Relationship between the conserved alpha subunit arginine 107 and effects of phosphate on the activity and stability of Vibrio harveyi luciferase

Mechanisms of Viscous Media Effects on Elementary Steps of Bacterial Bioluminescent Reaction

Enzymes activity in a cell is determined by many factors, among which viscosity of the microenvironment plays a significant role. Various cosolvents can imitate intracellular conditions in vitro, allowing to reduce a combination of different regulatory effects. The aim of the study was to analyze the media viscosity effects on the rate constants of the separate stages of the bacterial bioluminescent reaction. Non-steady-state reaction kinetics in glycerol and sucrose solutions was measured by stopped-flow technique and analyzed with a mathematical model developed in accordance with the sequence of reaction stages. Molecular dynamics methods were applied to reveal the effects of cosolvents on luciferase structure. We observed both in glycerol and in sucrose media that the stages of luciferase binding with flavin and aldehyde, in contrast to oxygen, are diffusion-limited. Moreover, unlike glycerol, sucrose solutions enhanced the rate of an electronically excited intermediate formation. The MD simulations showed that, in comparison with sucrose, glycerol molecules could penetrate the active-site gorge, but sucrose solutions caused a conformational change of functionally important αGlu175 of luciferase. Therefore, both cosolvents induce diffusion limitation of substrates binding. However, in sucrose media, increasing enzyme catalytic constant neutralizes viscosity effects. The activating effect of sucrose can be attributed to its exclusion from the catalytic gorge of luciferase and promotion of the formation of the active site structure favorable for the catalysis.

Bacterial luciferase: Molecular mechanisms and applications

Bacterial luciferase is a flavin-dependent monooxygenase which is remarkable for its distinctive feature in transforming chemical energy to photons of visible light. The bacterial luciferase catalyzes bioluminescent reaction using reduced flavin mononucleotide, long-chain aldehyde and oxygen to yield oxidized flavin, corresponding acid, water and light at λ_max around 490nm. The enzyme comprises of two non-identical α and β subunits, where α subunit is a catalytic center and β subunit is crucially required for maintaining catalytic function of the α subunit. The crystal structure with FMN bound and mutagenesis studies have assigned a number of amino acid residues that are important in coordinating critical reactions and stabilizing intermediates to attain optimum reaction efficiency. The enzyme achieves monooxygenation by generating C4a-hydroperoxyflavin intermediate that later changes its protonation status to become C4a-peroxyflavin, which is necessary for the nucleophilic attacking with aldehyde substrate. The decomposing of C4a-peroxyhemiacetal produces excited C4a-hydroxyflavin and acid product. The chemical basis regrading bioluminophore generation in Lux reaction remains an inconclusive issue. However, current data can, at least, demonstrate the involvement of electron transfer to create radical molecules which is the key step in this mechanism. Lux is a self-sufficient bioluminescent system in which all substrates can be recycled and produced by a group of enzymes from the lux operon. This makes Lux distinctively advantageous over other luciferases for reporter enzyme application. The progression of understanding of Lux catalysis is beneficial to improve light emitting efficiency in order to expand the robustness of Lux application.

Analysis of the bacterial luciferase mobile loop by replica-exchange molecular dynamics

Bacterial luciferase contains an extended 29-residue mobile loop. Movements of this loop are governed by binding of either flavin mononucleotide (FMNH2) or polyvalent anions. To understand this process, loop dynamics were investigated using replica-exchange molecular dynamics that yielded conformational ensembles in either the presence or absence of FMNH2. The resulting data were analyzed using clustering and network analysis. We observed the closed conformations that are visited only in the simulations with the ligand. Yet the mobile loop is intrinsically flexible, and FMNH2 binding modifies the relative populations of conformations. This model provides unique information regarding the function of a crystallographically disordered segment of the loop near the binding site. Structures at or near the fringe of this network were compatible with flavin binding or release. Finally, we demonstrate that the crystallographically observed conformation of the mobile loop bound to oxidized flavin was influenced by crystal packing. Thus, our study has revealed what we believe are novel conformations of the mobile loop and additional context for experimentally determined structures.

