecA-like domain of SrmB at 2.9 Å. The models suggest two distinct mechanisms by which RraA might modulate the activity of these and potentially other helicases.