Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Neuroblastoma killing properties of Vδ2 and Vδ2-negative γδT cells following expansion by artificial antigen-presenting cells.

Literature DB >> 24893631

Neuroblastoma killing properties of Vδ2 and Vδ2-negative γδT cells following expansion by artificial antigen-presenting cells.

Jonathan P H Fisher¹, Mengyong Yan¹, Jennifer Heuijerjans¹, Lisa Carter², Ayda Abolhassani¹, Jennifer Frosch¹, Rebecca Wallace¹, Barry Flutter¹, Anna Capsomidis¹, Mike Hubank¹, Nigel Klein³, Robin Callard³, Kenth Gustafsson⁴, John Anderson⁵.

Abstract

PURPOSE: The majority of circulating human γδT lymphocytes are of the Vγ9Vδ2 lineage, and have T-cell receptor (TCR) specificity for nonpeptide phosphoantigens. Previous attempts to stimulate and expand these cells have therefore focused on stimulation using ligands of the Vγ9Vδ2 receptor, whereas relatively little is known about variant blood γδT subsets and their potential role in cancer immunotherapy. EXPERIMENTAL
DESIGN: To expand the full repertoire of γδT without bias toward specific TCRs, we made use of artificial antigen-presenting cells loaded with an anti γδTCR antibody that promoted unbiased expansion of the γδT repertoire. Expanded cells from adult blood donors were sorted into 3 populations expressing respectively Vδ2 TCR chains (Vδ2(+)), Vδ1 chains (Vδ1(+)), and TCR of other δ chain subtypes (Vδ1(neg)Vδ2(neg)).
RESULTS: Both freshly isolated and expanded cells showed heterogeneity of differentiation markers, with a less differentiated phenotype in the Vδ1 and Vδ1(neg)Vδ2(neg) populations. Expanded cells were largely of an effector memory phenotype, although there were higher numbers of less differentiated cells in the Vδ1(+) and Vδ1(neg)Vδ2(neg) populations. Using neuroblastoma tumor cells and the anti-GD2 therapeutic mAb ch14.18 as a model system, all three populations showed clinically relevant cytotoxicity. Although killing by expanded Vδ2 cells was predominantly antibody dependent and proportionate to upregulated CD16, Vδ1 cells killed by antibody-independent mechanisms.
CONCLUSIONS: In conclusion, we have demonstrated that polyclonal-expanded populations of γδT cells are capable of both antibody-dependent and -independent effector functions in neuroblastoma. ©2014 American Association for Cancer Research.

Entities: Chemical

Mesh：

Substances：

Year: 2014 PMID： 24893631 PMCID： PMC4445920 DOI： 10.1158/1078-0432.CCR-13-3464

Source DB: PubMed Journal: Clin Cancer Res ISSN： 1078-0432 Impact factor: 12.531

49 in total

1. High frequency of circulating gamma delta T cells with dominance of the v(delta)1 subset in a healthy population.

Authors: L Hviid; B D Akanmori; S Loizon; J A Kurtzhals; C H Ricke; A Lim; K A Koram; F K Nkrumah; O Mercereau-Puijalon; C Behr
Journal: Int Immunol Date: 2000-06 Impact factor: 4.823

2. Extensive expansion of primary human gamma delta T cells generates cytotoxic effector memory cells that can be labeled with Feraheme for cellular MRI.

Authors: Gabrielle M Siegers; Emeline J Ribot; Armand Keating; Paula J Foster
Journal: Cancer Immunol Immunother Date: 2012-10-26 Impact factor: 6.968

3. Engineering artificial antigen-presenting cells to express a diverse array of co-stimulatory molecules.

Authors: Megan M Suhoski; Tatiana N Golovina; Nicole A Aqui; Victoria C Tai; Angel Varela-Rohena; Michael C Milone; Richard G Carroll; James L Riley; Carl H June
Journal: Mol Ther Date: 2007-03-20 Impact factor: 11.454

4. Pilot trial of interleukin-2 and zoledronic acid to augment γδ T cells as treatment for patients with refractory renal cell carcinoma.

Authors: Joshua M Lang; Mahazarin R Kaikobad; Marianne Wallace; Mary Jane Staab; Dorothea L Horvath; George Wilding; Glenn Liu; Jens C Eickhoff; Douglas G McNeel; Miroslav Malkovsky
Journal: Cancer Immunol Immunother Date: 2011-06-07 Impact factor: 6.968

Review 5. Mechanisms of immune evasion of human neuroblastoma.

Authors: Lizzia Raffaghello; Ignazia Prigione; Irma Airoldi; Marta Camoriano; Fabio Morandi; Paolo Bocca; Claudio Gambini; Soldano Ferrone; Vito Pistoia
Journal: Cancer Lett Date: 2005-10-18 Impact factor: 8.679

6. Human Vδ1 γδ T cells expanded from peripheral blood exhibit specific cytotoxicity against B-cell chronic lymphocytic leukemia-derived cells.

