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      The kinetics of two dimensional TCR and pMHC interactions determine T cell responsiveness

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          Abstract

          The T cell receptor (TCR) interacts with peptide-major histocompatibility complexes (pMHC) to discriminate pathogens from self-antigens and trigger adaptive immune responses. Direct physical contact is required between the T cell and the antigen-presenting cell (APC) for cross-junctional binding where the TCR and pMHC are anchored on two-dimensional (2D) membranes of the apposing cells 1. Despite their 2D nature, TCR-pMHC binding kinetics have only been analyzed three-dimensionally (3D) with a varying degree of correlation with the T cell responsiveness 2- 4. Here we use two mechanical assays 5, 6 to show high 2D affinities between a TCR and its antigenic pMHCs driven by rapid on-rates. Compared to their 3D counterparts, 2D affinities and on-rates of the TCR for a panel of pMHC ligands possess far broader dynamic ranges that match that of their corresponding T cell responses. The best 3D predictor of response is the off-rate, with agonist pMHC dissociating the slowest 2- 4. In contrast, 2D off-rates are up to 8,300-fold faster, with the agonist pMHC dissociating the fastest. Our 2D data suggest rapid antigen sampling by T cells and serial engagement of a few agonist pMHCs by TCRs in a large self pMHC background. Thus, the cellular environment amplifies the TCR-pMHC binding to generate broad affinities and rapid kinetics that determine T-cell responsiveness.

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          Use of cyclodextrins to manipulate plasma membrane cholesterol content: evidence, misconceptions and control strategies.

          Raphael Zidovetzki, Irena Levitan (2007)
          The physiological importance of cholesterol in the cell plasma membrane has attracted increased attention in recent years. Consequently, the use of methods of controlled manipulation of membrane cholesterol content has also increased sharply, especially as a method of studying putative cholesterol-enriched cell membrane domains (rafts). The most common means of modifying the cholesterol content of cell membranes is the incubation of cells or model membranes with cyclodextrins, a family of compounds, which, due to the presence of relatively hydrophobic cavity, can be used to extract cholesterol from cell membranes. However, the mechanism of this activity of cyclodextrins is not completely established. Moreover, under conditions commonly used for cholesterol extraction, cyclodextrins may remove cholesterol from both raft and non-raft domains of the membrane as well as alter the distribution of cholesterol between plasma and intracellular membranes. In addition, other hydrophobic molecules such as phospholipids may also be extracted from the membranes by cyclodextrins. We review the evidence for the specific and non-specific effects of cyclodextrins and what is known about the mechanisms for cyclodextrin-induced cholesterol and phospholipid extraction. Finally, we discuss useful control strategies that may help to verify that the observed effects are due specifically to cyclodextrin-induced changes in cellular cholesterol.
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            Complete but curtailed T cell response to very low affinity antigen

            Dietmar Zehn, Sarah Lee, Michael J. Bevan (2009)
            Following an infection, CD8+ T cells are activated and undergo a characteristic kinetic sequence of rapid expansion, subsequent contraction and formation of memory cells1–3. The pool of naïve T cell clones is diverse and contains cells bearing T cell antigen receptors (TCR) that differ in their affinity for the same antigen4,5. How these differences in affinity impact the function and the response kinetics of individual T cell clones was previously unknown. Here we show that during the in vivo response to microbial infection, even very weak TCR-ligand interactions are sufficient to activate naïve T cells, induce rapid initial proliferation and generate effector and memory cells. The strength of the TCR-ligand interaction critically impacts when expansion stops, when the cells exit lymphoid organs and when contraction begins, i.e. strongly stimulated T cells contract and exit lymphoid organs later than do weakly stimulated cells. Our data challenges the prevailing view that strong TCR ligation is a prerequisite for CD8+ T cell activation. Instead, very weak interactions are sufficient for activation, but strong TCR ligation is required to sustain T cell expansion. We propose that in response to microbial challenge, T cell clones with a broad range of avidities for foreign ligands are initially recruited, and that the pool of T cells subsequently matures in affinity due to the more prolonged expansion of high affinity T cell clones.
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              Serial triggering of many T-cell receptors by a few peptide-MHC complexes.

              S Valitutti, S. Müller, M. Cella (1995)
              T lymphocytes can recognize and be activated by a very small number of complexes of peptide with major histocompatibility complex (MHC) molecules displayed on the surface of antigen-presenting cells (APCs). The interaction between the T-cell receptor (TCR) and its ligand has low affinity and high off-rate. Both findings suggest that an extremely small number of TCRs must be engaged in interaction with APCs and raise the question of how so few receptors can transduce an activation signal. Here we show that a small number of peptide-MHC complexes can achieve a high TCR occupancy, because a single complex can serially engage and trigger up to approximately 200 TCRs. Furthermore, TCR occupancy is proportional to the T cell's biological response. Our findings suggest that the low affinity of the TCR can be instrumental in enabling a small number of antigenic complexes to be detected.
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                Author and article information

                Journal
                Journal ID (nlm-journal-id): 0410462
                Journal ID (pubmed-jr-id): 6011
                Journal ID (nlm-ta): Nature
                Title: Nature
                ISSN (Print): 0028-0836
                ISSN (Electronic): 1476-4687
                Publication date Nihms-submitted: 2 June 2010
                Publication date (Electronic): 31 March 2010
                Publication date (Print): 8 April 2010
                Publication date PMC-release: 8 October 2010
                Volume: 464
                Issue: 7290
                Pages: 932-936
                Affiliations
                [1 ]Coulter Department of Biomedical Engineering, Georgia Institute of Technology, Atlanta, GA 30332, USA
                [2 ]Department of Microbiology and Immunology, Emory University School of Medicine, Atlanta, GA, 30322, USA
                Author notes
                Correspondence and requests for materials should be addressed to C. Z. ( cheng.zhu@ 123456bme.gatech.edu ) or B. E. ( bevavol@ 123456emory.edu )
                [3]

                Present address: Department of Microbiology & Immunology and The Howard Hughes Medical Institute, Stanford University School of Medicine, Stanford, CA 94305, USA

                [4]

                Present address: Department of Bioengineering, Stanford University, Stanford, CA, 94305, USA

                Article
                Manuscript ID: nihpa182843
                DOI: 10.1038/nature08944
                PMC ID: 2925443
                PubMed ID: 20357766
                SO-VID: 58e24ef5-92e5-454e-9f97-c92c7a4a44ca
                History
                Funding
                Funded by: National Institute of Neurological Disorders and Stroke : NINDS
                Award ID: R01 NS062358-01A1 ||NS
                Categories
                Subject: Article

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