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277 results on '"Corbett, Alexandra J."'

1. MAIT cell-MR1 reactivity is highly conserved across multiple divergent species

Author

Edmans, Matthew D., Connelley, Timothy K., Morgan, Sophie, Pediongco, Troi J., Jayaraman, Siddharth, Juno, Jennifer A., Meehan, Bronwyn S., Dewar, Phoebe M., Maze, Emmanuel A., Roos, Eduard O., Paudyal, Basudev, Mak, Jeffrey Y.W., Liu, Ligong, Fairlie, David P., Wang, Huimeng, Corbett, Alexandra J., McCluskey, James, Benedictus, Lindert, Tchilian, Elma, Klenerman, Paul, and Eckle, Sidonia B.G.

Published
2024
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2. Dual TCR-α Expression on Mucosal-Associated Invariant T Cells as a Potential Confounder of TCR Interpretation.

Author

Suliman, Sara, Kjer-Nielsen, Lars, Iwany, Sarah K, Lopez Tamara, Kattya, Loh, Liyen, Grzelak, Ludivine, Kedzierska, Katherine, Ocampo, Tonatiuh A, Corbett, Alexandra J, McCluskey, James, Rossjohn, Jamie, León, Segundo R, Calderon, Roger, Lecca-Garcia, Leonid, Murray, Megan B, Moody, D Branch, and Van Rhijn, Ildiko

Subjects
Vaccine Related (AIDS), Prevention, Vaccine Related, Immunization, 2.1 Biological and endogenous factors, Aetiology, Histocompatibility Antigens Class I, Humans, Minor Histocompatibility Antigens, Mucosal-Associated Invariant T Cells, Mucous Membrane, Receptors, Antigen, T-Cell, Immunology
Abstract

Mucosal-associated invariant T (MAIT) cells are innate-like T cells that are highly abundant in human blood and tissues. Most MAIT cells have an invariant TCRα-chain that uses T cell receptor α-variable 1-2 (TRAV1-2) joined to TRAJ33/20/12 and recognizes metabolites from bacterial riboflavin synthesis bound to the Ag-presenting molecule MHC class I related (MR1). Our attempts to identify alternative MR1-presented Ags led to the discovery of rare MR1-restricted T cells with non-TRAV1-2 TCRs. Because altered Ag specificity likely alters affinity for the most potent known Ag, 5-(2-oxopropylideneamino)-6-d-ribitylaminouracil (5-OP-RU), we performed bulk TCRα- and TCRβ-chain sequencing and single-cell-based paired TCR sequencing on T cells that bound the MR1-5-OP-RU tetramer with differing intensities. Bulk sequencing showed that use of V genes other than TRAV1-2 was enriched among MR1-5-OP-RU tetramerlow cells. Although we initially interpreted these as diverse MR1-restricted TCRs, single-cell TCR sequencing revealed that cells expressing atypical TCRα-chains also coexpressed an invariant MAIT TCRα-chain. Transfection of each non-TRAV1-2 TCRα-chain with the TCRβ-chain from the same cell demonstrated that the non-TRAV1-2 TCR did not bind the MR1-5-OP-RU tetramer. Thus, dual TCRα-chain expression in human T cells and competition for the endogenous β-chain explains the existence of some MR1-5-OP-RU tetramerlow T cells. The discovery of simultaneous expression of canonical and noncanonical TCRs on the same T cell means that claims of roles for non-TRAV1-2 TCR in MR1 response must be validated by TCR transfer-based confirmation of Ag specificity.

Published
2022

4. Guidelines for the use of flow cytometry and cell sorting in immunological studies (second edition)

Author

Cossarizza, Andrea, Chang, Hyun-Dong, Radbruch, Andreas, Acs, Andreas, Adam, Dieter, Adam-Klages, Sabine, Agace, William W, Aghaeepour, Nima, Akdis, Mübeccel, Allez, Matthieu, Almeida, Larissa Nogueira, Alvisi, Giorgia, Anderson, Graham, Andrä, Immanuel, Annunziato, Francesco, Anselmo, Achille, Bacher, Petra, Baldari, Cosima T, Bari, Sudipto, Barnaba, Vincenzo, Barros-Martins, Joana, Battistini, Luca, Bauer, Wolfgang, Baumgart, Sabine, Baumgarth, Nicole, Baumjohann, Dirk, Baying, Bianka, Bebawy, Mary, Becher, Burkhard, Beisker, Wolfgang, Benes, Vladimir, Beyaert, Rudi, Blanco, Alfonso, Boardman, Dominic A, Bogdan, Christian, Borger, Jessica G, Borsellino, Giovanna, Boulais, Philip E, Bradford, Jolene A, Brenner, Dirk, Brinkman, Ryan R, Brooks, Anna ES, Busch, Dirk H, Büscher, Martin, Bushnell, Timothy P, Calzetti, Federica, Cameron, Garth, Cammarata, Ilenia, Cao, Xuetao, Cardell, Susanna L, Casola, Stefano, Cassatella, Marco A, Cavani, Andrea, Celada, Antonio, Chatenoud, Lucienne, Chattopadhyay, Pratip K, Chow, Sue, Christakou, Eleni, Čičin-Šain, Luka, Clerici, Mario, Colombo, Federico S, Cook, Laura, Cooke, Anne, Cooper, Andrea M, Corbett, Alexandra J, Cosma, Antonio, Cosmi, Lorenzo, Coulie, Pierre G, Cumano, Ana, Cvetkovic, Ljiljana, Dang, Van Duc, Dang-Heine, Chantip, Davey, Martin S, Davies, Derek, De Biasi, Sara, Del Zotto, Genny, Dela Cruz, Gelo Victoriano, Delacher, Michael, Della Bella, Silvia, Dellabona, Paolo, Deniz, Günnur, Dessing, Mark, Di Santo, James P, Diefenbach, Andreas, Dieli, Francesco, Dolf, Andreas, Dörner, Thomas, Dress, Regine J, Dudziak, Diana, Dustin, Michael, Dutertre, Charles-Antoine, Ebner, Friederike, Eckle, Sidonia BG, Edinger, Matthias, Eede, Pascale, Ehrhardt, Götz RA, Eich, Marcus, Engel, Pablo, Engelhardt, Britta, and Erdei, Anna

Subjects
1.1 Normal biological development and functioning, Underpinning research, Inflammatory and immune system, Allergy and Immunology, Cell Separation, Consensus, Flow Cytometry, Humans, Phenotype, Immunology
Abstract

These guidelines are a consensus work of a considerable number of members of the immunology and flow cytometry community. They provide the theory and key practical aspects of flow cytometry enabling immunologists to avoid the common errors that often undermine immunological data. Notably, there are comprehensive sections of all major immune cell types with helpful Tables detailing phenotypes in murine and human cells. The latest flow cytometry techniques and applications are also described, featuring examples of the data that can be generated and, importantly, how the data can be analysed. Furthermore, there are sections detailing tips, tricks and pitfalls to avoid, all written and peer-reviewed by leading experts in the field, making this an essential research companion.

