Using DNA sequencing data to quantify T cell fraction and therapy response

Bentham, R; Litchfield, K; Watkins, T; Lim, E; Rosenthal, R; Martinez-Ruiz, C; Hiley, C; Bakir, M; Salgado, R; Moore, D; Jamal-Hanjani, M; Birkbak, N; Escudero, M; Stewart, A; Rowan, A; Goldman, J; Van Loo, P; Stone, R; Denner, T; Nye, E; Ward, S; Boeing, S; Greco, M; Nicod, J; Puttick, C; Enfield, K; Colliver, E; Campbell, B; Frankell, A; Cook, D; Angelova, M; Magness, A; Bailey, C; Toncheva, A; Dijkstra, K; Kisistok, J; Sokac, M; Pich, O; Demeulemeester, J; Cadieux, E; Castignani, C; Thakkar, K; Fu, H; Karasaki, T; Al-Sawaf, O; Hill, M; Abbosh, C; Wu, Y; Veeriah, S; Hynds, R; Georgiou, A; Werner Sunderland, M; Reading, J; Quezada, S; Peggs, K; Marafioti, T; Hartley, J; Lowe, H; Ensell, L; Spanswick, V; Karamani, A; Biswas, D; Beck, S; Chervova, O; Tanic, M; Huebner, A; Dietzen, M; Black, J; Naceur-Lombardelli, C; Akther, M; Zhai, H; Kanu, N; Summan, S; Gimeno-Valiente, F; Chen, K; Manzano, E; Kaur Bola, S; Ghorani, E; de Massy, M; Hoxha, E; Hatipoglu, E; Chain, B; Pearce, D; Herrero, J; Zaccaria, S; Lester, J; Morgan, F; Kornaszewska, M; Attanoos, R; Adams, H; Davies, H; Shaw, J; Riley, J; Primrose, L; Fennell, D; Nakas, A; Rathinam, S; Plummer, R; Boyles, R; Tufail, M; Bajaj, A; Brozik, J; Ang, K; Chowdhry, M; Monteiro, W; Marshall, H; Dawson, A; Busacca, S; Marrone, D; Smith, C; Anand, G; Khan, S; Price, G; Khalil, M; Kerr, K; Richardson, S; Cheyne, H; Miller, J; Buchan, K; Chetty, M; Dubois-Marshall, S; Lock, S; Gilbert, K; Naidu, B; Langman, G; Bancroft, H; Kadiri, S; Middleton, G; Djearaman, M; Osman, A; Shackleford, H; Patel, A; Leek, A; Totten, N; Hodgkinson, J; Rogan, J; Moore, K; Waddington, R; Califano, R; Shah, R; Krysiak, P; Rammohan, K; Fontaine, E; Booton, R; Evison, M; Moss, S; Novasio, J; Joseph, L; Bishop, P; Chaturvedi, A; Doran, H; Granato, F; Joshi, V; Smith, E; Montero, A; Crosbie, P; Blackhall, F; Priest, L; Krebs, M; Dive, C; Rothwell, D; Kerr, A; Kilgour, E; Baker, K; Carter, M; Lindsay, C; Gomes, F; Tugwood, J; Pierce, J; Clipson, A; Schwarz, R; Kaufmann, T; Huska, M; Szallasi, Z; Csabai, I; Diossy, M; Aerts, H; Fekete, C; Royle, G; Veiga, C; Skrzypski, M; Lawrence, D; Hayward, M; Panagiotopoulos, N; George, R; Patrini, D; Falzon, M; Borg, E; Khiroya, R; Ahmed, A; Taylor, M; Choudhary, J; Janes, S; Forster, M; Ahmad, T; Lee, S; Navani, N; Papadatos-Pastos, D; Scarci, M; Gorman, P; Bertoja, E; Stephens, R; Hoogenboom, E; Holding, J; Bandula, S; Thakrar, R; Anand, R; Selvaraju, K; Wilson, J; Hessey, S; Ashford, P; Shah, M; Duran, M; Mackenzie, M; Wilcox, M; Hackshaw, A; Ngai, Y; Sharp, A; Rodrigues, C; Pressey, O; Smith, S; Gower, N; Dhanda, H; Chan, K; Chakraborty, S; Ottensmeier, C; Chee, S; Johnson, B; Alzetani, A; Cave, J; Scarlett, L; Shaw, E; Lim, E; De Sousa, P; Jordan, S; Rice, A; Raubenheimer, H; Bhayani, H; Hamilton, M; Ambrose, L; Devaraj, A; Chavan, H; Begum, S; Buderi, S; Kaniu, D; Malima, M; Booth, S; Nicholson, A; Fernandes, N; Deeley, C; Shah, P; Proli, C; Lau, K; Sheaff, M; Schmid, P; Lim, L; Conibear, J; Hewish, M; Danson, S; Bury, J; Edwards, J; Hill, J; Matthews, S; Kitsanta, Y; Rao, J; Tenconi, S; Socci, L; Suvarna, K; Kibutu, F; Fisher, P; Young, R; Barker, J; Taylor, F; Lloyd, K; Shackcloth, M; Asante-Siaw, J; Gosney, J; Light, T; Horey, T; Russell, P; Papadatos-Pastos, D; Blyth, K; Dick, C; Kidd, A; Kirk, A; Asif, M; Butler, J; Bilancia, R; Kostoulas, N; Thomas, M; Wilson, G; Swanton, C; Mcgranahan, N

