Visualizing Dynamic Microvillar Search and Stabilization during Ligand Detection by T Cells

Cai, En; Marchuk, Kyle; Beemiller, Peter; Beppler, Casey; Rubashkin, Matthew G.; Weaver, Valerie M.; Gérard, Audrey; T-L., Liu; B-C., Chen; Betzig, Eric; Bartumeus, Frederic; Krummel, Matthew F.

doi:10.1016/j.bpj.2017.11.2992

Cited by 59 publications

(143 citation statements)

References 26 publications

(37 reference statements)

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“…Inter-NP spacing from 40 nm to 120 nm, cluster sizes from 240 nm to 1440 nm diameter, and densities from ~100/µm 2 to ~30/µm 2 were compared (Fig 2a). The pY signal on all patterns was multifocal, likely reflecting natural patterns of small, F-actin-dependent projections that mediate first contact of T cells with the surface 26 . The pY signal was strongly colocalized with the UCHT1 Fab’ clusters regardless of the geometry (Fig.…”

Section: Effects Of Ligand Spacing and Density On 2d Arraysmentioning

confidence: 98%

Full control of ligand positioning reveals spatial thresholds for T cell receptor triggering

et al. 2018

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Elucidating the rules for receptor triggering in cell-cell and cell-matrix contacts requires precise control of ligand positioning in three dimensions. Here, we use the T cell receptor (TCR) as a model and subject T cells to different geometric arrangements of ligands, using a nanofabricated single-molecule array platform. This is comprised of monovalent TCR ligands anchored to lithographically patterned nanoparticle clusters surrounded by mobile adhesion molecules on a supported lipid bilayer (SLB). The TCR ligand could be co-planar with the SLB (2D), excluding the CD45 transmembrane tyrosine phosphatase, or elevated by 10 nm on solid nanopedestals (3D), allowing closer access of CD45 to engaged TCR. The two configurations resulted in different T cell responses, depending on the lateral spacing between the ligands. These results identify the important contributions of lateral and axial components of ligand positioning and create a more complete foundation for receptor engineering for immunotherapy.

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Section: Effects Of Ligand Spacing and Density On 2d Arraysmentioning

confidence: 98%

Full control of ligand positioning reveals spatial thresholds for T cell receptor triggering

et al. 2018

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“…Instead of waiting for passive close contact formation and hence TCR/pMHC binding, T cells actively produce close contacts. They use structures known as microvilli or invadosome‐like protrusions (ILPs) . These actin‐rich 100‐200 nm diameter protrusions enable T cells to push on nearby cells in order to achieve close membrane apposition compatible with TCR/pMHC interactions, which leads to CD45 segregation (Figure B).…”

Section: Mechanisms Of T‐cell Sensitivity To Antigenmentioning

confidence: 99%

“…They use structures known as microvilli or invadosome‐like protrusions (ILPs) . These actin‐rich 100‐200 nm diameter protrusions enable T cells to push on nearby cells in order to achieve close membrane apposition compatible with TCR/pMHC interactions, which leads to CD45 segregation (Figure B). It is noteworthy that these structures have short (approximately 5‐50 seconds) lifetimes without antigen, but upon antigen recognition, they can be stabilized for long (approximately 10 minutes) timescales .…”

Section: Mechanisms Of T‐cell Sensitivity To Antigenmentioning

confidence: 99%

“…These actin‐rich 100‐200 nm diameter protrusions enable T cells to push on nearby cells in order to achieve close membrane apposition compatible with TCR/pMHC interactions, which leads to CD45 segregation (Figure B). It is noteworthy that these structures have short (approximately 5‐50 seconds) lifetimes without antigen, but upon antigen recognition, they can be stabilized for long (approximately 10 minutes) timescales . This stabilization may involve TCR signaling leading to sustained actin polymerization, a phenomenon observed in these protrusions …”

Section: Mechanisms Of T‐cell Sensitivity To Antigenmentioning

confidence: 99%

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Molecular mechanisms of T cell sensitivity to antigen

Siller-Farfán

Dushek

2018

Immunological Reviews

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T cells initiate and regulate adaptive immune responses that can clear infections. To do this, they use their T cell receptors (TCRs) to continually scan the surfaces of other cells for cognate peptide antigens presented on major histocompatibility complexes (pMHCs). Experimental work has established that as few 1-10 pMHCs are sufficient to activate T cells. This sensitivity is remarkable in light of a number of factors, including the observation that the TCR and pMHC are short molecules relative to highly abundant long surface molecules, such as CD45, that can hinder initial binding, and moreover, the TCR/pMHC interaction is of weak affinity with solution lifetimes of approximately 1 second. Here, we review experimental and mathematical work that has contributed to uncovering molecular mechanisms of T cell sensitivity. We organize the mechanisms by where they act in the pathway to activate T cells, namely mechanisms that (a) promote TCR/pMHC binding, (b) induce rapid TCR signaling, and (c) amplify TCR signaling. We discuss work showing that high sensitivity reduces antigen specificity unless molecular feedbacks are invoked. We conclude by summarizing a number of open questions.

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“…The role of cytoskeletal forces for kinetic segregation, along with associated kinetic proofreading models for TCR signaling have been exhaustively reviewed in Comrie et al [88]. Further evidence for active formation of microclusters comes from a recent study which used high-resolution light sheet microscopy to show that dynamic microvilli on T cells drive the formation of close contacts on the APC surface, which are colocalized with TCR microclusters [89]. This is consistent with earlier work showing the correlation between microclusters and regions of reduced membrane fluctuations [84].…”

Section: Mechanosensing At the Cellular Scalementioning

confidence: 99%

Mechanosensing in the immune response

Upadhyaya

2017

Seminars in Cell & Developmental Biology

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Cells have a remarkable ability to sense and respond to the mechanical properties of their environment. Mechanosensing is essential for many phenomena from cell movements and tissue rearrangements to cell differentiation and the immune response. Cells of the immune system get activated when membrane receptors bind to cognate antigen on the surface of antigen presenting cells. Both T and B lymphocyte signaling has been shown to be responsive to physical forces and mechanical cues. Cytoskeletal forces exerted by cells likely mediate this mechanical modulation. Here we discuss recent advances in the field of immune cell mechanobiology at the molecular and cellular scale.

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Visualizing Dynamic Microvillar Search and Stabilization during Ligand Detection by T Cells

Cited by 59 publications

References 26 publications

Full control of ligand positioning reveals spatial thresholds for T cell receptor triggering

Full control of ligand positioning reveals spatial thresholds for T cell receptor triggering

Molecular mechanisms of T cell sensitivity to antigen

Mechanosensing in the immune response

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