Mutational Signatures Associate With Survival in Gastrointestinal Carcinomas

Discussion

The impact of mutational signatures on patient survival has not been assessed previously. The herein presented data suggest that COSMIC mutational signatures have cancer-specific associations with diverse prognostic groups among the major GI cancers.

From all GI cancers, SBS1, SBS5 and SBS40 signatures have been most frequently found in colorectal adenocarcinomas and SBS5 is ubiquitous also in benign GI tissues (3, 12). Both SBS5 and SBS40 are flat signatures, and their misattribution has not been excluded (3, 13). The activity of both SBS5 and SBS40 correlate with age, but the etiology especially behind SBS40 is still unknown (3). According to our analysis, the high activity of both SBS5 and SBS40 associated with improved OS in patients with rectal adenocarcinoma. In addition, both SBS5 and SBS40 associated very convincingly with long DSS, the upper limit of 95%CI of the HR being as low as 0.076 for SBS5 and 0.15 for SBS40, respectively. These estimates exceed by far the traditional colorectal cancer prognostic factors, including stage. Nevertheless, rectal cancer-specific survival should be considered as an approximation in TCGA data, while OS is more strongly recommended for use (7). Intriguingly, SBS5 activity did not reflect the total number of mutations in rectal adenocarcinomas, although SBS40 had such a correlation. Neither SBS5 and SBS40 associated with stage, sex, or the site of primary carcinoma in rectum. This may emphasize their occurrence possibly in the early phases of carcinogenesis, but also suggests their independent roles as novel prognostic factors in rectal adenocarcinomas. These results are in contradiction with the inherent clock-like nature of these SBS5 and SBS40 and suggest that their association to non-malignant behavior of rectal adenocarcinomas should be assessed in more mechanistical studies.

SBS17b is considered an easily trackable signature and it has a marked characteristic of T>G substitutions, possibly caused by oxidative damage in the nucleotide pool (4). Although high SBS17b activity was observed only in 7% of the evaluable patients with rectal adenocarcinoma, it associated very strongly with poor rectal adenocarcinoma-specific survival. Again, these DSS rates should be interpreted with caution due to relatively short follow-up (7). There is an enrichment of high SBS17b activity in tumors treated with 5-fluorouracil or capecitabine, which are widely used agents in stage III rectal adenocarcinomas requiring perioperative therapy (3, 14). The association between high SBS17b activity and poor survival was still independent from stage. Recent evidence suggests that high SBS17b activity is also connected to anti-EGFR antibody resistance in colorectal cancer (15).

Sidedness affects a wide spectrum of CRC features, including consensus molecular subtypes and microbiome, but has also a clinically meaningful impact on prognosis and treatment in metastatic setting (16). Contradictory to what was observed in patients with rectal adenocarcinoma, we observed dismal OS outcome in patients with left-sided colon adenocarcinoma, who had either high SBS5 or SBS40 activity. Such associations were not observed in patients with adenocarcinoma originating from the right side of colon and thus the clock-like nature of these signatures does not explain these results. Whether preoperative radiotherapy, used in rectal adenocarcinomas but not in colon adenocarcinomas, could induce SBS5 and SBS40 is currently unknown. High SBS2 activity predicted poor OS in patients with left-sided colon adenocarcinoma, but again not in those whose primary tumor was right-sided. SBS2 signature is formed due to APOBEC activity and is one of the most well-defined mutational signatures (4, 17). Although the prognostic value of mutational signatures has been previously described hardly in any malignancies, APOBEC signatures seem to associate with high mutational load and worse OS also in the patients with multiple myeloma (18).

