Gregory A. Hunter

Pre-steady-state Reaction of 5-Aminolevulinate Synthase EVIDENCE FOR A RATE-DETERMINING PRODUCT RELEASE

5-Aminolevulinate synthase (ALAS) is the first enzyme of the heme biosynthetic pathway in non-plant eukaryotes and the α-subclass of purple bacteria. The pyridoxal 5′-phosphate cofactor at the active site undergoes changes in absorptive properties during substrate binding and catalysis that have allowed us to study the kinetics of these reactions spectroscopically. Rapid scanning stopped-flow experiments of murine erythroid 5-aminolevulinate synthase demonstrate that reaction with glycine plus succinyl-CoA results in a pre-steady-state burst of quinonoid intermediate formation. Thus, a step following binding of substrates and initial quinonoid intermediate formation is rate-determining. The steady-state spectrum of the enzyme is similar to that formed in the presence of 5-aminolevulinate, suggesting that release of this product limits the overall rate. Reaction of either glycine or 5-aminolevulinate with ALAS is slow (k f = 0.15 s−1) and approximatesk cat. The rate constant for reaction with glycine is increased at least 90-fold in the presence of succinyl-CoA and most likely represents a slow conformational change of the enzyme that is accelerated by succinyl-CoA. The slow rate of reaction of 5-aminolevulinate with ALAS is 5-aminolevulinate-independent, suggesting that it also represents a slow isomerization of the enzyme. Reaction of succinyl-CoA with the enzyme-glycine complex to form a quinonoid intermediate is a biphasic process and may be irreversible. Taken together, the data suggest that turnover is limited by release of 5-aminolevulinate or a conformational change associated with 5-aminolevulinate release.

Transient Kinetic Studies Support Refinements to the Chemical and Kinetic Mechanisms of Aminolevulinate Synthase

5-Aminolevulinate synthase catalyzes the pyridoxal 5′-phosphate-dependent condensation of glycine and succinyl-CoA to produce carbon dioxide, CoA, and 5-aminolevulinate, in a reaction cycle involving the mechanistically unusual successive cleavage of two amino acid substrate α-carbon bonds. Single and multiple turnover rapid scanning stopped-flow experiments have been conducted from pH 6.8–9.2 and 5–35 °C, and the results, interpreted within the framework of the recently solved crystal structures, allow refined characterization of the central kinetic and chemical steps of the reaction cycle. Quinonoid intermediate formation occurs with an apparent pKa of 7.7 ± 0.1, which is assigned to His-207 acid-catalyzed decarboxylation of the α-amino-β-ketoadipate intermediate to form an enol that is in rapid equilibrium with the 5-aminolevulinate-bound quinonoid species. Quinonoid intermediate decay occurs in two kinetic steps, the first of which is acid-catalyzed with a pKa of 8.1 ± 0.1, and is assigned to protonation of the enol by Lys-313 to generate the product-bound external aldimine. The second step of quinonoid decay defines kcat and is relatively pH-independent and is assigned to opening of the active site loop to allow ALA dissociation. The data support important refinements to both the chemical and kinetic mechanisms and indicate that 5-aminolevulinate synthase operates under the stereoelectronic control predicted by Dunathans hypothesis.

Metal Ion Substrate Inhibition of Ferrochelatase

Ferrochelatase catalyzes the insertion of ferrous iron into protoporphyrin IX to form heme. Robust kinetic analyses of the reaction mechanism are complicated by the instability of ferrous iron in aqueous solution, particularly at alkaline pH values. At pH 7.00 the half-life for spontaneous oxidation of ferrous ion is approximately 2 min in the absence of metal complexing additives, which is sufficient for direct comparisons of alternative metal ion substrates with iron. These analyses reveal that purified recombinant ferrochelatase from both murine and yeast sources inserts not only ferrous iron but also divalent cobalt, zinc, nickel, and copper into protoporphyrin IX to form the corresponding metalloporphyrins but with considerable mechanistic variability. Ferrous iron is the preferred metal ion substrate in terms of apparent kcat and is also the only metal ion substrate not subject to severe substrate inhibition. Substrate inhibition occurs in the order Cu2+ > Zn2+ > Co2+ > Ni2+ and can be alleviated by the addition of metal complexing agents such as β-mercaptoethanol or imidazole to the reaction buffer. These data indicate the presence of two catalytically significant metal ion binding sites that may coordinately regulate a selective processivity for the various potential metal ion substrates.

