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Information on EC 1.14.99.56 - lytic cellulose monooxygenase (C4-dehydrogenating)
for references in articles please use BRENDA:EC1.14.99.56
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EC Tree 1 Oxidoreductases
1.14 Acting on paired donors, with incorporation or reduction of molecular oxygen
1.14.99 Miscellaneous
1.14.99.56 lytic cellulose monooxygenase (C4-dehydrogenating)
IUBMB Comments
This copper-containing enzyme, found in fungi and bacteria, cleaves cellulose in an oxidative manner. The cellulose fragments that are formed contain a 4-dehydro-D-glucose residue at the non-reducing end. Some enzymes also oxidize cellulose at the C-1 position of the reducing end forming a D-glucono-1,5-lactone residue [cf. EC 1.14.99.54, lytic cellulose monooxygenase (C1-hydroxylating)].
The expected taxonomic range for this enzyme is: Eukaryota, Bacteria
Reaction Schemes
showSynonyms
AA9, AA9A, Cel61a, chitin-binding domain 3 protein, EglD, FG02202.1, gh61-5, gh61e, GH61I, LPMO-02916, more
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SYNONYM 
ORGANISM
UNIPROT
COMMENTARY 
LITERATURE
AA9A
Cel61a
EglD
FG02202.1
gh61-5
LPMO10B
LPMO9A
LPMO9C
LPMO9D
LPMO9f
LPMO9I
LPMOJ
MYCTH_79765
NCU08760
Tfu_1268
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REACTION
REACTION DIAGRAM
COMMENTARY
ORGANISM
UNIPROT
LITERATURE
[(1->4)-beta-D-glucosyl]n+m + reduced acceptor + O2 = 4-dehydro-beta-D-glucosyl-[(1->4)-beta-D-glucosyl]n-1 + [(1->4)-beta-D-glucosyl]m + acceptor + H2O
-
-
-
-
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PATHWAY SOURCE
PATHWAYS
BRENDA
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SYSTEMATIC NAME
IUBMB Comments
cellulose, hydrogen-donor:oxygen oxidoreductase (D-glucosyl C4-dehydrogenating)
This copper-containing enzyme, found in fungi and bacteria, cleaves cellulose in an oxidative manner. The cellulose fragments that are formed contain a 4-dehydro-D-glucose residue at the non-reducing end. Some enzymes also oxidize cellulose at the C-1 position of the reducing end forming a D-glucono-1,5-lactone residue [cf. EC 1.14.99.54, lytic cellulose monooxygenase (C1-hydroxylating)].
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SUBSTRATE
PRODUCT
REACTION DIAGRAM
ORGANISM
UNIPROT
LITERATURE
COMMENTARY
Reversibility
r=reversible
ir=irreversible
?=not specified
r=reversible
ir=irreversible
?=not specified
amorphous cellulose + ascorbate + O2
C1/C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
arabinoxylan + ascorbic acid + O2
C1/C4-oxidized oxidized xylo-oligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
avicel + ascorbate + O2
C1/C4-oxidized oligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
avicel + ascorbate + O2
oxidized cellooligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
avicel + ascorbic acid + O2
? + dehydroascorbic acid + H2O
-
Substrates: -
Products: -
Products: -
?
beta-(1->3,1->4)-glucan + ascorbate + O2
C4-oxidized glucan oligosaccharides + dehydroascorbate + H2O
Substrates: substrate is regenerated amorphous cellulose
Products: -
Products: -
?
birch wood xylan + ascorbic acid + O2
C1/C4-oxidized oxidized xylobiose, xylotriose, xylotetraoase and xylyopentaose + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
carboxy methyl cellulose + ascorbate + O2
C1/C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
carboxymethylellulose + ascorbate + O2
C1/C4-carboxymethylcellooligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
cellohexaose + acceptor + O2
oxidized cellobiose and cellotriose + reduced acceptor + H2O
-
Substrates: -
Products: -
Products: -
?
cellohexaose + ascorbate + O2
? + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
cellohexaose + ascorbate + O2
C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
cellohexaosyl-(2-aminobenzamide) + ascorbate + O2
cellotriose + oxidized cellotriosyl-(2-aminobenzamide) + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
cellooligosaccharide + pyrogallol + O2
?
-
Substrates: -
Products: -
Products: -
?
cellotetraose + acceptor + O2
? + reduced acceptor + H2O
-
Substrates: -
Products: -
Products: -
?
cellotriose + acceptor + O2
? + reduced acceptor + H2O
-
Substrates: -
Products: -
Products: -
?
cellulose + ? + O2
C1/C4-cellooligosaccharides + ? + H2O
-
Substrates: -
Products: -
Products: -
?
cellulose + ascorbate + O2
C1/C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
cellulose + ascorbate + O2
C4-oxidized gluco-oligosaccharides + dehydroascorbate + H2O
Substrates: substrate is regenerated amorphous cellulose
Products: sole release of C4-oxidized and non-oxidized gluco-oligosaccharides
Products: sole release of C4-oxidized and non-oxidized gluco-oligosaccharides
?
cellulose + ascorbic acid + O2
? + dehydroascorbic acid + H2O
-
Substrates: -
Products: -
Products: -
?
cellulose + dopamine + O2
C4-oxidized gluco-oligosaccharides + 4-(2-aminoethyl)cyclohexa-3,5-diene-1,2-dione + H2O
Substrates: -
Products: dopamine shows 6% of the activity with ascorbate
Products: dopamine shows 6% of the activity with ascorbate
?
cellulose + reduced acceptor + O2
? + oxidized acceptor + H2O
-
Substrates: -
Products: -
Products: -
?
cellulose acetate + ? + O2
? + H2O
-
Substrates: lytic polysaccharide monooxygenase is able to cleave cellulose acetates with a degree of acetylation of up to 1.4. Preferentially, fragments with a low degree of acetylation are released
Products: -
Products: -
?
colloidal cellulose nanofibrils + ascorbate + O2
oxidized cellooligosaccharides + dehydroascorbate + H2O
-
Substrates: substrate colloidal cellulose nanofibrils from potato tubers is produced by alkaline treatment to remove noncellulosic polysaccharides, followed by hypochlorite oxidation and homogenization. Substrate consists of about 94% cellulose, and carboxyl groups on the surface prevent their agglomeration, its suspensions have up to two times higher optical transparency than phosphoric acid swollen cellulose
Products: -
Products: -
?
