Porphobilinogen synthase,the first source of Heme's asymmetry

Porphobilinogen is the monopyrrole precursor of all biological tetrapyrroles. The biosynthesis of porphobilinogen involves the asymmetric condensation of two molecules of 5-aminolevulinate and is carried out by the enzyme porphobilinogen synthase (PBGS), also known as 5-aminolevulinate dehydratase. This review documents what is known about the mechanism of the PBGS-catalyzed reaction. The metal ion constitutents of PBGS are of particular interest because PBGS is a primary target for the environmental toxin lead. Mammalian PBGS contains two zinc ions at each active site. Bacterial and plant PBGS use a third metal ion, magnesium, as an allosteric activator. In addition, some bacterial and plant PBGS may use magnesium in place of one or both of the zinc ions of mammalian PBGS. These phylogenetic variations in metal ion usage are described along with a proposed rationale for the evolutionary divergence in metal ion usage. Finally, I describe what is known about the structure of PBGS, an enzyme which has as yet eluded crystal structure determination.     

Pseudomonas aeruginosa contains a novel type V porphobilinogen synthase with no required catalytic metal ions.

Porphobilinogen synthases (PBGS) are metalloenzymes that catalyze the first common step in tetrapyrrole biosynthesis. The PBGS enzymes have previously been categorized into four types (I-IV) by the number of Zn(2+) and/or Mg(2+) utilized at three different metal binding sites termed A, B, and C. In this study Pseudomonas aeruginosa PBGS is found to bind only four Mg(2+) per octamer as determined by atomic absorption spectroscopy, in the presence or absence of substrate/product. This is the lowest number of bound metal ions yet found for PBGS where other enzymes bind 8-16 divalent ions. These four Mg(2+) allosterically stimulate a metal ion independent catalytic activity, in a fashion dependent upon both pH and K(+). The allosteric Mg(2+) of PBGS is located in metal binding site C, which is outside the active site. No evidence is found for metal binding to the potential high-affinity active site metal binding sites A and/or B. P. aeruginosa PBGS was investigated using Mn(2+) as an EPR probe for Mg(2+), and the active site was investigated using [3,5-(13)C]porphobilinogen as an NMR probe. The magnetic resonance data exclude the direct involvement of Mg(2+) in substrate binding and product formation. The combined data suggest that P. aeruginosa PBGS represents a new type V enzyme. Type V PBGS has the remarkable ability to synthesize porphobilinogen in a metal ion independent fashion. The total metal ion stoichiometry of only 4 per octamer suggests half-sites reactivity.     

Control of tetrapyrrole biosynthesis by alternate quaternary forms of porphobilinogen synthase

Porphobilinogen synthase (PBGS) catalyzes the first common step in the biosynthesis of tetrapyrroles (such as heme and chlorophyll). Although the predominant oligomeric form of this enzyme, as inferred from many crystal structures, is that of a homo-octamer, a rare human PBGS allele, F12L, reveals the presence of a hexameric form. Rearrangement of an N-terminal arm is responsible for this oligomeric switch, which results in profound changes in kinetic behavior. The structural transition between octamer and hexamer must proceed through an unparalleled equilibrium containing two different dimer structures. The allosteric magnesium, present in most PBGS, has a binding site in the octamer but not in the hexamer. The unprecedented structural rearrangement reported here relates to the allosteric regulation of PBGS and suggests that alternative PBGS oligomers may function in a magnesium-dependent regulation of tetrapyrrole biosynthesis in plants and some bacteria.     

