The Arabidopsis AtSWEET13 transporter discriminates sugars by selective facial and positional substrate recognition
Data files
Apr 15, 2024 version files 60.02 GB
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F1.zip
19.55 MB
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F2.zip
5.10 GB
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F3.zip
1.89 MB
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F4.zip
50.95 MB
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F6.zip
5.07 MB
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GITHUB.zip
2.47 MB
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msm_objects.zip
17.42 MB
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per_directory_readme.md
4.33 KB
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README.md
2.21 KB
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seeds.zip
5.49 GB
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SF01.zip
85.98 MB
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SF02.zip
38.44 MB
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SF04.zip
28.72 MB
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SF05.zip
28.73 MB
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SF06.zip
48.01 MB
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SF07.zip
48.05 MB
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SF08.zip
48.06 MB
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SF09.zip
48.09 MB
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SF10.zip
87.79 MB
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SF11.zip
800.33 KB
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SF12.zip
53.44 MB
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SF13.zip
53.73 MB
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SF14.zip
91.11 MB
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SF15.zip
91.06 MB
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SF16.zip
91.07 MB
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SF17.zip
91.17 MB
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SF18.zip
54.32 MB
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SF19.zip
54.25 MB
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SF20.zip
91.34 MB
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SF21.zip
91.52 MB
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SF22.zip
91.37 MB
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SF23.zip
91.46 MB
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SF24.zip
54.13 MB
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SF25.zip
54.19 MB
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SF26.zip
91.32 MB
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SF27.zip
91.35 MB
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SF28.zip
91.49 MB
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SF29.zip
91.46 MB
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SF32_33.zip
2.95 GB
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SF36.zip
17.68 MB
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SF37_38_39.zip
17.42 MB
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SF40_ITS.zip
3.01 MB
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SF41_42_43_bootstrapping_APO.zip
2.88 GB
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SF41_42_43_bootstrapping_GLC.zip
12.35 GB
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SF41_42_43_bootstrapping_SUC.zip
29.23 GB
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source_data.txt
6.14 KB
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source_data.yml
6.95 KB
Abstract
Transporters are targeted by endogenous metabolites and exogenous molecules to reach cellular destinations, but it is generally not understood how different substrate classes exploit the same transporter’s mechanism. Any disclosure of plasticity in transporter mechanism when treated with different substrates becomes critical for developing general selectivity principles in membrane transport catalysis. Using extensive molecular dynamics simulations with an enhanced sampling approach, we select the Arabidopsis sugar transporter AtSWEET13 as a model system to identify the basis for glucose versus sucrose molecular recognition and transport. Here we find that AtSWEET13 chemical selectivity originates from a conserved substrate facial selectivity demonstrated when committing alternate access, despite mono-/di-saccharides experiencing differing degrees of conformational and positional freedom throughout other stages of transport. However, substrate interactions with structural hallmarks associated with known functional annotations can help reinforce selective preferences in molecular transport.
README: The Arabidopsis AtSWEET13 transporter discriminates sugars by selective facial and positional substrate recognition
https://doi.org/10.5061/dryad.8sf7m0cxn
The data files provided in this dataset are mainly targeted towards recreating all figures (Main Text and Supplemental) from our manuscript.
Description of the data and file structure
Each figure generated from a numerical analysis, and its related files, are enumerated in different zipped directories. Each directory is named after the figure that encodes (Main Text = F1, F2, F3, F4, F6; SI = SF01 ...). Within each folder contains either a python script or a jupyter notebook, which can be used to execute the necessary codes to reproduce the figures. Raw data is either provided as pkl files or as Excel sheets. Necessary information related to distribution statistics is included as Excel workbooks.
Other files not directly related to figure reproduction are provided as well. MSM-related files are provided in msm_objects. The directory seeds contains every single coordinate file used to begin production simulations for adaptive sampling of apo and holo AtSWEET13 simulations.
The interactive contents within each directory are described in the file per_directory_readme.md.
Sharing/Access information
Files related to simulation analyses (scripts, outputs of scripts that were compiled into pkl files), Markov state model pipelines, and some topology files have also been made available on Box:
[https://uofi.box.com/s/mqwnlc52xnkf6rnmron36tclv68kklv9\](https://uofi.box.com/s/mqwnlc52xnkf6rnmron36tclv68kklv9\)
A copy of the contents with our related Github repository (GITHUB) is provided in zipped format as a means of version control. However, this Github repository mainly exists as a means to point towards the provided Box link (i.e., is mostly an empty repository).
Code/Software
Codes and jupyter notebooks provided here can be used to reproduce figures. Analyses unrelated to direct figure reproduction are provided on Box. These python codes can be executed using a conda environment build from either the provided source_data.txt or source_data.yml.
Methods
Molecular dynamics trajectories were generated using AMBER18, performed on NCSA Blue Waters supercomputing resources. Analyses were performed with python scripts.
This work has been performed by Austin T. Weigle & Diwakar Shukla at the University of Illinois Urbana-Champaign.
This Dryad dataset has been made available in compliance with the "minimum dataset"/source data requirement per the Data Availability guidelines by Communications Biology.
For further inquiries concerning further data availability, please contact Prof. Diwakar Shukla at diwakar@illinois.edu. Austin T. Weigle (https://orcid.org/0000-0002-1619-2452) prepared this Dryad repository.