Berta M. Martins

Radical-mediated dehydration reactions in anaerobic bacteria

Abstract Most dehydratases catalyse the elimination of water from β-hydroxy ketones, β-hydroxy carboxylic acids or β-hydroxyacyl-CoA. The electron-withdrawing carbonyl functionalities acidify the α-hydrogens to enable their removal by basic amino acid side chains. Anaerobic bacteria, however, ferment amino acids via α- or γ-hydroxyacyl-CoA, dehydrations of which involve the abstraction of a β-hydrogen, which is ostensibly non-acidic (pK ca. 40). Evidence is accumulating that β-hydrogens are acidified via transient conversion of the CoA derivatives to enoxy radicals by one-electron transfers, which decrease the pK to 14. The dehydrations of (R)-2-hydroxyacyl-CoA to (E)-2-enoyl-CoA are catalysed by heterodimeric [4Fe-4S]-containing dehydratases, which require reductive activation by an ATP-dependent one-electron transfer mediated by a homodimeric protein with a [4Fe-4S] cluster between the two subunits. The electron is further transferred to the substrate, yielding a ketyl radical anion, which expels the hydroxyl group and forms an enoxy radical. The dehydration of 4-hydroxybutyryl-CoA to crotonyl-CoA involves a similar mechanism, in which the ketyl radical anion is generated by one-electron oxidation. The structure of the FAD- and [4Fe-4S]-containing homotetrameric dehydratase is related to that of acyl-CoA dehydrogenases, suggesting a radical-based mechanism for both flavoproteins.

Structural Basis for a Kolbe-Type Decarboxylation Catalyzed by a Glycyl Radical Enzyme.

4-Hydroxyphenylacetate decarboxylase is a [4Fe-4S] cluster containing glycyl radical enzyme proposed to use a glycyl/thiyl radical dyad to catalyze the last step of tyrosine fermentation in clostridia. The decarboxylation product p-cresol (4-methylphenol) is a virulence factor of the human pathogen Clostridium difficile . Here we describe the crystal structures at 1.75 and 1.81 Å resolution of substrate-free and substrate-bound 4-hydroxyphenylacetate decarboxylase from the related Clostridium scatologenes . The structures show a (βγ)(4) tetramer of heterodimers composed of a catalytic β-subunit harboring the putative glycyl/thiyl dyad and a distinct small γ-subunit with two [4Fe-4S] clusters at 40 Å distance from the active site. The γ-subunit comprises two domains displaying pseudo-2-fold symmetry that are structurally related to the [4Fe-4S] cluster-binding scaffold of high-potential iron-sulfur proteins. The N-terminal domain coordinates one cluster with one histidine and three cysteines, and the C-terminal domain coordinates the second cluster with four cysteines. Whereas the C-terminal cluster is buried in the βγ heterodimer interface, the N-terminal cluster is not part of the interface. The previously postulated decarboxylation mechanism required the substrates hydroxyl group in the vicinity of the active cysteine residue. In contrast to expectation, the substrate-bound state shows a direct interaction between the substrates carboxyl group and the active site Cys503, while His536 and Glu637 at the opposite side of the active site pocket anchor the hydroxyl group. This state captures a possible catalytically competent complex and suggests a Kolbe-type decarboxylation for p-cresol formation.

Structural basis for stereo-specific catalysis in NAD+-dependent (R)-2-hydroxyglutarate dehydrogenase from Acidaminococcus fermentans

NAD+‐dependent (R)‐2‐hydroxyglutarate dehydrogenase (HGDH) catalyses the reduction of 2‐oxoglutarate to (R)‐2‐hydroxyglutarate and belongs to the d‐2‐hydroxyacid NAD+‐dependent dehydrogenase (d‐2‐hydroxyacid dehydrogenase) protein family. Its crystal structure was determined by phase combination to 1.98 Å resolution. Structure–function relationships obtained by the comparison of HGDH with other members of the d‐2‐hydroxyacid dehydrogenase family give a chemically satisfying view of the substrate stereoselectivity and catalytic requirements for the hydride transfer reaction. A model for substrate recognition and turnover is discussed. The HGDH active site architecture is structurally optimized to recognize and bind the negatively charged substrate 2‐oxoglutarate. The structural position of the side chain of Arg52, and its counterparts in other family members, strongly correlates with substrate specificity towards substitutions at the C3 atom (linear or branched substrates). Arg235 interacts with the substrates α‐carboxylate and carbonyl groups, having a dual role in both substrate binding and activation, and the γ‐carboxylate group can dock at an arginine cluster. The proton‐relay system built up by Glu264 and His297 permits His297 to act as acid–base catalyst and the 4Re‐hydrogen from NADH is transferred as hydride to the carbonyl group Si‐face leading to the formation of the correct enantiomer (R)‐2‐hydroxyglutarate.