Investigations on the metal switch region of human porphobilinogen synthase

Porphobilinogen synthase (PBGS) is an ancient and highly conserved protein that functions in the first common step in tetrapyrrole biosynthesis. The PBGS protein sequence contains a unique metal switch region that has been postulated to dictate an exclusive catalytic use of either zinc or magnesium, and perhaps also potassium. In some PBGS, the cysteines of the metal switch sequence DXCXCX(Y/F)X(3)G(H/Q)CG have been demonstrated to bind a catalytic zinc, and in other PBGS, the aspartic acid residues of the metal switch sequence DXALDX(Y/F)X(3)G(H/Q)DG have been postulated to bind a catalytically essential magnesium and/or potassium. The current work describes chimeric proteins that contain the aspartate-rich sequences of pea PBGS and Pseudomonas aeruginosa PBGS in place of the naturally occurring cysteine-rich sequence of human PBGS. The resultant chimeric PBGS proteins, peainhuman PBGS and psuinhuman PBGS, are substantially activated by both magnesium and potassium, but not by zinc. The specific activities of the chimeras are significantly lower than human PBGS. Detailed kinetic and inhibition data are presented for both chimeric proteins and are discussed in terms of this unique phylogenetic variation in metal ion usage. The identity of a basic residue, which is Arg221 in human PBGS, strictly correlates with the presence or absence of the cysteine-rich sequence. Those PBGS with the aspartate-rich metal switch sequence contain Lys in the analogous position. The R221K mutation was inserted into wild type and chimeric human PBGS and found to further reduce the activity of both, illustrating the subtle nature of the role of this residue.     

Redox and metal-regulated oligomeric state for human porphobilinogen synthase activation

The oligomeric state of human porphobilinogen synthase (PBGS) [EC.4.2.1.24] is homooctamer, which consists of conformationally heterogenous subunits in the tertiary structure under air-saturated conditions. When PBGS is activated by reducing agent with zinc ion, a reservoir zinc ion coordinated by Cys²²³ is transferred in the active center to be coordinated by Cys¹²², Cys¹²⁴, and Cys¹³² (Sawada et al. in J Biol Inorg Chem 10:199–207, 2005). The latter zinc ion serves as an electrophilic catalysis. In this study, we investigated a conformational change associated with the PBGS activation by reducing agent and zinc ion using analytical ultracentrifugation, negative staining electron microscopy, native PAGE, and enzyme activity staining. The results are in good agreement with our notion that the main component of PBGS is octamer with a few percent of hexamer and that the octamer changes spatial subunit arrangement upon reduction and further addition of zinc ion, accompanying decrease in f/f ₀. It is concluded that redox-regulated PBGS activation via cleavage of disulfide bonds among Cys¹²², Cys¹²⁴, and Cys¹³² and coordination with zinc ion is closely linked to change in the oligomeric state.     

Probing the oligomeric assemblies of pea porphobilinogen synthase by analytical ultracentrifugation

The enzyme porphobilinogen synthase (PBGS) can exist in different nonadditive homooligomeric assemblies, and under appropriate conditions, the distribution of these assemblies can respond to ligands such as metals or substrate. PBGS from most organisms was believed to be octameric until work on a rare allele of human PBGS revealed an alternate hexameric assembly, which is also available to the wild-type enzyme at elevated pH [Breinig, S., et al. (2003) Nat. Struct. Biol. 10, 757-763]. Herein, we establish that the distribution of pea PBGS quaternary structures also contains octamers and hexamers, using both sedimentation velocity and sedimentation equilibrium experiments. We report results in which the octamer dominates under purification conditions and discuss conditions that influence the octamer:hexamer ratio. As predicted by PBGS crystal structures from related organisms, in the absence of magnesium, the octameric assembly is significantly destabilized, and the oligomeric distribution is dominated largely by the hexameric assembly. Although the PBGS hexamer-to-octamer oligomeric rearrangement is well documented under some conditions, both assemblies are very stable (under AU conditions) in the time frame of our ultracentrifuge experiments.     