Published
2019

6. RIPK3 controls MAIT cell accumulation during development but not during infection

Author

Patton, Timothy, Zhao, Zhe, Lim, Xin Yi, Eddy, Eleanor, Wang, Huimeng, Nelson, Adam G., Ennis, Bronte, Eckle, Sidonia B. G., Souter, Michael N. T., Pediongco, Troi J., Koay, Hui-Fern, Zhang, Jian-Guo, Djajawi, Tirta M., Louis, Cynthia, Lalaoui, Najoua, Jacquelot, Nicolas, Lew, Andrew M., Pellicci, Daniel G., McCluskey, James, Zhan, Yifan, Chen, Zhenjun, Lawlor, Kate E., and Corbett, Alexandra J.

Published
2023
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8. Endoplasmic reticulum chaperones stabilize ligand-receptive MR1 molecules for efficient presentation of metabolite antigens

Author

McWilliam, Hamish E. G., Mak, Jeffrey Y. W., Awad, Wael, Zorkau, Matthew, Cruz-Gomez, Sebastian, Lim, Hui Jing, Yan, Yuting, Wormald, Sam, Dagley, Laura F., Eckle, Sidonia B. G., Corbett, Alexandra J., Liu, Haiyin, Li, Shihan, Reddiex, Scott J. J., Mintern, Justine D., Liu, Ligong, McCluskey, James, Rossjohn, Jamie, Fairlie, David P., and Villadangos, Jose A.

Published
2020

10. Varicella Zoster Virus disrupts MAIT cell polyfunctional effector responses.

Author

Purohit, Shivam. K., Stern, Lauren, Corbett, Alexandra J., Mak, Jeffrey Y. W., Fairlie, David P., Slobedman, Barry, and Abendroth, Allison

Subjects
TRANSCRIPTION factors, VARICELLA-zoster virus, VIRUS diseases, IMMUNE response, CHICKENPOX, T cells, VITAMIN B2
Abstract

Mucosal-associated invariant T (MAIT) cells are unconventional T cells that respond to riboflavin biosynthesis and cytokines through TCR-dependent and -independent pathways, respectively. MAIT cell activation plays an immunoprotective role against several pathogens, however the functional capacity of MAIT cells following direct infection or exposure to infectious agents remains poorly defined. We investigated the impact of Varicella Zoster Virus (VZV) on blood-derived MAIT cells and report virus-mediated impairment of activation, cytokine production, and altered transcription factor expression by VZV infected (antigen+) and VZV exposed (antigen-) MAIT cells in response to TCR-dependent and -independent stimulation. Furthermore, we reveal that suppression of VZV exposed (antigen-) MAIT cells is not mediated by a soluble factor from neighbouring VZV infected (antigen+) MAIT cells. Finally, we demonstrate that VZV impairs the cytolytic potential of MAIT cells in response to riboflavin synthesising bacteria. In summary, we report a virus-mediated immune-evasion strategy that disarms MAIT cell responses. Author summary: Mucosal-associated invariant T (MAIT) cells are a uniquely specialised and substantial innate-T cell population that can rapidly respond to diverse bacterial and fungal pathogens through T cell receptor dependent recognition of riboflavin synthesis derived metabolite antigens. Additionally, MAIT cells can be triggered by local pro-inflammatory cues such as cytokines; therefore extending their functionality to non-riboflavin pathogens such as viral infections. Despite the capacity of MAIT cells to play a protective role against several classes of pathogens, there remains a dearth of studies investigating direct pathogenic suppression of MAIT cell functionality. Here, we investigate a previously uncharacterised interplay between MAIT cells and the causative agent of varicella (chickenpox) and shingles (zoster): Varicella Zoster Virus (VZV). VZV successfully infects and establishes lifelong latency within the host; in part to their ability to effectively manipulate several innate and adaptive axes of the host immune response. In this study, we report that VZV profoundly impairs MAIT cell activation in response to both riboflavin synthesis and cytokine stimulation, therefore resulting in a downstream paralysis of several effector functions such as cytokine production and cytotoxic potential. This work highlights a previously uncharacterised strategy of viral pathogens to effectively target and restrict the MAIT cell effector response. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Francisella tularensis induces Th1 like MAIT cells conferring protection against systemic and local infection

Author

Zhao, Zhe, Wang, Huimeng, Shi, Mai, Zhu, Tianyuan, Pediongco, Troi, Lim, Xin Yi, Meehan, Bronwyn S., Nelson, Adam G., Fairlie, David P., Mak, Jeffrey Y. W., Eckle, Sidonia B. G., de Lima Moreira, Marcela, Tumpach, Carolin, Bramhall, Michael, Williams, Cameron G., Lee, Hyun Jae, Haque, Ashraful, Evrard, Maximilien, Rossjohn, Jamie, McCluskey, James, Corbett, Alexandra J., and Chen, Zhenjun

Published
2021
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18. Synthetic 5-amino-6-D-ribitylaminouracil paired with inflammatory stimuli facilitates MAIT cell expansion in vivo

Author

Nelson, Adam G., primary, Wang, Huimeng, additional, Dewar, Phoebe M., additional, Eddy, Eleanor M., additional, Li, Songyi, additional, Lim, Xin Yi, additional, Patton, Timothy, additional, Zhou, Yuchen, additional, Pediongco, Troi J., additional, Meehan, Lucy J., additional, Meehan, Bronwyn S., additional, Mak, Jeffrey Y. W., additional, Fairlie, David P., additional, Stent, Andrew W., additional, Kjer-Nielsen, Lars, additional, McCluskey, James, additional, Eckle, Sidonia B. G., additional, Corbett, Alexandra J., additional, Souter, Michael N. T., additional, and Chen, Zhenjun, additional

Published
2023
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19. Supplementary Data from MAIT Cells Promote Tumor Initiation, Growth, and Metastases via Tumor MR1

Author

Yan, Juming, primary, Allen, Stacey, primary, McDonald, Elizabeth, primary, Das, Indrajit, primary, Mak, Jeffrey Y.W., primary, Liu, Ligong, primary, Fairlie, David P., primary, Meehan, Bronwyn S., primary, Chen, Zhenjun, primary, Corbett, Alexandra J., primary, Varelias, Antiopi, primary, Smyth, Mark J., primary, and Teng, Michele W.L., primary

Published
2023
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23. Synthetic 5-amino-6-Dribitylaminouracil paired with inflammatory stimuli facilitates MAIT cell expansion in vivo.

Author

Nelson, Adam G., Huimeng Wang, Dewar, Phoebe M., Eddy, Eleanor M., Songyi Li, Xin Yi Lim, Patton, Timothy, Yuchen Zhou, Pediongco, Troi J., Meehan, Lucy J., Meehan, Bronwyn S., Mak, Jeffrey Y. W., Fairlie, David P., Stent, Andrew W., Kjer-Nielsen, Lars, McCluskey, James, Eckle, Sidonia B. G., Corbett, Alexandra J., Souter, Michael N. T., and Zhenjun Chen

Subjects
MICROBIOLOGICAL synthesis, LABORATORY mice, T cells, CELL populations, ANIMAL disease models
Abstract

