NKp46-expressing human gut-resident intraepithelial Vδ1 T cell subpopulation exhibits high antitumor activity against colorectal cancer
Joanna Mikulak, Ferdinando Oriolo, Elena Bruni, Alessandra Roberto, Federico S. Colombo, Anna Villa, Marita Bosticardo, Ileana Bortolomai, Elena Lo Presti, Serena Meraviglia, Francesco Dieli, Stefania Vetrano, Silvio Danese, Silvia Della Bella, Michele M. Carvello, Matteo Sacchi, Giovanni Cugini, Giovanni Colombo, Marco Klinger, Paola Spaggiari, Massimo Roncalli, Immo Prinz, Sarina Ravens, Biagio di Lorenzo, Emanuela Marcenaro, Bruno Silva-Santos, Antonino Spinelli, Domenico Mavilio
Joanna Mikulak, Ferdinando Oriolo, Elena Bruni, Alessandra Roberto, Federico S. Colombo, Anna Villa, Marita Bosticardo, Ileana Bortolomai, Elena Lo Presti, Serena Meraviglia, Francesco Dieli, Stefania Vetrano, Silvio Danese, Silvia Della Bella, Michele M. Carvello, Matteo Sacchi, Giovanni Cugini, Giovanni Colombo, Marco Klinger, Paola Spaggiari, Massimo Roncalli, Immo Prinz, Sarina Ravens, Biagio di Lorenzo, Emanuela Marcenaro, Bruno Silva-Santos, Antonino Spinelli, Domenico Mavilio
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Research Article Gastroenterology Immunology

NKp46-expressing human gut-resident intraepithelial Vδ1 T cell subpopulation exhibits high antitumor activity against colorectal cancer

Abstract

γδ T cells account for a large fraction of human intestinal intraepithelial lymphocytes (IELs) endowed with potent antitumor activities. However, little is known about their origin, phenotype, and clinical relevance in colorectal cancer (CRC). To determine γδ IEL gut specificity, homing, and functions, γδ T cells were purified from human healthy blood, lymph nodes, liver, skin, and intestine, either disease-free, affected by CRC, or generated from thymic precursors. The constitutive expression of NKp46 specifically identifies a subset of cytotoxic Vδ1 T cells representing the largest fraction of gut-resident IELs. The ontogeny and gut-tropism of NKp46+/Vδ1 IELs depends both on distinctive features of Vδ1 thymic precursors and gut-environmental factors. Either the constitutive presence of NKp46 on tissue-resident Vδ1 intestinal IELs or its induced expression on IL-2/IL-15–activated Vδ1 thymocytes are associated with antitumor functions. Higher frequencies of NKp46+/Vδ1 IELs in tumor-free specimens from CRC patients correlate with a lower risk of developing metastatic III/IV disease stages. Additionally, our in vitro settings reproducing CRC tumor microenvironment inhibited the expansion of NKp46+/Vδ1 cells from activated thymic precursors. These results parallel the very low frequencies of NKp46+/Vδ1 IELs able to infiltrate CRC, thus providing insights to either follow-up cancer progression or to develop adoptive cellular therapies.

Authors

Joanna Mikulak, Ferdinando Oriolo, Elena Bruni, Alessandra Roberto, Federico S. Colombo, Anna Villa, Marita Bosticardo, Ileana Bortolomai, Elena Lo Presti, Serena Meraviglia, Francesco Dieli, Stefania Vetrano, Silvio Danese, Silvia Della Bella, Michele M. Carvello, Matteo Sacchi, Giovanni Cugini, Giovanni Colombo, Marco Klinger, Paola Spaggiari, Massimo Roncalli, Immo Prinz, Sarina Ravens, Biagio di Lorenzo, Emanuela Marcenaro, Bruno Silva-Santos, Antonino Spinelli, Domenico Mavilio

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Figure 3

TCR repertoires of NKp46+ and NKp46 γδ IELs.

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TCR repertoires of NKp46+ and NKp46– γδ IELs. (A) Treemap graphs showing...
(A) Treemap graphs showing the distribution of TRG clones within NKp46+ and NKp46 γδ IELs from 2 representative patients (out of 4). Squares represent individual clones and are proportional to the abundance of the given clone within the TCR repertoire. Color codes indicate V chain usage. CDR3 sequences of the most expanded clones are given. (B) Dot plot graph showing the quantification of V chains for TRG repertoires. Each dot represents 1 patient. (C) Treemap graphs showing the distribution of Vδ1+ TRD clones within NKp46+ and NKp46 IELs of 2 patients. Each square indicates 1 clone within the given TRD repertoires. J elements are color coded, and CDR3 sequences of the most expanded clones are indicated. (D) Dot plot graph showing the TRG and TRD diversity that is determined by the D50 score (number of clones within 50% of the given TCR repertoire). Each dot represents 1 patient. (E) Heatmap graph displaying the number of shared TRG (lower part, orange–yellow) and TRD (upper part, blue–yellow) clones between patient samples.