Kinetics and thermodynamics of the interchange of the morpheein forms of human porphobilinogen synthase

A morpheein is a homo-oligomeric protein that can adopt different nonadditive quaternary assemblies (morpheein forms) with different functionalities. The human porphobilinogen synthase (PBGS) morpheein forms are a high activity octamer, a low activity hexamer, and two structurally distinct dimer conformations. Conversion between hexamer and octamer involves dissociation to dimers, conformational change at the dimer level, followed by association to the alternate assembly. The current work promotes an alternative and novel view of the physiologically relevant dimeric structures, which are derived from the crystal structures, but are distinct from the asymmetric units of their crystal forms. Using a well characterized heteromeric system (WT+F12L; Tang, L. et al. (2005) J. Biol. Chem. 280, 15786-15793), extensive study of the human PBGS morpheein reequilibration process now reveals that the intervening dimers do not dissociate to monomers. The morpheein equilibria of wild type (WT) human PBGS are found to respond to changes in pH, PBGS concentration, and substrate turnover. Notably, the WT enzyme is predominantly an octamer at neutral pH, but increasing pH results in substantial conversion to lower order oligomers. Most significantly, the free energy of activation for the conversion of WT+F12L human PBGS heterohexamers to hetero-octamers is determined to be the same as that for the catalytic conversion of substrate to product by the octamer, remarkably suggesting a common rate-limiting step for both processes, which is postulated to be the opening/closing of the active site lid.     

The porphobilinogen synthase catalyzed reaction mechanism

Porphobilinogen synthase (PBGS) catalyzes the first common reaction in the biosynthesis of the tetrapyrroles, the asymmetric condensation of two molecules of delta-aminolevulinic acid to form porphobilinogen. There is a variable requirement for an essential active site zinc that necessitates consideration of PBGS as an enzyme that may exhibit phylogenetic diversity in its chemical reaction mechanism. Recent crystal structures suggest reaction mechanisms that involve two covalent Schiff base linkages between adjacent active site lysine residues and each of the two substrate molecules. The reaction appears to stall at a covalently bound almost-product intermediate that is poised for breakdown to product upon binding of a substrate molecule to an adjacent active site and a subsequent conformational change.     

A structural basis for half-of-the-sites metal binding revealed in Drosophila melanogaster porphobilinogen synthase

Porphobilinogen synthase (PBGS) proteins fall into several distinct groups with different metal ion requirements. Drosophila melanogaster porphobilinogen synthase (DmPBGS) is the first non-mammalian metazoan PBGS to be characterized. The sequence shows the determinants for two zinc binding sites known to be present in both mammalian and yeast PBGS, proteins that differ in the exhibition of half-of-the-sites metal binding. The pH-dependent activity of DmPBGS is uniquely affected by zinc. A tight binding catalytic zinc binds at 0.5/subunit with a Kd well below microm. A second inhibitory zinc exhibits a Kd of approximately 5 microm and appears to bind at a stoichiometry of 1/subunit. A molecular model of DmPBGS suggests that the inhibitory zinc is located at a subunit interface using Cys-219 and His-10 as ligands. Zinc binding to this previously unknown inhibitory site is proposed to inhibit opening of the active site lid. As predicted, the DmPBGS mutant H10F is active but is not inhibited by zinc. H10F binds a catalytic zinc at 0.5/subunit and binds a second nonessential and noninhibitory zinc at 0.5/subunit. This result reveals a structural basis for half-of-the-sites metal binding that is consistent with a reciprocating motion model for function of oligomeric PBGS.     

Single amino acid mutations alter the distribution of human porphobilinogen synthase quaternary structure isoforms (morpheeins)

