Chancellery Research - Research Publications

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Start date: 2021 Ă— End date: 2021 Ă— Author: McCluskey, James Ă—

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    Mouse models illuminate MAIT cell biology
    Wang, H ; Chen, Z ; McCluskey, J ; Corbett, AJ (PERGAMON-ELSEVIER SCIENCE LTD, 2021-02)
    The field of mucosal-associated invariant T cell (MAIT) biology has grown rapidly since the identification of the vitamin-B-based antigens recognised by these specialised T cells. Over the past few years, our understanding of the complexities of MAIT cell function has developed, as they find their place among the other better known cells of the immune system. Key questions relate to understanding when MAIT cells help, when they hinder or cause harm, and when they do not matter. Exploiting mouse strains that differ in MAIT cell numbers, leveraged by specific detection of MAIT cells using MR1-tetramers, it has now been shown that MAIT cells play important immune roles in settings that include bacterial and viral infections, autoimmune diseases and cancer. We have also learnt much about their development, modes of activation and response to commensal microbiota, and begun to try ways to manipulate MAIT cells to improve disease outcomes. Here we review recent studies that have assessed MAIT cells in models of disease.
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    Guidelines for the use of flow cytometry and cell sorting in immunological studies (third edition)
    Cossarizza, A ; Chang, H-D ; Radbruch, A ; Abrignani, S ; Addo, R ; Akdis, M ; Andrae, I ; Andreata, F ; Annunziato, F ; Arranz, E ; Bacher, P ; Bari, S ; Barnaba, V ; Barros-Martins, J ; Baumjohann, D ; Beccaria, CG ; Bernardo, D ; Boardman, DA ; Borger, J ; Boettcher, C ; Brockmann, L ; Burns, M ; Busch, DH ; Cameron, G ; Cammarata, I ; Cassotta, A ; Chang, Y ; Chirdo, FG ; Christakou, E ; Cicin-Sain, L ; Cook, L ; Corbett, AJ ; Cornelis, R ; Cosmi, L ; Davey, MS ; De Biasi, S ; De Simone, G ; del Zotto, G ; Delacher, M ; Di Rosa, F ; Di Santo, J ; Diefenbach, A ; Dong, J ; Doerner, T ; Dress, RJ ; Dutertre, C-A ; Eckle, SBG ; Eede, P ; Evrard, M ; Falk, CS ; Feuerer, M ; Fillatreau, S ; Fiz-Lopez, A ; Follo, M ; Foulds, GA ; Froebel, J ; Gagliani, N ; Galletti, G ; Gangaev, A ; Garbi, N ; Garrote, JA ; Geginat, J ; Gherardin, NA ; Gibellini, L ; Ginhoux, F ; Godfrey, DI ; Gruarin, P ; Haftmann, C ; Hansmann, L ; Harpur, CM ; Hayday, AC ; Heine, G ; Hernandez, DC ; Herrmann, M ; Hoelsken, O ; Huang, Q ; Huber, S ; Huber, JE ; Huehn, J ; Hundemer, M ; Hwang, WYK ; Iannacone, M ; Ivison, SM ; Jaeck, H-M ; Jani, PK ; Keller, B ; Kessler, N ; Ketelaars, S ; Knop, L ; Knopf, J ; Koay, H-F ; Kobow, K ; Kriegsmann, K ; Kristyanto, H ; Krueger, A ; Kuehne, JF ; Kunze-Schumacher, H ; Kvistborg, P ; Kwok, I ; Latorre, D ; Lenz, D ; Levings, MK ; Lino, AC ; Liotta, F ; Long, HM ; Lugli, E ; MacDonald, KN ; Maggi, L ; Maini, MK ; Mair, F ; Manta, C ; Manz, RA ; Mashreghi, M-F ; Mazzoni, A ; McCluskey, J ; Mei, HE ; Melchers, F ; Melzer, S ; Mielenz, D ; Monin, L ; Moretta, L ; Multhoff, G ; Munoz, LE ; Munoz-Ruiz, M ; Muscate, F ; Natalini, A ; Neumann, K ; Ng, LG ; Niedobitek, A ; Niemz, J ; Almeida, LN ; Notarbartolo, S ; Ostendorf, L ; Pallett, LJ ; Patel, AA ; Percin, GI ; Peruzzi, G ; Pinti, M ; Pockley, AG ; Pracht, K ; Prinz, I ; Pujol-Autonell, I ; Pulvirenti, N ; Quatrini, L ; Quinn, KM ; Radbruch, H ; Rhys, H ; Rodrigo, MB ; Romagnani, C ; Saggau, C ; Sakaguchi, S ; Sallusto, F ; Sanderink, L ; Sandrock, I ; Schauer, C ; Scheffold, A ; Scherer, HU ; Schiemann, M ; Schildberg, FA ; Schober, K ; Schoen, J ; Schuh, W ; Schueler, T ; Schulz, AR ; Schulz, S ; Schulze, J ; Simonetti, S ; Singh, J ; Sitnik, KM ; Stark, R ; Starossom, S ; Stehle, C ; Szelinski, F ; Tan, L ; Tarnok, A ; Tornack, J ; Tree, TIM ; van Beek, JJP ; van de Veen, W ; van Gisbergen, K ; Vasco, C ; Verheyden, NA ; von Borstel, A ; Ward-Hartstonge, KA ; Warnatz, K ; Waskow, C ; Wiedemann, A ; Wilharm, A ; Wing, J ; Wirz, O ; Wittner, J ; Yang, JHM ; Yang, J (WILEY, 2021-12)
    The third edition of Flow Cytometry Guidelines provides the key aspects to consider when performing flow cytometry experiments and includes comprehensive sections describing phenotypes and functional assays of all major human and murine immune cell subsets. Notably, the Guidelines contain helpful tables highlighting phenotypes and key differences between human and murine cells. Another useful feature of this edition is the flow cytometry analysis of clinical samples with examples of flow cytometry applications in the context of autoimmune diseases, cancers as well as acute and chronic infectious diseases. Furthermore, there are sections detailing tips, tricks and pitfalls to avoid. All sections are written and peer-reviewed by leading flow cytometry experts and immunologists, making this edition an essential and state-of-the-art handbook for basic and clinical researchers.