glucomannan + ascorbate + O2
C4-oxidized cellotriose + oxidized cellotetraose + oxidized cellopentaose + dehydroascorbate + H2O
konjac glucomannan + ascorbic acid + O2
? + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
microcrystalline cellulose + ascorbate + O2
C1/C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
phosphoric acid swollen cellulose + acceptor + O2
oxidized cellobiose and cellotriose + reduced acceptor + H2O
-
Substrates: -
Products: main products, C4 is the sole site of oxidation
Products: main products, C4 is the sole site of oxidation
?
phosphoric acid swollen cellulose + ascorbate + O2
C1/C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbate + O2
oxidized cellooligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbic acid + O2
? + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbic acid + O2
C4-oxidized cellooligosaccharides + dehydroascorbic acid + H2O
phosphoric acid swollen cellulose + ascorbic acid + O2
oxidized cellooligosaccharides + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
phosphoric acid-swollen cellulose + ascorbate + O2
C1/C4-cellooligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + ascorbate + O2
C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
phosphoric acid-swollen cellulose + ascorbate + O2
C4-oxidized cellooligosaccharides + dehydroascorbic acid + H2O
phosphoric acid-swollen cellulose + ascorbate + O2
cellooligosaccharide + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
reduced xyloglucan oligosaccharide + ascorbic acid + O2
xyloglucan oligosaccharides + dehydroascorbic acid + H2O
Substrates: pure xyloglucan oligosaccharide with DP14
Products: -
Products: -
?
soluble beta-glucan + ascorbic acid + O2
? + dehydroascorbic acid + H2O
-
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + ascorbic acid + O2
? + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
xyloglucan + ascorbate + O2
C4-oxidized oligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
[(1->4)-beta-D-glucosyl]n+m + reduced acceptor + O2
4-dehydro-beta-D-glucosyl-[(1->4)-beta-D-glucosyl]n-1 + [(1->4)-beta-D-glucosyl]m + acceptor + H2O
D9SZQ3
Substrates: -
Products: -
Products: -
?
2,6-dimethoxyphenol + 2 H2O2
coerulignone + 2 H2O
-
Substrates: -
Products: -
Products: -
?
2,6-dimethoxyphenol + 2 H2O2
coerulignone + 2 H2O
-
Substrates: -
Products: -
Products: -
?
amorphous cellulose + ascorbate + O2
C1/C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
amorphous cellulose + ascorbate + O2
C1/C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
avicel PH 101 + ascorbic acid + O2
? + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
avicel PH 101 + ascorbic acid + O2
? + dehydroascorbic acid + H2O
-
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
A0A5S8WF95
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
cello-hexaose + 2 cysteine + O2
C4-oxidized cellotriose + C4-oxidized cellotetraose + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
cellopentaose + ascorbate + O2
? + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
cellopentaose + ascorbate + O2
? + dehydroascorbate + H2O
Aspergillus tamarii CBS 117626
-
Substrates: -
Products: -
Products: -
?
cellopentaose + ascorbate + O2
? + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
cellopentaose + ascorbate + O2
? + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
-
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
-
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
-
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
A0A5S8WF95
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
-
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
-
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + 2 cysteine + O2
C4-oxidized gluco-oligosaccharides + cystine + H2O
-
Substrates: crystalline cellulose
Products: -
Products: -
?
cellulose + ascorbate + O2
C1/C4-oxidized cello-oligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
cellulose + ascorbate + O2
C1/C4-oxidized cello-oligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
cellulose + ascorbate + O2
C1/C4-oxidized oligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
cellulose + ascorbate + O2
C1/C4-oxidized oligosaccharides + dehydroascorbate + H2O
Aspergillus tamarii CBS 117626
-
Substrates: -
Products: -
Products: -
?
cellulose + ascorbate + O2
C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
cellulose + ascorbate + O2
C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
cellulose + ascorbate + O2
C4/C6-oxidized gluco-oligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
cellulose + ascorbate + O2
C4/C6-oxidized gluco-oligosaccharides + dehydroascorbate + H2O
-
Substrates: -
Products: -
Products: -
?
chitin + ascorbic acid + O2
? + dehydroascorbate + H2O
D9SZQ3
Substrates: -
Products: -
Products: -
?
chitin + ascorbic acid + O2
? + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
glucomannan + ascorbate + O2
C4-oxidized cellotriose + oxidized cellotetraose + oxidized cellopentaose + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
glucomannan + ascorbate + O2
C4-oxidized cellotriose + oxidized cellotetraose + oxidized cellopentaose + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
microcrystalline cellulose + ascorbate + O2
C1/C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
microcrystalline cellulose + ascorbate + O2
C1/C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
NaOH pretreated soy spent flakes + ascorbic acid + O2
? + dehydroascorbic acid + H2O
-
Substrates: -
Products: -
Products: -
?
NaOH pretreated soy spent flakes + ascorbic acid + O2
? + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulase + ascorbic acid + O2
? + dehydroascorbate + H2O
D9SZQ3
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulase + ascorbic acid + O2
? + dehydroascorbate + H2O
Micromonospora aurantiaca (nom. illeg.) DSM 43813
D9SZQ3
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulase + ascorbic acid + O2
? + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulase + ascorbic acid + O2
? + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbate + O2
? + dehydroascorbate + H2O
Substrates: -
Products: the nonreducing end product is a 4-ketoaldose
Products: the nonreducing end product is a 4-ketoaldose
?
phosphoric acid swollen cellulose + ascorbate + O2
? + dehydroascorbate + H2O
Substrates: -
Products: the nonreducing end product is a 4-ketoaldose
Products: the nonreducing end product is a 4-ketoaldose
?
phosphoric acid swollen cellulose + ascorbic acid + O2
? + dehydroascorbic acid + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbic acid + O2
? + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbic acid + O2
? + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbic acid + O2
? + dehydroascorbic acid + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbic acid + O2
? + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbic acid + O2
? + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbic acid + O2
C4-oxidized cellooligosaccharides + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid swollen cellulose + ascorbic acid + O2
C4-oxidized cellooligosaccharides + dehydroascorbic acid + H2O
Thermothelomyces thermophilus DSM 1799
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
A0A5S8WF95
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + 2 cysteine + O2
C4-oxidized cello-oligosaccharide + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + ascorbate + O2
C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + ascorbate + O2
C4-oxidized cellooligosaccharides + dehydroascorbate + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + ascorbate + O2
C4-oxidized cellooligosaccharides + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
phosphoric acid-swollen cellulose + ascorbate + O2
C4-oxidized cellooligosaccharides + dehydroascorbic acid + H2O
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
A0A5S8WF95
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
tamarind xyloglucan + 2 cysteine + O2
? + cystine + H2O
-
Substrates: -
Products: -
Products: -
?
xyloglucan + gallate + O2
?