Porphobilinogen synthase (PBGS) is an obligate oligomer that can exist in functionally distinct quaternary states of different stoichiometries, which are called morpheeins. The morpheein concept describes an ensemble of quaternary structure isoforms wherein different structures of the monomer dictate different multiplicities of the oligomer (Jaffe, E. K. (2005) Trends Biochem. Sci. 30, 490-497). Human PBGS assembles into long-lived morpheeins and has been shown to be capable of forming either a high activity octamer or a low activity hexamer (Breinig, S., Kervinen, J., Stith, L., Wasson, A. S., Fairman, R., Wlodawer, A., Zdanov, A., and Jaffe, E. K. (2003) Nat. Struct. Biol. 10, 757-763). All PBGS monomers contain an alphabeta-barrel domain and an N-terminal arm domain. The N-terminal arm structure varies among PBGS morpheeins, and the spatial relationship between the arm and the barrel dictates the different quaternary assemblies. We have analyzed the structures of human PBGS morpheeins for key interactions that would be predicted to affect the oligomeric assembly. Examples of individual mutations that shift assembly of human PBGS away from the native octamer are R240A and W19A. The alternate morpheeins of human PBGS variants R240A and W19A are chromatographically separable from each other and kinetically distinct; their structure and dynamics have been characterized by native gel electrophoresis, dynamic light scattering, and analytical ultracentrifugation. R240A assembles into a metastable hexamer, which can undergo a reversible conversion to the octamer in the presence of substrate. The metastable nature of the R240A hexamer supports the hypothesis that octameric and hexameric morpheeins of PBGS are very close in energy. W19A assembles into a mixture of dimers, which appear to be stable.     

Substrate-induced interconversion of protein quaternary structure isoforms

Human porphobilinogen synthase (PBGS) can exist in two dramatically different quaternary structure isoforms, which have been proposed to be in dynamic equilibrium. The quaternary structure isoforms of PBGS result from two alternative conformations of the monomer; one monomer structure assembles into a high activity octamer, whereas the other monomer structure assembles into a low activity hexamer. The kinetic behavior of these oligomers led to the hypothesis that turnover facilitates the interconversion of the oligomeric structures. The current work demonstrates that the interactions of ligands at the enzyme active site promote the structural interconversion between human PBGS quaternary structure isoforms, favoring formation of the octamer. This observation illustrates that the assembly and disassembly of oligomeric proteins can be facilitated by the protein motions that accompany enzymatic catalysis.     

High resolution crystal structure of a Mg2+-dependent porphobilinogen synthase.

Common to the biosynthesis of all known tetrapyrroles is the condensation of two molecules of 5-aminolevulinic acid to the pyrrole porphobilinogen catalyzed by the enzyme porphobilinogen synthase (PBGS). Two major classes of PBGS are known. Zn2+-dependent PBGSs are found in mammals, yeast and some bacteria including Escherichia coli, while Mg2+-dependent PBGSs are present mainly in plants and other bacteria. The crystal structure of the Mg2+-dependent PBGS from the human pathogen Pseudomonas aeruginosa in complex with the competitive inhibitor levulinic acid (LA) solved at 1.67 A resolution shows a homooctameric enzyme that consists of four asymmetric dimers. The monomers in each dimer differ from each other by having a "closed" and an "open" active site pocket. In the closed subunit, the active site is completely shielded from solvent by a well-defined lid that is partially disordered in the open subunit. A single molecule of LA binds to a mainly hydrophobic pocket in each monomer where it is covalently attached via a Schiff base to an active site lysine residue. Whereas no metal ions are found in the active site of both monomers, a single well-defined and highly hydrated Mg2+is present only in the closed form about 14 A away from the Schiff base forming nitrogen atom of the active site lysine. We conclude that the observed differences in the active sites of both monomers might be induced by Mg2+-binding to this remote site and propose a structure-based mechanism for this allosteric Mg2+in rate enhancement.     

