Holly R. Ellis

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.

Mechanism for sulfur acquisition by the alkanesulfonate monooxygenase system.

The bacterial alkanesulfonate monooxygenase system is involved in the acquisition of sulfur from organosulfonated compounds during limiting sulfur conditions. The reaction relies on an FMN reductase to supply reduced flavin to the monooxygenase enzyme. The reaction catalyzed by the alkanesulfonate monooxygenase enzyme involves the carbon-sulfur bond cleavage of a wide range of organosulfonated compounds. A C4a-(hydro)peroxyflavin is the oxygenating intermediate in the mechanism of desulfonation by the alkanesulfonate monooxygenase. This review discusses the physiological importance of this system, and the individual kinetic parameters and mechanistic properties of this enzyme system.

Addition of an external electron donor to in vitro assays of cysteine dioxygenase precludes the need for exogenous iron.

Cysteine dioxygenase (CDO) utilizes a 3-His facial triad for coordination of its metal center. Recombinant CDO present in cellular lysate exists primarily in the ferrous form and exhibits significant catalytic activity. Removal of CDO from the reducing cellular environment during purification results in the loss of bound iron and oxidation of greater than 99% of the remaining metal centers. The as-isolated recombinant enzyme has comparable activity as the background level of L-cysteine oxidation confirming that CDO is inactive under the aerobic conditions required for catalysis. Including exogenous ferrous iron in assays resulted in non-enzymatic product formation; however, addition of an external reductant in assays of the purified protein resulted in the recovery of CDO activity. EPR spectroscopy of CDO in the presence of a reductant confirms that the recovered activity is consistent with reduction of iron to the ferrous form. The as-isolated enzyme in the presence of L-cysteine was nearly unreactive with the dioxygen analog, but had increased affinity when pre-incubated with an external reductant. These studies shed light on the discrepancies among reported kinetic parameters for CDO and also juxtapose the stability of the 3-His and 2-His/1-carboxylate ferrous enzymes in the presence of dioxygen.

Catalytic role of a conserved cysteine residue in the desulfonation reaction by the alkanesulfonate monooxygenase enzyme

Detailed kinetic studies were performed in order to determine the role of the single cysteine residue in the desulfonation reaction catalyzed by SsuD. Mutation of the conserved cysteine at position 54 in SsuD to either serine or alanine had little effect on FMNH(2) binding. The k(cat)/K(m) value for the C54S SsuD variant increased 3-fold, whereas the k(cat)/K(m) value for C54A SsuD decreased 6-fold relative to wild-type SsuD. An initial fast phase was observed in kinetic traces obtained for the oxidation of flavin at 370 nm when FMNH(2) was mixed against C54S SsuD (k(obs), 111 s(-1)) in oxygenated buffer that was 10-fold faster than wild-type SsuD (k(obs), 12.9 s(-1)). However, there was no initial fast phase observed in similar kinetic traces obtained for C54A SsuD. This initial fast phase was previously assigned to the formation of the C4a-(hydro)peroxyflavin in studies with wild-type SsuD. There was no evidence for the formation of the C4a-(hydro)peroxyflavin with either SsuD variant when octanesulfonate was included in rapid reaction kinetic studies, even at low octanesulfonate concentrations. The absence of any C4a-(hydro)peroxyflavin accumulation correlates with the increased catalytic activity of C54S SsuD. These results suggest that the conservative serine substitution is able to effectively take the place of cysteine in catalysis. Conversely, decreased accumulation of the C4a-(hydro)peroxyflavin intermediate with the C54A SsuD variant may be due to decreased activity. The data described suggest that Cys54 in SsuD may be either directly or indirectly involved in stabilizing the C4a-(hydro)peroxyflavin intermediate formed during catalysis through hydrogen bonding interactions.

Shifting redox states of the iron center partitions CDO between crosslink formation or cysteine oxidation.

Cysteine dioxygenase (CDO) is a mononuclear iron-dependent enzyme that catalyzes the oxidation of L-cysteine to L-cysteine sulfinic acid. The mammalian CDO enzymes contain a thioether crosslink between Cys93 and Tyr157, and purified recombinant CDO exists as a mixture of the crosslinked and non crosslinked isoforms. The current study presents a method of expressing homogenously non crosslinked CDO using a cell permeative metal chelator in order to provide a comprehensive investigation of the non crosslinked and crosslinked isoforms. Electron paramagnetic resonance analysis of purified non crosslinked CDO revealed that the iron was in the EPR silent Fe(II) form. Activity of non crosslinked CDO monitoring dioxygen utilization showed a distinct lag phase, which correlated with crosslink formation. Generation of homogenously crosslinked CDO resulted in an ∼5-fold higher kcat/Km value compared to the enzyme with a heterogenous mixture of crosslinked and non crosslinked CDO isoforms. EPR analysis of homogenously crosslinked CDO revealed that this isoform exists in the Fe(III) form. These studies present a new perspective on the redox properties of the active site iron and demonstrate that a redox switch commits CDO towards either formation of the Cys93-Tyr157 crosslink or oxidation of the cysteine substrate.

