Proliferation is a key hallmark of cancer, but whether it differs between evolutionarily distinct clones co-existing within a tumor is unknown. We introduce the Single-cell Proliferation Rate Inference in Non-homogeneous Tumors through Evolutionary Routes (SPRINTER) algorithm that uses single-cell whole-genome DNA sequencing data to enable accurate identification and clone assignment of S- and G2-phase cells, as assessed by generating accurate ground truth data. Applied to a newly generated longitudinal, primary-metastasis-matched dataset of 14,994 non-small cell lung cancer cells, SPRINTER revealed widespread clone proliferation heterogeneity, orthogonally supported by Ki-67 staining, nuclei imaging and clinical imaging. We further demonstrated that high-proliferation clones have increased metastatic seeding potential, increased circulating tumor DNA shedding and clone-specific altered replication timing in proliferation- or metastasis-related genes associated with expression changes. Applied to previously generated datasets of 61,914 breast and ovarian cancer cells, SPRINTER revealed increased single-cell rates of different genomic variants and enrichment of proliferation-related gene amplifications in high-proliferation clones.
Characterizing the evolutionary dynamics of cancer proliferation in single-cell clones with SPRINTER / Lucas, Olivia; Ward, Sophia; Zaidi, Rija; Bunkum, Abigail; Frankell, Alexander M; Moore, David A; Hill, Mark S; Liu, Wing Kin; Marinelli, Daniele; Lim, Emilia L; Hessey, Sonya; Naceur-Lombardelli, Cristina; Rowan, Andrew; Purewal-Mann, Sukhveer Kaur; Zhai, Haoran; Dietzen, Michelle; Ding, Boyue; Royle, Gary; Aparicio, Samuel; Mcgranahan, Nicholas; Jamal-Hanjani, Mariam; Kanu, Nnennaya; Swanton, Charles; Zaccaria, Simone. - In: NATURE GENETICS. - ISSN 1546-1718. - (2024). [10.1038/s41588-024-01989-z]
Characterizing the evolutionary dynamics of cancer proliferation in single-cell clones with SPRINTER
Marinelli, Daniele;
2024
Abstract
Proliferation is a key hallmark of cancer, but whether it differs between evolutionarily distinct clones co-existing within a tumor is unknown. We introduce the Single-cell Proliferation Rate Inference in Non-homogeneous Tumors through Evolutionary Routes (SPRINTER) algorithm that uses single-cell whole-genome DNA sequencing data to enable accurate identification and clone assignment of S- and G2-phase cells, as assessed by generating accurate ground truth data. Applied to a newly generated longitudinal, primary-metastasis-matched dataset of 14,994 non-small cell lung cancer cells, SPRINTER revealed widespread clone proliferation heterogeneity, orthogonally supported by Ki-67 staining, nuclei imaging and clinical imaging. We further demonstrated that high-proliferation clones have increased metastatic seeding potential, increased circulating tumor DNA shedding and clone-specific altered replication timing in proliferation- or metastasis-related genes associated with expression changes. Applied to previously generated datasets of 61,914 breast and ovarian cancer cells, SPRINTER revealed increased single-cell rates of different genomic variants and enrichment of proliferation-related gene amplifications in high-proliferation clones.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
