A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response

Justin Melunis; Bruce Freedman; Uri Hershberg

doi:10.1109/AISW.2015.7469234

A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response

Justin Melunis, Bruce Freedman, Uri Hershberg

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Calcium dynamics lie at the heart of many adaptive cellular signals and are thus tightly controlled. While the importance of calcium in immune cell modulation has long been known, it is only in recent studies that immune cell differentiation, maturation and response to T cell receptor signaling, have been linked to the dynamics of calcium. Postantigen binding calcium signaling is controlled by the release of internal stores from the endoplasmatic reticulum (ER) and the opening of channels in the plasma membrane (PM). The release of calcium from the ER allow the stromal interaction molecule 1s (STIM1s) to dimerize and localize at the ER-PM junction where they are then able to bind to calcium releaseactivated calcium channel protein 1s (Orai1s) at the PM. This causes the Orai1 channels to become permeable to calcium, causing a flux across the membrane. It is unclear if STIM1 and Orai1 are directed to bind by some signaling mechanism or simply co-localize because of normal diffusion constraints of molecular motion. We here present a stochastic model of STIM1 and Orai1 movement and interaction and relate them to observed patterns seen pre and post activation of the T cell receptor. With this simulation we have taken a sampling rate of molecule locations, similar to experimental observation, and determined observed rates of diffusion based on individual molecules that we simulated within our analysis. Thanks to our mode of simulation, we can model how the movement of individual molecules and the influx of calcium appear at the population level post T cell stimulation. Through our model, we find that diffusion trap mechanics are sufficient to describe the observed STIM accumulation at the ER-PM junction and that the boundary conditions of a diffusion trap and the decrease in diffusion due to STIM-Orai conjugate formations could account fully for the observed decrease in the rate of STIM motion after ER calcium release.

Original language	American English
Title of host publication	International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation
Subtitle of host publication	Immunology without Borders, Proceedings
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9781509002986
DOIs	https://doi.org/10.1109/AISW.2015.7469234
State	Published - 11 May 2016
Externally published	Yes
Event	International Workshop on Artificial Immune Systems, AIS 2015 - Taormina, Sicily, Italy Duration: 17 Jul 2015 → 18 Jul 2015

Publication series

Name	International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings

Conference

Conference	International Workshop on Artificial Immune Systems, AIS 2015
Country/Territory	Italy
City	Taormina, Sicily
Period	17/07/15 → 18/07/15

Keywords

ORAI
STIM
calcium
differentiation
diffusion trap
stochastic modeling
thymocytes

All Science Journal Classification (ASJC) codes

Computer Networks and Communications
Immunology
Health Informatics
Immunology and Allergy

Access to Document

10.1109/AISW.2015.7469234

Cite this

Melunis, J., Freedman, B., & Hershberg, U. (2016). A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response. In International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings Article 7469234 (International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/AISW.2015.7469234

Melunis, Justin ; Freedman, Bruce ; Hershberg, Uri. / A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response. International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings. Institute of Electrical and Electronics Engineers Inc., 2016. (International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings).

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title = "A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response",

abstract = "Calcium dynamics lie at the heart of many adaptive cellular signals and are thus tightly controlled. While the importance of calcium in immune cell modulation has long been known, it is only in recent studies that immune cell differentiation, maturation and response to T cell receptor signaling, have been linked to the dynamics of calcium. Postantigen binding calcium signaling is controlled by the release of internal stores from the endoplasmatic reticulum (ER) and the opening of channels in the plasma membrane (PM). The release of calcium from the ER allow the stromal interaction molecule 1s (STIM1s) to dimerize and localize at the ER-PM junction where they are then able to bind to calcium releaseactivated calcium channel protein 1s (Orai1s) at the PM. This causes the Orai1 channels to become permeable to calcium, causing a flux across the membrane. It is unclear if STIM1 and Orai1 are directed to bind by some signaling mechanism or simply co-localize because of normal diffusion constraints of molecular motion. We here present a stochastic model of STIM1 and Orai1 movement and interaction and relate them to observed patterns seen pre and post activation of the T cell receptor. With this simulation we have taken a sampling rate of molecule locations, similar to experimental observation, and determined observed rates of diffusion based on individual molecules that we simulated within our analysis. Thanks to our mode of simulation, we can model how the movement of individual molecules and the influx of calcium appear at the population level post T cell stimulation. Through our model, we find that diffusion trap mechanics are sufficient to describe the observed STIM accumulation at the ER-PM junction and that the boundary conditions of a diffusion trap and the decrease in diffusion due to STIM-Orai conjugate formations could account fully for the observed decrease in the rate of STIM motion after ER calcium release.",

keywords = "ORAI, STIM, calcium, differentiation, diffusion trap, stochastic modeling, thymocytes",

author = "Justin Melunis and Bruce Freedman and Uri Hershberg",

note = "Publisher Copyright: {\textcopyright} 2015 IEEE.; International Workshop on Artificial Immune Systems, AIS 2015 ; Conference date: 17-07-2015 Through 18-07-2015",

year = "2016",

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doi = "10.1109/AISW.2015.7469234",

