Real-time Genomic Characterization of Advanced Pancreatic Cancer to Enable Precision Medicine

Biopsy Approach and Patient Cohort

The PancSeq protocol was developed as an institutional review board (IRB)–approved multidisciplinary biopsy program to obtain tissue from core-needle biopsies or fine-needle aspirates in patients with metastatic or locally advanced PDAC for rapid turnaround genomic analysis. Between March 2015 and June 2017, 79 patients underwent biopsy on the PancSeq protocol (Supplementary Table S1; Supplementary Fig. S1). An initial pilot phase (n = 10 patients) was conducted in patients having clinically indicated biopsies to optimize workflow, tissue processing, nucleic acid extraction, whole- exome sequencing (WES), and RNA sequencing (RNA-seq) from small-volume needle biopsies (approximately 15–20 mg of tissue per biopsy). Subsequently, 69 additional patients underwent biopsy and WES was performed in a Clinical Laboratory Improvement Amendments (CLIA)–certified laboratory, with return of selected somatic and germline variants to referring clinicians. Patients had a median age of 64 years and most had metastatic disease (96%) and no prior therapy (70%; Supplementary Table S1). Most patients had a diagnosis of PDAC (95%), although several patients with less common histologies were enrolled. Biopsies were obtained from liver (n = 63), pancreas (n = 7), peritoneum (n = 6), lymph nodes (n = 2), and ovary (n = 1; Supplementary Table S2). Biopsies were performed percutaneously by interventional radiology (n = 72), with endoscopic ultrasound (n = 6), or intraoperatively (n = 1), and a median of 5 (range, 1–10) cores or biopsy specimens were collected per patient. A low rate of serious complications was observed, with only 1 patient having a self-limited hepatic subcapsular hematoma in the setting of a clinically indicated liver biopsy and therapeutic anticoagulation with an oral factor Xa inhibitor (rivaroxaban) for prior deep venous thrombosis.

Real-time DNA Sequencing and Exome Analysis

From the formalin-fixed, paraffin-embedded core, tumor content was quantified by histopathology, and 92% (73/79) of cases had sufficient tumor content (≥5% tumor nuclei) to proceed with WES. ABSOLUTE purity (16) was examined in WES data, and successful mutation and copy-number calls could be made for all but two of these samples (Supplementary Table S2; Supplementary Fig. S1).

Consistent with prior genome sequencing studies of primary PDAC samples, samples from our cohort of patients with PDAC displayed low neoplastic cellularity, with a median cellularity by histologic assessment of 40%, and by WES using the ABSOLUTE algorithm of 34% (Supplementary Fig. S2A–S2B; ref. 16). Neoplastic cellularity estimates by histologic assessment and by the ABSOLUTE algorithm on WES data were significantly correlated (Pearson product–moment correlation = 0.386; 95% CI, 0.195–0.548; P = 0.00016; Supplementary Fig. S2A). This level of correlation is consistent with that observed in other studies (12, 16) and is affected by variability between biopsy specimens as well as differential sensitivity between the two methods for identification of neoplastic cellularity. For our biopsy samples, we performed deep WES with a median of mean target coverage of 191× in the tumor and 176× in the normal (Supplementary Table S2). Within the CLIA-certified phase of the study, analyzed results were available within an average of 39 days (range, 16–67) from the date of clinically indicated biopsies and 28 days (range, 15–51) for research-only biopsies (Supplementary Table S2). Additional time for return of results for clinically indicated biopsies was required, as these specimens were held in the pathology department until a formal histologic diagnosis was confirmed. A report of clinically relevant events was returned to the referring clinician detailing somatic mutations, small insertions/deletions, and copy-number alterations (CNA) as well as pathogenic/likely pathogenic germline alterations in a curated list of 81 PDAC-relevant genes (Supplementary Table S3). These genes were chosen based on somatic or germline clinical relevance, therapeutic actionability, and/or recurrent mutation across published PDAC genome-sequencing cohorts (4–12). Most of these genes (n = 69) were associated with clinical trial or off-label FDA-approved targeted therapies. Comprehensive analysis of all genes from WES data was simultaneously performed in the research setting.