Targeting the Active Site Gate to Yield Hyperactive Variants of 5-Aminolevulinate Synthase

The rate of porphyrin biosynthesis in mammals is controlled by the activity of the pyridoxal 5′-phosphate-dependent enzyme 5-aminolevulinate synthase (EC 2.3.1.37). Based on the postulate that turnover in this enzyme is controlled by conformational dynamics associated with a highly conserved active site loop, we constructed a variant library by targeting imperfectly conserved noncatalytic loop residues and examined the effects on product and porphyrin production. Functional loop variants of the enzyme were isolated via genetic complementation in Escherichia coli strain HU227. Colony porphyrin fluorescence varied widely when bacterial cells harboring the loop variants were grown on inductive media; this facilitated identification of clones encoding unusually active enzyme variants. Nine loop variants leading to high in vivo porphyrin production were purified and characterized kinetically. Steady state catalytic efficiencies for the two substrates were increased by up to 100-fold. Presteady state single turnover reaction data indicated that the second step of quinonoid intermediate decay, previously assigned as reaction rate-limiting, was specifically accelerated such that in three of the variants this step was no longer kinetically significant. Overall, our data support the postulate that the active site loop controls the rate of product and porphyrin production in vivo and suggest the possibility of an as yet undiscovered means of allosteric regulation.

Unstable Reaction Intermediates and Hysteresis during the Catalytic Cycle of 5-Aminolevulinate Synthase IMPLICATIONS FROM USING PSEUDO AND ALTERNATE SUBSTRATES AND A PROMISCUOUS ENZYME VARIANT

Background: Aminolevulinate synthase (ALAS) catalyzes decarboxylative condensation of glycine with succinyl-CoA yielding 5-aminolevulinate. Results: Unstable ALAS-catalyzed reaction intermediates and conformational changes were characterized using physiological and non-physiological substrates and promiscuous T148A variant. Conclusion: Rate of ALA release is controlled by a hysteretic kinetic mechanism initiated by ALAS conformational changes. Significance: Unraveling the ALAS catalytic pathway enhances possible development of therapies for heme synthesis-associated disorders. 5-Aminolevulinate (ALA), an essential metabolite in all heme-synthesizing organisms, results from the pyridoxal 5′-phosphate (PLP)-dependent enzymatic condensation of glycine with succinyl-CoA in non-plant eukaryotes and α-proteobacteria. The predicted chemical mechanism of this ALA synthase (ALAS)-catalyzed reaction includes a short-lived glycine quinonoid intermediate and an unstable 2-amino-3-ketoadipate intermediate. Using liquid chromatography coupled with tandem mass spectrometry to analyze the products from the reaction of murine erythroid ALAS (mALAS2) with O-methylglycine and succinyl-CoA, we directly identified the chemical nature of the inherently unstable 2-amino-3-ketoadipate intermediate, which predicates the glycine quinonoid species as its precursor. With stopped-flow absorption spectroscopy, we detected and confirmed the formation of the quinonoid intermediate upon reacting glycine with ALAS. Significantly, in the absence of the succinyl-CoA substrate, the external aldimine predominates over the glycine quinonoid intermediate. When instead of glycine, l-serine was reacted with ALAS, a lag phase was observed in the progress curve for the l-serine external aldimine formation, indicating a hysteretic behavior in ALAS. Hysteresis was not detected in the T148A-catalyzed l-serine external aldimine formation. These results with T148A, a mALAS2 variant, which, in contrast to wild-type mALAS2, is active with l-serine, suggest that active site Thr-148 modulates ALAS strict amino acid substrate specificity. The rate of ALA release is also controlled by a hysteretic kinetic mechanism (observed as a lag in the ALA external aldimine formation progress curve), consistent with conformational changes governing the dissociation of ALA from ALAS.