Catalytic Mechanism of the Glycyl Radical Enzyme 4-Hydroxyphenylacetate Decarboxylase from Continuum Electrostatic and QC/MM Calculations

Using continuum electrostatics and QC/MM calculations, we investigate the catalytic cycle of the glycyl radical enzyme 4-hydroxyphenylacetate decarboxylase, an enzyme involved in the fermentative production of p-cresol from tyrosine in clostridia. On the basis of our calculations, we propose a five-step mechanism for the reaction. In the first step, the substrate 4-hydroxyphenylacetate is activated by an unusual concerted abstraction of an electron and a proton. Namely, Cys503 radical abstracts an electron from the substrate and Glu637 abstracts a proton. Thus in total, a hydrogen atom is abstracted from the substrate. In the second step, the carboxylic group readily splits off from the phenoxy-acetate radical anion to give carbon dioxide. This decarboxylation step is coupled to a proton transfer from Glu637 back to the phenolic hydroxyl group which leads to a p-hydroxybenzyl radical. The remaining steps of the reaction involve a rotation of the Cys503 side chain followed by a proton transfer from Glu505 to Cys503 and a hydrogen atom transfer from Cys503 to the p-hydroxybenzyl radical to form p-cresol. The calculated mechanism agrees with experimental data suggesting that both Cys503 and Glu637 are essential for the catalytic function of 4-hydroxyphenylacetate decarboxylase and that the substrate requires a hydroxyl group in para-position to the acetate moiety.

Zero-field splittings in metHb and metMb with aquo and fluoro ligands: a FD-FT THz-EPR study

A combined X-band and frequency-domain Fourier-transform THz electron paramagnetic resonance (FD-FT THz-EPR) approach has been employed to determine heme Fe(III) S = 5/2 zero-field splitting (ZFS) parameters of frozen metHb and metMb solutions, both with fluoro and aquo ligands. Frequency-domain EPR measurements have been carried out by an improved synchrotron-based FD-FT THz-EPR spectrometer. ZFS has been determined by field dependence of spin transitions within the mS = ±1/2 manifold, for all four protein systems, and by zero-field spin transitions between mS = ±1/2 and mS = ±3/2 levels, for metHb and metMb flouro-states. FD-FT THz-EPR data were simulated with a novel numerical routine based on Easyspin, which allows now for direct comparison of EPR spectra in field and frequency domain. We found purely axial ZFSs of D = 5.0(1) cm−1 (flouro-metMb), D = 9.2(4) cm−1 (aquo-metMb), D = 5.1(1) cm−1 (flouro-metHB) and D = 10.4(2) cm−1 (aquo-metHb).

4-Hydroxyphenylacetate decarboxylase activating enzyme catalyses a classical S-adenosylmethionine reductive cleavage reaction

Abstract4-Hydroxyphenylacetate decarboxylase (4Hpad) is an Fe/S cluster containing glycyl radical enzyme (GRE), which catalyses the last step of tyrosine fermentation in clostridia, generating the bacteriostatic p-cresol. The respective activating enzyme (4Hpad-AE) displays two cysteine-rich motifs in addition to the classical S-adenosylmethionine (SAM) binding cluster (RS cluster) motif. These additional motifs are also present in other glycyl radical activating enzymes (GR-AE) and it has been postulated that these orthologues may use an alternative SAM homolytic cleavage mechanism, generating a putative 3-amino-3-carboxypropyl radical and 5′-deoxy-5′-(methylthio)adenosine but not a 5′-deoxyadenosyl radical and methionine. 4Hpad-AE produced from a codon-optimized synthetic gene binds a maximum of two [4Fe–4S]2+/+ clusters as revealed by EPR and Mössbauer spectroscopy. The enzyme only catalyses the turnover of SAM under reducing conditions, and the reaction products were identified as 5′-deoxyadenosine (quenched form of 5′-deoxyadenosyl radical) and methionine. We demonstrate that the 5′-deoxyadenosyl radical is the activating agent for 4Hpad through p-cresol formation and correlation between the production of 5′-deoxyadenosine and the generation of glycyl radical in 4Hpad. Therefore, we conclude that 4Hpad-AE catalyses a classical SAM-dependent glycyl radical formation as reported for GR-AE without auxiliary clusters. Our observation casts doubt on the suggestion that GR-AE containing auxiliary clusters catalyse the alternative cleavage reaction detected for glycerol dehydratase activating enzyme.