doi:10.1038/s41586-021-03894-5

The immune microenvironment influences tumour evolution and can be both prognostic and predict response to immunotherapy1,2. However, measurements of tumour infiltrating lymphocytes (TILs) are limited by a shortage of appropriate data. Whole-exome sequencing (WES) of DNA is frequently performed to calculate tumour mutational burden and identify actionable mutations. Here we develop T cell exome TREC tool (T cell ExTRECT), a method for estimation of T cell fraction from WES samples using a signal from T cell receptor excision circle (TREC) loss during V(D)J recombination of the T cell receptor-α gene (TCRA (also known as TRA)). TCRA T cell fraction correlates with orthogonal TIL estimates and is agnostic to sample type. Blood TCRA T cell fraction is higher in females than in males and correlates with both tumour immune infiltrate and presence of bacterial sequencing reads. Tumour TCRA T cell fraction is prognostic in lung adenocarcinoma. Using a meta-analysis of tumours treated with immunotherapy, we show that tumour TCRA T cell fraction predicts immunotherapy response, providing value beyond measuring tumour mutational burden. Applying T cell ExTRECT to a multi-sample pan-cancer cohort reveals a high diversity of the degree of immune infiltration within tumours. Subclonal loss of 12q24.31–32, encompassing SPPL3, is associated with reduced TCRA T cell fraction. T cell ExTRECT provides a cost-effective technique to characterize immune infiltrate alongside somatic changes.

Bentham, R., Litchfield, K., Watkins, T., Lim, E., Rosenthal, R., Martinez-Ruiz, C., et al. (2021). Using DNA sequencing data to quantify T cell fraction and therapy response. NATURE, 597(7877), 555-560 [10.1038/s41586-021-03894-5].