Substrates: -
Products: -
Products: -
?
additional information
?
-
-
Substrates: no substrate: xylan, starch, laminarin, chitin. cleavage of cleavage of hemicelluloses and phosphoric acid swollen cellulose C uses both C1- and C4-oxidizing mechanisms, reaction of EC 1.14.99.54 and EC 1.14.99.56
Products: -
Products: -
?
additional information
?
-
-
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
-
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
-
Substrates: isoforms AA9A and AA9B react on cellulose and on xyloglucan
Products: -
Products: -
?
additional information
?
-
Aspergillus tamarii CBS 117626
-
Substrates: isoforms AA9A and AA9B react on cellulose and on xyloglucan
Products: -
Products: -
?
additional information
?
-
-
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme catalyzes mixed C1/C4 oxidative cleavage of cellulose, reactions of EC 1.14.99.54 and EC1.14.99.56, and xyloglucan, reaction of lytic xyloglucan monooxygenase, but is inactive toward other (1,4)-linked beta-glucans or chitin and cellooligosaccharides with a degree of polymerization DP 3-6. It shows broad specificity on xyloglucan, cleaving any glycosidic bond in the beta-glucan main chain, regardless of xylosyl substitutions. When incubated with a mixture of xyloglucan and cellulose, LPMO9A efficiently attacks the xyloglucan, whereas cellulose conversion is inhibited. no substrates: xyloglucan-heptamer, birchwood xylan, wheat arabinoxylan, konjac glucomannan, ivory nut mannan, beta-glucan from barley, lichenan from Icelandic moss, starch, and spruce galactoglucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme catalyzes mixed C1/C4 oxidative cleavage of cellulose, reactions of EC 1.14.99.54 and EC1.14.99.56, and xyloglucan, reaction of lytic xyloglucan monooxygenase, but is inactive toward other (1,4)-linked beta-glucans or chitin and cellooligosaccharides with a degree of polymerization DP 3-6. It shows broad specificity on xyloglucan, cleaving any glycosidic bond in the beta-glucan main chain, regardless of xylosyl substitutions. When incubated with a mixture of xyloglucan and cellulose, LPMO9A efficiently attacks the xyloglucan, whereas cellulose conversion is inhibited. no substrates: xyloglucan-heptamer, birchwood xylan, wheat arabinoxylan, konjac glucomannan, ivory nut mannan, beta-glucan from barley, lichenan from Icelandic moss, starch, and spruce galactoglucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: gradual addition of H2O2 allows LPMO activity at very low, substoichiometric reductant concentrations. Enzyme accepts ascorbate and gallate as reductant, but not 2,3-dihydroxybenzoate under standard aerobic conditions. 2,3-dihydroxybenzoate is accepted in the presence of externally added H2O2 and at alkaline pH it is able to drive the LPMO reaction without externally added H2O2. No substrates: phosphoric acid-swollen cellulose, soluble cello-oligosaccharides (Glc5 and Glc6), konjac glucomannan, lichenan from Icelandic moss, birchwood xylan, galactomannan, wheat arabinoxylan, barley beta-glucan, ivory nut mannan
Products: -
Products: -
?
additional information
?
-
-
Substrates: no substrate: locus bean glucomannan, tamarind xyloglucan, barley beta-1,3/1,4-glucan and birchwood xylan, carboxymethylcellulose or short cellooligosaccharides
Products: -
Products: -
?
additional information
?
-
Substrates: poor substrate: bacterial microcrystalline cellulose
Products: -
Products: -
?
additional information
?
-
Substrates: poor substrate: bacterial microcrystalline cellulose
Products: -
Products: -
?
additional information
?
-
-
Substrates: both cellulosic and hemicellulosic substrates are equally preferred
Products: -
Products: -
?
additional information
?
-
Substrates: the enzyme inserts oxygen at the 4-position. After oxygen insertion, the glycosidic bond is destabilized and likely broken by an elimination reaction, which may be catalyzed by the PMO or occur spontaneously. This elimination is irreversible because the carbon on the reducing or nonreducing end has been oxidized
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan. Enzyme is active on xyloglucan only in the presence of phosphoric acid-swollen cellulose
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan. Enzyme is active on xyloglucan only in the presence of phosphoric acid-swollen cellulose
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan. Enzyme is active on xyloglucan only in the presence of phosphoric acid-swollen cellulose
Products: -
Products: -
?
additional information
?
-
Substrates: acts on cellooligosaccharides with degree of polymerization above 5, xyloglucan, glucomannan, and x02beta-glucan, exclusively products oxidized at the C4 position are found. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: acts on cellooligosaccharides with degree of polymerization above 5, xyloglucan, glucomannan, and x02beta-glucan, exclusively products oxidized at the C4 position are found. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: acts on cellooligosaccharides with degree of polymerization above 5, xyloglucan, glucomannan, and x02beta-glucan, exclusively products oxidized at the C4 position are found. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: the enzyme inserts oxygen at the 4-position. After oxygen insertion, the glycosidic bond is destabilized and likely broken by an elimination reaction, which may be catalyzed by the PMO or occur spontaneously. This elimination is irreversible because the carbon on the reducing or nonreducing end has been oxidized
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan. Enzyme is active on xyloglucan only in the presence of phosphoric acid-swollen cellulose
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan. Enzyme is active on xyloglucan only in the presence of phosphoric acid-swollen cellulose
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan. Enzyme is active on xyloglucan only in the presence of phosphoric acid-swollen cellulose
Products: -
Products: -
?
additional information
?