The FMN-dependent two-component monooxygenase systems

The FMN-dependent two-component monooxygenase systems catalyze a diverse range of reactions. These two-component systems are composed of an FMN reductase enzyme and a monooxygenase enzyme that catalyze the oxidation of various substrates. The role of the reductase is to supply reduced flavin to the monooxygenase enzyme, while the monooxygenase enzyme utilizes the reduced flavin to activate molecular oxygen. Unlike flavoproteins with a tightly or covalently bound prosthetic group, these enzymes catalyze the reductive and oxidative half-reaction on two separate enzymes. An interesting feature of these enzymes is their ability to transfer reduced flavin from the reductase to the monooxygenase enzyme. This review covers the reported mechanistic and structural properties of these enzyme systems, and evaluates the mechanism of flavin transfer.

Two lysine residues in the bacterial luciferase mobile loop stabilize reaction intermediates

Bacterial luciferase catalyzes the reaction of FMNH(2), O(2), and a long chain aliphatic aldehyde, yielding FMN, carboxylic acid, and blue-green light. The most conserved contiguous region of the primary sequence corresponds to a crystallographically disordered loop adjacent to the active center (Fisher, A. J., Raushel, F. M., Baldwin, T. O., and Rayment, I. (1995) Biochemistry 34, 6581-6586; Fisher, A. J., Thompson, T. B., Thoden, J. B., Baldwin, T. O., and Rayment, I. (1996) J. Biol. Chem. 271, 21956-21968). Deletion of the mobile loop does not alter the chemistry of the reaction but decreases the total quantum yield of bioluminescence by 2 orders of magnitude (Sparks, J. M., and Baldwin, T. O. (2001) Biochemistry 40, 15436-15443). In this study, we attempt to localize the loss of activity observed in the loop deletion mutant to individual residues in the mobile loop. Using alanine mutagenesis, the effects of substitution at 15 of the 29 mobile loop residues were examined. Nine of the point mutants had reduced activity in vivo. Two mutations, K283A and K286A, resulted in a loss in quantum yield comparable with that of the loop deletion mutant. The bioluminescence emission spectrum of both mutants was normal, and both yielded the carboxylic acid chemical product at the same efficiency as the wild-type enzyme. Substitution of Lys(283) with alanine resulted in destabilization of intermediate II, whereas mutation of Lys(286) had an increase in exposure of reaction intermediates to a dynamic quencher. Based on a model of the enzyme-reduced flavin complex, the two critical lysine residues are adjacent to the quininoidal edge of the isoalloxazine.

Crystal structure of the bacterial luciferase/flavin complex provides insight into the function of the beta subunit

Bacterial luciferase from Vibrio harveyi is a heterodimer composed of a catalytic alpha subunit and a homologous but noncatalytic beta subunit. Despite decades of enzymological investigation, structural evidence defining the active center has been elusive. We report here the crystal structure of V. harveyi luciferase bound to flavin mononucleotide (FMN) at 2.3 A. The isoalloxazine ring is coordinated by an unusual cis-Ala-Ala peptide bond. The reactive sulfhydryl group of Cys106 projects toward position C-4a, the site of flavin oxygenation. This structure also provides the first data specifying the conformations of a mobile loop that is crystallographically disordered in both prior crystal structures [(1995) Biochemistry 34, 6581-6586; (1996) J. Biol. Chem. 271, 21956 21968]. This loop appears to be a boundary between solvent and the active center. Within this portion of the protein, a single contact was observed between Phe272 of the alpha subunit, not seen in the previous structures, and Tyr151 of the beta subunit. Substitutions at position 151 on the beta subunit caused reductions in activity and total quantum yield. Several of these mutants were found to have decreased affinity for reduced flavin mononucleotide (FMNH(2)). These findings partially address the long-standing question of how the beta subunit stabilizes the active conformation of the alpha subunit, thereby participating in the catalytic mechanism.

