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

A potent and durable malaria transmission-blocking vaccine designed from a single-component 60-copy Pfs230D1 nanoparticle

Malaria transmission-blocking vaccines (TBVs) reduce disease transmission by breaking the continuous cycle of infection between the human host and the mosquito vector. Domain 1 (D1) of Pfs230 is a leading TBV candidate and comprises the majority of transmission-reducing activity (TRA) elicited by Pfs230. Here we show that the fusion of Pfs230D1 to a 60-copy multimer of the catalytic domain of dihydrolipoyl acetyltransferase protein (E2p) results in a single-component nanoparticle composed of 60 copies of the fusion protein with high stability, homogeneity, and production yields. The nanoparticle presents a potent human transmission-blocking epitope within Pfs230D1, indicating the antigen is correctly oriented on the surface of the nanoparticle. Two vaccinations of New Zealand White rabbits with the Pfs230D1 nanoparticle elicited a potent and durable antibody response with high TRA when formulated in two distinct adjuvants suitable for translation to human use. This single-component nanoparticle vaccine may play a key role in malaria control and has the potential to improve production pipelines and the cost of manufacturing of a potent and durable TBV.

In vitro reconstitution and characterization of pyruvate dehydrogenase and 2-oxoglutarate dehydrogenase hybrid complex from Corynebacterium glutamicum

Pyruvate dehydrogenase (PDH) and 2‐oxoglutarate dehydrogenase (ODH) are critical enzymes in central carbon metabolism. In Corynebacterium glutamicum, an unusual hybrid complex consisting of CgE1p (thiamine diphosphate‐dependent pyruvate dehydrogenase, AceE), CgE2 (dihydrolipoamide acetyltransferase, AceF), CgE3 (dihydrolipoamide dehydrogenase, Lpd), and CgE1o (thiamine diphosphate‐dependent 2‐oxoglutarate dehydrogenase, OdhA) has been suggested. Here, we elucidated that the PDH‐ODH hybrid complex in C. glutamicum probably consists of six copies of CgE2 in its core, which is rather compact compared with PDH and ODH in other microorganisms that have twenty‐four copies of E2. We found that CgE2 formed a stable complex with CgE3 (CgE2‐E3 subcomplex) in vitro, hypothetically comprised of two CgE2 trimers and four CgE3 dimers. We also found that CgE1o exists mainly as a hexamer in solution and is ready to form an active ODH complex when mixed with the CgE2‐E3 subcomplex. Our in vitro reconstituted system showed CgE1p‐ and CgE1o‐dependent inhibition of ODH and PDH, respectively, actively supporting the formation of the hybrid complex, in which both CgE1p and CgE1o associate with a single CgE2‐E3. In gel filtration chromatography, all the subunits of CgODH were eluted in the same fraction, whereas CgE1p was eluted separately from CgE2‐E3, suggesting a weak association of CgE1p with CgE2 compared with that of CgE1o. This study revealed the unique molecular architecture of the hybrid complex from C. glutamicum and the compact‐sized complex would provide an advantage to determine the whole structure of the unusual hybrid complex.

Swinging arms and swinging domains in multifunctional enzymes: catalytic machines for multistep reactions

Multistep chemical reactions are increasingly seen as important in a growing number of complex biotransformations. Covalently attached prosthetic groups or swinging arms, and their associated protein domains, are essential to the mechanisms of active-site coupling and substrate channeling in a number of the multifunctional enzyme systems responsible. The protein domains, for which the posttranslational machinery in the cell is highly specific, are crucially important, contributing to the processes of molecular recognition that define and protect the substrates and the catalytic intermediates. The domains have novel folds and move by virtue of conformationally flexible linker regions that tether them to other components of their respective multienzyme complexes. Structural and mechanistic imperatives are becoming apparent as the assembly pathways and the coupling of multistep reactions catalyzed by these dauntingly complex molecular machines are unraveled.

Competitive interaction of component enzymes with the peripheral subunit-binding domain of the pyruvate dehydrogenase multienzyme complex of Bacillus stearothermophilus: kinetic analysis using surface plasmon resonance detection

The interactions of the peripheral enzymes (E1, a pyruvate decarboxylase, and E3, dihydrolipoyl dehydrogenase) with the core component (E2, dihydrolipoyl acetyltransferase) of the pyruvate dehydrogenase (PDH) multienzyme complex of Bacillus stearothermophilus have been analyzed using a biosensor based on surface plasmon resonance detection. A recombinant di-domain (lipoyl domain plus peripheral subunit-binding domain) from E2 was attached to the biosensor chip by means of the pendant lipoyl group. The dissociation constant (Kd) for the complex between the peripheral subunit-binding domain and E3 (5.8 x 10(-10) M) was found to be almost twice that for the complex with E1 (3.24 x 10(-10) M). This was due to differences in the rate constants for dissociation (kdiss); these were 1.06 x 10(-3) and 1.87 x 10(-3) s-1 for the complexes with E1 and E3, respectively, whereas the rate constants for association (kass) were identical (3.26 x 10(6) M-1 s-1). Separate studies using non-denaturing polyacrylamide gel electrophoresis confirmed the difference in affinity and demonstrated that E1 can rapidly displace E3 from an E3-di-domain complex and vice versa. The peripheral subunit-binding domain showed no detectable interaction with the E1 alpha subunit of E1 (alpha 2 beta 2) but exhibited a strong affinity for E1 beta (Kd = 8.5 x 10(-9) M), confirming that the E1 beta subunit is responsible for binding E1 to E2. These measurements introduce new features of potential importance into the assembly and mechanism of the multienzyme complex.

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.