Pancreatic adenocarcinoma has a dismal prognosis and lacks reproducible genetic or molecular prognostic biomarkers. SBS10 signature was recently split into distinct SBS10a and SBS10b signatures, which are both caused by polymerase epsilon exonuclease (POLE) proofreading defects (3, 19, 20). Specific POLE mutations define in endometrial carcinomas a specific ultramutated subtype, with improved prognosis (21). In line with this, the high activity of SBS10b signature in the patients with pancreatic adenocarcinoma was present in 10% of patients and it associated with longer DSS and OS, with a similar magnitude of effect for both endpoints. Both OS and DSS are considered as reliable endpoints in the TCGA data of pancreatic adenocarcinomas (7). SBS10b was not associated with any of the studied traditional prognostic factors or total mutation load. It is worth emphasizing that the stage distribution of pancreatic adenocarcinomas in TCGA does not represent the distribution seen in usual clinical practice, as 95% cases in the TCGA dataset are stage I-II tumors. Thus, these results suggest that the high activity of SBS10b, indicating POLE repair deficiency and hypermutator phenotype, may be a novel prognostic factor in early pancreatic adenocarcinoma. This could offer a possibility to guide risk-based adjuvant therapy and surveillance after surgery with curative intention. In advanced endometrial cancers, high SBS10 signature activity has been connected to improved response for checkpoint inhibitors, probably due to increased neoepitope formation (4, 19, 20).

In contrast to other GI carcinomas, there are some preliminary data regarding the COSMIC signatures and survival in patients with esophageal and gastroesophageal junction (GEJ) carcinoma. High SBS17 activity (without a separation to SBS17a and SBS17b) predicted worse survival in the material of 83 Chinese GEJ adenocarcinoma patients (22). Also in a small set of esophageal adenocarcinomas, the characteristic of SBS signatures, SBS, 5′-C[T>G]T-3′, predicted worse OS in univariate analysis (23). In line with these data, and with the current results from rectal adenocarcinomas, SBS17b activity predicted poor OS outcomes in esophageal carcinomas, consisting almost solely of adenocarcinomas.

SBS1 associated in stomach adenocarcinomas with short DFI, which is considered as a reliable endpoint in TCGA stomach adenocarcinoma cohort (7). SBS1 correlates tightly with age and mutation load in most cancers, also in stomach adenocarcinomas (3, 24) and age is one of the most important prognostic factors in stomach cancer (25).

Both SBS17b and SBS18 signatures arise after cellular stress, especially due to reactive oxygen species (4). Particularly, SBS17 signatures may be a consequence of exposure for gastric acid or 5-fluorouracil/capecitabine (4), which are one of the most applied chemotherapeutic agents also in esophageal carcinomas. It is possible, that the linkage between SBS17b and shorter survival in patients with esophageal carcinomas may just reflect the increased use chemotherapy or (chemo)radiotherapy in the most aggressive esophageal carcinomas, which would have consequently led to increased number of SBS17b signatures. From all GI carcinomas, SBS18 is the most prevalent in both esophageal carcinomas (3, 26). High SBS18 activity associated with improved DFI in TCGA data and also with prolonged OS in PCAWG dataset. This was the only result from whole-exome TCGA dataset, which could be confirmed in the whole-genome PCAWG data. Taken together, it seems that there is a different origin of signature between SBS17b and SBS18 and consequently diverse contribution to survival in esophageal carcinomas.

There are several limitations in our study, which mostly relate to the nature of TCGA data. We did not have the treatment data available, although we were able to use various other clinically important prognostic factors as co-variates in multivariate analysis. Using PFI and DFI may be criticized for them being surrogates rather than clinically hard endpoints. On the other hand, in TCGA cohorts PFI and DFI are considered the most reliable endpoints due to generally sufficient follow-up (7). Again, DSS results should be interpreted with caution in most cancer types as discussed above (7). As TCGA is based on exome data, only a small proportion of mutations in human genome footprint are covered. This is also a likely reason for our final analyses including only SBSs, but not other types of signatures. The results from PCAWG data were mainly not in concordance with TCGA results. This is not surprising since PCAWG whole-genome data consists of only one endpoint, OS, it lacks the largely clinical variables, and above all, has a limited sample size.