Species-specific inhibition of porphobilinogen synthase by 4-oxosebacic acid

Porphobilinogen synthase (PBGS) catalyzes the condensation of two molecules of 5-aminolevulinic acid (ALA), an essential step in tetrapyrrole biosynthesis. 4-Oxosebacic acid (4-OSA) and 4,7-dioxosebacic acid (4,7-DOSA) are bisubstrate reaction intermediate analogs for PBGS. We show that 4-OSA is an active site-directed irreversible inhibitor for Escherichia coli PBGS, whereas human, pea, Pseudomonas aeruginosa, and Bradyrhizobium japonicum PBGS are insensitive to inhibition by 4-OSA. Some variants of human PBGS (engineered to resemble E. coli PBGS) have increased sensitivity to inactivation by 4-OSA, suggesting a structural basis for the specificity. The specificity of 4-OSA as a PBGS inhibitor is significantly narrower than that of 4,7-DOSA. Comparison of the crystal structures for E. coli PBGS inactivated by 4-OSA versus 4,7-DOSA shows significant variation in the half of the inhibitor that mimics the second substrate molecule (A-side ALA). Compensatory changes occur in the structure of the active site lid, which suggests that similar changes normally occur to accommodate numerous hybridization changes that must occur at C3 of A-side ALA during the PBGS-catalyzed reaction. A comparison of these with other PBGS structures identifies highly conserved active site water molecules, which are isolated from bulk solvent and implicated as proton acceptors in the PBGS-catalyzed reaction.     

Tracking the evolution of porphobilinogen synthase metal dependence in vitro

Metal ions are indispensable cofactors for chemical catalysis by a plethora of enzymes. Porphobilinogen synthases (PBGSs), which catalyse the second step of tetrapyrrole biosynthesis, are grouped according to their dependence on Zn(2+). Using site-directed mutagenesis, we embarked on transforming Zn(2+)-independent Pseudomonas aeruginosa PBGS into a Zn(2+)-dependent enzyme. Nine PBGS variants were generated by permutationally introducing three cysteine residues and a further two residues into the active site of the enzyme to match the homologous Zn(2+)-containing PBGS from Escherichia coli. Crystal structures of seven enzyme variants were solved to elucidate the nature of Zn(2+) coordination at high resolution. The three single-cysteine variants were invariably found to be enzymatically inactive and only one (D139C) was found to bind detectable amounts of Zn(2+). The double mutant A129C/D139C is enzymatically active and binds Zn(2+) in a tetrahedral coordination. Structurally and functionally it mimics mycobacterial PBGS, which bears an equivalent Zn(2+)-coordination site. The remaining two double mutants, without known natural equivalents, reveal strongly distorted tetrahedral Zn(2+)-binding sites. Variant A129C/D131C possesses weak PBGS activity while D131C/D139C is inactive. The triple mutant A129C/D131C/D139C, finally, displays an almost ideal tetrahedral Zn(2+)-binding geometry and a significant Zn(2+)-dependent enzymatic activity. Two additional amino acid exchanges further optimize the active site architecture towards the E.coli enzyme with an additional increase in activity. Our study delineates the potential evolutionary path between Zn(2+)-free and Zn(2+)-dependent PBGS enyzmes showing that the rigid backbone of PBGS enzymes is an ideal framework to create or eliminate metal dependence through a limited number of amino acid exchanges.     

Mechanistic implications of mutations to the active site lysine of porphobilinogen synthase

Porphobilinogen synthase (PBGS) is a homo-octameric protein that catalyzes the complex asymmetric condensation of two molecules of 5-aminolevulinic acid (ALA). The only characterized intermediate in the PBGS-catalyzed reaction is a Schiff base that forms between the first ALA that binds and a conserved lysine, which in Escherichia coli PBGS is Lys-246 and in human PBGS is Lys-252. In this study, E. coli PBGS mutants K246H, K246M, K246W, K246N, and K246G and human PBGS mutant K252G were characterized. Alterations to this lysine result in a disabled but not totally inactive protein suggesting an alternate mechanism in which proximity and orientation are major catalytic devices. (13)C NMR studies of [3,5-(13)C]porphobilinogen bound at the active sites of the E. coli PBGS and the mutants show only minor chemical shift differences, i.e. environmental alterations. Mammalian PBGS is established to have four functional active sites, whereas the crystal structure of E. coli PBGS shows eight spatially distinct and structurally equivalent subunits. Biochemical data for E. coli PBGS have been interpreted to support both four and eight active sites. A unifying hypothesis is that formation of the Schiff base between this lysine and ALA triggers a conformational change that results in asymmetry. Product binding studies with wild-type E. coli PBGS and K246G demonstrate that both bind porphobilinogen at four per octamer although the latter cannot form the Schiff base from substrate. Thus, formation of the lysine to ALA Schiff base is not required to initiate the asymmetry that results in half-site reactivity.     