-
Substrates: acts on cellooligosaccharides with degree of polymerization above 5, xyloglucan, glucomannan, and x02beta-glucan, exclusively products oxidized at the C4 position are found. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: acts on cellooligosaccharides with degree of polymerization above 5, xyloglucan, glucomannan, and x02beta-glucan, exclusively products oxidized at the C4 position are found. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: acts on cellooligosaccharides with degree of polymerization above 5, xyloglucan, glucomannan, and x02beta-glucan, exclusively products oxidized at the C4 position are found. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exclusively oxidizes at C4. Enzyme efficiently uses H2O2 as a cosubstrate, yielding product profiles identical to those obtained in O2-driven reactions with phosphoric acid-swollen cellulose, xyloglucan, or glucomannan
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme cleaves cellulose, xyloglucan, reaction of lytic xyloglucan monooxogenase, mixed-linkage glucan and glucomannan. Oligosaccharides are cleaved using a C4-oxidizing mechanism, reaction of EC 1.14.99.56, whereas polysaccharides are cleaved with both C1- and C4-oxidizing mechanisms in varying proportions, reactions of EC 1.14.99.54 and EC 1.14.99.56
Products: -
Products: -
?
additional information
?
-
A0A5S8WF95
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme exhibits a mixed C1/C4 oxidative cleavage activity on cellulose and xyloglucan, but not on xylan
Products: -
Products: -
?
additional information
?
-
-
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
-
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
-
Substrates: enzyme produces C4-oxidized products from cellulose with no evidence of C1 oxidation
Products: -
Products: -
?
additional information
?
-
-
Substrates: no substrates: xylan, starch, or chitin
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme shows activity toward PASC, tamarind xyloglucan and steam-exploded birch in the presence of ascorbic acid, while it is inactive toward cellopentaose, ivory nut mannan, konjac glucomannan, and xylan from birch wood. In the presence of ascorbic acid, LPMO9A releases a mixture of C1- and C4-oxidized oligosaccharides
Products: -
Products: -
?
additional information
?
-
Substrates: in the absence of substrate with ascorbate as reductant, enzyme shows a H2O2 production rate of about 1.00 per min
Products: -
Products: -
?
additional information
?
-
Substrates: for isoforms LPMO9A, LPMO9B and LPMO9C, ascorbic acid is one of the best electron donors. Besides ascorbic acid, compounds bearing a 1,2-benzenediol moiety such as 3-methylcatechol, 3,4-dihydroxyphenylalanine, or a 1,2,3-benzenetriol moiety such as gallic acid, epigallocatechin-gallate give formation of oxidized and non-oxidized gluco-oligosaccharides. Sinapic acid actes as donor. No electron donor: quercetin or taxifolin, and tannic acid
Products: -
Products: -
?
additional information
?
-
Substrates: enzyme performs C4-oxidation and is active against cellulose, soluble cello-oligosaccharides, and xyloglucan. No substrates: konjac glucomannan, barley beta-glucan and sugar beet arabinan
Products: -
Products: -
?
additional information
?
-
-
Substrates: additionally catalyzes the reaction with xyloglucan
Products: -
Products: -
?
additional information
?
-
Thermothelomyces thermophilus DSM 1799
Substrates: enzyme performs C4-oxidation and is active against cellulose, soluble cello-oligosaccharides, and xyloglucan. No substrates: konjac glucomannan, barley beta-glucan and sugar beet arabinan
Products: -
Products: -
?
additional information
?
-
Substrates: no substrates: galactan, cellopentaose, or cellohexaose
Products: -
Products: -
?
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COFACTOR
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
IMAGE
additional information
in the absence of electron donor, such as ascorbic acid, no reaction is detected
-
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METALS and IONS
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
copper
Cu2+
copper
D9SZQ3
the active site is formed by His37 and His144 that coordinate the copper atom in a T-shaped geometry
Cu2+
D9SZQ3
the active site in is formed by residues His-37 and His-144 that coordinate the copper atom in a T-shaped geometry
Cu2+
-
the reduction of the mononuclear active-site copper by ascorbic acid increases the affinity and the maximum binding capacity of LPMO for cellulose
Cu2+
the calculated dissociation energies suggest that the reactive intermediate is either a Cu(II)-oxyl, a Cu(III)-oxyl, or a Cu(III)-hydroxide, indicating that O-O bond breaking occurs before the C-H activation step
Cu2+
-
residue Tyr203 is placed approximately 15 A away from the copper active site
Cu2+
enzyme is Cu(II) saturated with a 3fold molar excess of Cu(II)SO4 prior to assay
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INHIBITOR
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
IMAGE
H2O2
low concentrations of H2O2 boost LPMO activity, whereas excess H2O2 leads to LPMO inactivation
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ACTIVATING COMPOUND
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
IMAGE
Chlorophyllin
activity of LPMO enzymes is increased in presence of a light-driven system where photopigments such as chlorophyllin combined with a reductant donate high redox potential electrons to the LPMO. The addition of superoxide dismutase or catalase to remove reactive oxygen species does not attenuate the capacity of the light-driven LPMO system to oxidize PASC, as measured by formation of oxidized oligosaccharides
H2O2
low concentrations of H2O2 boost LPMO activity, whereas excess H2O2 leads to LPMO inactivation
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KM VALUE [mM]
SUBSTRATE
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
IMAGE
85.68
2,6-dimethoxyphenol
-
variant with an additional C-terminal carbohydrate binding domain, pH 6, 23°C
87.7
2,6-dimethoxyphenol
-
variant lacking the C-terminal linker-like region, pH 6, 23°C
0.31
H2O2
-
variant lacking the C-terminal linker-like region, pH 6, 23°C
1.03
H2O2
-
variant with an additional C-terminal carbohydrate binding domain, pH 6, 23°C
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TURNOVER NUMBER [1/s]
SUBSTRATE
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
IMAGE
0.53
2,6-dimethoxyphenol
-
variant with an additional C-terminal carbohydrate binding domain, pH 6, 23°C
0.96
2,6-dimethoxyphenol
-
variant lacking the C-terminal linker-like region, pH 6, 23°C
0.17
H2O2
-
variant lacking the C-terminal linker-like region, pH 6, 23°C
0.25
H2O2
-
variant with an additional C-terminal carbohydrate binding domain, pH 6, 23°C
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kcat/KM VALUE [1/mMs-1]
SUBSTRATE
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
IMAGE
0.003
2,6-dimethoxyphenol
-
variant with an additional C-terminal carbohydrate binding domain, pH 6, 23°C
0.011
2,6-dimethoxyphenol
-
variant lacking the C-terminal linker-like region, pH 6, 23°C
0.14
H2O2
-
variant with an additional C-terminal carbohydrate binding domain, pH 6, 23°C
0.55
H2O2
-
variant lacking the C-terminal linker-like region, pH 6, 23°C
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pH OPTIMUM
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
9 - 10
-
enzyme activity starts decreasing after approximately 700 s, while the enzymatic activity continues until the end of the experiment at pHs 6.0 and 7.0
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pH RANGE
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
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TEMPERATURE OPTIMUM
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
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pI VALUE
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
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ORGANISM
COMMENTARY
LITERATURE
UNIPROT
SEQUENCE DB
SOURCE
Thermothelomyces thermophilus DSM 1799
cf. EC 3.2.1.4, EC 3.2.1.54
UniProt
brenda
Micromonospora aurantiaca (nom. illeg.) DSM 43813
cf. EC 1.14.99.53, 1.14.99.54
D9SZQ3
UniProt
brenda
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SOURCE TISSUE
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
SOURCE
Highest Expressing Human Cell Lines
Cell Line LinksPlease wait a moment until the data is sorted. This message will disappear when the data is sorted.
