L(+)-Mandelate dehydrogenase from Rhodotorula graminis: purification, partial characterization and identification as a flavocytochrome b

Antimicrobial enzymes: an emerging strategy to fight microbes and microbial biofilms

With the increasing prevalence of antibiotic resistance, antimicrobial enzymes aimed at the disruption of bacterial cellular machinery and biofilm formation are under intense investigation. Several enzyme-based products have already been commercialized for application in the healthcare, food and biomedical industries. Successful removal of complex biofilms requires the use of multi-enzyme formulations that contain enzymes capable of degrading microbial DNA, polysaccharides, proteins and quorum-sensing molecules. The inclusion of anti-quorum sensing enzymes prevents biofilm reformation. The development of effective complex enzyme formulations is urgently needed to deal with the problems associated with biofilm formation in manufacturing, environmental protection and healthcare settings. Nevertheless, advances in synthetic biology, enzyme engineering and whole DNA-Sequencing technologies show great potential to facilitate the development of more effective antimicrobial and anti-biofilm enzymes.

Site-directed mutagenesis of the heme axial ligands in the hemoflavoenzyme cellobiose dehydrogenase

Cellobiose dehydrogenase (CDH) from Phanerochaete chrysosporium is an extracellular 90-kDa hemoflavoenzyme, organized into an N-terminal heme domain and a C-terminal flavin domain. The amino acid residues Met65 and His114 or His163 were suggested to be heme iron ligands. Mutations of these residues were made and mutant proteins were characterized. H114A mutant cultures produce a stable hemoflavoenzyme with spectral and kinetic characteristics similar to those of wild-type CDH. The M65A and H163A transformants secrete a 90-kDa hemoflavoenzyme, which oxidizes cellobiose in the presence of 2,6-dichlorophenol-indophenol (DCPIP), but is unable to reduce cytochrome c. The heme domains of the M65A and H163A CDH variants are, however, unstable and susceptible to degradation, both yielding a 70-kDa cellobiose-oxidizing flavoenzyme. The spectral and kinetic characteristics of these truncated variants suggest that they contain only their respective flavin domains. The yield of the 90-kDa proteins was low and the proteins could not be purified to homogeneity; however, absorption spectra indicate that the 90-kDa proteins do contain the heme domain. Like the truncated flavoenzymes, the 90-kDa variants reduce DCPIP but are unable to transfer electrons to cytochrome c, in contrast to wild-type CDH. These findings suggest that H163 and M65 are the axial heme ligands and that both ligands are required for the reactivity and structural integrity of the heme domain.

Humicola insolens cellobiose dehydrogenase: cloning, redox chemistry, and "logic gate"-like dual functionality

1Cellobiose dehydrogenase is a hemoflavoenzyme that catalyzes the sequential electron-transfer from an electron-donating substrate (e.g. cellobiose) to a flavin center, then to an electron-accepting substrate (e.g. quinone) either directly or via a heme center after an internal electron-transfer from the flavin to heme. We cloned the dehydrogenase from Humicola insolens, which encodes a protein of 761 amino acid residues containing an N-terminal heme domain and a C-terminal flavin domain, and studied how the catalyzed electron transfers are regulated. Based on the correlation between the rate and redox potential, we demonstrated that with a reduced flavin center, the enzyme, as a reductase, could export electron from its heme center by a "outer-sphere" mechanism. With the "resting" flavin center, however, the enzyme could have a peroxidase-like function and import electron to its heme center after a peroxidative activation. The dual functionality of its heme center makes the enzyme a molecular "logic gate", in which the electron flow through the heme center can be switched in direction by the redox state of the coupled flavin center.

L-Mandelate dehydrogenase from Rhodotorula graminis: cloning, sequencing and kinetic characterization of the recombinant enzyme and its independently expressed flavin domain

The l-mandelate dehydrogenase (L-MDH) from the yeast Rhodotorula graminis is a mitochondrial flavocytochrome b2 which catalyses the oxidation of mandelate to phenylglyoxylate coupled with the reduction of cytochrome c. We have used the N-terminal sequence of the enzyme to isolate the gene encoding this enzyme using the PCR. Comparison of the genomic sequence with the sequence of cDNA prepared by reverse transcription PCR revealed the presence of 11 introns in the coding region. The predicted amino acid sequence indicates a close relationship with the flavocytochromes b2 from Saccharomyces cerevisiae and Hansenula anomala, with about 40% identity to each. The sequence shows that a key residue for substrate specificity in S. cerevisiae flavocytochrome b2, Leu-230, is replaced by Gly in L-MDH. This substitution is likely to play an important part in determining the different substrate specificities of the two enzymes. We have developed an expression system and purification protocol for recombinant L-MDH. In addition, we have expressed and purified the flavin-containing domain of L-MDH independently of its cytochrome domain. Detailed steady-state and pre-steady-state kinetic investigations of both L-MDH and its independently expressed flavin domain have been carried out. These indicate that L-MDH is efficient with both physiological (cytochrome c, kcat=225 s-1 at 25 degrees C) and artificial (ferricyanide, kcat=550 s-1 at 25 degrees C) electron acceptors. Kinetic isotope effects with [2-2H]mandelate indicate that H-C-2 bond cleavage contributes somewhat to rate-limitation. However, the value of the isotope effect erodes significantly as the catalytic cycle proceeds. Reduction potentials at 25 degrees C were measured as -120 mV for the 2-electron reduction of the flavin and -10 mV for the 1-electron reduction of the haem. The general trends seen in the kinetic studies show marked similarities to those observed previously with the flavocytochrome b2 (L-lactate dehydrogenase) from S. cerevisiae.