Deletional studies to investigate the functional role of a dynamic loop region of alkanesulfonate monooxygenase

Several bacterial organisms rely on the two-component alkanesulfonate monooxygenase system for the acquisition of organosulfonate compounds when inorganic sulfur is limiting in the environment. This system is comprised of an FMN reductase (SsuE) that supplies reduced flavin to the alkanesulfonate monooxygenase (SsuD). Desulfonation of alkanesulfonates by SsuD is catalyzed through the activation of dioxygen by reduced flavin. The three-dimensional structure of SsuD exists as a TIM-barrel fold with several discrete insertion regions. An extensive insertion region near the putative active site was disordered in the SsuD structure, suggesting the importance of protein dynamics in the desulfonation mechanism. Three variants containing a partial deletion of the loop region were constructed to evaluate the functional properties of this region. There were no overall gross changes in secondary structure for the three SsuD deletion variants compared to wild-type SsuD, but each variant was found to be catalytically inactive. The deletion variants were unable to undergo the conformational changes necessary for catalysis even though they were able to bind reduced flavin. Rapid kinetic analyses monitoring the reductive and oxidative half-reactions indicated that the SsuD deletion variants failed to protect reduced flavin from unproductive oxidation. These studies define the importance of dynamic loop region for protection and stabilization of reduced flavin and reaction intermediates.

Probing the flavin transfer mechanism in alkanesulfonate monooxygenase system

Bacteria acquire sulfur through the sulfur assimilation pathway, but under sulfur limiting conditions bacteria must acquire sulfur from alternative sources. The alkanesulfonate monooxygenase enzymes are expressed under sulfur-limiting conditions, and catalyze the desulfonation of wide-range of alkanesulfonate substrates. The SsuE enzyme is an NADPH-dependent FMN reductase that provides reduced flavin to the SsuD monooxygenase. The mechanism for the transfer of reduced flavin in flavin dependent two-component systems occurs either by free-diffusion or channeling. Previous studies have shown the presence of protein-protein interactions between SsuE and SsuD, but the identification of putative interaction sights have not been investigated. Current studies utilized HDX-MS to identify protective sites on SsuE and SsuD. A conserved α-helix on SsuD showed a decrease in percent deuteration when SsuE was included in the reaction. This suggests the role of α-helix in promoting protein-protein interactions. Specific SsuD variants were generated in order to investigate the role of these residues in protein-protein interactions and catalysis. Variant containing substitutions at the charged residues showed a six-fold decrease in the activity, while a deletion variant of SsuD lacking the α-helix showed no activity when compared to wild-type SsuD. In addition, there was no protein-protein interactions identified between SsuE and his-tagged SsuD variants in pull-down assays, which correlated with an increase in the Kd value. The α-helix is located right next to a dynamic loop region, positioned at the entrance of the active site. The putative interaction site and dynamic loop region located so close to the active site of SsuD suggests the importance of this region in the SsuD catalysis. Stopped-flow studies were performed to analyze the lag-phase which signifies the stabilization and transfer of reduced flavin from SsuE to SsuD. The SsuD variants showed a decrease in lag-phase, which could be because of a downturn in flavin transfer. A competitive assay was devised to evaluate the mechanism of flavin transfer in the alkanesulfonate monooxygenase system. A variant of SsuE was generated which interacted with SsuD, but was not able to reduce FMN. Assays that included varying concentrations of Y118A SsuE and wild-type SsuE in the coupled assays showed a decrease in the desulfonation activity of SsuD. The decrease in activity could be by virtue of Y118A SsuE competing with the wild-type SsuE for the putative docking site on SsuD. These studies define the importance of protein-protein interactions for the efficient transfer of reduced flavin from SsuE to SsuD leading to the desulfonation of alkanesulfonates.