GENERAL INFORMATION
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
metabolism
physiological function
metabolism
-
substrates cellulose and xyloglucan show a stabilizing effect on the apparent transition midpoint temperature of the reduced, catalytically active enzyme. Oxidative auto-inactivation and destabilization are observed in the absence of a suitable substrate
metabolism
D9SZQ3
enzyme is a C1/C4-oxidizing lytic polysaccharide monooxygenase. Surface properties near the catalytic copper are major determinants of the C1:C4 ratio. Neither truncation of the carbohydrate-binding module nor mutations altering access to the solvent-exposed axial copper coordination site significantly change the C1:C4 ratio
metabolism
-
role of LPMO's structural dynamics during polysaccharide degradation, comparison of multiple LPMO structures. The substrate binding region is highly flexible with significant and sustained micro-scale level conformational changes.The loops on the binding side of the substrate are most mobile, in concert with the dynamic modes influencing the motions during binding. There are dynamic differences between families AA9, AA10, AA11, and AA13 that consist of more than one structure. The patterns of motion in the loop regions among the AA9 structures are distinct from those in the AA10 structures
metabolism
Micromonospora aurantiaca (nom. illeg.) DSM 43813
-
enzyme is a C1/C4-oxidizing lytic polysaccharide monooxygenase. Surface properties near the catalytic copper are major determinants of the C1:C4 ratio. Neither truncation of the carbohydrate-binding module nor mutations altering access to the solvent-exposed axial copper coordination site significantly change the C1:C4 ratio
-
physiological function
-
the enzyme prefers oxidation of products at C4, which lowers product binding affinity and thereby should enhance product release and processive hydrolytic turnover. Product inhibition resulting from binding of oxidized products is likely not significant
physiological function
-
isoforms LPMO9C and LPMO9F bind to nanocrystalline cellulose with high preference for the very same substrate surfaces that are also used by Hypocrea jecorina processive cellulase CBH I to move along during hydrolytic cellulose degradation. The bound LPMOs are immobile during their adsorbed residence time on cellulose. Treatment with LPMO results in fibrillation of crystalline cellulose and more than 2fold enhances the cellulase adsorption. It also increased enzyme turnover on the cellulose surface, thus boosting the hydrolytic conversion
physiological function
LPMO9B cooperates with and stimulates the activity of cellobiohydrolase Cel7A
physiological function
-
the enzyme prefers oxidation of products at C4, which lowers product binding affinity and thereby should enhance product release and processive hydrolytic turnover. Product inhibition resulting from binding of oxidized products is likely not significant
-
physiological function
-
LPMO9B cooperates with and stimulates the activity of cellobiohydrolase Cel7A
-
Show AA Sequence and Transmembrane Helices (13944 entries)
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PDB
SCOP
CATH
UNIPROT
ORGANISM
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MOLECULAR WEIGHT
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
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SUBUNIT
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
?
-
x * 27000, SDS-PAGE, x * 23000, calculated for isoform AA9A, x * 29000, SDS-PAGE, x * 24000, calculated for isoform AA9B, respectively
?
Aspergillus tamarii CBS 117626
-
x * 27000, SDS-PAGE, x * 23000, calculated for isoform AA9A, x * 29000, SDS-PAGE, x * 24000, calculated for isoform AA9B, respectively
-
?
x * 30000, SDS-PAGE, x * 27000 after deglycosylation with Endo Hf
?
