The role of Glu39 in MnII binding and oxidation by manganese peroxidase from Phanerochaete chrysoporium.

Manganese peroxidase (MnP) is a heme-containing enzyme produced by white-rot fungi and is part of the extracellular lignin degrading system in these organisms. MnP is unique among Mn binding enzymes in its ability to bind and oxidize Mn(II) and efficiently release Mn(III). Initial site-directed mutagenesis studies identified the residues E35, E39, and D179 as the Mn binding ligands. However, an E39D variant was recently reported to display wild-type Mn binding and rate of oxidation, calling into question the role of E39 as an Mn ligand. To investigate this hypothesis, we performed computer modeling studies which indicated metal-ligand bond distances in the E39D variant and in an E35D--E39D--D179E triple variant which might allow Mn binding and oxidation. To test the model, we reconstructed the E35D and E39D variants used in the previous study, as well as an E39A single variant and the E35D--E39D--D179E triple variant of MnP isozyme 1 from Phanerochaete chrysosporium. We find that all of the variant proteins are impaired for Mn(II) binding (K(m) increases 20--30-fold) and Mn(II) oxidation (k(cat) decreases 50--400-fold) in both the steady state and the transient state. In particular, mutation of the E39 residue in MnP decreases both Mn binding and oxidation. The catalytic efficiency of the E39A variants decreased approximately 10(4)-fold, while that of the E39D variant decreased approximately 10(3)-fold. Contrary to initial modeling results, the triple variant performed only as well as any of the single Mn ligand variants. Interestingly, the catalytic efficiency of the triple variant decreased only 10(4)-fold, which is approximately 10(2)-fold better than that reported for the E35Q--D179N double variant. These combined studies indicate that precise geometry of the Mn ligands within the Mn binding site of MnP is essential for the efficient binding, oxidation, and release of Mn by this enzyme. The results clearly indicate that E39 is a Mn ligand and that mutation of this ligand decreases both Mn binding and the rate of Mn oxidation.

Role of arginine 177 in the MnII binding site of manganese peroxidase. Studies with R177D, R177E, R177N, and R177Q mutants.

Previously, we reported that Arg177 is involved in MnII binding at the MnII binding site of manganese peroxidase isozyme 1 (MnP1) of Phanerochaete chrysosporium by examining two mutants: R177A and R177K. We now report on additional mutants: R177D, R177E, R177N, and R177Q. These new mutant enzymes were produced by homologous expression in P. chrysosporium and were purified to homogeneity. The molecular mass and the UV/visible spectra of the ferric and oxidized intermediates of the mutant enzymes were similar to those of the wild-type enzyme, suggesting proper folding, heme insertion, and preservation of the heme environment. However, steady-state and transient-state kinetic analyses demonstrate significantly altered characteristics of MnII oxidation by these new mutant enzymes. Increased dissociation constants (Kd) and apparent Km values for MnII suggest that these mutations at Arg177 decrease binding of MnII to the enzyme. These lowered binding efficiencies, as observed with the R177A and R177K mutants, suggest that the salt-bridge between Arg177 and the MnII binding ligand Glu35 is disrupted in these new mutants. Decreased kcat values for MnII oxidation, decreased second-order rate constants for compound I reduction (k2app), and decreased first-order rate constants for compound II reduction (k3) indicate that these new mutations also decrease the electron-transfer rate. This decrease in rate constants for compounds I and II reduction was not observed in our previous study on the R177A and R177K mutations. The lower rate constants suggest that, even with high MnII concentrations, the MnII binding geometries may be altered in the MnII binding site of these new mutants. These new results, combined with the results from our previous study, clearly indicate a role for Arg177 in promoting efficient MnII binding and oxidation by MnP.

MnII is not a productive substrate for wild-type or recombinant lignin peroxidase isozyme H2.

