Mineralization of
            <sup>14</sup>
            C-Ring-Labeled Synthetic Lignin Correlates with the Production of Lignin Peroxidase, not of Manganese Peroxidase or Laccase

Perez, J.; Jeffries, Thomas W.

doi:10.1128/aem.56.6.1806-1812.1990

Cited by 99 publications

(51 citation statements)

References 37 publications

(38 reference statements)

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“…These data not only indicated for the first time that the LiPs play a dominant role in lignin degradation but also showed that a strain of P. chrysosporium which lacked LiP activity could still degrade lignin, albeit to a minor extent. These conclusions were independently corroborated by later studies of Bonnarme and Jeffries [39] and Perez and Jeffries [45], who observed that LiP production is completely suppressed in the presence of high levels of Mn(II) and that only 10-11% of the lignin degradation occurs in such a medium, as compared to an identical medium with low levels of Mn(II) in which both LiPs and MnPs are produced. The above results further indicated that LiP production in P. chrysosporium is regulated differently, at least in some aspects, from MnP production and that LiPs play a dominant role in mineralizing synthetic [14C]lignin in liquid cultures.…”

Section: Regulation Of Lip Productionsupporting

confidence: 60%

Physiology and molecular biology of the lignin peroxidases of Phanerochaete chrysosporium

Reddy¹

1994

FEMS Microbiology Reviews

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The white-rot basidiomycete Phanerochaete chrysosporium produces lignin peroxidases (LiPs), a family of extracellular glycosylated heme proteins, as major components of its lignin-degrading system. Up to 15 LiP isozymes, ranging in M(r) values from 38,000 to 43,000, are produced depending on culture conditions and strains employed. Manganese-dependent peroxidases (MnPs) are a second family of extracellular heme proteins produced by P. chrysosporium that are also believed to be important in lignin degradation by this organism. LiP and MnP production is seen during secondary metabolism and is completely suppressed under conditions of excess nitrogen and carbon. Excess Mn(II) in the medium, on the other hand, suppresses LiP production but enhances MnP production. Nitrogen regulation of LiP and MnP production is independent of carbon and Mn(II) regulation. LiP activity is also affected by idiophasic extracellular proteases. Intracellular cAMP levels appear to be important in regulating the production of LiPs and MnPs, although LiP production is affected more than MnP production. Studies on the sequencing and characterization of lip cDNAs and genes of P. chrysosporium have shown that the major LiP isozymes are each encoded by a separate gene. Each lip gene encodes a mature protein that is 343-344 amino acids long, contains 1 putative N-glycosylation site, a number of putative O-glycosylation sites, and is preceded by a 27-28-amino acid leader peptide ending in a Lys-Arg cleavage site. The coding region of each lip gene is interrupted by 8-9 introns (50-63 bp), and the positions of the last two introns appear to be highly conserved. There are substantial differences in the temporal transcription patterns of the major lip genes. The sequence data suggest the presence of three lip gene subfamilies. The genomic DNA of P. chrysosporium strain BKMF-1767 was resolved into 10 chromosomes (genome size of 29 Mb), and that of strain ME-446 into 11 chromosomes (genome size of 32 Mb). The lip genes have been localized to five chromosomes in BKMF-1767 and to four chromosomes in ME-446. DNA transformation studies have reported both integrative and non-integrative transformation in P. chrysosporium.

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Section: Regulation Of Lip Productionsupporting

confidence: 60%

Physiology and molecular biology of the lignin peroxidases of Phanerochaete chrysosporium

Reddy¹

1994

FEMS Microbiology Reviews

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“…3E). In analogous chromatographic conditions in P. chrysosporium [15,20] and Bjerkandera spp. [17] cultures, LiP peaks exhibiting lower retention time than those showing MnP activity has been described.…”

Section: Resultsmentioning

confidence: 99%

“…Fast protein liquid chromatography (FPLC) of haemproteins was performed according to Perez and Je¡ries [15]. Peak detection was monitored at 280 nm (for total proteins) and at 405 nm (for haemproteins).…”

Section: Fplc Haemprotein Analysesmentioning

confidence: 99%

The effect of manganese on the production of Phanerochaete flavido-alba ligninolytic peroxidases in nitrogen limited cultures