x * 25000-30000, SDS-PAGE, x * 24400, calculated from seqeunce
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POSTTRANSLATIONAL MODIFICATION
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
glycoprotein
glycoprotein
-
after deglycosylation with PNGase F, the protein migrates close to the 27 kDa
glycoprotein
Gloeophyllum trabeum 925-B
-
after deglycosylation with PNGase F, the protein migrates close to the 27 kDa
-
glycoprotein
-
lack of potential N-glycosylation sites, presence of 37 predicted O-linked glycosylation sites. Molecular mass of recombinant protein is 75 kDa by SDS-PAGE, as compared with 32500 predicted
glycoprotein
molecular mass decreases by 3000 Da after deglycosylation with Endo Hf. Putative N-glycosylation sites are N34 and N80
glycoprotein
-
about 20% of molecular mass are glycosyl residues. Seuence harbors 28 potential glycosylation sites
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CRYSTALLIZATION (Commentary)
ORGANISM
UNIPROT
LITERATURE
homology modeling, His67 and Ser78 are substrate-interacting residues
structure of the catalytic domain (residues 37-230, lacking the linker and the CBM2) to 1.08 A resolution. Structure shows the typical LPMO fold with a central beta-sandwich made up by two distorted beta-sheets connected by several loops and helices. The active site is formed by His37 and His144 that coordinate the copper atom in a T-shaped geometry
D9SZQ3
structure of the catalytic domain, residues 37-230, to 1.08 A resolution. The active site in is formed by residues His-37 and His-144 that coordinate the copper atom in a T-shaped geometry
D9SZQ3
structure of copper-bound monooxygenase LPMO9A at 1.6 A resolution. Isoforms LPMO9A and LPMO9C, containing a CBM1 carbohydrate-binding module, bind cellulose more strongly and are less susceptible to inactivation than LPMO9D, which lacks a CBM
structure of copper-bound monooxygnase LPMO9A at 1.6 A resolution. Isoforms LPMO9A and LPMO9C, containing a CBM1 carbohydrate-binding module, bind cellulose more strongly and are less susceptible to inactivation than LPMO9D, which lacks a CBM
structure of AA9A bound to cellulosic and non-cellulosic oligosaccharides
substrate cellohexaose binds to subsites ?4 to +2, and cellotriose from subsites -1 to +2. Residue Tyr203 is placed approximately 15 A away from the copper active site
-
structure of the catalytic domain, residues 37-230, to 1.08 A resolution. The active site in is formed by residues His-37 and His-144 that coordinate the copper atom in a T-shaped geometry
molecular modeling. Structure is similar to those of other AA9 LPMOs
-
hybrid quantum mechanics and molecular mechanics investigation of the first steps of the LPMO mechanism, which is reduction of Cu(II) to Cu(I) and the formation of a Cu(II)-superoxide complex. In the complex, the superoxide can bind either in an equatorial or an axial position. The equatorial isomer of the superoxide complex is over 60 kJ/mol more stable than the axial isomer because it is stabilized by interactions with a second-coordination-sphere glutamine residue
comparison of isoforms LPMO9A, LPMO9B and LPMO9C. LPMO9B contains distal from the coordinated copper sphere an additional loop (Gly115-Asn121), which is not present in LPMO9A and LPMO9C. The copper ion in LPMO9A, LPMO9B and LPMO9C is coordinated by His1-His68-Tyr153, His1-His79-Tyr170 and His1-His84-Tyr166, respectively. All three LPMOs share two putative disulfide bridges
low-resolution SAXS LPMO9H structure in solution. The position of CBM1 lies within the tail of the tadpole appended via long linker peptide to the catalytic domain which can be placed in its head
-
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PROTEIN VARIANTS
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
D140A
N85F
N85F/Y116F
D9SZQ3
22.5% residual C1- and 5.82% residual C4-oxidizing activity
Q141W
D9SZQ3
27.4% residual C1- and 11.3% residual C4-oxidizing activity, ratio C1:C4-activity is 2.2
W82Y
W82Y/N85F
W82Y/N85F/Q141W
W82Y/N85F/Y116F
W82Y/N85F/Y116F/Q141W
Y116F
A148G
mutation leads to loss of C4 oxidation, i.e to the activity of EC 1.14.99.54
A148S
mutation leads to loss of C4 oxidation, i.e to the activity of EC 1.14.99.54
W88Y/N91F
mutation leads to loss of C4 oxidation, i.e to the activity of EC 1.14.99.54
additional information
D140A
D9SZQ3
mutant shows moderately reduced activity and essentially unchanged oxidative regioselectivity
D140A
D9SZQ3
45.9% residual C1- and 33.6% residual C4-oxidizing activity, ratio C1:C4-activity is 1.23
N85F
D9SZQ3
mutation changes the C1:C4 oxidation ratio from 0.9 (for the wild-type) to 5.9
N85F
D9SZQ3
15.7% residual C1- and 2.4% residual C4-oxidizing activity, ratio C1:C4-activity is 5.93
W82Y
D9SZQ3
mutation changes the C1:C4 oxidation ratio from 0.9 (for the wild-type) to 2.0
W82Y
D9SZQ3
20.9% residual C1- and 9.2% residual C4-oxidizing activity, ratio C1:C4-activity is 2.04
W82Y/N85F
D9SZQ3
mutation changes the C1:C4 oxidation ratio from 0.9 (for the wild-type) to 10.9
W82Y/N85F
D9SZQ3
14.5% residual C1- and 1.2% residual C4-oxidizing activity, ratio C1:C4-activity is 10.94
W82Y/N85F/Q141W
D9SZQ3
mutation changes the C1:C4 oxidation ratio from 0.9 (for the wild-type) to 5.1
W82Y/N85F/Q141W
D9SZQ3
12.21% residual C1- and 2.1% residual C4-oxidizing activity, ratio C1:C4-activity is 5.06
W82Y/N85F/Y116F
D9SZQ3
mutation changes the C1:C4 oxidation ratio from 0.9 (for the wild-type) to 14.7
W82Y/N85F/Y116F
D9SZQ3
14.2% residual C1- and 0.9% residual C4-oxidizing activity, ratio C1:C4-activity is 14.69
W82Y/N85F/Y116F/Q141W
D9SZQ3
mutation changes the C1:C4 oxidation ratio from 0.9 (for the wild-type) to 5.8
W82Y/N85F/Y116F/Q141W
D9SZQ3
10.2% residual C1- and 1.6% residual C4-oxidizing activity, ratio C1:C4-activity is 5.78
Y116F
D9SZQ3
15.2% residual C1- and 14.7% residual C4-oxidizing activity, ratio C1:C4-activity is 0.93
additional information
D9SZQ3
neither truncation of the LPMO10B family 2 carbohydrate-binding module nor mutations altering access to the solvent-exposed axial copper coordination site significantly change the C1:C4 oxidation ratio
additional information
-
construction of a variant lacking the C-terminal linker-like region and one with an additional C-terminal carbohydrate binding domain. The variant with only the catalytic domain shows thermostability, similar to wild-type, the presence of a CBM reduces the thermostability
additional information