Probing the Functionalities of αGlu328 and αAla74 of Vibrio harveyi Luciferase by Site-Directed Mutagenesis and Chemical Rescue

This work aimed at identifying essential residues on the alpha subunit of Vibrio harveyi luciferase and elucidating their functional roles. Four conserved alpha-subunit residues at the proposed luciferase active site were initially mutated to Ala. Screening of the in vivo bioluminescence of cells expressing these mutated luciferases allowed the work to focus on alphaGlu328 for additional mutations to Phe, Leu, Gln, His, and Asp. V. harveyi luciferase is known to contain, at the same proposed active site, an unusual cis-peptide linkage between alphaAla74 and alphaAla75. To explore the structure-function relationship, luciferase variants alphaA74F and alphaA74G were constructed. The six alphaGlu328-mutated and the two alphaAla74-mutated luciferase variants were purified and characterized with respect to Vmax, Michaelis constants, light and dark decays, quantum yield, and, for alphaE328F and alphaA74F, yield of the 4a-hydroperoxyFMN intermediate and the ability to oxidize aldehyde substrate. Results indicated that the structural integrities of both alphaGlu328 and alphaAla74 were essential to luciferase bioluminescence activity. Moreover, the essentiality of alphaGlu328 was linked to the acidic nature of its side chain. The low activity of alphaE328A was sensitive to chemical rescue by sodium acetate, an effect that was not reproduced by phosphate. The efficiency of activity rescue by acetate progressively increased at lower pH in the range from 6.0 to 8.0, supporting the interpretation of alphaGlu328 as a catalytic general acid. The rescuing effect of acetate was on a reaction step after the formation of the 4a-hydroperoxyFMN intermediate. The exact catalytic function of alphaGlu328 is unclear, but possibilities are discussed.

Active Site Hydrophobicity Is Critical to the Bioluminescence Activity of Vibrio harveyi Luciferase

Vibrio harveyi luciferase is an alphabeta heterodimer containing a single active site, proposed earlier to be at a cleft in the alpha subunit. In this work, six conserved phenylalanine residues at this proposed active site were subjected to site-directed mutations to investigate their possible functional roles and to delineate the makeup of luciferase active site. After initial screening of Phe --> Ala mutants, alphaF46, alphaF49, alphaF114, and alphaF117 were chosen for additional mutations to Asp, Ser, and Tyr. Comparisons of the general kinetic properties of wild-type and mutated luciferases indicated that the hydrophobic nature of alphaF46, alphaF49, alphaF114, and alphaF117 was important to luciferase V(max) and V(max)/K(m), which were reduced by 3-5 orders of magnitude for the Phe --> Asp mutants. Both alphaF46 and alphaF117 also appeared to be involved in the binding of reduced flavin substrate. Additional studies on the stability and yield of the 4a-hydroperoxyflavin intermediate II and measurements of decanal substrate oxidation by alphaF46D, alphaF49D, alphaF114D, and alphaF117D revealed that their marked reductions in the overall quantum yield (phi( degrees )) were a consequence of diminished yields of luciferase intermediates and, with the exception of alphaF114D, emission quantum yield of the excited emitter due to the replacement of the hydrophobic Phe by the anionic Asp. The locations of these four critical Phe residues in relation to other essential and/or hydrophobic residues are depicted in a refined map of the active site. Functional implications of these residues are discussed.

Crystal structure of methylenetetrahydromethanopterin reductase (Mer) in complex with coenzyme F420: Architecture of the F420/FMN binding site of enzymes within the nonprolyl cis-peptide containing bacterial luciferase family

Methylenetetratetrahydromethanopterin reductase (Mer) is involved in CO(2) reduction to methane in methanogenic archaea and catalyses the reversible reduction of methylenetetrahydromethanopterin (methylene-H(4)MPT) to methyl-H(4)MPT with coenzyme F(420)H(2), which is a reduced 5'-deazaflavin. Mer was recently established as a TIM barrel structure containing a nonprolyl cis-peptide bond but the binding site of the substrates remained elusive. We report here on the crystal structure of Mer in complex with F(420) at 2.6 A resolution. The isoalloxazine ring is present in a pronounced butterfly conformation, being induced from the Re-face of F(420) by a bulge that contains the non-prolyl cis-peptide bond. The bindingmode of F(420) is very similar to that in F(420)-dependent alcohol dehydrogenase Adf despite the low sequence identity of 21%. Moreover, binding of F(420) to the apoenzyme was only associated with minor conformational changes of the polypeptide chain. These findings allowed us to build an improved model of FMN into its binding site in bacterial luciferase, which belongs to the same structural family as Mer and Adf and also contains a nonprolyl cis-peptide bond in an equivalent position.

