Assays

Curation guidelines for molecular interaction causal statements

RNAseq raw data derived from continuous culture samples

Supplemental files for the publication

Links to additional gitlab repositories

Rawdata for RNAseq derived from biofilms on chalcopyrite grains

Link to RNAseq raw data

Conversion of XYL to KG in a cell free extract of Caulobacter crescentus, without Mn2+ added, but with NAD recycling, metabolites measured enzymatically. https://jjj.bio.vu.nl/models/experiments/shen2020_fig4d/simulate

Conversion of XYL to KG in a cell free extract of Caulobacter crescentus, with 0.15 mM Mn2+ added, but no NAD recycling, metabolites measured enzymatically. https://jjj.bio.vu.nl/models/experiments/shen2020_fig4c/simulate

Conversion of XYL to KG in a cell free extract of Caulobacter crescentus, with 0.15 mM Mn2+ added, and with NAD recycling, metabolites measured enzymatically. https://jjj.bio.vu.nl/models/experiments/shen2020_fig4b/simulate

Conversion of XYL to KG in one pot cascade of Weimberg pathway enzymes of Caulobacter crescentus, using old enzymes with optimal protein distribution, with NAD recycling, measured in NMR. https://jjj.bio.vu.nl/models/experiments/shen2020_fig3d/simulate

Conversion of XYL to KG in one pot cascade of Weimberg pathway enzymes of Caulobacter crescentus, with NAD recycling, measured in NMR. https://jjj.bio.vu.nl/models/experiments/shen2020_fig3b/simulate

Conversion of XYL to KG in one pot cascade of Weimberg pathway enzymes of Caulobacter crescentus, omitting XLA, measured in NMR. https://jjj.bio.vu.nl/models/experiments/shen2020_fig3c/simulate

Conversion of XYL to KG in one pot cascade of Weimberg pathway enzymes of Caulobacter crescentus, measured in NMR. https://jjj.bio.vu.nl/models/experiments/shen2020_fig3a/simulate

Conversion of XYL to KG by sequential addition of Weimberg pathway enzymes of Caulobacter crescentus, measured in NMR. https://jjj.bio.vu.nl/models/experiments/shen2020_fig2c/simulate

Kinetic characterisation and mathematical modelling of XDH.

Kinetic characterisation and mathematical modelling of XLA.

Kinetic characterisation and mathematical modelling of XAD.

Kinetic characterisation and mathematical modelling of KDXD.

Kinetic characterisation and mathematical modelling of KGSADH.

Conversion of Xyl to XLAC by Caulobacter crescentus XDH, measured in NMR.

Conversion of XLAC to XA by Caulobacter crescentus XLA, measured in NMR.

Conversion of XA to KDX by Caulobacter crescentus XAD, measured in NMR.

Conversion of KDX to KGSA by Caulobacter crescentus KDXD, measured in NMR.

Conversion of KGSA to KG by Caulobacter crescentus KGSADH, measured in NMR.

Model that eliminates several light inputs. RVE8, NOX are incorporated. Individual representation of CCA1 and LHY. Several changes in conections and light inputs. Fogelmark reports eight parameter sets. This SBML file contains the first parameter set Related PublicationsFogelmark K, Troein C (2014). Rethinking transcriptional activation in the Arabidopsis circadian clock.. PLoS Comput Biology. Retrieved from: http://journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1003705Originally ...

The model is an extensio of PLM_67v3 with an additional an additional variable Temp in ODE 25. This change allows to simulated warm pulses that affect EC stability using COPASI. 

Originally submitted to PLaSMo on 2014-03-10 13:16:25