The glyceraldehyde-3-phosphate dehydrogenase (gpd) gene promoter was used to drive the homologous expression of the lignin peroxidase (LiP) isozyme H2 gene in primary metabolic cultures of Phanerochaete chrysosporium. The molecular mass, pI, and optical absorption spectra of purified recombinant LiPH2 (rLiPH2) were essentially identical to those of wild-type LiPH2 (wtLiPH2). wtLiPH2 was prepared by growing cells in the absence of MnII, conditions under which P. chrysosporium manganese peroxidase (MnP) is not expressed, ensuring that wtLiPH2 was not contaminated with MnP. The kinetics of veratryl alcohol (VA) oxidation were essentially identical for rLiPH2 and wtLiPH2. The rLiPH2, wtLiPH2, and wild-type LiP isozyme H8 (wt-LiPH8) enzymes were used to reexamine previous claims that LiPH2 can oxidize Mn" at a rate sufficient to promote catalytic turnover of the enzyme. Our results demonstrate that rLiPH2, wtLiPH2, and LiPH8 do not turn over under steady-state conditions, when MnII is the sole reducing substrate. Furthermore, transient-state kinetic analyses show that the reduction rate of the catalytic intermediate, LiP compound I, by VA was at least 2 x 10(3)-fold higher than the rate of reduction in the presence of MnII. No reduction of LiP compound II was observed in the presence of MnII. In contrast to previous claims, these data strongly suggest that MnII is not a productive substrate for LiPH2 or LiPH8.

Arginine 177 is involved in Mn(II) binding by manganese peroxidase.

Site-directed mutations R177A and R177K in the gene encoding manganese peroxidase isozyme 1 (mnp1) from Phanerochaete chrysosporium were generated. The mutant enzymes were expressed in P. chrysosporium during primary metabolic growth under the control of the glyceraldehyde-3-phosphate dehydrogenase gene promoter, purified to homogeneity, and characterized by spectroscopic and kinetic methods. The UV-vis spectra of the ferric and oxidized states and resonance Raman spectra of the ferric state were similar to those of the wild-type enzyme, indicating that the heme environment was not significantly affected by the mutations at Arg177. Apparent K(m) values for Mn(II) were approximately 20-fold greater for the R177A and R177K MnPs than for wild-type MnP. However, the apparent K(m) values for the substrates, H(2)O(2) and ferrocyanide, and the k(cat) values for Mn(II) and ferrocyanide oxidation were similar to those of the wild-type enzyme. The second-order rate constants for compound I (MnPI) reduction of the mutant MnPs by Mn(II) were approximately 10-fold lower than for wild-type MnP. In addition, the K(D) values calculated from the first-order plots of MnP compound II (MnPII) reduction by Mn(II) for the mutant enzymes were approximately 22-fold greater than for wild-type MnP. In contrast, the first-order rate constants for MnPII reduction by Mn(II) were similar for the mutant and wild-type MnPs. Furthermore, second-order rate constants for the wild-type and mutant enzymes for MnPI formation, for MnPI reduction by bromide, and for MnPI and MnPII reduction by ferrocyanide were not significantly changed. These results indicate that both the R177A and R177K mutations specifically affect the binding of Mn, whereas the rate of electron transfer from Mn(II) to the oxidized heme apparently is not affected.

Homologous expression of recombinant lignin peroxidase in Phanerochaete chrysosporium.

The glyceraldehyde-3-phosphate dehydrogenase (gpd) promoter was used to drive expression of lip2, the gene encoding lignin peroxidase (LiP) isozyme H8, in primary metabolic cultures of Phanerochaete chrysosporium. The expression vector, pUGL, also contained the Schizophyllum commune ura1 gene as a selectable marker. pUGL was used to transform a P. chrysosporium Ura11 auxotroph to prototrophy. Ura+ transformants were screened for peroxidase activity in liquid cultures containing high-carbon and high-nitrogen medium. Recombinant LiP (rLiP) was secreted in active form by the transformants after 4 days of growth, whereas endogenous lip genes were not expressed under these conditions. Approximately 2 mg of homogeneous rLiP/liter was obtained after purification. The molecular mass, pI, and optical absorption spectrum of rLiPH8 were essentially identical to those of the wild-type LiPh8 (wt LiPH8), indicating that heme insertion, folding, and secretion functioned normally in the transformant. Steady-state and transient-state kinetic properties for the oxidation of veratryl alcohol between wtLiPH8 and rLiPH8 were also identical.

Degradation of 2,4,6-trichlorophenol by Phanerochaete chrysosporium: involvement of reductive dechlorination.