The crystal structure of R-specific alcohol dehydrogenase from Lactobacillus brevis suggests the structural basis of its metal dependency

The crystal structure of the apo-form of an R-specific alcohol dehydrogenase from Lactobacillus brevis (LB-RADH) was solved and refined to 1.8A resolution. LB-RADH is a member of the short-chain dehydrogenase/reductase (SDR) enyzme superfamily. It is a homotetramer with 251 amino acid residues per subunit and uses NADP(H) as co-enzyme. NADPH and the substrate acetophenone were modelled into the active site. The enantiospecificity of the enzyme can be explained on the basis of the resulting hypothetical ternary complex. In contrast to most other SDR enzymes, the catalytic activity of LB-RADH depends strongly on the binding of Mg(2+). Mg(2+) removal by EDTA inactivates the enzyme completely. In the crystal structure, the Mg(2+)-binding site is well defined. The ion has a perfect octahedral coordination sphere and occupies a special position concerning crystallographic and molecular point symmetry, meaning that each RADH tetramer contains two magnesium ions. The magnesium ion is no direct catalytic cofactor. However, it is structurally coupled to the putative C-terminal hinge of the substrate-binding loop and, via an extended hydrogen bonding network, to some side-chains forming the substrate binding region. Therefore, the presented structure of apo-RADH provides plausible explanations for the metal dependence of the enzyme.     

A Triple Mutant in the Ω-loop of TEM-1 β-Lactamase Changes the Substrate Profile via a Large Conformational Change and an Altered General Base for Catalysis

β-Lactamases are bacterial enzymes that hydrolyze β-lactam antibiotics. TEM-1 is a prevalent plasmid-encoded β-lactamase in Gram-negative bacteria that efficiently catalyzes the hydrolysis of penicillins and early cephalosporins but not oxyimino-cephalosporins. A previous random mutagenesis study identified a W165Y/E166Y/P167G triple mutant that displays greatly altered substrate specificity with increased activity for the oxyimino-cephalosporin, ceftazidime, and decreased activity toward all other β-lactams tested. Surprisingly, this mutant lacks the conserved Glu-166 residue critical for enzyme function. Ceftazidime contains a large, bulky side chain that does not fit optimally in the wild-type TEM-1 active site. Therefore, it was hypothesized that the substitutions in the mutant expand the binding site in the enzyme. To investigate structural changes and address whether there is an enlargement in the active site, the crystal structure of the triple mutant was solved to 1.44 Å. The structure reveals a large conformational change of the active site Ω-loop structure to create additional space for the ceftazidime side chain. The position of the hydroxyl group of Tyr-166 and an observed shift in the pH profile of the triple mutant suggests that Tyr-166 participates in the hydrolytic mechanism of the enzyme. These findings indicate that the highly conserved Glu-166 residue can be substituted in the mechanism of serine β-lactamases. The results reveal that the robustness of the overall β-lactamase fold coupled with the plasticity of an active site loop facilitates the evolution of enzyme specificity and mechanism.     