Structure and Function of Benzylsuccinate Synthase and Related Fumarate-Adding Glycyl Radical Enzymes

The pathway of anaerobic toluene degradation is initiated by a remarkable radical-type enantiospecific addition of the chemically inert methyl group to the double bond of a fumarate cosubstrate to yield (R)-benzylsuccinate as the first intermediate, as catalyzed by the glycyl radical enzyme benzylsuccinate synthase. In recent years, it has become clear that benzylsuccinate synthase is the prototype enzyme of a much larger family of fumarate-adding enzymes, which play important roles in the anaerobic metabolism of further aromatic and even aliphatic hydrocarbons. We present an overview on the biochemical properties of benzylsuccinate synthase, as well as its recently solved structure, and present the results of an initial structure-based modeling study on the reaction mechanism. Moreover, we compare the structure of benzylsuccinate synthase with those predicted for different clades of fumarate-adding enzymes, in particular the paralogous enzymes converting p-cresol, 2-methylnaphthalene or n-alkanes.

Determinants of substrate specificity and biochemical properties of the sn-glycerol-3-phosphate ATP binding cassette transporter (UgpB-AEC2 ) of Escherichia coli.

Under phosphate starvation conditions, Escherichia coli can utilize sn‐glycerol‐3‐phosphate (G3P) and G3P diesters as phosphate source when transported by an ATP binding cassette importer composed of the periplasmic binding protein, UgpB, the transmembrane subunits, UgpA and UgpE, and a homodimer of the nucleotide binding subunit, UgpC. The current knowledge on the Ugp transporter is solely based on genetic evidence and transport assays using intact cells. Thus, we set out to characterize its properties at the level of purified protein components. UgpB was demonstrated to bind G3P and glycerophosphocholine with dissociation constants of 0.68 ± 0.02 μM and 5.1 ± 0.3 μM, respectively, while glycerol‐2‐phosphate (G2P) is not a substrate. The crystal structure of UgpB in complex with G3P was solved at 1.8 Å resolution and revealed the interaction with two tryptophan residues as key to the preferential binding of linear G3P in contrast to the branched G2P. Mutational analysis validated the crucial role of Trp‐169 for G3P binding. The purified UgpAEC2 complex displayed UgpB/G3P‐stimulated ATPase activity in proteoliposomes that was neither inhibited by phosphate nor by the signal transducing protein PhoU or the phosphodiesterase UgpQ. Furthermore, a hybrid transporter composed of MalFG–UgpC could be functionally reconstituted while a UgpAE–MalK complex was unstable.

Photoactivatable mussel-based underwater adhesive proteins by an expanded genetic code

Marine mussels exhibit potent underwater adhesion abilities under hostile conditions by employing 3,4‐dihydroxyphenylalanine (DOPA)‐rich mussel adhesive proteins (MAPs). However, their recombinant production is a major biotechnological challenge. Herein, a novel strategy based on genetic code expansion has been developed by engineering efficient aminoacyl‐transfer RNA synthetases (aaRSs) for the photocaged noncanonical amino acid ortho‐nitrobenzyl DOPA (ONB‐DOPA). The engineered ONB‐DOPARS enables in vivo production of MAP type 5 site‐specifically equipped with multiple instances of ONB‐DOPA to yield photocaged, spatiotemporally controlled underwater adhesives. Upon exposure to UV light, these proteins feature elevated wet adhesion properties. This concept offers new perspectives for the production of recombinant bioadhesives.

Structure and Function of 4-Hydroxyphenylacetate Decarboxylase and Its Cognate Activating Enzyme.

4-Hydroxyphenylacetate decarboxylase (4Hpad) is the prototype of a new class of Fe-S cluster-dependent glycyl radical enzymes (Fe-S GREs) acting on aromatic compounds. The two-enzyme component system comprises a decarboxylase responsible for substrate conversion and a dedicated activating enzyme (4Hpad-AE). The decarboxylase uses a glycyl/thiyl radical dyad to convert 4-hydroxyphenylacetate into p-cresol (4-methylphenol) by a biologically unprecedented Kolbe-type decarboxylation. In addition to the radical dyad prosthetic group, the decarboxylase unit contains two [4Fe-4S] clusters coordinated by an extra small subunit of unknown function. 4Hpad-AE reductively cleaves S-adenosylmethionine (SAM or AdoMet) at a site-differentiated [4Fe-4S]2+/+ cluster (RS cluster) generating a transient 5′-deoxyadenosyl radical that produces a stable glycyl radical in the decarboxylase by the abstraction of a hydrogen atom. 4Hpad-AE binds up to two auxiliary [4Fe-4S] clusters coordinated by a ferredoxin-like insert that is C-terminal to the RS cluster-binding motif. The ferredoxin-like domain with its two auxiliary clusters is not vital for SAM-dependent glycyl radical formation in the decarboxylase, but facilitates a longer lifetime for the radical. This review describes the 4Hpad and cognate AE families and focuses on the recent advances and open questions concerning the structure, function and mechanism of this novel Fe-S-dependent class of GREs.