Landscape of Somatic Mutations and CNAs in Advanced PDAC

Genome-sequencing studies have elucidated the molecular landscape of archived primary PDAC tumors and have demonstrated distinct molecular subtypes of disease (6–12). In our cohort of 71 patients with PDAC, we identified significantly recurrent mutations in KRAS, TP53, CDKN2A, SMAD4, ARID1A, and TGFBR2—a collection of genes that were also recurrently mutated in primary PDAC tumors (refs. 7, 10, 12; Fig. 1). Moreover, we observed frequent mutations in additional tumor suppressor genes (e.g., RNF43) or oncogenes (e.g., BRAF, GNAS), as well as recurrent mutations in genes involved in DNA-damage repair (DDR) and chromatin modification (Fig. 1). Recurrent high-level amplifications were observed in several genomic loci, encompassing genes such as MYC, AKT2, and GATA6 (Fig. 1; Supplementary Fig. S3). Deletions were identified at numerous loci, including frequent homozygous deletions of CDKN2A and SMAD4 (Fig. 1; Supplementary Fig. S3).

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Figure 1.

Landscape of genomic alterations identified by WES in biopsies of patients with advanced PDAC. Co-mutation plot displaying integrated genomic data for 71 samples displayed as columns, including somatic mutations, high-level amplifications and homozygous deletions, and germline mutations for selected genes. For each sample, the site of biopsy, the ABSOLUTE neoplastic cellularity (purity) from WES data, and the neoplastic cellularity as assessed by histologic evaluation are shown as tracks at the top. Significantly mutated genes with q value ≤ 0.1 that were identified by exome sequencing are listed at the top (black) vertically in order of decreasing significance. Genes from recurrently altered functional classes are also shown, including tumor suppressor genes (yellow), oncogenes (red), DDR genes (green), and chromatin modification genes (blue). H&E, hematoxylin and eosin; LN, lymph node; Indel, insertion/deletion.

Mutational Signature Analysis from WES Data

Mutational signature analysis was performed using a Bayesian variant of the non-negative matrix factorization approach in a two-stage manner from the set of single-nucleotide variants (SNV) in our dataset, as previously described (SignatureAnalyzer; Supplementary Experimental Methods; refs. 17–20). First, we performed de novo signature discovery and our analytic pipeline identified three primary signatures: SigA that best resembled Catalogue of Somatic Mutations in Cancer (COSMIC) signature 3 with cosine similarity 0.87 [BRCA mutant signature suggestive of homologous recombination deficiency (HRD)]; SigB that best resembled COSMIC signature 1 with cosine similarity 0.96 (C>T transitions at CpG dinucleotides, Aging); and SigC that best resembled COSMIC signature 17 with cosine similarity 0.91 (etiology unknown; Supplementary Fig. S4A–S4B). In addition, we observed a relative elevation of C>G transversions and C>T transitions at TC[A/T] contexts in SigA corresponding to canonical hotspots of APOBEC mutagenesis (COSMIC signatures 2 and 13), suggesting that APOBEC signature is possibly operative in this cohort, but not cleanly separable due to a lack of mutations (17). Based on this de novo analysis, we concluded that four main mutational processes were likely active in these data (Aging/COSMIC1, BRCA/HRD/COSMIC3, APOBEC/COSMIC2+13, and COSMIC17). To better evaluate discrete contributions of these mutational processes in our data and to minimize signature contamination, we next performed a projection analysis to infer a signature activity across our biopsy cohort using the signature profiles of the five contributing COSMIC signatures: COSMIC1, 2, 3, 13, 17 (Fig. 2A; Supplementary Experimental Methods). Consistent with the de novo analysis, the inferred signature activity with these five COSMIC signatures reveals a clear contribution of the Aging/COSMIC1 signature in almost all patients and a notable activity of the HRD/COSMIC3 signatures in many patients (Fig. 2A).

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Figure 2.

