John James

John James, Associate Professor

Tel : 024 7652 28367 | Email John.James@warwick.ac.uk

Plain English

T-cells are an essential blood cell-type in our immune system that can eliminate infections to keep us healthy despite constant exposure to pathogens. T-cells contain an intricate signalling network, which decides whether the cells of our body have become infected. Current methods to investigate this important network invariably also lead to its disruption.
We overcome this problem by developing new molecular tools so that we can investigate the signalling network while keeping it intact. We do this by engineering T-cell stimuli that are light-responsive, giving us precise control over signalling in space and time.

This enables us to directly answer questions about how T-cells can calculate the appropriate functional response, in a way not possible with standard techniques. Our goal is to find parts of the decision-making network that could be fine-tuned by drugs to improve our immune system when T-cell function becomes incapable of maintaining our health.

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John James

John James, Associate Professor

Tel : 024 7652 28367 | Email John.James@warwick.ac.uk

PubMed | ORCID

Plain English

Technical Summary

We have a near-complete characterisation of the components for many biological signalling networks, but their dynamic interconnections remain poorly understood. Current methods to investigate intracellular signalling generally disrupt one point in the network and compare cell function afterwards. However, the intervention can never be made without perturbing the rest of the system and rarely provides the dynamic information required for a mechanistic understanding of network function.

Our strategy to investigate cell signalling is to provide quantitative and dynamic inputs to the intact network, measure the corresponding functional outputs and then infer characteristics of the underlying system. To achieve the required spatio-temporal control over signalling, we develop light-controlled biological components that enable us to modulate both the intensity and frequency of signalling within the network.

We currently focus on the intracellular signalling of T cells, an essential immune cell-type that detect infected cells and orchestrate their removal. Using our new tools, our key goal is to provide a quantitative understanding of how different T cell inputs are decoded by the dynamics of the signalling pathways to specify the appropriate response. Through this, we hope to discover parts of the network that could be fine-tuned therapeutically to alleviate diseases when T cell function becomes deleterious.

Selected publications

James, J.R. (2018) Tuning ITAM multiplicity on T cell receptors can control potency and selectivity to ligand density. Sci Signal. 11(531). doi:10.1126/scisignal.aan1088

Liaunardy-Jopeace, A., Murton, B.L., Mahesh, M., Chin, J.W., James, J.R. (2017) Encoding optical control in LCK kinase to quantitatively investigate its activity in live cells. Nat Struct Mol Biol. 24(12). doi:10.1038/nsmb.3492

Li, J., Stagg, N.J., Johnston, J., Harris, M.J., Menzies, S.A., […] James, J.R., Junttila, T.T. (2017) Membrane-Proximal Epitope Facilitates Efficient T Cell Synapse Formation by Anti-FcRH5/CD3 and Is a Requirement for Myeloma Cell Killing. Cancer Cell. 31(3). doi:10.1016/j.ccell.2017.02.001

James, J.R., Vale, R.D. (2012) Biophysical mechanism of T-cell receptor triggering in a reconstituted system. Nature. 487(7405). doi:10.1038/nature11220