Introduction: Mucosal-associated invariant T (MAIT) cells are a population of innate-like T cells, which mediate host immunity to microbial infection by recognizing metabolite antigens derived from microbial riboflavin synthesis presented by the MHC-I-related protein 1 (MR1). Namely, the potent MAIT cell antigens, 5-(2-oxopropylideneamino)-6-D-ribitylaminouracil (5-OP-RU) and 5-(2- oxoethylideneamino)-6-D-ribitylaminouracil (5-OE-RU), form via the condensation of the riboflavin precursor 5-amino-6-D-ribitylaminouracil (5-A-RU) with the reactive carbonyl species (RCS) methylglyoxal (MG) and glyoxal (G), respectively. Although MAIT cells are abundant in humans, they are rare in mice, and increasing their abundance using expansion protocols with antigen and adjuvant has been shown to facilitate their study in mouse models of infection and disease. Methods: Here,we outline threemethods to increase the abundance of MAIT cells in C57BL/6 mice using a combination of inflammatory stimuli, 5-A-RU and MG. Results: Our data demonstrate that the administration of synthetic 5-A-RU in combination with one of three different inflammatory stimuli is sufficient to increase the frequency and absolute numbers of MAIT cells in C57BL/6 mice. The resultant boosted MAIT cells are functional and can provide protection against a lethal infection of Legionella longbeachae. Conclusion: These results provide alternative methods for expanding MAIT cells with high doses of commercially available 5-A-RU (± MG) in the presence of various danger signals. [ABSTRACT FROM AUTHOR]

Published
2023
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26. MAIT cells contribute to protection against lethal influenza infection in vivo

Author

van Wilgenburg, Bonnie, Loh, Liyen, Chen, Zhenjun, Pediongco, Troi J., Wang, Huimeng, Shi, Mai, Zhao, Zhe, Koutsakos, Marios, Nüssing, Simone, Sant, Sneha, Wang, Zhongfang, D’Souza, Criselle, Jia, Xiaoxiao, Almeida, Catarina F., Kostenko, Lyudmila, Eckle, Sidonia B. G., Meehan, Bronwyn S., Kallies, Axel, Godfrey, Dale I., Reading, Patrick C., Corbett, Alexandra J., McCluskey, James, Klenerman, Paul, Kedzierska, Katherine, and Hinks, Timothy S. C.

Published
2018
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27. CD8 coreceptor engagement of MR1 enhances antigen responsiveness by human MAIT and other MR1-reactive T cells

Author

Souter, Michael N.T., primary, Awad, Wael, additional, Li, Shihan, additional, Pediongco, Troi J., additional, Meehan, Bronwyn S., additional, Meehan, Lucy J., additional, Tian, Zehua, additional, Zhao, Zhe, additional, Wang, Huimeng, additional, Nelson, Adam, additional, Le Nours, Jérôme, additional, Khandokar, Yogesh, additional, Praveena, T., additional, Wubben, Jacinta, additional, Lin, Jie, additional, Sullivan, Lucy C., additional, Lovrecz, George O., additional, Mak, Jeffrey Y.W., additional, Liu, Ligong, additional, Kostenko, Lyudmila, additional, Kedzierska, Katherine, additional, Corbett, Alexandra J., additional, Fairlie, David P., additional, Brooks, Andrew G., additional, Gherardin, Nicholas A., additional, Uldrich, Adam P., additional, Chen, Zhenjun, additional, Rossjohn, Jamie, additional, Godfrey, Dale I., additional, McCluskey, James, additional, Pellicci, Daniel G., additional, and Eckle, Sidonia B.G., additional

Published
2022
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29. The balance of interleukin‐12 and interleukin‐23 determines the bias of MAIT1versusMAIT17 responses during bacterial infection

Author

Wang, Huimeng, primary, Nelson, Adam G, additional, Wang, Bingjie, additional, Zhao, Zhe, additional, Lim, Xin Yi, additional, Shi, Mai, additional, Meehan, Lucy J, additional, Jia, Xiaoxiao, additional, Kedzierska, Katherine, additional, Meehan, Bronwyn S, additional, Eckle, Sidonia BG, additional, Souter, Michael NT, additional, Pediongco, Troi J, additional, Mak, Jeffrey YW, additional, Fairlie, David P, additional, McCluskey, James, additional, Wang, Zhongfang, additional, Corbett, Alexandra J, additional, and Chen, Zhenjun, additional

Published
2022
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30. Dual TCR-alpha expression on MAIT cells as a potential confounder of TCR interpretation

Author

Suliman, Sara, Kjer-Nielsen, Lars, Iwany, Sarah K., Tamara, Kattya Lopez, Loh, Liyen, Grzelak, Ludivine, Kedzierska, Katherine, Ocampo, Tonatiuh A., Corbett, Alexandra J., McCluskey, James, Rossjohn, Jamie, León, Segundo R, Calderon, Roger, Lecca-Garcia, Leonid, Murray, Megan B., Moody, D. Branch, and Van Rhijn, Ildiko

Subjects
Minor Histocompatibility Antigens, Mucous Membrane, Histocompatibility Antigens Class I, Receptors, Antigen, T-Cell, Humans, Article, Mucosal-Associated Invariant T Cells
Abstract

Mucosal-associated invariant T (MAIT) cells are innate-like T cells that are highly abundant in human blood and tissues. Most MAIT cells have an invariant T cell receptor (TCR) α chain that uses TRAV1–2 joined to TRAJ33/20/12 and recognize metabolites from bacterial riboflavin synthesis bound to the antigen-presenting molecule, Major Histocompatibility Complex (MHC) class I-related (MR1). Our attempts to identify alternative MR1-presented antigens led to the discovery of rare MR1-restricted T cells with non-TRAV1–2 TCRs. Because altered antigen specificity likely alters affinity for the most potent known antigen, 5-(2-oxopropylideneamino)-6-D-ribitylaminouracil (5-OP-RU), we performed bulk TCRα and β chain sequencing and single cell-based paired TCR sequencing on T cells that bound the MR1–5-OP-RU tetramer with differing intensities. Bulk sequencing showed that use of V genes other than TRAV1–2 was enriched among MR1–5-OP-RU tetramer(low) cells. Whereas we initially interpreted these as diverse MR1-restricted TCRs, single cell TCR sequencing revealed that cells expressing atypical TCRα chains also co-expressed an invariant MAIT TCRα chain. Transfection of each non-TRAV1–2 TCRα chain with the TCRβ chain from the same cell demonstrated that the non-TRAV1–2 TCR did not bind the MR1–5-OP-RU tetramer. Thus, dual TCRα chain expression in human T cells and competition for the endogenous β chain explains the existence of some MR1–5-OP-RU tetramer(low) T cells. The discovery of simultaneous expression of canonical and non-canonical TCRs on the same T cell means that claims of roles for non-TRAV1–2 TCR in MR1 response must be validated by TCR transfer-based confirmation of antigen specificity.