variants of LPMO9A, with and without the methylation on His1 are identical in terms of substrate preferences, cleavage specificities and the ability to activate molecular oxygen. The ability to cleave xyloglucan is identical for both variants. Methylation has minimal effects on the pKa of His1, the affinity for copper and the redox potential of bound copper. The variants show clear differences in their resistance against oxidative damage, the methylated variant, produced in Aspergillus oryzae, is more resistant to excess H2O2
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pH STABILITY
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
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TEMPERATURE STABILITY
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
35
-
midpoint transition temperature, pH 4.0, citrate buffer, oxidized enzyme
44
-
midpoint transition temperature, pH 4.0, acetate buffer, oxidized enzyme
48.8
-
midpoint transition temperature, pH 6.0, phosphate buffer, presence of ascorbic acid
53
-
midpoint transition temperature, pH 6.0, phosphate buffer, presence of EDTA
57.8
-
variant with an additional C-terminal carbohydrate binding domain
61.5
-
midpoint transition temperature, pH 6.0, phosphate buffer, oxidized enzyme
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PURIFICATION (Commentary)
ORGANISM
UNIPROT
LITERATURE
recombinant protein, purified from culture medium in two chromatographic steps to ca. 95% purity
recombinant protein, using hydrophobic interaction chromatography followed by size exclusion chromatography
recombinant protein, using ion exchange and hydrophobic interaction chromatography
-
recombinant proteins, starting with anion exchange chromatography followed by size exclusion chromatography
-
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CLONED (Commentary)
ORGANISM
UNIPROT
LITERATURE
expression in Aspergillus oryzae
expression in Escherichia coli
expression in Pichia pastoris
expression in Trichoderma reesei
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APPLICATION
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
analysis
degradation
synthesis
analysis
-
a fast, robust, and sensitive spectrophotometric activity assay based on a peroxidase activity of LPMO, using 2,6-dimethoxyphenol and H2O2. The high molar absorption coefficient of the formed Product coerulignone displays a high molar absorption coefficinet that makes the assay sensitive and allows reliable activity measurements of LPMO in concentrations of approx. 0.550 mg/L
analysis
-
substrate colloidal cellulose nanofibrils from potato tubers is produced by alkaline treatment to remove noncellulosic polysaccharides, followed by hypochlorite oxidation and homogenization. Substrate consists of about 94% cellulose, and carboxyl groups on the surface prevent their agglomeration, its suspensions have up to two times higher optical transparency than phosphoric acid swollen cellulose
degradation
-
lytic polysaccharide monooxygenase is able to cleave cellulose acetates with a degree of acetylation of up to 1.4
degradation
-
the intrinsic physicochemical characteristics of Kraft pulp fibers (e.g. cellulose accessibility/degree of polymerization/crystallinity/charge) are positively enhanced by the synergistic cooperation of endoglucanase, LPMO and xylanase. LPMO addition results in the oxidative cleavage of the pulps, increasing the negative charge on the cellulose fibers, although gross fiber properties (fiber length, width and morphology) are relatively unchanged. This improves cellulose nanofibrilliation while stabilizing the nanofibril suspension, without sacrificing nanocellulose thermostability
degradation
in combination with endoglucanase and beta-glucosidase, Cel61A shows the ability to release more than 36% of the pretreated soy spent flake glucose
degradation
oxidative activity of Cel61A displays a synergistic effect capable of boosting endoglucanase activity, and thereby substrate depolymerization of soy cellulose, by 27%
degradation
-
in combination with endoglucanase and beta-glucosidase, Pte6 shows the ability to release more than 36% of the pretreated soy spent flake glucose
degradation
together with cellobiohydrolases CBH II or EG II, enzyme displays synergism on the degradation of microcrystalline or amorphous cellulose, respectively. The synergism is expressed to the greatest extent in the initial reaction period. The mixtures with CBH I also demonstrates synergism on microcrystalline cellulose as a substrate
degradation
together with cellobiohydrolases CBH II or EG II, enzyme displays synergism on the degradation of microcrystalline or amorphous cellulose, respectively. The synergism is expressed to the greatest extent in the initial reaction period. The mixtures with CBH I also demonstrates synergism on microcrystalline cellulose as a substrate
degradation
-
in the presence of an electron source, LPMO increases the activity of a commercial cellulase on filter paper, and the xylanase activity of Xyn10A on beechwood xylan. A mixture of 60% Celluclast 1.5 L, 20% Xyn10A and 20% LPMO increases total reducing sugar production of pretreated wheat straw by 54%, while the conversions of glucan to glucose and xylan to xylose are increased by 40 and 57%, respectively
degradation
enzyme shows a higher boosting effect on the enzymatic saccharification of complex lignocellulosic substrates associated with xyloglucan than on the lignocellulosic substrates without xyloglucan particularly in low commercial cellulase dosage cases
degradation
-
product formation is remarkably increased when LPMO9H is combined with GH7 endoglucanase
degradation
-
enzymatic cocktails constituted of commercial cellulase CellicCTec2 with PMO9A_MALCI (9:1/8:2) lead to synergistic improvement in saccharification of acid and alkali pretreated biomass
degradation
-
overexpression of LPMO9C and cellobiohydrolase CBH1 in a catabolite-derepressed strain of Penicillium funiculosum. Transformants show improved LPMO and CBH1 expression at both the transcriptional and translational levels, with 200% and 66% increases in ascorbate-induced LPMO and avicelase activities, respectively. the simultaneous overexpression of the two genes leads to a 20% increase in saccharification efficiency over that observed with Penicillium funiculosum Mig188, i.e. an engineered variant
degradation
Gloeophyllum trabeum 925-B
-
in the presence of an electron source, LPMO increases the activity of a commercial cellulase on filter paper, and the xylanase activity of Xyn10A on beechwood xylan. A mixture of 60% Celluclast 1.5 L, 20% Xyn10A and 20% LPMO increases total reducing sugar production of pretreated wheat straw by 54%, while the conversions of glucan to glucose and xylan to xylose are increased by 40 and 57%, respectively
-