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Melunis, J, Freedman, B & Hershberg, U 2016, A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response. in International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings., 7469234, International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings, Institute of Electrical and Electronics Engineers Inc., International Workshop on Artificial Immune Systems, AIS 2015, Taormina, Sicily, Italy, 17/07/15. https://doi.org/10.1109/AISW.2015.7469234

A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response. / Melunis, Justin; Freedman, Bruce; Hershberg, Uri.
International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings. Institute of Electrical and Electronics Engineers Inc., 2016. 7469234 (International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response

AU - Melunis, Justin

AU - Freedman, Bruce

AU - Hershberg, Uri

PY - 2016/5/11

Y1 - 2016/5/11

N2 - Calcium dynamics lie at the heart of many adaptive cellular signals and are thus tightly controlled. While the importance of calcium in immune cell modulation has long been known, it is only in recent studies that immune cell differentiation, maturation and response to T cell receptor signaling, have been linked to the dynamics of calcium. Postantigen binding calcium signaling is controlled by the release of internal stores from the endoplasmatic reticulum (ER) and the opening of channels in the plasma membrane (PM). The release of calcium from the ER allow the stromal interaction molecule 1s (STIM1s) to dimerize and localize at the ER-PM junction where they are then able to bind to calcium releaseactivated calcium channel protein 1s (Orai1s) at the PM. This causes the Orai1 channels to become permeable to calcium, causing a flux across the membrane. It is unclear if STIM1 and Orai1 are directed to bind by some signaling mechanism or simply co-localize because of normal diffusion constraints of molecular motion. We here present a stochastic model of STIM1 and Orai1 movement and interaction and relate them to observed patterns seen pre and post activation of the T cell receptor. With this simulation we have taken a sampling rate of molecule locations, similar to experimental observation, and determined observed rates of diffusion based on individual molecules that we simulated within our analysis. Thanks to our mode of simulation, we can model how the movement of individual molecules and the influx of calcium appear at the population level post T cell stimulation. Through our model, we find that diffusion trap mechanics are sufficient to describe the observed STIM accumulation at the ER-PM junction and that the boundary conditions of a diffusion trap and the decrease in diffusion due to STIM-Orai conjugate formations could account fully for the observed decrease in the rate of STIM motion after ER calcium release.

AB - Calcium dynamics lie at the heart of many adaptive cellular signals and are thus tightly controlled. While the importance of calcium in immune cell modulation has long been known, it is only in recent studies that immune cell differentiation, maturation and response to T cell receptor signaling, have been linked to the dynamics of calcium. Postantigen binding calcium signaling is controlled by the release of internal stores from the endoplasmatic reticulum (ER) and the opening of channels in the plasma membrane (PM). The release of calcium from the ER allow the stromal interaction molecule 1s (STIM1s) to dimerize and localize at the ER-PM junction where they are then able to bind to calcium releaseactivated calcium channel protein 1s (Orai1s) at the PM. This causes the Orai1 channels to become permeable to calcium, causing a flux across the membrane. It is unclear if STIM1 and Orai1 are directed to bind by some signaling mechanism or simply co-localize because of normal diffusion constraints of molecular motion. We here present a stochastic model of STIM1 and Orai1 movement and interaction and relate them to observed patterns seen pre and post activation of the T cell receptor. With this simulation we have taken a sampling rate of molecule locations, similar to experimental observation, and determined observed rates of diffusion based on individual molecules that we simulated within our analysis. Thanks to our mode of simulation, we can model how the movement of individual molecules and the influx of calcium appear at the population level post T cell stimulation. Through our model, we find that diffusion trap mechanics are sufficient to describe the observed STIM accumulation at the ER-PM junction and that the boundary conditions of a diffusion trap and the decrease in diffusion due to STIM-Orai conjugate formations could account fully for the observed decrease in the rate of STIM motion after ER calcium release.

KW - ORAI

KW - STIM

KW - calcium

KW - differentiation

KW - diffusion trap

KW - stochastic modeling

KW - thymocytes

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U2 - 10.1109/AISW.2015.7469234

DO - 10.1109/AISW.2015.7469234

M3 - Conference contribution

T3 - International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings

BT - International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - International Workshop on Artificial Immune Systems, AIS 2015

Y2 - 17 July 2015 through 18 July 2015

ER -

Melunis J, Freedman B, Hershberg U. A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response. In International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings. Institute of Electrical and Electronics Engineers Inc. 2016. 7469234. (International Workshop on Artificial Immune Systems, AIS 2015/ICSI3 2015 - Systems Immunology, Immunoinformatics and Immune-computation: Immunology without Borders, Proceedings). doi: 10.1109/AISW.2015.7469234

A molecular model of STIM1-Orai1 movement and binding and their influence on calcium dynamics in T cell receptor response

Abstract

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Conference

Keywords

All Science Journal Classification (ASJC) codes

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