Published
2022

31. Dual TCR-a Expression on Mucosal-Associated Invariant T Cells as a Potential Confounder of TCR Interpretation

Author

Suliman, Sara, Kjer-Nielsen, Lars, Iwany, Sarah K, Lopez Tamara, Kattya, Loh, Liyen, Grzelak, Ludivine, Kedzierska, Katherine, Ocampo, Tonatiuh A, Corbett, Alexandra J, McCluskey, James, Rossjohn, Jamie, León, Segundo R, Calderon, Roger, Lecca-Garcia, Leonid, Murray, Megan B, Moody, D Branch, Van Rhijn, Ildiko, Suliman, Sara, Kjer-Nielsen, Lars, Iwany, Sarah K, Lopez Tamara, Kattya, Loh, Liyen, Grzelak, Ludivine, Kedzierska, Katherine, Ocampo, Tonatiuh A, Corbett, Alexandra J, McCluskey, James, Rossjohn, Jamie, León, Segundo R, Calderon, Roger, Lecca-Garcia, Leonid, Murray, Megan B, Moody, D Branch, and Van Rhijn, Ildiko

Abstract

Mucosal-associated invariant T (MAIT) cells are innate-like T cells that are highly abundant in human blood and tissues. Most MAIT cells have an invariant TCRa-chain that uses T cell receptor a-variable 1-2 (TRAV1-2) joined to TRAJ33/20/12 and recognizes metabolites from bacterial riboflavin synthesis bound to the Ag-presenting molecule MHC class I related (MR1). Our attempts to identify alternative MR1-presented Ags led to the discovery of rare MR1-restricted T cells with non-TRAV1-2 TCRs. Because altered Ag specificity likely alters affinity for the most potent known Ag, 5-(2-oxopropylideneamino)-6-D-ribitylaminouracil (5-OP-RU), we performed bulk TCRa- and TCRb-chain sequencing and single-cell-based paired TCR sequencing on T cells that bound the MR1-5-OP-RU tetramer with differing intensities. Bulk sequencing showed that use of V genes other than TRAV1-2 was enriched among MR1-5-OP-RU tetramerlow cells. Although we initially interpreted these as diverse MR1-restricted TCRs, single-cell TCR sequencing revealed that cells expressing atypical TCRa-chains also coexpressed an invariant MAIT TCRa-chain. Transfection of each non-TRAV1-2 TCRa-chain with the TCRb-chain from the same cell demonstrated that the non-TRAV1-2 TCR did not bind the MR1-5-OP-RU tetramer. Thus, dual TCRa-chain expression in human T cells and competition for the endogenous b-chain explains the existence of some MR1-5-OP-RU tetramerlow T cells. The discovery of simultaneous expression of canonical and noncanonical TCRs on the same T cell means that claims of roles for non-TRAV1-2 TCR in MR1 response must be validated by TCR transfer-based confirmation of Ag specificity. The Journal of Immunology, 2022, 208: 1-7.

Published
2022

32. Dual TCR-a Expression on Mucosal-Associated Invariant T Cells as a Potential Confounder of TCR Interpretation

Author

Immunologie, dI&I RA-I&I I&I, Suliman, Sara, Kjer-Nielsen, Lars, Iwany, Sarah K, Lopez Tamara, Kattya, Loh, Liyen, Grzelak, Ludivine, Kedzierska, Katherine, Ocampo, Tonatiuh A, Corbett, Alexandra J, McCluskey, James, Rossjohn, Jamie, León, Segundo R, Calderon, Roger, Lecca-Garcia, Leonid, Murray, Megan B, Moody, D Branch, Van Rhijn, Ildiko, Immunologie, dI&I RA-I&I I&I, Suliman, Sara, Kjer-Nielsen, Lars, Iwany, Sarah K, Lopez Tamara, Kattya, Loh, Liyen, Grzelak, Ludivine, Kedzierska, Katherine, Ocampo, Tonatiuh A, Corbett, Alexandra J, McCluskey, James, Rossjohn, Jamie, León, Segundo R, Calderon, Roger, Lecca-Garcia, Leonid, Murray, Megan B, Moody, D Branch, and Van Rhijn, Ildiko

Published
2022

34. The Establishment of a CMV-Specific CD8 + T-Cell Threshold by Kinetic Modelling for Prediction of Post-HSCT Reactivation

Author

Zhang, Jing, primary, Cao, Jinpeng, additional, Zheng, Runhui, additional, Yu, Mengqiu, additional, Lin, Zhengfang, additional, Wang, Caixia, additional, McCluskey, James, additional, Yang, Ji, additional, Chen, Zhenjun, additional, Corbett, Alexandra J., additional, Cao, Pengxing, additional, Mo, Wenjian, additional, and Wang, Zhongfang, additional

Published
2022
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35. Guidelines for the use of flow cytometry and cell sorting in immunological studies (third edition)

Author

Cossarizza, Andrea, primary, Chang, Hyun‐Dong, additional, Radbruch, Andreas, additional, Abrignani, Sergio, additional, Addo, Richard, additional, Akdis, Mübeccel, additional, Andrä, Immanuel, additional, Andreata, Francesco, additional, Annunziato, Francesco, additional, Arranz, Eduardo, additional, Bacher, Petra, additional, Bari, Sudipto, additional, Barnaba, Vincenzo, additional, Barros‐Martins, Joana, additional, Baumjohann, Dirk, additional, Beccaria, Cristian G., additional, Bernardo, David, additional, Boardman, Dominic A., additional, Borger, Jessica, additional, Böttcher, Chotima, additional, Brockmann, Leonie, additional, Burns, Marie, additional, Busch, Dirk H., additional, Cameron, Garth, additional, Cammarata, Ilenia, additional, Cassotta, Antonino, additional, Chang, Yinshui, additional, Chirdo, Fernando Gabriel, additional, Christakou, Eleni, additional, Čičin‐Šain, Luka, additional, Cook, Laura, additional, Corbett, Alexandra J., additional, Cornelis, Rebecca, additional, Cosmi, Lorenzo, additional, Davey, Martin S., additional, De Biasi, Sara, additional, De Simone, Gabriele, additional, del Zotto, Genny, additional, Delacher, Michael, additional, Di Rosa, Francesca, additional, Di Santo, James, additional, Diefenbach, Andreas, additional, Dong, Jun, additional, Dörner, Thomas, additional, Dress, Regine J., additional, Dutertre, Charles‐Antoine, additional, Eckle, Sidonia B. G., additional, Eede, Pascale, additional, Evrard, Maximilien, additional, Falk, Christine S., additional, Feuerer, Markus, additional, Fillatreau, Simon, additional, Fiz‐Lopez, Aida, additional, Follo, Marie, additional, Foulds, Gemma A., additional, Fröbel, Julia, additional, Gagliani, Nicola, additional, Galletti, Giovanni, additional, Gangaev, Anastasia, additional, Garbi, Natalio, additional, Garrote, José Antonio, additional, Geginat, Jens, additional, Gherardin, Nicholas A., additional, Gibellini, Lara, additional, Ginhoux, Florent, additional, Godfrey, Dale I., additional, Gruarin, Paola, additional, Haftmann, Claudia, additional, Hansmann, Leo, additional, Harpur, Christopher M., additional, Hayday, Adrian C., additional, Heine, Guido, additional, Hernández, Daniela Carolina, additional, Herrmann, Martin, additional, Hoelsken, Oliver, additional, Huang, Qing, additional, Huber, Samuel, additional, Huber, Johanna E., additional, Huehn, Jochen, additional, Hundemer, Michael, additional, Hwang, William Y. K., additional, Iannacone, Matteo, additional, Ivison, Sabine M., additional, Jäck, Hans‐Martin, additional, Jani, Peter K., additional, Keller, Baerbel, additional, Kessler, Nina, additional, Ketelaars, Steven, additional, Knop, Laura, additional, Knopf, Jasmin, additional, Koay, Hui‐Fern, additional, Kobow, Katja, additional, Kriegsmann, Katharina, additional, Kristyanto, H., additional, Krueger, Andreas, additional, Kuehne, Jenny F., additional, Kunze‐Schumacher, Heike, additional, Kvistborg, Pia, additional, Kwok, Immanuel, additional, Latorre, Daniela, additional, Lenz, Daniel, additional, Levings, Megan K., additional, Lino, Andreia C., additional, Liotta, Francesco, additional, Long, Heather M., additional, Lugli, Enrico, additional, MacDonald, Katherine N., additional, Maggi, Laura, additional, Maini, Mala K., additional, Mair, Florian, additional, Manta, Calin, additional, Manz, Rudolf Armin, additional, Mashreghi, Mir‐Farzin, additional, Mazzoni, Alessio, additional, McCluskey, James, additional, Mei, Henrik E., additional, Melchers, Fritz, additional, Melzer, Susanne, additional, Mielenz, Dirk, additional, Monin, Leticia, additional, Moretta, Lorenzo, additional, Multhoff, Gabriele, additional, Muñoz, Luis Enrique, additional, Muñoz‐Ruiz, Miguel, additional, Muscate, Franziska, additional, Natalini, Ambra, additional, Neumann, Katrin, additional, Ng, Lai Guan, additional, Niedobitek, Antonia, additional, Niemz, Jana, additional, Almeida, Larissa Nogueira, additional, Notarbartolo, Samuele, additional, Ostendorf, Lennard, additional, Pallett, Laura J., additional, Patel, Amit A., additional, Percin, Gulce Itir, additional, Peruzzi, Giovanna, additional, Pinti, Marcello, additional, Pockley, A. Graham, additional, Pracht, Katharina, additional, Prinz, Immo, additional, Pujol‐Autonell, Irma, additional, Pulvirenti, Nadia, additional, Quatrini, Linda, additional, Quinn, Kylie M., additional, Radbruch, Helena, additional, Rhys, Hefin, additional, Rodrigo, Maria B., additional, Romagnani, Chiara, additional, Saggau, Carina, additional, Sakaguchi, Shimon, additional, Sallusto, Federica, additional, Sanderink, Lieke, additional, Sandrock, Inga, additional, Schauer, Christine, additional, Scheffold, Alexander, additional, Scherer, Hans U., additional, Schiemann, Matthias, additional, Schildberg, Frank A., additional, Schober, Kilian, additional, Schoen, Janina, additional, Schuh, Wolfgang, additional, Schüler, Thomas, additional, Schulz, Axel R., additional, Schulz, Sebastian, additional, Schulze, Julia, additional, Simonetti, Sonia, additional, Singh, Jeeshan, additional, Sitnik, Katarzyna M., additional, Stark, Regina, additional, Starossom, Sarah, additional, Stehle, Christina, additional, Szelinski, Franziska, additional, Tan, Leonard, additional, Tarnok, Attila, additional, Tornack, Julia, additional, Tree, Timothy I. M., additional, van Beek, Jasper J. P., additional, van de Veen, Willem, additional, van Gisbergen, Klaas, additional, Vasco, Chiara, additional, Verheyden, Nikita A., additional, von Borstel, Anouk, additional, Ward‐Hartstonge, Kirsten A., additional, Warnatz, Klaus, additional, Waskow, Claudia, additional, Wiedemann, Annika, additional, Wilharm, Anneke, additional, Wing, James, additional, Wirz, Oliver, additional, Wittner, Jens, additional, Yang, Jennie H. M., additional, and Yang, Juhao, additional