Changes in the kinetics and emission spectrum on mutation of the chromophore-binding platform in Vibrio harveyi luciferase

The recently proposed model for the bacteria luciferase-flavin mononucleotide complex identifies a number of critical intermolecular interactions that define a binding platform for the isoalloxazine ring of flavin [Lin, L. Y., Sulea, T., Szittner, R., Vassilyev, V., Purisima, E. O., and Meighen, E. A. (2001) Protein Sci. 10, 1563-1571]. A key interaction involving van der Waals contact between the isopropyl side chain of alphaVal173 and the 7,8-dimethyl benzene plane of the isoalloxazine chromophore represents an important target to test the validity of the proposed model. Here, structure-function analysis of luciferase variants carrying single point mutations at position alpha173 have verified the functional layout of the active site architecture and implicated this site directly in flavin binding. Moreover, a decrease in the stability of the enzyme-bound C4a-hydroperoxyflavin intermediate in the mutants could account for changes in saturation with the fatty aldehyde substrate. A predicted red-shift on mutation of position alpha173 to increase its polarity confirmed that alphaVal173 was an integral component of the chromophore-binding microenvironment. Introduction of mutations in residues that contact the pyrimidine plane of the isoalloxazine chromophore (alphaA75G/C106V) into the alphaV173A, alphaV173C, alphaV173T, and alphaV173S mutants led to the retention of high levels of enzyme activity (10-40% of wild type) and further red-shifted the emission spectra in the triple mutants. The additivity of the mutation-induced red-shifts in the emission wavelength spectrum provides the basis toward engineering luciferase variants that emit different light colors with the proposed flavin-luciferase model complex as a design reference.

Demonstration of two independently folding domains in the alpha subunit of bacterial luciferase by preferential ligand binding-induced stabilization

The alpha subunit of bacterial luciferase unfolds and refolds reversibly by a three-state mechanism in urea-containing buffer. It has been proposed that the three-state unfolding of the alpha subunit arises from a stepwise unfolding of a C-terminal folding domain at lower concentrations of urea, followed by unfolding of the N-terminal domain at higher concentrations of urea (Noland, B. W., Dangott, L. J., and Baldwin, T. O. (1999) Biochemistry 38, 16136-16145). The location of an anion binding site in the proposed N-terminal folding domain allowed the folding mechanism to be probed in the context of the intact polypeptide. Anions preferentially stabilized the N-terminal domain in a concentration-dependent manner. The polyvalent anions sulfate and phosphate were found to be more stabilizing than monovalent chloride ion. Cations did not show a similar stabilizing effect, demonstrating that the stabilization was due to the anions alone. The purified N-terminal domain prepared by limited proteolysis and anion exchange chromatography was found to refold cooperatively with a midpoint approximately that of the second unfolding transition of the alpha subunit. Phosphate ion stabilized this fragment to roughly the same extent as it did the alpha subunit. The results presented are consistent with the proposed two-domain folding model and demonstrate that anion binding to the N-terminal folding domain stabilizes the alpha subunit of bacterial luciferase.

Implications of the reactive thiol and the proximal non-proline cis-peptide bond in the Structure and function of Vibrio harveyi luciferase

The role of a highly reactive cysteine residue, Cys106, in Vibrio harveyi luciferase in modulating the substrate-enzyme interactions and in turn affecting the enzyme activity has been extensively investigated over the past three decades. Replacing Cys106 with valine dramatically hinders the ability of luciferase to stabilize the C4a-hydroperoxyflavin intermediate [Abu-Soud, H. M., Clark, A. C., Francisco, W. A., Baldwin, T. O., and Raushel, F. M. (1993) J. Biol. Chem. 268, 7699-7706] and consume aldehyde substrate [Xi, L., Cho, K.-W., Herndon, M. E., and Tu, S.-C. (1990) J. Biol. Chem. 265, 4200-4203], therefore markedly decreasing enzyme activity. On the basis of the structure-activity relationship of flavin analogues and the location of the phosphate binding site of flavin mononucleotide (FMN) coupled with molecular modeling, the functional part of the isoalloxazine ring of FMN, the thiol side chain of Cys106, the methyl group of Ala75, and the unique non-prolyl cis-peptide bond between Ala74 and Ala75 were found to be closely packed [Lin, L. Y., Sulea, T., Szittner, R., Vassilyev, V., Purisima, E. O., and Meighen, E. A. (2001) Protein Sci. 10, 1563-1571]. Here, by mutating Ala75 to Gly, we restored key wild-type properties to the C106V mutant, in particular, high enzyme activity and a stable C4a-hydroperoxyflavin intermediate, demonstrating that the primary reason for the dark phenotype of the C106V mutant was the unfavorable steric interaction between Val106 and Ala75 side chains, which could in turn disturb the cis-oriented amide linkage of Ala74 and Ala75. Moreover, significant red shifts in light emission of 3-10 nm were measured for luciferases carrying Val106 with the spectrum of the double mutant C106V/A75G now red shifted to that of Photobacterium phosphoreum luciferase, which also has Val and Gly at positions 106 and 75, respectively. These results strengthen the validity of the binding geometry of the modeled flavin with the re-face of the pyrimidine end of the isoalloxazine ring next to Cys106 and implicate the Ala74-Ala75 cis-peptide as a key component in the bioluminescence reaction.