Using DNA sequencing data to quantify T cell fraction and therapy response

Bentham R.;Litchfield K.;Watkins T. B. K.;Lim E. L.;Rosenthal R.;Martinez-Ruiz C.;Hiley C. T.;Bakir M. A.;Salgado R.;Moore D. A.;Jamal-Hanjani M.;Birkbak N. J.;Escudero M.;Stewart A.;Rowan A.;Goldman J.;Van Loo P.;Stone R. K.;Denner T.;Nye E.;Ward S.;Boeing S.;Greco M.;Nicod J.;Puttick C.;Enfield K.;Colliver E.;Campbell B.;Frankell A. M.;Cook D.;Angelova M.;Magness A.;Bailey C.;Toncheva A.;Dijkstra K.;Kisistok J.;Sokac M.;Pich O.;Demeulemeester J.;Cadieux E. L.;Castignani C.;Thakkar K.;Fu H.;Karasaki T.;Al-Sawaf O.;Hill M. S.;Abbosh C.;Wu Y.;Veeriah S.;Hynds R. E.;Georgiou A.;Werner Sunderland M.;Reading J. L.;Quezada S. A.;Peggs K. S.;Marafioti T.;Hartley J. A.;Lowe H. L.;Ensell L.;Spanswick V.;Karamani A.;Biswas D.;Beck S.;Chervova O.;Tanic M.;Huebner A.;Dietzen M.;Black J. R. M.;Naceur-Lombardelli C.;Akther M. A.;Zhai H.;Kanu N.;Summan S.;Gimeno-Valiente F.;Chen K.;Manzano E.;Kaur Bola S.;Ghorani E.;de Massy M. R.;Hoxha E.;Hatipoglu E.;Chain B.;Pearce D. R.;Herrero J.;Zaccaria S.;Lester J.;Morgan F.;Kornaszewska M.;Attanoos R.;Adams H.;Davies H.;Shaw J. A.;Riley J.;Primrose L.;Fennell D.;Nakas A.;Rathinam S.;Plummer R.;Boyles R.;Tufail M.;Bajaj A.;Brozik J.;Ang K.;Chowdhry M. F.;Monteiro W.;Marshall H.;Dawson A.;Busacca S.;Marrone D.;Smith C.;Anand G.;Khan S.;Price G.;Khalil M.;Kerr K.;Richardson S.;Cheyne H.;Miller J.;Buchan K.;Chetty M.;Dubois-Marshall S.;Lock S.;Gilbert K.;Naidu B.;Langman G.;Bancroft H.;Kadiri S.;Middleton G.;Djearaman M.;Osman A.;Shackleford H.;Patel A.;Leek A.;Totten N.;Hodgkinson J. D.;Rogan J.;Moore K.;Waddington R.;Califano R.;Shah R.;Krysiak P.;Rammohan K.;Fontaine E.;Booton R.;Evison M.;Moss S.;Novasio J.;Joseph L.;Bishop P.;Chaturvedi A.;Doran H.;Granato F.;Joshi V.;Smith E.;Montero A.;Crosbie P.;Blackhall F.;Priest L.;Krebs M. G.;Dive C.;Rothwell D. G.;Kerr A.;Kilgour E.;Baker K.;Carter M.;Lindsay C. R.;Gomes F.;Tugwood J.;Pierce J.;Clipson A.;Schwarz R.;Kaufmann T. L.;Huska M.;Szallasi Z.;Csabai I.;Diossy M.;Aerts H.;Fekete C.;Royle G.;Veiga C.;Skrzypski M.;Lawrence D.;Hayward M.;Panagiotopoulos N.;George R.;Patrini D.;Falzon M.;Borg E.;Khiroya R.;Ahmed A.;Taylor M.;Choudhary J.;Janes S. M.;Forster M.;Ahmad T.;Lee S. M.;Navani N.;Papadatos-Pastos D.;Scarci M.;Gorman P.;Bertoja E.;Stephens R. C. M.;Hoogenboom E. M.;Holding J. W.;Bandula S.;Thakrar R.;Anand R.;Selvaraju K.;Wilson J.;Hessey S.;Ashford P.;Shah M.;Duran M. V.;MacKenzie M.;Wilcox M.;Hackshaw A.;Ngai Y.;Sharp A.;Rodrigues C.;Pressey O.;Smith S.;Gower N.;Dhanda H. K.;Chan K.;Chakraborty S.;Ottensmeier C.;Chee S.;Johnson B.;Alzetani A.;Cave J.;Scarlett L.;Shaw E.;Lim E.;De Sousa P.;Jordan S.;Rice A.;Raubenheimer H.;Bhayani H.;Hamilton M.;Ambrose L.;Devaraj A.;Chavan H.;Begum S.;Buderi S. I.;Kaniu D.;Malima M.;Booth S.;Nicholson A. G.;Fernandes N.;Deeley C.;Shah P.;Proli C.;Lau K.;Sheaff M.;Schmid P.;Lim L.;Conibear J.;Hewish M.;Danson S.;Bury J.;Edwards J.;Hill J.;Matthews S.;Kitsanta Y.;Rao J.;Tenconi S.;Socci L.;Suvarna K.;Kibutu F.;Fisher P.;Young R.;Barker J.;Taylor F.;Lloyd K.;Shackcloth M.;Asante-Siaw J.;Gosney J.;Light T.;Horey T.;Russell P.;Papadatos-Pastos D.;Blyth K. G.;Dick C.;Kidd A.;Kirk A.;Asif M.;Butler J.;Bilancia R.;Kostoulas N.;Thomas M.;Wilson G. A.;Swanton C.;McGranahan N.