Published
2021
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36. T-cell activation by transitory neo-antigens derived from distinct microbial pathways

Author

Corbett, Alexandra J., Eckle, Sidonia B.G., Birkinshaw, Richard W., Liu, Ligong, Patel, Onisha, Mahony, Jennifer, Chen, Zhenjun, Reantragoon, Rangsima, Meehan, Bronwyn, Cao, Hanwei, Williamson, Nicholas A., Strugnell, Richard A., Van Sinderen, Douwe, Mak, Jeffrey Y.W., Fairlie, David P., Kjer-Nielsen, Lars, Rossjohn, Jamie, and McCluskey, James

Subjects
T cells -- Physiological aspects, Physiological research, Immune response -- Research, Antigens -- Properties, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

T cells discriminate between foreign and host molecules by recognizing distinct microbial molecules, predominantly peptides and lipids (1-4). Riboflavin precursors found in many bacteria and yeast also selectively activate mucosal-associated [...]

Published
2014

37. T‐cell receptor αβ+ double‐negative T cells in the kidney are predominantly extravascular and increase in abundance in response to ischemia–reperfusion injury.

Author

Snelgrove, Sarah L, Susanto, Olivia, Yeung, Louisa, Hall, Pamela, Norman, M Ursula, Corbett, Alexandra J, Kitching, A Richard, and Hickey, Michael J

Subjects
T cells, REPERFUSION injury, KIDNEYS, CELL populations, T cell receptors, FLOW cytometry, CD8 antigen
Abstract

T‐cell receptor+CD4−CD8− double‐negative (DN) T cells are a population of T cells present in low abundance in blood and lymphoid organs, but enriched in various organs including the kidney. Despite burgeoning interest in these cells, studies examining their abundance in the kidney have reported conflicting results. Here we developed a flow cytometry strategy to clearly segregate DN T cells from other immune cells in the mouse kidney and used it to characterize their phenotype and response in renal ischemia–reperfusion injury (IRI). These experiments revealed that in the healthy kidney, most DN T cells are located within the renal parenchyma and exhibit an effector memory phenotype. In response to IRI, the number of renal DN T cells is unaltered after 24 h, but significantly increased by 72 h. This increase is not related to alterations in proliferation or apoptosis. By contrast, adoptive transfer studies indicate that circulating DN T cells undergo preferential recruitment to the postischemic kidney. Furthermore, DN T cells show the capacity to upregulate CD8, both in vivo following adoptive transfer and in response to ex vivo activation. Together, these findings provide novel insights regarding the phenotype of DN T cells in the kidney, including their predominant extravascular location, and show that increases in their abundance in the kidney following IRI occur in part as a result of increased recruitment from the circulation. Furthermore, the observation that DN T cells can upregulate CD8 in vivo has important implications for detection and characterization of DN T cells in future studies. [ABSTRACT FROM AUTHOR]

Published
2023
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38. T cell activation by transitory neo-antigens derived from distinct microbial pathways

Author

Birkinshaw, Richard W., Corbett, Alexandra J., Eckle, Sidonia B.G., Liu, Ligong, Patel, Onisha, Mahony, Jennifer, Chen, Zhenjun, Reantragoon, Rangsima, Meehan, Bronwyn, Cao, Hanwei, Williamson, Nicholas A., Strugnell, Richard A., Van Sinderen, Douwe, Mak, Jeffrey Y.W., Fairlie, David P., Kjer-Nielsen, Lars, Rossjohn, Jamie, and McCluskey, James

Published
2015

39. Human mucosal Vα7.2+CD161hi T cell distribution at physiologic state and in Helicobacter pylori infection.

Author

Boonpattanaporn, Norasate, Kongkaew, Thidarat, Sengprasert, Panjana, Souter, Michael N.T., Lakananurak, Narisorn, Rerknimitr, Rungsun, Corbett, Alexandra J., and Reantragoon, Rangsima

