Leibniz Institute DSMZ
DSMZ Digital Diversity
Login
Classic view
All enzymes
Enzyme history
BRENDA support
Any feedback?
Please rate this page
(search_result.php)
😁
😐
😡
(
0
/150)
Send feedback
BRENDA support
Refine search
Search Application
Application:
show
10
50
100
results
Don't show organism specific information (fast!)
Search organism in taxonomic tree (slow, choose "exact" as search mode, e.g. "mammalia" for rat,human,monkey,...)
(Not possible to combine with the first option)
Refine your search
Recommended Name:
EC Number:
contains
exact
begins with
ends with
use * as joker
Commentary:
contains
exact
begins with
ends with
use * as joker
Organism
:
contains
exact
begins with
ends with
use * as joker
Reference:
contains
exact
begins with
ends with
use * as joker
Search term:
Results
1
-
3
of
3
download as CSV
download all results as CSV
EC Number
Application
Commentary
Reference
1.2.98.1
degradation
resting Escherichia coli cells transformed with the formaldehyde dismutase gene degrade high concentrations of formaldehyde and produce formic acid and methanol that are molar equivalents of one-half of the degraded formaldehyde. The lyophilized cells of the recombinant Escherichia coli also degrade high concentrations of formaldehyde
762823
1.2.98.1
synthesis
formate production with immobilized enzyme
-
,
390489
1.2.98.1
synthesis
production of methanol and formic acid using a chemo-/biocatalytic oxidation cascade. Starting from synthetic biogas, methane is oxidized to formaldehyde over a mesoporous VOx/SBA-15 catalyst. Formaldehyde is disproportionated enzymatically towards methanol and formic acid in equimolar ratio by formaldehyde dismutase. The cascades generate methanol in much higher productivity compared to methane monooxygenase
762666
Results
1
-
3
of
3
download as CSV
download all results as CSV