Under secondary metabolic conditions, the lignin-degrading basidiomycete Phanerochaete chrysosporium mineralizes 2,4, 6-trichlorophenol. The pathway for the degradation of 2,4, 6-trichlorophenol has been elucidated by the characterization of fungal metabolites and oxidation products generated by purified lignin peroxidase (LiP) and manganese peroxidase (MnP). The multistep pathway is initiated by a LiP- or MnP-catalyzed oxidative dechlorination reaction to produce 2,6-dichloro-1,4-benzoquinone. The quinone is reduced to 2,6-dichloro-1,4-dihydroxybenzene, which is reductively dechlorinated to yield 2-chloro-1,4-dihydroxybenzene. The latter is degraded further by one of two parallel pathways: it either undergoes further reductive dechlorination to yield 1, 4-hydroquinone, which is ortho-hydroxylated to produce 1,2, 4-trihydroxybenzene, or is hydroxylated to yield 5-chloro-1,2, 4-trihydroxybenzene, which is reductively dechlorinated to produce the common key metabolite 1,2,4-trihydroxybenzene. Presumably, the latter is ring cleaved with subsequent degradation to CO2. In this pathway, the chlorine at C-4 is oxidatively dechlorinated, whereas the other chlorines are removed by a reductive process in which chlorine is replaced by hydrogen. Apparently, all three chlorine atoms are removed prior to ring cleavage. To our knowledge, this is the first reported example of aromatic reductive dechlorination by a eukaryote.

Identification, cloning and sequence of the Aspergillus niger areA wide domain regulatory gene controlling nitrogen utilisation.

The gene encoding the positive-acting regulator of nitrogen metabolite repression (AREA) has been cloned and characterised from the industrially important filamentous fungus Aspergillus niger. The deduced amino acid sequence has an overall level of identity with its homologues from other fungal species which varies between 32 and 72%. This gene (areAnig) complements the A. nidulans areAr-18 loss-of-function mutation. Sequences upstream of the structural gene contain several putative GATA-type zinc finger protein-binding motifs. Northern analysis indicates the synthesis of multiple transcripts, the major species being approximately 2.95 kb and 3.1 kb. Maximal expression of areAnig is observed under conditions of nitrogen starvation and is mainly due to an increase in the level of the shorter transcript.

Disruption of three acid proteases in Aspergillus niger--effects on protease spectrum, intracellular proteolysis, and degradation of target proteins.

Three acid protease genes encoding two extracellular proteases (PEPA and PEPB) and one intracellular protease (PEPE) were disrupted in Aspergillus niger. Northern-blot analysis showed the absence of wild-type protease mRNAs in the disruptants while western-blot analysis proved the absence of the encoded proteases. Characterization of the residual proteolytic spectra in the disruptants indicated that the extracellular protease activity was reduced to 16% and 94% for the delta pepA and the delta pepB disruptants, repectively. In the delta pepE disruptant, the total intracellular proteolytic activity was reduced to 32%. Apart from the reduced intracellular pepstatin-inhibitable aspartyl protease activity, serine protease and serine carboxypeptidase activities were also significantly reduced in the delta pepE strain. This may indicate the presence of a cascade activation mechanism for several vacuolar proteases, triggered by the PEPE protein, similar to the situation in Saccharomyces cerevisiae. Disruption of a single protease gene had no effects on the transcription of other non-disrupted protease genes in A. niger. In supernatants of the disruptants, reduced degradation of a proteolytically very susceptible tester protein (PELB) was observed. By recombination, we also constructed delta pepA delta pepB, delta pepB delta pepE and delta pepA delta pepE double disruptants as well as a delta pepA delta pepB delta pepE triple disruptant, lacking all three acid protease activities. The in vitro residual PELB activity was the highest in the triple disruptant and the delta pepA delta pepB recombinant.

Partial conversion of cinnamic acid into styrene by growing cultures and cell-free extracts of the yeast Cryptococcus elinovii.

Cultures of Cryptococcus elinovii CBS 7051 grown at the expense of cinnamic acid as the sole source of carbon and energy partially converted this substrate into styrene. The latter is toxic and eventually kills the culture. Cell-free extracts of cultures grown on cinnamic acid produced styrene from cinnamate. Other basidiomycetous yeasts tested did not produce styrene from cinnamic acid.

Degradation of some phenols and hydroxybenzoates by the imperfect ascomycetous yeasts Candida parapsilosis and Arxula adeninivorans: evidence for an operative gentisate pathway.

The imperfect ascomycetous yeasts Candida parapsilosis and Arxula adeninivorans degraded 3-hydroxybenzoic acid via gentisate which was the cleavage substrate. 4-Hydroxybenzoic acid was metabolized via protocatechuate. No cleavage enzyme for the latter was detected. In stead of this NADH- and NADPH-dependent monooxygenases were present. In cells grown at the expense of hydroquinone and 4-hydroxybenzoic acid, enzymes of the hydroxyhydroquinone variant of the 3-oxoadipate pathway were demonstrated, which also took part in the degradation of 2,4-dihydroxybenzoic acid by C. parapsilosis.