Cloning of a cDNA encoding cellobiose dehydrogenase, a hemoflavoenzyme from Phanerochaete chrysosporium

Cellobiose dehydrogenase (CDH) is an extracellular hemoflavoenzyme produced by cellulose-degrading cultures of the wood-degrading basidiomycete Phanerochaete chrysosporium. CDH contains one flavin adenine dinucleotide (FAD) and one heme b per molecule, and it oxidizes cellobiose to cellobionolactone. In this report, a 2.4-kb cDNA encoding CDH was isolated by screening an expression library of P. chrysosporium OGC101 with a CDH-specific polyclonal antibody. The cDNA encodes a 755-amino-acid protein with a predicted mass of 80,115 Da. Sequence analysis suggests that the heme domain is located at the N terminus and that the falvin domain is located at the C terminus. The flavin domain shows a beta 1-alpha A-beta 2 motif for FAD binding and has high sequence similarity to several FAD-dependent enzymes. Little sequence similarity to hemoflavoenzymes is found. CDH binds to cellulose similarly to cellulases. However, little sequence similarity is observed with the conserved cellulose-binding sequences of cellulases. This suggests that CDH might possess a specific sequence for cellulose binding which is different from that of cellulases. Northern (RNA) blot analysis of total RNA from cellulose-, glucose-, and cellobiose-grown P. chrysosporium indicated that CDH mRNA is produced only in cellulose-grown cells. This suggests that CDH expression is regulated at the transcriptional level by either cellulose or one of its degradation products. Southern blot analysis suggests the presence of only a single gene for CDH in P. chrysosporium OGC101.

alpha/beta barrel evolution and the modular assembly of enzymes: emerging trends in the flavin oxidase/dehydrogenase family

Alpha/beta barrels have an ill-defined origin. Evidence exists which favours their divergent evolution from a common ancestral barrel and convergent evolution to a stable fold. However, recent sequence and structural information for the flavin oxidase/dehydrogenase family of barrel enzymes indicate that sub-families of alpha/beta barrels have evolved divergently. The modular fusion of barrel domains with core structures from other gene families has also contributed to the evolution of related but catalytically distinct enzyme molecules within each sub-family of the flavin oxidases/dehydrogenases. An analysis of the structures and sequences of the flavin oxidases/dehydrogenases has now enabled studies focusing on the evolutionary origins and modular assembly of this important family of proteins to be initiated.

The cytochrome b5-fold: an adaptable module

The family of b5-like cytochromes encompasses, besides cytochrome b5 itself, hemoprotein domains covalently associated with other redox proteins, in flavocytochrome b2 (L-lactate dehydrogenase), sulfite oxidase and assimilatory nitrate reductase. A comparison of about 40 amino acid sequences deposited in data banks shows that eight residues are invariant and about 15 positions carry strongly conservative substitutions. Examination of the location of these invariant and conserved positions in the light of the three-dimensional structures of beef cytochrome b5 and S cerevisiae flavocytochrome b2 suggests a strongly conserved protein structure for the b5-like heme-binding domain throughout evolution. Numerous NMR studies have demonstrated the existence of a positional isomerism for the heme, which involves both a 180 degree-rotation around the heme alpha,gamma-meso carbon atoms and a rotation through an axis normal to the heme plane at the iron. NMR studies did not detect significant differences in protein structure between reduced and oxidized states, or between species. The role of a number of side chains was probed by site-directed mutagenesis. Studies of complex formation and of electron transfer rates between cytochrome b5 and redox partners have led to the idea that complexation is driven by electrostatic forces, that it is generally the exposed heme edge which makes contact with electron donors and acceptors, but that there are multiple overlapping sites within this general area. For the bi- and trifunctional members of the family, extrapolation of available data would suggest a mobile heme-binding domain within a complex structure. In these cases the existence of a single interaction area for both electron donor and acceptor, or of two different ones, remains open to discussion.