synthesis
easy and fast protocol for cloning, expression, and purification of active LPMOs in the architecture: natural signal peptide, LPMO enzyme, TEV protease site, and His6-Tag. A commercial methanol inducible expression vector is modified to allow the LPMO expression. Gibson assembly is adopted for the direct assembly of intron-less or intron-containing genes and the modified expression vector. His6-tagged LPMO constructs can be submitted to TEV proteolysis for removal of the questionable C-terminal His6-Tag, obtaining a close-to-native form of LPMO
synthesis
enzyme facilitates the isolation of nanocellulose from Ciona intestinalis tunic and improves the overall process yield. A significant increase in the atomic percentage of the C=O/O-C-O and O-C=O bonds is observed upon the addition of LPMO, the obtained nanocrystals exhibit higher thermal stability compared to the untreated ones
synthesis
-
easy and fast protocol for cloning, expression, and purification of active LPMOs in the architecture: natural signal peptide, LPMO enzyme, TEV protease site, and His6-Tag. A commercial methanol inducible expression vector is modified to allow the LPMO expression. Gibson assembly is adopted for the direct assembly of intron-less or intron-containing genes and the modified expression vector. His6-tagged LPMO constructs can be submitted to TEV proteolysis for removal of the questionable C-terminal His6-Tag, obtaining a close-to-native form of LPMO
-
synthesis
Thermothelomyces thermophilus DSM 1799
-
enzyme facilitates the isolation of nanocellulose from Ciona intestinalis tunic and improves the overall process yield. A significant increase in the atomic percentage of the C=O/O-C-O and O-C=O bonds is observed upon the addition of LPMO, the obtained nanocrystals exhibit higher thermal stability compared to the untreated ones
-
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Thermoascus aurantiacus (G3XAP7)
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448
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Thermothielavioides terrestris (D0VWZ9)
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449
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Aspergillus terreus, Trichoderma reesei (O14405)
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Neurospora crassa
-
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Gloeophyllum trabeum
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Trichoderma reesei (O14405)
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Fusarium graminearum (I1REU9), Fusarium graminearum ATCC MYA-4620 (I1REU9)
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brenda
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894
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Neurospora crassa
brenda
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Heterobasidion irregulare
brenda
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Thermoascus aurantiacus
brenda
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-
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Thermothelomyces thermophilus, Neurospora crassa
brenda
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A fast and easy strategy for lytic polysaccharide monooxygenase-cleavable His6-Tag cloning, expression, and purification
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brenda
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167
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Penicillium parvum (A0A6C0M6J9)
brenda
Mendez-Lixadter, J.; Ayuso-Fernandez, I.; Csarman, F.; de Eugenio, L.; Miguez, N.; Plou, F.; Prieto, A.; Ludwig, R.; Martinez, M.
Lytic polysaccharide monooxygenase from Talaromyces amestolkiae with an enigmatic linker-like region The role of this enzyme on cellulose saccharification
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22
13611
2021
Talaromyces amestolkiae
brenda
Petrovic, D.M.; Varnai, A.; Dimarogona, M.; Mathiesen, G.; Sandgren, M.; Westereng, B.; Eijsink, V.G.H.
Comparison of three seemingly similar lytic polysaccharide monooxygenases from Neurospora crassa suggests different roles in plant biomass degradation
J. Biol. Chem.
294
15068-15081
2019
Neurospora crassa (Q7SHI8), Neurospora crassa (Q1K8B6), Neurospora crassa (Q7S439), Neurospora crassa DSM 1257 (Q7SHI8), Neurospora crassa DSM 1257 (Q1K8B6), Neurospora crassa DSM 1257 (Q7S439)
brenda
Frandsen, K.; Haon, M.; Grisel, S.; Henrissat, B.; Leggio, L.; Berrin, J.
Identification of the molecular determinants driving the substrate specificity of fungal lytic polysaccharide monooxygenases (LPMOs)
J. Biol. Chem.
296
100086
2021
Armillaria gallica, Aspergillus fumigatus (Q4WBU0), Aspergillus fumigatus ATCC MYA-4609 (Q4WBU0), Aspergillus oryzae (Q2US83), Bjerkandera adusta, Panus similis (A0A5S8WF95), Phanerochaete carnosa, Phanerodontia chrysosporium, Schizophyllum commune
brenda
Arora, R.; Bharval, P.; Sarswati, S.; Sen, T.; Yennamalli, R.
Structural dynamics of lytic polysaccharide monoxygenases reveals a highly flexible substrate binding region
J. Mol. Graph. Model.
88
1-10
2019
Bacteria
brenda
Kadowaki, M.; Varnai, A.; Jameson, J.; Leite, A.; Costa-Filho, A.; Kumagai, P.; Prade, R.; Polikarpov, I.; Eijsink, V.
Functional characterization of a lytic polysaccharide monooxygenase from the thermophilic fungus Myceliophthora thermophila
PLoS ONE
13
e0202148
2018
Thermothelomyces thermophilus (G2Q7A5), Thermothelomyces thermophilus DSM 1799 (G2Q7A5)
brenda
Liu, B.; Krishnaswamyreddy, S.; Muraleedharan, M.; Olson, A.; Broberg, A.; Stahlberg, J.; Sandgren, M.
Side-by-side biochemical comparison of two lytic polysaccharide monooxygenases from the white-rot fungus Heterobasidion irregulare on their activity against crystalline cellulose and glucomannan
PLoS ONE
13
e0203430
2018
Heterobasidion irregulare (W4K8M0), Heterobasidion irregulare TC 32-1 (W4K8M0)
brenda
Monclaro, A.; Petrovic, D.; Alves, G.; Costa, M.; Midorikawa, G.; Miller, R.; Filho, E.; Eijsink, V.; Varnai, A.
Characterization of two family AA9 LPMOs from Aspergillus tamarii with distinct activities on xyloglucan reveals structural differences linked to cleavage specificity
PLoS ONE
15
e0235642
2020
Aspergillus tamarii, Aspergillus tamarii CBS 117626
brenda
Petrovic, D.M.; Bissaro, B.; Chylenski, P.; Skaugen, M.; Sorlie, M.; Jensen, M.S.; Aachmann, F.L.; Courtade, G.; Varnai, A.; Eijsink, V.G.H.
Methylation of the N-terminal histidine protects a lytic polysaccharide monooxygenase from auto-oxidative inactivation
Protein Sci.
27
1636-1650
2018
Thermoascus aurantiacus (G3XAP7)
brenda
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