Mutational signature analysis of WES data from patients with advanced PDAC. A, Projection of signatures representing four main mutational processes identified in de novo signature analysis. All 71 samples in the cohort are listed as columns. Each row represents a signature as defined in the text: COSMIC1 (C>T transitions at CpG dinucleotides, Aging), COSMIC2 and 13 (APOBEC), COSMIC3 (HRD or BRCA deficient), and COSMIC17 (unknown). B, Samples are shown by the number of HRD/COSMIC3 mutations (y-axis) and binned according to whether they have a mutation or gene expression alteration in the known HR genes BRCA1, BRCA2, PALB2, or RAD51C (HRD altered; x-axis). Legend below indicates coloring based on type of alteration. RAD51C downregulation refers to more than 2-fold downregulation of mRNA expression levels below the mean value for the entire cohort. “No events” refers to no detected mutation, copy-number alteration, or mRNA downregulation in the genes indicated. C, Scatter plot of samples displayed by the number of large (≥9 base pairs) deletions on the y-axis and the number of HRD/COSMIC3 mutations on the x-axis. Coloring as shown in the legend below.

To further investigate the HRD/COSMIC3 signature in these data, we integrated mutation and copy-number data from WES and gene-expression data from RNA-seq for a core set of known homologous recombination (HR) genes (BRCA1, BRCA2, PALB2, and RAD51C) that are known to be associated with the HRD/COSMIC3 signature (18) and categorized samples as “HRD altered” or “WT” (wild-type). We defined HRD-altered samples based on the presence of damaging germline and somatic mutations (null, truncating, and splice-site variants), homozygous deletions, or more than 2-fold downregulation of mRNA expression levels. We observed a significant enrichment of HRD/COSMIC3 signature mutations within HRD-altered samples (Fig. 2B; P < 0.000002 by one-tailed Wilcoxon rank-sum test). The increased occurrence of large deletions of up to 50 base pairs with overlapping microhomology is another characteristic of HR-deficient samples, and we indeed observed an increased incidence of such deletions (≥9 base pairs) in our HRD-altered samples (Fig. 2C; P < 0.00002 by one-tailed Wilcoxon rank-sum test). Eight of the top 14 samples with HRD/COSMIC3 signature activity harbored deleterious mutations or homozygous deletions in one of the four core HRD genes. Six of these eight HRD-altered samples had both germline and somatic events or a somatic alteration with coexisting loss of heterozygosity (LOH) in BRCA1 or BRCA2, supporting a “two-hit” hypothesis. Another sample (0400253) had both a p.Q750* nonsense and a p.F1016S missense mutation in PALB2. Furthermore, one sample harbored homozygous deletion of RAD51C. Two additional samples with HRD/COSMIC3 signature activity but without genomic alterations in the four core HRD genes displayed downregulation of RAD51C expression in the RNA-seq data, an event previously associated with HRD/COSMIC3 signature activity (18). Thus, a total of 10 of 14 samples with a high HRD/COSMIC3 signature activity could be explained by genomic alterations or downregulation of gene expression in BRCA1, BRCA2, PALB2, or RAD51C (Fig. 2B).

Notably, we also observed 4 samples that did not have clear DNA alterations or mRNA downregulation of BRCA1, BRCA2, PALB2, or RAD51C but nevertheless had enrichment of the HRD/COSMIC3 mutational signature at a level equal to or greater than those samples in the HRD-altered class (Fig. 2B and C). We conducted a broader examination of genes involved in DDR, including those responsible for HR, nonhomologous end joining, base excision repair, nucleotide excision repair (NER), and DDR checkpoint responses. One patient with a high activity of the HRD/COSMIC3 signature had an ERCC2^N238S mutation in a conserved helicase domain of this key enzyme involved in NER. This ERCC2^N238S mutation corresponds to one of the recurrent mutational hotspots observed in patients with muscle-invasive urothelial carcinoma who achieved a complete response to neoadjuvant cisplatin-based therapy (21). ERCC2 mutations have been associated with a separate mutational signature that has a significant overlap with the HRD/COSMIC3 signature (20); thus, the apparent enrichment of the HRD/COSMIC3 signature for this patient with PDAC with an ERCC2^N238S mutation may be attributed to the presence of an ERCC2 mutational signature. Notably, this patient experienced a partial response to platinum-based FOLFIRINOX therapy (5-FU, leucovorin, irinotecan, and oxaliplatin), but progressed after 4 to 5 months of treatment. For the remaining three samples with unexplained HRD/COSMIC3 signature enrichment, we did not observe other mutations or copy-number events in recognized DDR genes. Thus, our data suggest that the HRD/COSMIC3 signature analysis in WES data may detect additional patients with HRD not identified solely by mutation profiling of specific genes known to be related to HR.