Arg-85 and Thr-430 in murine 5-aminolevulinate synthase coordinate acyl-CoA-binding and contribute to substrate specificity

5‐Aminolevulinate synthase (ALAS) controls the rate‐limiting step of heme biosynthesis in mammals by catalyzing the condensation of succinyl‐coenzyme A and glycine to produce 5‐aminolevulinate, coenzyme‐A (CoA), and carbon dioxide. ALAS is a member of the α‐oxoamine synthase family of pyridoxal 5′‐phosphate (PLP)‐dependent enzymes and shares high degree of structural similarity and reaction mechanism with the other members of the family. The X‐ray crystal structure of ALAS from Rhodobacter capsulatus reveals that the alkanoate component of succinyl‐CoA is coordinated by a conserved arginine and a threonine. The functions of the corresponding acyl‐CoA‐binding residues in murine erthyroid ALAS (R85 and T430) in relation to acyl‐CoA binding and substrate discrimination were examined using site‐directed mutagenesis and a series of CoA‐derivatives. The catalytic efficiency of the R85L variant with octanoyl‐CoA was 66‐fold higher than that of the wild‐type protein, supporting the proposal of this residue as key in discriminating substrate binding. Substitution of the acyl‐CoA‐binding residues with hydrophobic amino acids caused a ligand‐induced negative dichroic band at 420 nm in the CD spectra, suggesting that these residues affect substrate‐mediated changes to the PLP microenvironment. Transient kinetic analyses of the R85K variant‐catalyzed reactions confirm that this substitution decreases microscopic rates associated with formation and decay of a key reaction intermediate and show that the nature of the acyl‐CoA tail seriously affect product binding. These results show that the bifurcate interaction of the carboxylate moiety of succinyl‐CoA with R85 and T430 is an important determinant in ALAS function and may play a role in substrate specificity.

Serine 254 Enhances an Induced Fit Mechanism in Murine 5-Aminolevulinate Synthase

5-Aminolevulinate synthase (EC 2.3.1.37) (ALAS), a pyridoxal 5′-phosphate (PLP)-dependent enzyme, catalyzes the initial step of heme biosynthesis in animals, fungi, and some bacteria. Condensation of glycine and succinyl coenzyme A produces 5-aminolevulinate, coenzyme A, and carbon dioxide. X-ray crystal structures of Rhodobacter capsulatus ALAS reveal that a conserved active site serine moves to within hydrogen bonding distance of the phenolic oxygen of the PLP cofactor in the closed substrate-bound enzyme conformation and within 3–4 Å of the thioester sulfur atom of bound succinyl-CoA. To evaluate the role(s) of this residue in enzymatic activity, the equivalent serine in murine erythroid ALAS was substituted with alanine or threonine. Although both the KmSCoA and kcat values of the S254A variant increased, by 25- and 2-fold, respectively, the S254T substitution decreased kcat without altering KmSCoA. Furthermore, in relation to wild-type ALAS, the catalytic efficiency of S254A toward glycine improved ∼3-fold, whereas that of S254T diminished ∼3-fold. Circular dichroism spectroscopy revealed that removal of the side chain hydroxyl group in the S254A variant altered the microenvironment of the PLP cofactor and hindered succinyl-CoA binding. Transient kinetic analyses of the variant-catalyzed reactions and protein fluorescence quenching upon 5-aminolevulinate binding demonstrated that the protein conformational transition step associated with product release was predominantly affected. We propose the following: 1) Ser-254 is critical for formation of a competent catalytic complex by coupling succinyl-CoA binding to enzyme conformational equilibria, and 2) the role of the active site serine should be extended to the entire α-oxoamine synthase family of PLP-dependent enzymes.

Identification and Characterization of an Inhibitory Metal Ion-binding Site in Ferrochelatase