Authors: Gabrielle M Siegers; Helena Dhamko; Xing-Hua Wang; A Mark Mathieson; Yoko Kosaka; Tania C Felizardo; Jeffrey A Medin; Shuji Tohda; Julia Schueler; Paul Fisch; Armand Keating
Journal: Cytotherapy Date: 2011-02-11 Impact factor: 5.414

Review 7. Sorting through subsets: which T-cell populations mediate highly effective adoptive immunotherapy?

Authors: Christopher A Klebanoff; Luca Gattinoni; Nicholas P Restifo
Journal: J Immunother Date: 2012 Nov-Dec Impact factor: 4.456

Review 8. Potential of human γδ T cells for immunotherapy of osteosarcoma.

Authors: Zhaoxu Li
Journal: Mol Biol Rep Date: 2012-10-14 Impact factor: 2.316

9. Anti-metastatic potential of human Vδ1(+) γδ T cells in an orthotopic mouse xenograft model of colon carcinoma.

Authors: Christel Devaud; Benoît Rousseau; Sonia Netzer; Vincent Pitard; Christian Paroissin; Camille Khairallah; Pierre Costet; Jean-François Moreau; Franck Couillaud; Julie Dechanet-Merville; Myriam Capone
Journal: Cancer Immunol Immunother Date: 2013-04-26 Impact factor: 6.968

10. Differentiation of effector/memory Vdelta2 T cells and migratory routes in lymph nodes or inflammatory sites.

Authors: Francesco Dieli; Fabrizio Poccia; Martin Lipp; Guido Sireci; Nadia Caccamo; Caterina Di Sano; Alfredo Salerno
Journal: J Exp Med Date: 2003-08-04 Impact factor: 14.307

46 in total

Review 1. Nanovaccines for cancer immunotherapy.

Authors: Yu Zhang; Shuibin Lin; Xiang-Yang Wang; Guizhi Zhu
Journal: Wiley Interdiscip Rev Nanomed Nanobiotechnol Date: 2019-06-06

2. Single-cell RNA sequencing unveils the shared and the distinct cytotoxic hallmarks of human TCRVδ1 and TCRVδ2 γδ T lymphocytes.

Authors: Gabriele Pizzolato; Hannah Kaminski; Marie Tosolini; Don-Marc Franchini; Fréderic Pont; Fréderic Martins; Carine Valle; Delphine Labourdette; Sarah Cadot; Anne Quillet-Mary; Mary Poupot; Camille Laurent; Loic Ysebaert; Serena Meraviglia; Francesco Dieli; Pierre Merville; Pierre Milpied; Julie Déchanet-Merville; Jean-Jacques Fournié
Journal: Proc Natl Acad Sci U S A Date: 2019-05-22 Impact factor: 11.205

3. Avoidance of On-Target Off-Tumor Activation Using a Co-stimulation-Only Chimeric Antigen Receptor.

Authors: Jonathan Fisher; Pierre Abramowski; Nisansala Dilrukshi Wisidagamage Don; Barry Flutter; Anna Capsomidis; Gordon Weng-Kit Cheung; Kenth Gustafsson; John Anderson
Journal: Mol Ther Date: 2017-03-22 Impact factor: 11.454

4. Ex vivo expanded human circulating Vδ1 γδT cells exhibit favorable therapeutic potential for colon cancer.

Authors: Dang Wu; Pin Wu; Xianguo Wu; Jun Ye; Zhen Wang; Shuai Zhao; Chao Ni; Guoming Hu; Jinghong Xu; Yuehua Han; Ting Zhang; Fuming Qiu; Jun Yan; Jian Huang
Journal: Oncoimmunology Date: 2015-01-22 Impact factor: 8.110

5. Resistance to Immunotherapy: Mechanisms and Means for Overcoming.

Authors: Mohamad A Salkeni; John Y Shin; James L Gulley
Journal: Adv Exp Med Biol Date: 2021 Impact factor: 2.622

6. TCR-Vγδ usage distinguishes protumor from antitumor intestinal γδ T cell subsets.

Authors: Bernardo S Reis; Patrick W Darcy; Iasha Z Khan; Christine S Moon; Adam E Kornberg; Vanessa S Schneider; Yelina Alvarez; Olawale Eleso; Caixia Zhu; Marina Schernthanner; Ainsley Lockhart; Aubrey Reed; Juliana Bortolatto; Tiago B R Castro; Angelina M Bilate; Sergei Grivennikov; Arnold S Han; Daniel Mucida
Journal: Science Date: 2022-07-14 Impact factor: 63.714