Subjects
HELICOBACTER pylori infections, T cells, MUCOUS membranes
Abstract

Mucosal‐associated invariant T (MAIT) cells are innate‐like, unconventional T cells that are present in peripheral blood and mucosal surfaces. A clear understanding of how MAIT cells in the mucosae function and their role in host immunity is still lacking. Therefore, our aim was to investigate MAIT cell distribution and their characteristics in the gastrointestinal (GI) mucosal tissue based on Vα7.2+CD161hi identification. We showed that Vα7.2+CD161hi T cells are present in both intraepithelial layer and lamina propriae of the GI mucosa, but have different abundance at each GI site. Vα7.2+CD161hi T cells were most abundant in the duodenum, but had the lowest reactivity to MR1‐5‐OP‐RU tetramers when compared with Vα7.2+CD161hi T cells at other GI tissue sites. Striking discrepancies between MR1‐5‐OP‐RU tetramer reactive cells and Vα7.2+CD161hi T cells were observed along each GI tissue sites. Vα7.2+CD161hi TCR repertoire was most diverse in the ileum. Similar dominant profiles of TRBV usage were observed among peripheral blood, duodenum, ileum, and colon. Some TRBV chains were detected at certain intestinal sites and not elsewhere. The frequency of peripheral blood Vα7.2+CD161hi T cells correlated with mucosal Vα7.2+CD161hi T cells in lamina propriae ileum and lamina propriae colon. The frequency of peripheral blood Vα7.2+CD161hi T cells in Helicobacter pylori‐infected individuals was significantly lower than uninfected individuals, but this was not observed with gastric Vα7.2+CD161hi T cells. This study illustrates the biology of Vα7.2+CD161hi T cells in the GI mucosa and provides a basis for understanding MAIT cells in the mucosa and MAIT‐related GI diseases. [ABSTRACT FROM AUTHOR]

Published
2022
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41. Guidelines for the use of flow cytometry and cell sorting in immunological studies (third edition)

Author

Rolf M. Schwiete Foundation, Associazione Italiana per la Ricerca sul Cancro, German Research Foundation, National Institutes of Health (US), European Commission, Cossarizza, Andrea, Chang, Hyun‐Dong, Radbruch, Andreas, Abrignani, Sergio, Addo, Richard, Akdis, Mübeccel, Andrä, Immanuel, Andreata, Francesco, Annunziato, Francesco, Arranz, Eduardo, Bacher, Petra, Knop, Laura, Knopf, Jasmin, Koay, Hui-Fern, Kobow, Katja, Kriegsmann, Katharina, Kristyanto, H., Krueger, Andreas, Kuehne, Jenny F., Kunze-Schumacher, Heike, Maini, Mala K., Verheyden, Nikita A., Kvistborg, Pia, Kwok, Immanuel, Latorre, Daniela, Mair, Florian, Bari, Sudipto, Manta, Calin, Armin Manz, Rudolf, Mashreghi, Mir-Farzin, Mazzoni, Alessio, McCluskey, James, Borstel, Anouk von, Mei, Henrik E., Melchers, Fritz, Melzer, Susanne, Mielenz, Dirk, Monin, Leticia, Barnaba, Vincenzo, Moretta, Lorenzo, Multhoff, Gabriele, Muñoz, Luis Enrique, Muñoz-Ruiz, Miguel, Ward-Hartstonge, Kirsten A., Muscate, Franziska, Natalini, Ambra, Neumann, Katrin, Guan N., Lai, Niedobitek, Antonia, Niemz, Jana, Barros-Martins, Joana, Nogueira Almeida, Larissa, Notarbartolo, Samuele, Ostendorf, Lennard, Warnatz, Klaus, Pallett, Laura J., Patel, Amit A., Itir Percin, Gulce, Peruzzi, Giovanna, Pinti, Marcello, Pockley, A. Graham, Pracht, Katharina, Baumjohann, Dirk, Prinz, Immo, Pujol-Autonell, Irma, Waskow, Claudia, Pulvirenti, Nadia, Quatrini, Linda, Quinn, Kylie M., Radbruch, Helena, Rhys, Hefin, Rodrigo, Maria B., Romagnani, Chiara, Saggau, Carina, Beccaria, Cristian G., Sakaguchi, Shimon, Wiedemann, Annika, Sallusto, Federica, Sanderink, Lieke, Sandrock, Inga, Schauer, Christine, Scheffold, Alexander, Scherer, Hans U., Schiemann, Matthias, Schildberg, Frank A., Schober, Kilian, Bernardo, David, Wilharm, Anneke, Schoen, Janina, Schuh, Wolfgang, Schüler, Thomas, Schulz, Axel R., Schulz, Sebastian, Schulze, Julia, Simonetti, Sonia, Singh, Jeeshan, Sitnik, Katarzyna M., Stark, Regina, Wing, James, Boardman, Dominic A., Starossom, Sarah, Stehle, Christina, Szelinski, Franziska, Tan, Leonard, Tarnok, Attila, Tornack, Julia, Tree, Timothy I. M., Van Beek, Jasper J. P., Veen, Willem van de, Wirz, Oliver, Gisbergen, Klaas van, Borger, Jessica, Vasco, Chiara, Böttcher, Chotima, Lenz, Daniel, Wittner, Jens, Yang, Jennie H. M., Yang, Juhao, Brockmann, Leonie, Burns, Marie, Busch, Dirk H., Cameron, Garth, Cammarata, Ilenia, Cassotta, Antonino, Chang, Yinshui, Levings, Megan K., Chirdo, Fernando G., Christakou, Eleni, Cicin-Sain, Luka, Cook, Laura, Corbett, Alexandra J., Cornelis, Rebecca, Cosmi, Lorenzo, Davey, Martin S., Biasi, Sara De, Simone, Gabriele De, Lino, Andreia C., Zotto, Genny del, Delacher, Michael, Rosa, Francesca Di, Santo, James Di, Diefenbach, Andreas, Dong, Jun, Dörner, Thomas, Dress, Regine J., Dutertre, Charles-Antoine, Eckle, Sidonia B. G., Liotta, Francesco, Eede, Pascale, Evrard, Maximilien, Falk, Christine S., Feuerer, Markus, Fillatreau, Simon, Fiz-López, Aida, Follo, Marie, Foulds, Gemma A., Fröbel, Julia, Gagliani, Nicola, Long, Heather M., Galletti, Giovanni, Gangaev, Anastasia, Garbi, Natalio, Garrote, José Antonio, Geginat, Jens, Gherardin, Nicholas A., Gibellini, Lara, Ginhoux, Florent, Godfrey, Dale I., Gruarin, Paola, Lugli, Enrico, Haftmann, Claudia, Hansmann, Leo, Harpur, Christopher M., Hayday, Adrian C., Heine, Guido, Hernández, Daniela Carolina, Herrmann, Martin, Hoelsken, Oliver, Huang, Qing, Huber, Samuel, MacDonald, Katherine N., Huber, Johanna E., Huehn, Jochen, Hundemer, Michael, Hwang, William Y. K., Iannacone, Matteo, Ivison, Sabine M., Jäck, Hans-Martin, Jani, Peter K., Keller, Baerbel, Kessler, Nina, Maggi, Laura, Ketelaars, Steven, Rolf M. Schwiete Foundation, Associazione Italiana per la Ricerca sul Cancro, German Research Foundation, National Institutes of Health (US), European Commission, Cossarizza, Andrea, Chang, Hyun‐Dong, Radbruch, Andreas, Abrignani, Sergio, Addo, Richard, Akdis, Mübeccel, Andrä, Immanuel, Andreata, Francesco, Annunziato, Francesco, Arranz, Eduardo, Bacher, Petra, Knop, Laura, Knopf, Jasmin, Koay, Hui-Fern, Kobow, Katja, Kriegsmann, Katharina, Kristyanto, H., Krueger, Andreas, Kuehne, Jenny F., Kunze-Schumacher, Heike, Maini, Mala K., Verheyden, Nikita A., Kvistborg, Pia, Kwok, Immanuel, Latorre, Daniela, Mair, Florian, Bari, Sudipto, Manta, Calin, Armin Manz, Rudolf, Mashreghi, Mir-Farzin, Mazzoni, Alessio, McCluskey, James, Borstel, Anouk von, Mei, Henrik E., Melchers, Fritz, Melzer, Susanne, Mielenz, Dirk, Monin, Leticia, Barnaba, Vincenzo, Moretta, Lorenzo, Multhoff, Gabriele, Muñoz, Luis Enrique, Muñoz-Ruiz, Miguel, Ward-Hartstonge, Kirsten A., Muscate, Franziska, Natalini, Ambra, Neumann, Katrin, Guan N., Lai, Niedobitek, Antonia, Niemz, Jana, Barros-Martins, Joana, Nogueira Almeida, Larissa, Notarbartolo, Samuele, Ostendorf, Lennard, Warnatz, Klaus, Pallett, Laura J., Patel, Amit A., Itir Percin, Gulce, Peruzzi, Giovanna, Pinti, Marcello, Pockley, A. Graham, Pracht, Katharina, Baumjohann, Dirk, Prinz, Immo, Pujol-Autonell, Irma, Waskow, Claudia, Pulvirenti, Nadia, Quatrini, Linda, Quinn, Kylie M., Radbruch, Helena, Rhys, Hefin, Rodrigo, Maria B., Romagnani, Chiara, Saggau, Carina, Beccaria, Cristian G., Sakaguchi, Shimon, Wiedemann, Annika, Sallusto, Federica, Sanderink, Lieke, Sandrock, Inga, Schauer, Christine, Scheffold, Alexander, Scherer, Hans U., Schiemann, Matthias, Schildberg, Frank A., Schober, Kilian, Bernardo, David, Wilharm, Anneke, Schoen, Janina, Schuh, Wolfgang, Schüler, Thomas, Schulz, Axel R., Schulz, Sebastian, Schulze, Julia, Simonetti, Sonia, Singh, Jeeshan, Sitnik, Katarzyna M., Stark, Regina, Wing, James, Boardman, Dominic A., Starossom, Sarah, Stehle, Christina, Szelinski, Franziska, Tan, Leonard, Tarnok, Attila, Tornack, Julia, Tree, Timothy I. M., Van Beek, Jasper J. P., Veen, Willem van de, Wirz, Oliver, Gisbergen, Klaas van, Borger, Jessica, Vasco, Chiara, Böttcher, Chotima, Lenz, Daniel, Wittner, Jens, Yang, Jennie H. M., Yang, Juhao, Brockmann, Leonie, Burns, Marie, Busch, Dirk H., Cameron, Garth, Cammarata, Ilenia, Cassotta, Antonino, Chang, Yinshui, Levings, Megan K., Chirdo, Fernando G., Christakou, Eleni, Cicin-Sain, Luka, Cook, Laura, Corbett, Alexandra J., Cornelis, Rebecca, Cosmi, Lorenzo, Davey, Martin S., Biasi, Sara De, Simone, Gabriele De, Lino, Andreia C., Zotto, Genny del, Delacher, Michael, Rosa, Francesca Di, Santo, James Di, Diefenbach, Andreas, Dong, Jun, Dörner, Thomas, Dress, Regine J., Dutertre, Charles-Antoine, Eckle, Sidonia B. G., Liotta, Francesco, Eede, Pascale, Evrard, Maximilien, Falk, Christine S., Feuerer, Markus, Fillatreau, Simon, Fiz-López, Aida, Follo, Marie, Foulds, Gemma A., Fröbel, Julia, Gagliani, Nicola, Long, Heather M., Galletti, Giovanni, Gangaev, Anastasia, Garbi, Natalio, Garrote, José Antonio, Geginat, Jens, Gherardin, Nicholas A., Gibellini, Lara, Ginhoux, Florent, Godfrey, Dale I., Gruarin, Paola, Lugli, Enrico, Haftmann, Claudia, Hansmann, Leo, Harpur, Christopher M., Hayday, Adrian C., Heine, Guido, Hernández, Daniela Carolina, Herrmann, Martin, Hoelsken, Oliver, Huang, Qing, Huber, Samuel, MacDonald, Katherine N., Huber, Johanna E., Huehn, Jochen, Hundemer, Michael, Hwang, William Y. K., Iannacone, Matteo, Ivison, Sabine M., Jäck, Hans-Martin, Jani, Peter K., Keller, Baerbel, Kessler, Nina, Maggi, Laura, and Ketelaars, Steven