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    MAIT cells regulate NK cell-mediated tumor immunity
    Petley, E ; Koay, H-F ; Henderson, MA ; Sek, K ; Todd, KL ; Keam, SP ; Lai, J ; House, IG ; Li, J ; Zethoven, M ; Chen, AXY ; Oliver, AJ ; Michie, J ; Freeman, AJ ; Giuffrida, L ; Chan, JD ; Pizzolla, A ; Mak, JYW ; McCulloch, TR ; Souza-Fonseca-Guimaraes, F ; Kearney, CJ ; Millen, R ; Ramsay, RG ; Huntington, ND ; McCluskey, J ; Oliaro, J ; Fairlie, DP ; Neeson, PJ ; Godfrey, D ; Beavis, PA ; Darcy, PK (NATURE PORTFOLIO, 2021-08-06)
    The function of MR1-restricted mucosal-associated invariant T (MAIT) cells in tumor immunity is unclear. Here we show that MAIT cell-deficient mice have enhanced NK cell-dependent control of metastatic B16F10 tumor growth relative to control mice. Analyses of this interplay in human tumor samples reveal that high expression of a MAIT cell gene signature negatively impacts the prognostic significance of NK cells. Paradoxically, pre-pulsing tumors with MAIT cell antigens, or activating MAIT cells in vivo, enhances anti-tumor immunity in B16F10 and E0771 mouse tumor models, including in the context of established metastasis. These effects are associated with enhanced NK cell responses and increased expression of both IFN-Îł-dependent and inflammatory genes in NK cells. Importantly, activated human MAIT cells also promote the function of NK cells isolated from patient tumor samples. Our results thus describe an activation-dependent, MAIT cell-mediated regulation of NK cells, and suggest a potential therapeutic avenue for cancer treatment.
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    Francisella tularensis induces Th1 like MAIT cells conferring protection against systemic and local infection
    Zhao, Z ; Wang, H ; Shi, M ; Zhu, T ; Pediongco, T ; Lim, XY ; Meehan, BS ; Nelson, AG ; Fairlie, DP ; Mak, JYW ; Eckle, SBG ; Moreira, MDL ; Tumpach, C ; Bramhall, M ; Williams, CG ; Lee, HJ ; Haque, A ; Evrard, M ; Rossjohn, J ; McCluskey, J ; Corbett, AJ ; Chen, Z (NATURE PORTFOLIO, 2021-07-16)
    Mucosal-associated Invariant T (MAIT) cells are recognized for their antibacterial functions. The protective capacity of MAIT cells has been demonstrated in murine models of local infection, including in the lungs. Here we show that during systemic infection of mice with Francisella tularensis live vaccine strain results in evident MAIT cell expansion in the liver, lungs, kidney and spleen and peripheral blood. The responding MAIT cells manifest a polarised Th1-like MAIT-1 phenotype, including transcription factor and cytokine profile, and confer a critical role in controlling bacterial load. Post resolution of the primary infection, the expanded MAIT cells form stable memory-like MAIT-1 cell populations, suggesting a basis for vaccination. Indeed, a systemic vaccination with synthetic antigen 5-(2-oxopropylideneamino)-6-D-ribitylaminouracil in combination with CpG adjuvant similarly boosts MAIT cells, and results in enhanced protection against both systemic and local infections with different bacteria. Our study highlights the potential utility of targeting MAIT cells to combat a range of bacterial pathogens.