2021

Abstract

The immune microenvironment influences tumour evolution and can be both prognostic and predict response to immunotherapy1,2. However, measurements of tumour infiltrating lymphocytes (TILs) are limited by a shortage of appropriate data. Whole-exome sequencing (WES) of DNA is frequently performed to calculate tumour mutational burden and identify actionable mutations. Here we develop T cell exome TREC tool (T cell ExTRECT), a method for estimation of T cell fraction from WES samples using a signal from T cell receptor excision circle (TREC) loss during V(D)J recombination of the T cell receptor-α gene (TCRA (also known as TRA)). TCRA T cell fraction correlates with orthogonal TIL estimates and is agnostic to sample type. Blood TCRA T cell fraction is higher in females than in males and correlates with both tumour immune infiltrate and presence of bacterial sequencing reads. Tumour TCRA T cell fraction is prognostic in lung adenocarcinoma. Using a meta-analysis of tumours treated with immunotherapy, we show that tumour TCRA T cell fraction predicts immunotherapy response, providing value beyond measuring tumour mutational burden. Applying T cell ExTRECT to a multi-sample pan-cancer cohort reveals a high diversity of the degree of immune infiltration within tumours. Subclonal loss of 12q24.31–32, encompassing SPPL3, is associated with reduced TCRA T cell fraction. T cell ExTRECT provides a cost-effective technique to characterize immune infiltrate alongside somatic changes.

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	Sottotipologia
	
				Articolo in rivista - Articolo scientifico
			
	Parole chiave
	
				Adenocarcinoma of Lung; Aspartic Acid Endopeptidases; Cohort Studies; Exome; Female; Humans; Immunotherapy; Lymphocytes, Tumor-Infiltrating; Male; Mutation; Neoplasms; Prognosis; Receptors, Antigen, T-Cell, alpha-beta; T-Lymphocytes; Whole Exome Sequencing
			
	Lingua del contenuto
	
				English
			
	Data di pubblicazione
	
				2021
			
	Rivista
	
				NATURE
			
	Numero del volume
	
				597
			
	Fascicolo
	
				7877
			
	Pagina iniziale
	
				555
			
	Pagina finale
	
				560
			
	DOI dell'articolo
	
				https://dx.doi.org/10.1038/s41586-021-03894-5
			
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				reserved
			
	Citazione
	
				Bentham, R., Litchfield, K., Watkins, T., Lim, E., Rosenthal, R., Martinez-Ruiz, C., et al. (2021). Using DNA sequencing data to quantify T cell fraction and therapy response. NATURE, 597(7877), 555-560 [10.1038/s41586-021-03894-5].
			
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/508684

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Using DNA sequencing data to quantify T cell fraction and therapy response

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