Probing the mechanisms of the biological intermolecular transfer of reduced flavin

Oligomeric Changes Regulate Flavin Transfer in Two-Component FMN Reductases Involved in Sulfur Metabolism

The FMN reductases (SsuE and MsuE of the alkanesulfonate monooxygenase systems) supply reduced flavin to their partner monooxygenases for the desulfonation of alkanesulfonates. Flavin reductases that comprise two-component systems must be able to regulate both flavin reduction and transfer. One mechanism to control these distinct processes is through changes in the oligomeric state of the enzymes. Despite their similar overall structures, SsuE and MsuE showed clear differences in their oligomeric states in the presence of substrates. The oligomeric state of SsuE was converted from a tetramer to a dimer/tetramer equilibrium in the presence of FMN or NADPH in analytical ultracentrifugation studies. Conversely, MsuE shifted from a dimer to a single tetrameric state with FMN, and the NADPH substrate did not induce a similar oligomeric shift. There was a fast tetramer to dimer equilibrium shift occurring at the dimer/dimer interface in H/D-X investigations with apo SsuE. Formation of the SsuE/FMN complex slowed the tetramer/dimer conversion, leading to a slower exchange along the dimer/dimer interface. The oligomeric shift of the MsuE/FMN complex from a dimer to a distinct tetramer showed a decrease in H/D-X in the region around the π-helices at the dimer/dimer interface. Both SsuE and MsuE showed a comparable and significant increase in the melting temperature with the addition of FMN, indicating the conformers formed by each FMN-bound enzyme had increased stability. A mechanism that supports the different structural shifts is rationalized by the different roles these enzymes play in providing reduced flavin to single or multiple monooxygenase enzymes.

Evaluation of the Conformational Stability of Recombinant Desulfurizing Enzymes from a Newly Isolated Rhodococcus sp

Metabolic pathways of aerobic bacteria able to assimilate sulfur can provide biocatalysts for biodesulfurization of petroleum and of other sulfur-containing pollutants. Of major interest is the so-called "4S pathway," in that C-S bonds are specifically cleaved leaving the carbon skeleton of substrates intact. This pathway is carried out by four enzymes, named Dsz A, B, C, and D. In view of a possible application of recombinant Dsz enzymes in biodesulfurization treatments, we have investigated the structural features of enzymes cloned from a Rhodococcus strain isolated from polluted environmental samples and their resistance to temperature (20-95 °C) and to organic solvents (5, 10, and 20 % v/v methanol, acetonitrile, hexane, and toluene). Changes in protein structures were assessed by circular dichroism and intrinsic fluorescence spectroscopy. We found that all Dsz proteins are unfolded by temperatures in the range 45-60 °C and by all solvents tested, with the most dramatic effect being produced by toluene. These results suggest that stabilization of the biocatalysts by protein engineering will be necessary for developing biodesulfurization technologies based on Dsz enzymes.

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.

Bioluminescence intensity difference observed in luminous bacteria groups with different motility

AIMS

The aim of this study was to compare the luminescent intensity of bioluminescence from marine luminous bacteria with different motility.

METHODS AND RESULTS

Luminescent bacteria were separated according to their motility using a microfluidic device. The cell densities of the separated samples were measured using a counting plate. The luminescent intensity of the separated samples was measured using a luminometer. The luminescent intensity per cell was calculated, and the values from the mobile (swimmers) and the nonmobile cells (nonswimmers) per single cell were compared; as a result, the former were proved to be larger than the latter.

CONCLUSIONS

Microfluidics were shown to be effective for the separation of bioluminescent bacteria and the bioluminescent intensity difference per cell was recognized with this experiment.

SIGNIFICANCE AND IMPACT OF THE STUDY

This study introduced for the first time a method to examine the individual cell function of Photobacterium kishitanii.

Fre Is the Major Flavin Reductase Supporting Bioluminescence from Vibrio harveyi Luciferase in Escherichia coli

Unlike the vast majority of flavoenzymes, bacterial luciferase requires an exogenous source of reduced flavin mononucleotide for bioluminescence activity. Within bioluminescent bacterial cells, species-specific oxidoreductases are believed to provide reduced flavin for luciferase activity. The source of reduced flavin in Escherichia coli-expressing bioluminescence is not known. There are two candidate proteins potentially involved in this process in E. coli, a homolog of the Vibrio harveyi Frp oxidoreductase, NfsA, and a luxG type oxidoreductase, Fre. Using single gene knock-out strains, we show that deletion of fre decreased light output by greater than two orders of magnitude, yet had no effect on luciferase expression in E. coli. Purified Fre is capable of supporting bioluminescence in vitro with activity comparable to that with the endogenous V. harveyi reductase (Frp), using either FMN or riboflavin as substrate. In a pull-down experiment, we found that neither Fre nor Frp co-purify with luciferase. In contrast to prior work, we find no evidence for stable complex formation between luciferase and oxidoreductase. We conclude that in E. coli, an enzyme primarily responsible for riboflavin reduction (Fre) can also be utilized to support high levels of bioluminescence.