Hamman

1999

FEMS Microbiology Letters

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Manganese supplementation of culture medium affected Phanerochaete flavido-alba FPL 106507 growth, glucose consumption and extracellular protein accumulation. Both the titre and time of detection of lignin peroxidase (LiP) were affected by manganese concentration in the medium, whereas with manganese peroxidase (MnP) only the titre was affected. In high Mn(II) containing cultures highest manganese peroxidase levels and a decrease in extracellular veratryl alcohol accumulation were observed. After FPLC a number of haemprotein peaks showing manganese peroxidase activity were detected in Mn(II) supplemented cultures. On the contrary, only haemprotein peaks of lignin peroxidase were detected in culture medium not supplemented with Mn(II). ß

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“…The production of LiP correlates, i.e. is simultaneous with the degradation of JaC-[Ring]-DHP to 14CO2 in P. radiata [28] and in P. chrysosporium [62]. Apparently, high evolution of 14CO, from 14C-[Ring]-labeIled DHP is in good correlation with the production of LiP in the cultures, provided that the fungus produces MnP.…”

Section: Degradation Of 14c-labelled Synthetic Lignin (Dhp) By Differmentioning

confidence: 96%

Lignin-modifying enzymes from selected white-rot fungi: production and role from in lignin degradation

Hatakka

1994

FEMS Microbiology Reviews

897

190

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White‐rot fungi produce extracellular lignin‐modifying enzymes, the best characterized of which are laccase (EC 1.10.3.2), lignin peroxidases (EC 1.11.1.7) and manganese peroxidases (EC 1.11.1.7). Lignin biodegradation studies have been carried out mostly using the white‐rot fungus Phanerochaete chrysosporium which produces multiple isoenzymes of lignin peroxidase and manganese peroxidase but does not produce laccase. Many other white‐rot fungi produce laccase in addition to lignin and manganese peroxidases and in varying combinations. Based on the enzyme production patterns of an array of white‐rot fungi, three categories of fungi are suggested: (i) lignin‐manganese peroxidase group (e.g.P. chrysosporium and Phlebia radiata), (ii) manganese peroxidase‐laccase group (e.g. Dichomitus squalens and Rigidoporus lignosus), and (iii) lignin peroxidase‐laccase group (e.g. Phlebia ochraceofulva and Junghuhnia separabilima). The most efficient lignin degraders, estimated by 14CO2 evolution from 14C‐[Ring]‐labelled synthetic lignin (DHP), belong to the first group, whereas many of the most selective lignin‐degrading fungi belong to the second, although only moderate to good [14C]DHP mineralization is obtained using fungi from this group. The lignin peroxidase‐laccase fungi only poorly degrade [14C]DHP.

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Mineralization of ¹⁴ C-Ring-Labeled Synthetic Lignin Correlates with the Production of Lignin Peroxidase, not of Manganese Peroxidase or Laccase

Cited by 99 publications

References 37 publications

Physiology and molecular biology of the lignin peroxidases of Phanerochaete chrysosporium

Physiology and molecular biology of the lignin peroxidases of Phanerochaete chrysosporium

The effect of manganese on the production of Phanerochaete flavido-alba ligninolytic peroxidases in nitrogen limited cultures

Lignin-modifying enzymes from selected white-rot fungi: production and role from in lignin degradation

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Mineralization of 14 C-Ring-Labeled Synthetic Lignin Correlates with the Production of Lignin Peroxidase, not of Manganese Peroxidase or Laccase

Cited by 99 publications

References 37 publications

Physiology and molecular biology of the lignin peroxidases of Phanerochaete chrysosporium

Physiology and molecular biology of the lignin peroxidases of Phanerochaete chrysosporium

The effect of manganese on the production of Phanerochaete flavido-alba ligninolytic peroxidases in nitrogen limited cultures

Lignin-modifying enzymes from selected white-rot fungi: production and role from in lignin degradation

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Mineralization of ¹⁴ C-Ring-Labeled Synthetic Lignin Correlates with the Production of Lignin Peroxidase, not of Manganese Peroxidase or Laccase