Plastid-associated Porphobilinogen Synthase from Toxoplasma gondii: KINETIC AND STRUCTURAL PROPERTIES VALIDATE THERAPEUTIC POTENTIAL*

Apicomplexan parasites (including Plasmodium spp. and Toxoplasma gondii) employ a four-carbon pathway for de novo heme biosynthesis, but this pathway is distinct from the animal/fungal C4 pathway in that it is distributed between three compartments: the mitochondrion, cytosol, and apicoplast, a plastid acquired by secondary endosymbiosis of an alga. Parasite porphobilinogen synthase (PBGS) resides within the apicoplast, and phylogenetic analysis indicates a plant origin. The PBGS family exhibits a complex use of metal ions (Zn²⁺ and Mg²⁺) and oligomeric states (dimers, hexamers, and octamers). Recombinant T. gondii PBGS (TgPBGS) was purified as a stable ∼320-kDa octamer, and low levels of dimers but no hexamers were also observed. The enzyme displays a broad activity peak (pH 7–8.5), with a K_m for aminolevulinic acid of ∼150 μm and specific activity of ∼24 μmol of porphobilinogen/mg of protein/h. Like the plant enzyme, TgPBGS responds to Mg²⁺ but not Zn²⁺ and shows two Mg²⁺ affinities, interpreted as tight binding at both the active and allosteric sites. Unlike other Mg²⁺-binding PBGS, however, metal ions are not required for TgPBGS octamer stability. A mutant enzyme lacking the C-terminal 13 amino acids distinguishing parasite PBGS from plant and animal enzymes purified as a dimer, suggesting that the C terminus is required for octamer stability. Parasite heme biosynthesis is inhibited (and parasites are killed) by succinylacetone, an active site-directed suicide substrate. The distinct phylogenetic, enzymatic, and structural features of apicomplexan PBGS offer scope for developing selective inhibitors of the parasite enzyme based on its quaternary structure characteristics.     

Substrate Binding Mechanism of a Type I Extradiol Dioxygenase

A meta-cleavage pathway for the aerobic degradation of aromatic hydrocarbons is catalyzed by extradiol dioxygenases via a two-step mechanism: catechol substrate binding and dioxygen incorporation. The binding of substrate triggers the release of water, thereby opening a coordination site for molecular oxygen. The crystal structures of AkbC, a type I extradiol dioxygenase, and the enzyme substrate (3-methylcatechol) complex revealed the substrate binding process of extradiol dioxygenase. AkbC is composed of an N-domain and an active C-domain, which contains iron coordinated by a 2-His-1-carboxylate facial triad motif. The C-domain includes a β-hairpin structure and a C-terminal tail. In substrate-bound AkbC, 3-methylcatechol interacts with the iron via a single hydroxyl group, which represents an intermediate stage in the substrate binding process. Structure-based mutagenesis revealed that the C-terminal tail and β-hairpin form part of the substrate binding pocket that is responsible for substrate specificity by blocking substrate entry. Once a substrate enters the active site, these structural elements also play a role in the correct positioning of the substrate. Based on the results presented here, a putative substrate binding mechanism is proposed.     

Insights into diterpene cyclization from structure of bifunctional abietadiene synthase from Abies grandis

Abietadiene synthase from Abies grandis (AgAS) is a model system for diterpene synthase activity, catalyzing class I (ionization-initiated) and class II (protonation-initiated) cyclization reactions. Reported here is the crystal structure of AgAS at 2.3 Å resolution and molecular dynamics simulations of that structure with and without active site ligands. AgAS has three domains (α, β, and γ). The class I active site is within the C-terminal α domain, and the class II active site is between the N-terminal γ and β domains. The domain organization resembles that of monofunctional diterpene synthases and is consistent with proposed evolutionary origins of terpene synthases. Molecular dynamics simulations were carried out to determine the effect of substrate binding on enzymatic structure. Although such studies of the class I active site do lead to an enclosed substrate-Mg²⁺ complex similar to that observed in crystal structures of related plant enzymes, it does not enforce a single substrate conformation consistent with the known product stereochemistry. Simulations of the class II active site were more informative, with observation of a well ordered external loop migration. This “loop-in” conformation not only limits solvent access but also greatly increases the number of conformational states accessible to the substrate while destabilizing the nonproductive substrate conformation present in the “loop-out” conformation. Moreover, these conformational changes at the class II active site drive the substrate toward the proposed transition state. Docked substrate complexes were further assessed with regard to the effects of site-directed mutations on class I and II activities.