Assays

This Jupyter Notebook assists you in understanding how a Selwyn Test works.

For help on installing the classical Jupyter Notebook, see here: https://jupyter.org/install

For documentation about Juypter Notebooks, see here: https://jupyter-notebook.readthedocs.io/en/stable/

There are multiple tutorials online that help you to learn how to use a Jupyter notebook.

The notebook is provided as an .ipynb and as a .pdf file.

The plots the script generates with the default values are also given as .png ...

This Jupyter Notebook assists you in understanding how a progress curve experiment can look like.

For help on installing the classical Jupyter Notebook, see here: https://jupyter.org/install

For documentation about Juypter Notebooks, see here: https://jupyter-notebook.readthedocs.io/en/stable/

There are multiple tutorials online that help you to learn how to use a Jupyter notebook.

The notebook is provided as an .ipynb and as a .pdf file.

The plots the script generates with the default values are ...

This Jupyter Notebook assists you in the analysis of initial rate experiments.

For help on installing the classical Jupyter Notebook, see here: https://jupyter.org/install

For documentation about Juypter Notebooks, see here: https://jupyter-notebook.readthedocs.io/en/stable/

There are multiple tutorials online that help you to learn how to use a Jupyter notebook.

The notebook is provided as an .ipynb and as a .pdf file. The plots the script generates with the default input data are also given as ...

This Jupyter Notebook assists you in the design of initial rate experiments.

For help on installing the classical Jupyter Notebook, see here: https://jupyter.org/install

For documentation about Juypter Notebooks, see here: https://jupyter-notebook.readthedocs.io/en/stable/

There are multiple tutorials online that help you to learn how to use a Jupyter notebook.

The notebook is provided as an .ipynb and as a .pdf file.

The plots the script generates with the default values are also given as .png ...

Homogeneity of the Gre2p samples in HEPES and PBS Buffer before and after different treatments.

Homogeneity of the Gre2p samples in KPi Buffer before and after different treatments, including different amounts of tween-20 in the buffer (0.01, 0.1, 1.0%).

ITC multiple injection (MIM) experiments to determine the kinetic parameters of NDK (nitrononane-2,8-dione) and NADPH with Gre2p in 100 mM KPi buffer pH 7.5 Data from ITC recurrent single injection (rSIM) experiments were used to achieve proper fitting of kcat values.

ITC multiple injection (MIM) experiments to determine the kinetic parameters of NDK (nitrononane-2,8-dione) and NADPH with Gre2p in 1x PBS buffer pH 7.5 Data from ITC recurrent single injection (rSIM) experiments were used to achieve proper fitting of kcat values.

ITC multiple injection (MIM) experiments to determine the kinetic parameters of NDK (nitrononane-2,8-dione) and NADPH with Gre2p in 100 mM HEPES buffer pH 7.5 Data from ITC recurrent single injection (rSIM) experiments were used to achieve proper fitting of kcat values.

ITC recurrent single injection (rSIM) to determine the kinetic parameters of NDK (nitrononane-2,8-dione) and NADPH with Gre2p in 100 mM KPi buffer, 1x PBS buffer and 100 mM HEPES buffer, all with pH 7.5

Python workflow for the analysis of ITC-BIND, ITC-MIM and ITC-(r)SIM experiments. Organized in a *.zip folder. Requires the following directory structure:

./ITC_analysis.py ./input/BINDING/.apj ./input/BINDING/.csv ./input/KINETICS/.apj ./input/KINETICS/.csv ./scripts/binding_neu.py ./scripts/kinetics_neu.py

And can be executed by running python ITC_analysis.py in the directory. Filenames for the input *.apj and *.csv files are defined in ITC_analysis.py. The output directory is written by ...

ITC multiple injection (MIM) experiments to determine the kinetic parameters of NDK (nitrononane-2,8-dione) and NADPH with Gre2p in 0.1%Tween-20-100 mM KPi buffer pH 7.5 Data from ITC recurrent single injection (rSIM) experiments were used to achieve proper fitting of kcat values.

ITC binding (BIND) experiments to determine the binding parameters of NADP+ to Gre2p in 1x PBS Buffer.

ITC binding (BIND) experiments to determine the binding parameters of NADP+ to Gre2p in 100 mM HEPES Buffer.

ITC binding (BIND) experiments to determine the binding parameters of NDK (nitrononane-2,8-dione) to Gre2p in 100 mM KPi Buffer. Experiments failed due to very weak binding and poor solubility of NDK in buffer.

ITC binding (BIND) experiments to determine the binding parameters of HK ((5S,8S)-anti hydroxyketone) to Gre2p in 100 mM KPi Buffer. Experiments failed due to very weak binding and poor solubility of HK in buffer.

Python workflow for the analysis of ITC-BIND, ITC-MIM and ITC-(r)SIM experiments. Organized in a *.zip folder. Requires the following directory structure:

./ITC_analysis.py ./input/BINDING/.apj ./input/BINDING/.csv ./input/KINETICS/.apj ./input/KINETICS/.csv ./scripts/binding_neu.py ./scripts/kinetics_neu.py

And can be executed by running python ITC_analysis.py in the directory. Filenames for the input *.apj and *.csv files are defined in ITC_analysis.py. The output directory is written by ...

ITC binding (BIND) experiment to determine the binding parameters of NADPH to Gre2p in 100 mM KPi Buffer with 0.1% Tween-20 added.

Specific activity of Gre2p measured by following the change in absorbance of NADPH at 340 nm for the conversion of nitrononane-2,8-dione (NDK).

Kinetic parameters (Km, kcat) of Gre2p measured by following the change in absorbance of NADPH at 340 nm for the conversion of nitrononane-2,8-dione (NDK) or hexane-2,5-dione. Initial rates at different substrate concentrations are measured.

Specific activity of Gre2p measured by following the change in absorbance of NADPH at 340 nm for the conversion of nitrononane-2,8-dione (NDK) using different enzyme concentrations.

ITC binding (BIND) experiment to determine the binding parameters of NADPH to Gre2p in 100 mM KPi Buffer.

ITC binding (BIND) experiment to determine the binding parameters of NADPH to Gre2p in 1x PBS Buffer.

ITC binding (BIND) experiments to determine the binding parameters of NADPH to Gre2p in 100 mM HEPES Buffer.

ITC binding (BIND) experiments to determine the binding parameters of NADP+ to Gre2p in 100 mM KPi Buffer.

Here would be the results from the Analysis part of the Simulation foundry. For the newest version, which was improved based on reviewers comments to represent best practices, of the Simulation Foundry for Methanol-Water mixtures no such results exist yet.

This is the simulation part of the Simulation Foundry, Version 1.5.

Download and unpack the zip file and the .sh bash script. Copy them into a folder which has a meaningful name. Launch the bash script, following the instructions in the manual.

Make sure you followed the instructions in "Preparation" before running this.

This is the analysis part of the Simulation Foundry, Version 1.5.

Download and unpack the zip file and the .sh bash script. Copy them into a folder which has a meaningful name. Launch the bash script, following the instructions in the manual.

Make sure you followed the instructions in "Preparation" before running this.

Preparation needed to use Simulation Foundry, Version 1.5.

Please read the manual before working with this Simulation Foundry.

Pay careful attention to the installation instructions.

Note the known issues.