Ferrochelatase catalyzes the insertion of ferrous iron into protoporphyrin IX to form heme. The severe metal ion substrate inhibition observed during in vitro studies of the purified enzyme is almost completely eliminated by mutation of an active site histidine residue (His-287, murine ferrochelatase numbering) to leucine and reduced over 2 orders of magnitude by mutation of a nearby conserved phenylalanine residue (Phe-283) to leucine. Elimination of substrate inhibition had no effect on the apparent Vmax for Ni2+, but the apparent Km was increased 100-fold, indicating that the integrity of the inhibitory binding site is important for the enzyme to turn over substrates rapidly at low micromolar metal ion concentrations. The inhibitory site was observed to have a pKa value of 8.0, and this value was reduced to 7.5 by the F283L mutation and to 7.4 in a naturally occurring positional variant observed in most bacterial ferrochelatases, murine ferrochelatase H287C. A H287N variant was also found to be substrate-inhibited, but unlike the H287C variant, pH dependence of substrate inhibition was largely eliminated. The data indicate that the inhibitory metal ion-binding site is composed of multiple residues but primarily defined by His-287 and Phe-283 and is crucial for optimal activity at low metal ion concentrations. It is proposed that this binding site may be important for ferrous iron acquisition and desolvation in vivo.

The Structure of the Complex between Yeast Frataxin and Ferrochelatase CHARACTERIZATION AND PRE-STEADY STATE REACTION OF FERROUS IRON DELIVERY AND HEME SYNTHESIS

Frataxin is a mitochondrial iron-binding protein involved in iron storage, detoxification, and delivery for iron sulfur-cluster assembly and heme biosynthesis. The ability of frataxin from different organisms to populate multiple oligomeric states in the presence of metal ions, e.g. Fe2+ and Co2+, led to the suggestion that different oligomers contribute to the functions of frataxin. Here we report on the complex between yeast frataxin and ferrochelatase, the terminal enzyme of heme biosynthesis. Protein-protein docking and cross-linking in combination with mass spectroscopic analysis and single-particle reconstruction from negatively stained electron microscopic images were used to verify the Yfh1-ferrochelatase interactions. The model of the complex indicates that at the 2:1 Fe2+-to-protein ratio, when Yfh1 populates a trimeric state, there are two interaction interfaces between frataxin and the ferrochelatase dimer. Each interaction site involves one ferrochelatase monomer and one frataxin trimer, with conserved polar and charged amino acids of the two proteins positioned at hydrogen-bonding distances from each other. One of the subunits of the Yfh1 trimer interacts extensively with one subunit of the ferrochelatase dimer, contributing to the stability of the complex, whereas another trimer subunit is positioned for Fe2+ delivery. Single-turnover stopped-flow kinetics experiments demonstrate that increased rates of heme production result from monomers, dimers, and trimers, indicating that these forms are most efficient in delivering Fe2+ to ferrochelatase and sustaining porphyrin metalation. Furthermore, they support the proposal that frataxin-mediated delivery of this potentially toxic substrate overcomes formation of reactive oxygen species.

Expression of murine 5-aminolevulinate synthase variants causes protoporphyrin IX accumulation and light-induced mammalian cell death.

5-Aminolevulinate synthase (ALAS; EC 2.3.1.37) catalyzes the first committed step of heme biosynthesis in animals. The erythroid-specific ALAS isozyme (ALAS2) is negatively regulated by heme at the level of mitochondrial import and, in its mature form, certain mutations of the murine ALAS2 active site loop result in increased production of protoporphyrin IX (PPIX), the precursor for heme. Importantly, generation of PPIX is a crucial component in the widely used photodynamic therapies (PDT) of cancer and other dysplasias. ALAS2 variants that cause high levels of PPIX accumulation provide a new means of targeted, and potentially enhanced, photosensitization. In order to assess the prospective utility of ALAS2 variants in PPIX production for PDT, K562 human erythroleukemia cells and HeLa human cervical carcinoma cells were transfected with expression plasmids for ALAS2 variants with greater enzymatic activity than the wild-type enzyme. The levels of accumulated PPIX in ALAS2-expressing cells were analyzed using flow cytometry with fluorescence detection. Further, cells expressing ALAS2 variants were subjected to white light treatments (21–22 kLux) for 10 minutes after which cell viability was determined. Transfection of HeLa cells with expression plasmids for murine ALAS2 variants, specifically for those with mutated mitochondrial presequences and a mutation in the active site loop, caused significant cellular accumulation of PPIX, particularly in the membrane. Light treatments revealed that ALAS2 expression results in an increase in cell death in comparison to aminolevulinic acid (ALA) treatment producing a similar amount of PPIX. The delivery of stable and highly active ALAS2 variants has the potential to expand and improve upon current PDT regimes.