1.14.99.53

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Enterococcus faecalis

1.14.99.53

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Burkholderia pseudomallei

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Trichoderma reesei

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Serratia marcescens

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Neurospora crassa

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Thermothielavioides terrestris

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Thermoascus aurantiacus

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Vibrio cholerae O1

1.14.99.53

Burkholderia pseudomallei

Q3JY22

1.14.99.53

Burkholderia pseudomallei 1710b

Q3JY22

1.14.99.53

Enterococcus faecalis

Q838S1

1.14.99.53

Enterococcus faecalis ATCC 700802

Q838S1

1.14.99.54

Neurospora crassa

Q1K8B6

1.14.99.54

Neurospora crassa

Q7SA19

1.14.99.54

Neurospora crassa DSM 1257

Q1K8B6

1.14.99.54

Neurospora crassa DSM 1257

Q7SA19

1.14.99.54

Serratia marcescens

O83009

1.14.99.54

Thermoascus aurantiacus

G3XAP7

1.14.99.54

Thermothielavioides terrestris

D0VWZ9

1.14.99.54

Trichoderma reesei

1.14.99.54

Trichoderma reesei QM6a

1.14.99.54

Vibrio cholerae O1

Q9KLD5

1.14.99.54

Vibrio cholerae O1 ATCC 39315

Q9KLD5

1.14.99.53

BURPS1710b_0114

Burkholderia pseudomallei

1.14.99.53

EF_0362

Enterococcus faecalis

1.14.99.54

AA9

CAZY auxilliary activity family 9

Trichoderma reesei

1.14.99.54

AA9

CAZY auxilliary activity family 9

Neurospora crassa

1.14.99.54

AA9

CAZY auxilliary activity family 9

Thermothielavioides terrestris

1.14.99.54

AA9

CAZY auxilliary activity family 9

Thermoascus aurantiacus

1.14.99.54

CBP21

Serratia marcescens

1.14.99.54

cel61b

Trichoderma reesei

1.14.99.54

GbpA

Vibrio cholerae O1

1.14.99.54

Gh61 isozyme a

Thermoascus aurantiacus

1.14.99.54

gh61-4

Neurospora crassa

1.14.99.54

gh61e

Thermothielavioides terrestris

1.14.99.54

PMO-2

Neurospora crassa

1.14.99.54

PMO-3

Serratia marcescens

1.14.99.54

PMO-3

Neurospora crassa

1.14.99.53

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Enterococcus faecalis

1.14.99.53

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Burkholderia pseudomallei

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Trichoderma reesei

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Serratia marcescens

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Neurospora crassa

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Thermothielavioides terrestris

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Thermoascus aurantiacus

1.14.99.54

comparative analysis of sequences, solved structures, and homology models from AA9 and AA10 LPMO families.The two LPMO families are highly conserved, structurally they have minimal sequence similarity outside the active site residues

Vibrio cholerae O1