Not as easy as π: an insertional residue does not explain the π-helix gain-of-function in two component FMN reductases: π-helical structures in two-component FMN reductases

The π‐helix located at the tetramer interface of two‐component FMN‐dependent reductases contributes to the structural divergence from canonical FMN‐bound reductases within the NADPH:FMN reductase family. The π‐helix in the SsuE FMN‐dependent reductase of the alkanesulfonate monooxygenase system has been proposed to be generated by the insertion of a Tyr residue in the conserved α4‐helix. Variants of Tyr118 were generated, and their X‐ray crystal structures determined, to evaluate how these alterations affect the structural integrity of the π‐helix. The structure of the Y118A SsuE π‐helix was converted to an α‐helix, similar to the FMN‐bound members of the NADPH:FMN reductase family. Although the π‐helix was altered, the FMN binding region remained unchanged. Conversely, deletion of Tyr118 disrupted the secondary structural properties of the π‐helix, generating a random coil region in the middle of helix 4. Both the Y118A and Δ118 SsuE SsuE variants crystallize as a dimer. The MsuE FMN reductase involved in the desulfonation of methanesulfonates is structurally similar to SsuE, but the π‐helix contains a His insertional residue. Exchanging the π‐helix insertional residue of each enzyme did not result in equivalent kinetic properties. Structure‐based sequence analysis further demonstrated the presence of a similar Tyr residue in an FMN‐bound reductase in the NADPH:FMN reductase family that is not sufficient to generate a π‐helix. Results from the structural and functional studies of the FMN‐dependent reductases suggest that the insertional residue alone is not solely responsible for generating the π‐helix, and additional structural adaptions occur to provide the altered gain of function.

Functional Evaluation of the π-Helix in the NAD(P)H:FMN Reductase of the Alkanesulfonate Monooxygenase System

A subgroup of enzymes in the NAD(P)H:FMN reductase family is comprised of flavin reductases from two-component monooxygenase systems. The diverging structural feature in these FMN reductases is a π-helix centrally located at the tetramer interface that is generated by the insertion of an amino acid in a conserved α4 helix. The Tyr insertional residue of SsuE makes specific contacts across the dimer interface that may assist in the altered mechanistic properties of this enzyme. The Y118F SsuE variant maintained the π-π stacking interactions at the tetramer interface and had kinetic parameters similar to those of wild-type SsuE. Substitution of the π-helical residue (Tyr118) to Ala or Ser transformed the enzymes into flavin-bound SsuE variants that could no longer support flavin reductase and desulfonation activities. These variants existed as dimers and could form protein-protein interactions with SsuD even though flavin transfer was not sustained. The ΔY118 SsuE variant was flavin-free as purified and did not undergo the tetramer to dimer oligomeric shift with the addition of flavin. The absence of desulfonation activity can be attributed to the inability of ΔY118 SsuE to promote flavin transfer and undergo the requisite oligomeric changes to support desulfonation. Results from these studies provide insights into the role of the SsuE π-helix in promoting flavin transfer and oligomeric changes that support protein-protein interactions with SsuD.

Use of Fluorescent NIR Dyes in Silica Nanoparticles and as Enzyme Substrates in Bioanalytical Applications

Near-Infrared (NIR) absorbing carbocyanine dyes have been increasingly used in analytical, biological and medical fields as they can be useful for developing bioanalytical and biomedical methods. The utilization of the NIR spectral region (650-900 nm) is advantageous and is due to the inherently lower background interference and the high molar absorptivities of NIR chromophores. NIR dyes typically have relatively lower fluorescent quantum yield as compared to visible fluorophores, but much higher molar absorptivities which more than compensates for the lower quantum yields regarding detection limits. Fluorescence intensity of NIR dyes significantly increases by enclosing several dye molecules in silica nanoparticles. Self quenching may become a problem for carbocyanines at such high concentrations that may be present in the silica nanoparticles. Dyes that have large Stokes’ shift can significantly decrease this problem. Increased Stokes’ shift for carbocyanines dyes can be achieved by substituting meso position halogens with a linker containing aliphatic or aromatic amino moiety which also serves as a covalent linker for attaching the dye molecule to the nanoparticle backbone. The primary applications of these particles are for bright fluorescent labels to be used in bioanalytical applications such as immunochemistry, flow cytometry, etc. This work also discusses the use of NIR dyes as enzyme substrates. NIR dyes can be used as enzyme substrates and hence for characterization of enzyme activity. The well characterized alkenesulfonate monooxygenase enzyme was chosen for these studies. Carbocyanines containing alkylsulfonate moieties do not exhibit significant fluorescence change upon binding to biomolecules however otherwise identical NIR dye analogs that contain alkylaldehyde moiety at the same position do exhibit changes which can be utilized for characterization of alkenesulfonate monooxygenase enzyme activity using near infrared dyes as substrates. In this study a new class of sulfonated penta- and heptamethine dyes were used as substrates in vitro utilizing a photo-reduced riboflavin mononucleotide (FMN) with a glucose/ glucose-oxygenase oxygen scavenging system. Laser Induced Fluorescence (LIF) detected CZE was utilized to detect the sulfonated and de-sulfonated carbocyanines. The lower fluorescence quantum yield of the less water soluble alkylaldehyde analogs was detected and enzyme activity was characterized.