Abstract

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.

Published
2021

42. MR1 presents microbial vitamin B metabolites to MAIT cells

Author

Kjer-Nielsen, Lars, Patel, Onisha, Corbett, Alexandra J., Le Nours, Jerome, Meehan, Bronwyn, Liu, Ligong, Bhati, Mugdha, Chen, Zhenjun, Kostenko, Lyudmila, Reantragoon, Rangsima, Williamson, Nicholas A., Purcell, Anthony W., Dudek, Nadine L., McConville, Malcolm J., O'Hair, Richard A.J., Khairallah, George N., Godfrey, Dale I., Fairlie, David P., Rossjohn, Jamie, and McCluskey, James

Subjects
Virulence (Microbiology) -- Research -- Physiological aspects -- Health aspects, T cells -- Physiological aspects -- Health aspects -- Research, Metabolites -- Physiological aspects -- Health aspects -- Research, Vitamin B -- Physiological aspects -- Health aspects -- Research, Vitamin B complex -- Physiological aspects -- Health aspects -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Antigen-presenting molecules, encoded by the major histocompatibility complex (MHC) and CD1 family, bind peptideand lipid-based antigens, respectively, for recognition by T cells. Mucosal- associated invariant T (mAit) cells are an abundant population of innate-like T cells in humans that are activated by an antigen(s) bound to the MHC class I-like molecule MR1. Although the identity of MR1-restricted antigen(s) is unknown, it is present in numerous bacteria and yeast. Here we show that the structure and chemistry within the antigen-binding cleft of MR1 is distinct from the MHC and CD1 families. MR1 is ideally suited to bind ligands originating from vitamin metabolites. The structure of MR1 in complex with 6-formyl pterin, a folic acid (vitamin B9) metabolite, shows the pterin ring sequestered within MR1. Furthermore, we characterize related MR1-restricted vitamin derivatives, originating from the bacterial riboflavin (vitamin B2) biosynthetic pathway, which specifically and potently activate MAIT cells. Accordingly, we show that metabolites of vitamin B represent a class of antigen that are presented by MR1 for MAIT-cell immunosurveillance. As many vitamin biosynthetic pathways are unique to bacteria and yeast, our data suggest that MAIT cells use these metabolites to detect microbial infection., MAIT cells, which comprise up to 10% of the peripheral blood T-cell population of humans, are readily detected in blood, mesenteric lymph nodes and the gastrointestinal mucosa (1). Despite the [...]