Characterization of the binding of Photobacterium phosphoreum P-flavin by Vibrio harveyi Luciferase

The isolated Photobacterium phosphoreum luciferase is associated with a bound flavin designated P-flavin and tentatively identified as 6-(3"-myristic acid)-FMN. Since FMN and myristic acid are products of the normal luciferase reaction, we explored the possibility that P-flavin can also be bound by luciferase from other luminous bacteria and serve as an active site probe. P-flavin has never been detected in Vibrio harveyi cells. We found that the V. harveyi luciferase binds P. phosphoreum P-flavin, at a ratio of 1 P-flavin per luciferase alphabeta dimer, and with concomitant absorption spectral perturbation of P-flavin, fluorescence quenching of P-flavin and luciferase, and activity inhibition of luciferase. Isolated P-flavin can be fully reduced photochemically. V. harveyi luciferase bound the oxidized P-flavin with a K(d) (or K(i) competitively against decanal) of 0.1-0.16 microM, which is three orders of magnitude lower than the K(d) for FMN binding but similar to that of reduced FMN binding. The reduced P-flavin exhibited a K(i) (competitively against the reduced FMN substrate) of 0.16 microM, also similar to the K(d) for reduced FMN. Hence, the covalent attachment of myristic acid to FMN greatly and preferentially enhanced the binding of oxidized P-flavin. The dissociation of P-flavin was slow in comparison with the binding of reduced FMN and decanal substrates. Modification of the alphaCys106 near the active site by N-ethylmaleimide can be retarded by P-flavin. These findings indicate that P-flavin is potentially a superb active site probe for luciferase. We hypothesize that P-flavin is a by-product of luciferase generated by a side reaction which is trivial with the V. harveyi luciferase but significant in the P. phosphoreum luciferase-catalyzed reaction.

Modeling of the bacterial luciferase-flavin mononucleotide complex combining flexible docking with structure-activity data

Although the crystal structure of Vibrio harveyi luciferase has been elucidated, the binding sites for the flavin mononucleotide and fatty aldehyde substrates are still unknown. The determined location of the phosphate-binding site close to Arg 107 on the alpha subunit of luciferase is supported here by point mutagenesis. This information, together with previous structure-activity data for the length of the linker connecting the phosphate group to the isoalloxazine ring represent important characteristics of the luciferase-bound conformation of the flavin mononucleotide. A model of the luciferase-flavin complex is developed here using flexible docking supplemented by these structural constraints. The location of the phosphate moiety was used as the anchor in a flexible docking procedure performed by conformation search by using the Monte Carlo minimization approach. The resulting databases of energy-ranked feasible conformations of the luciferase complexes with flavin mononucleotide, omega-phosphopentylflavin, omega-phosphobutylflavin, and omega-phosphopropylflavin were filtered according to the structure-activity profile of these analogs. A unique model was sought not only on energetic criteria but also on the geometric requirement that the isoalloxazine ring of the active flavin analogs must assume a common orientation in the luciferase-binding site, an orientation that is also inaccessible to the inactive flavin analog. The resulting model of the bacterial luciferase-flavin mononucleotide complex is consistent with the experimental data available in the literature. Specifically, the isoalloxazine ring of the flavin mononucleotide interacts with the Ala 74-Ala 75 cis-peptide bond as well as with the Cys 106 side chain in the alpha subunit of luciferase. The model of the binary complex reveals a distinct cavity suitable for aldehyde binding adjacent to the isoalloxazine ring and flanked by other key residues (His 44 and Trp 250) implicated in the active site.