Abstract 1417: Clonal succession in pancreatic cancer progression is not driven by genetic instability

Abstract

Abstract Our group has recently shown that human pancreatic cancer (PDAC) progression is driven by a succession of transiently active tumor initiating cell (TIC) clones during serial xenotransplantation. Genetic labeling demonstrated that serial PDAC xenograft tumors and even tumors of parallel mice transplanted with cells from the same donor xenografts harbored very little to no overlap of active TIC clones, indicating substantial changes in the proliferative activity of individual TIC predominantly producing progeny without detectable tumor-initiating activity. We now asked whether observed clonal activation and inactivation is caused by acquisition of de novo mutations during evolution of genetic subclones or by functional plasticity of genetically stable TIC clones. Therefore, we monitored somatic non-synonymous mutations in culture and during PDAC progression in genetically marked serial xenografts of two patients. DNA was isolated from xenografts, primary TIC cultures and corresponding normal pancreas or primary tumor tissue. Following paired-end exome sequencing, reads were aligned to a concatenated hs37d5 human and mm10 mouse genome assembly and human specific single nucleotide variants (SNVs) and small insertions/deletions (indels) were identified. We found a total of 45 altered gene coding genomic loci (P1 = 10; P2 = 35) not present in control tissue. Strikingly, most SNVs detected were present in all samples, only very few SNV were acquired during serial transplantation. In P1, 4 novel SNVs not present in the original patient tumor sample were detected within coding regions of TTC13, OR4K15, SSPO and TPGS1. Allele frequencies ranged from 2-27% in serial xenografts. In xenografts of P2 we detected 35 SNVs not present in healthy tissue. Of these, one mutation in the gene C10orf12 aroused after serial transplantation with a maximum altered allele frequency of 17%. None of these mutations is a known cancer driver or was found as recurrent in large scale cancer sequencing approaches. To evaluate whether the clonal TIC dynamics within established tumors are recapitulated in vitro, we analysed individual TIC clone kinetics in serially passaged cultures and in cultures derived from transduced xenografts. Strikingly, the kinetics in vitro were similar to those observed within serially transplanted xenografts. Every culture passage was formed by a distinct set of actively proliferating cell clones without significant overlap between individual serial passages indicating that clonal succession of TIC activity in PDAC is not dependent on the cellular context in tumors in vivo. The remarkable genetic stability of xenografts during serial transplantation strongly indicates that changes in the functional state of PDAC cells and not genetic instability drive clonal succession of TIC activity in PDAC. Citation Format: Karl Roland Ehrenberg, Claudia R. Ball, Felix Oppel, Naveed Ishaque, Taronish D. Dubash, Sebastian M. Dieter, Christopher M. Hoffmann, Ulrich Abel, Moritz Koch, Jens Werner, Frank Bergmann, Manfred Schmidt, Christof von Kalle, Wilko Weichert, Jürgen Weitz, Benedikt Brors, Hanno Glimm. Clonal succession in pancreatic cancer progression is not driven by genetic instability. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 1417. doi:10.1158/1538-7445.AM2015-1417