Published
2012
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43. The balance of interleukin‐12 and interleukin‐23 determines the bias of MAIT1 versus MAIT17 responses during bacterial infection.

Author

Wang, Huimeng, Nelson, Adam G, Wang, Bingjie, Zhao, Zhe, Lim, Xin Yi, Shi, Mai, Meehan, Lucy J, Jia, Xiaoxiao, Kedzierska, Katherine, Meehan, Bronwyn S, Eckle, Sidonia BG, Souter, Michael NT, Pediongco, Troi J, Mak, Jeffrey YW, Fairlie, David P, McCluskey, James, Wang, Zhongfang, Corbett, Alexandra J, and Chen, Zhenjun

Subjects
BACTERIAL diseases, INTERLEUKIN-23, INTERLEUKIN-12, MICROBIAL metabolites, T cells, VITAMIN B2
Abstract

Mucosal‐associated invariant T (MAIT) cells are a major subset of innate‐like T cells mediating protection against bacterial infection through recognition of microbial metabolites derived from riboflavin biosynthesis. Mouse MAIT cells egress from the thymus as two main subpopulations with distinct functions, namely, T‐bet‐expressing MAIT1 and RORγt‐expressing MAIT17 cells. Previously, we reported that inducible T‐cell costimulator and interleukin (IL)‐23 provide essential signals for optimal MHC‐related protein 1 (MR1)‐dependent activation and expansion of MAIT17 cells in vivo. Here, in a model of tularemia, in which MAIT1 responses predominate, we demonstrate that IL‐12 and IL‐23 promote MAIT1 cell expansion during acute infection and that IL‐12 is indispensable for MAIT1 phenotype and function. Furthermore, we showed that the bias toward MAIT1 or MAIT17 responses we observed during different bacterial infections was determined and modulated by the balance between IL‐12 and IL‐23 and that these responses could be recapitulated by cytokine coadministration with antigen. Our results indicate a potential for tailored immunotherapeutic interventions via MAIT cell manipulation. [ABSTRACT FROM AUTHOR]

Published
2022
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44. Dual TCR-alpha expression on MAIT cells as a potential confounder of TCR interpretation

Author

Suliman, Sara, primary, Kjer-Nielsen, Lars, additional, Iwany, Sarah K., additional, Tamara, Kattya Lopez, additional, Loh, Liyen, additional, Grzelak, Ludivine, additional, Kedzierska, Katherine, additional, Ocampo, Tonatiuh A., additional, Corbett, Alexandra J., additional, McCluskey, James, additional, Rossjohn, Jamie, additional, León, Segundo R, additional, Calderon, Roger, additional, Garcia, Leonid Lecca, additional, Murray, Megan B., additional, Moody, D. Branch, additional, and Van Rhijn, Ildiko, additional

Published
2021
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45. MAIT cells contribute to protection against lethal influenza infection in vivo

Author

Wilgenburg, Bonnie van, Loh, Liyen, Chen, Zhenjun, Pediongco, Troi J., Wang, Huimeng, Shi, Mai, Zhao, Zhe, Koutsakos, Marios, Nüssing, Simone, Sant, Sneha, Wang, Zhongfang, D’Souza, Criselle, Jia, Xiaoxiao, Almeida, Catarina F., Kostenko, Lyudmila, Eckle, Sidonia B. G., Meehan, Bronwyn S., Kallies, Axel, Godfrey, Dale I., Reading, Patrick C., Corbett, Alexandra J., McCluskey, James, Klenerman, Paul, Kedzierska, Katherine, and Hinks, Timothy S. C.

Subjects
Science, Histocompatibility Antigens Class I, Adoptive Transfer, Article, Mucosal-Associated Invariant T Cells, Mice, Inbred C57BL, Minor Histocompatibility Antigens, Orthomyxoviridae Infections, Influenza, Human, Animals, Cytokines, Humans, lcsh:Q, lcsh:Science, Lung
Abstract

Mucosal associated invariant T (MAIT) cells are evolutionarily-conserved, innate-like lymphocytes which are abundant in human lungs and can contribute to protection against pulmonary bacterial infection. MAIT cells are also activated during human viral infections, yet it remains unknown whether MAIT cells play a significant protective or even detrimental role during viral infections in vivo. Using murine experimental challenge with two strains of influenza A virus, we show that MAIT cells accumulate and are activated early in infection, with upregulation of CD25, CD69 and Granzyme B, peaking at 5 days post-infection. Activation is modulated via cytokines independently of MR1. MAIT cell-deficient MR1−/− mice show enhanced weight loss and mortality to severe (H1N1) influenza. This is ameliorated by prior adoptive transfer of pulmonary MAIT cells in both immunocompetent and immunodeficient RAG2−/−γC−/− mice. Thus, MAIT cells contribute to protection during respiratory viral infections, and constitute a potential target for therapeutic manipulation., MAIT cells are abundant in the lungs and confer protection against bacterial pathogens. Whilst activation of these cells has been described during viral infections, here van Wilgenburg and colleagues show that in a murine model MAIT cells contribute to the protective host immune response to influenza virus infection.

Published
2018

47. Human mucosal Vα7.2+CD161hiT cell distribution at physiologic state and in Helicobacter pyloriinfection

Author

Boonpattanaporn, Norasate, Kongkaew, Thidarat, Sengprasert, Panjana, Souter, Michael N.T., Lakananurak, Narisorn, Rerknimitr, Rungsun, Corbett, Alexandra J., and Reantragoon, Rangsima

Abstract

Mucosal‐associated invariant T (MAIT) cells are innate‐like, unconventional T cells that are present in peripheral blood and mucosal surfaces. A clear understanding of how MAIT cells in the mucosae function and their role in host immunity is still lacking. Therefore, our aim was to investigate MAIT cell distribution and their characteristics in the gastrointestinal (GI) mucosal tissue based on Vα7.2+CD161hiidentification. We showed that Vα7.2+CD161hiT cells are present in both intraepithelial layer and lamina propriae of the GI mucosa, but have different abundance at each GI site. Vα7.2+CD161hiT cells were most abundant in the duodenum, but had the lowest reactivity to MR1‐5‐OP‐RU tetramers when compared with Vα7.2+CD161hiT cells at other GI tissue sites. Striking discrepancies between MR1‐5‐OP‐RU tetramer reactive cells and Vα7.2+CD161hiT cells were observed along each GI tissue sites. Vα7.2+CD161hiTCR repertoire was most diverse in the ileum. Similar dominant profiles of TRBV usage were observed among peripheral blood, duodenum, ileum, and colon. Some TRBV chains were detected at certain intestinal sites and not elsewhere. The frequency of peripheral blood Vα7.2+CD161hiT cells correlated with mucosal Vα7.2+CD161hiT cells in lamina propriae ileum and lamina propriae colon. The frequency of peripheral blood Vα7.2+CD161hiT cells in Helicobacter pylori‐infected individuals was significantly lower than uninfected individuals, but this was not observed with gastric Vα7.2+CD161hiT cells. This study illustrates the biology of Vα7.2+CD161hiT cells in the GI mucosa and provides a basis for understanding MAIT cells in the mucosa and MAIT‐related GI diseases. Study of human Vα7.2+CD161hi T cell distribution in peripheral blood and different sites of gastrointestinal tract, its TCR characteristics and response to Helicobacterpyloriinfection

Published
2022
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