Germline Mutations

Identification of germline variants associated with PDAC can have important implications for treatment of the proband as well as for counseling and genetic screening of family members. Thus, in addition to somatic mutation and copy-number analysis, we simultaneously interrogated each patient's germline sequencing data for pathogenic/likely pathogenic variants in 81 genes (Supplementary Table S3). In total, we observed pathogenic/likely pathogenic germline variants in 18% (13/71) of patients (Table 1; Fig. 1). These patients were referred for genetic counseling and outreach to family members (Table 1).

Pathogenic/likely pathogenic germline variants were observed in several DDR genes, including BRCA1 (n = 2), BRCA2 (n = 3), and ATM (n = 3). An additional pathogenic CHEK2 deletion was observed through commercial testing in a patient who was referred due to a strong family history of malignancy (Table 1). Notably, our CLIA-certified WES platform was not validated for detection of exon-level CNAs in the germline at the time of this study. However, reexamination of the germline WES data confirmed the CHEK2 deletion seen on commercial testing.

All 5 patients with a germline mutation in BRCA1 or BRCA2 demonstrated evidence of enrichment in the genomic HRD/COSMIC3 signature (Fig. 2B), as well as LOH through somatic copy-number loss of the wild-type allele (Table 1). However, only 1 of 3 patients with a germline ATM mutation harbored a somatic alteration in the other allele. A somatic second hit was also not identified for patients with germline pathogenic/likely pathogenic mutations in BLM, FANCA, FANCL, or RAD50. Beyond the BRCA1/2-mutant cases, none of the patients harboring other germline DDR gene mutations showed evidence of HRD/COSMIC3 signature enrichment (Fig. 2B). The mean age at diagnosis did not significantly differ between cohorts with or without a pathogenic/likely pathogenic germline mutation (60.2 vs. 63.9 years, respectively; two-tailed t test, P = 0.14).

RNA-seq of PDAC Biopsies

Recent gene expression studies have identified subtypes of PDAC with prognostic and biological relevance (7, 12–14). These studies converge on at least two major neoplastic subtypes of PDAC including a squamous/basal-like/quasimesenchymal subtype and a classic/pancreatic progenitor subtype. To investigate these neoplastic PDAC subsets within our metastatic biopsy cohort, we performed RNA-seq on a separate biopsy specimen from that used for WES. We achieved successful RNA extraction and sequencing from 80% (63/79) of patients (Supplementary Fig. S1). Consistent with our prior observations in primary PDAC specimens, we observed clear distinctions at the RNA level of the basal-like and classic subtypes (ref. 14; Fig. 3A). However, samples with low neoplastic cellularity were more difficult to classify with the basal-like and classic subtype gene sets, and several of these samples showed a strong association with gene expression from normal liver tissue (Fig. 3A and B; Supplementary Fig. S5A), suggesting that the biopsy may have captured primarily adjacent liver parenchyma rather than the target tumor lesion. Moreover, integrated analysis of tumor and normal gene expression enabled clustering of samples by tumor-specific subtype and site of biopsy as well as identification of outlier samples based on tumor type, atypical genetic lesions, or predominant contribution from adjacent normal or stromal gene expression (Supplementary Fig. S5B).

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Figure 3.

PDAC gene expression signatures in the biopsy cohort. A, Heat map showing each sample as a column, with rows displaying gene sets defining the Moffitt basal-like (orange bar) and classic (blue bar) PDAC gene expression programs (14). Tracks at the top also show anatomic site and ABSOLUTE purity by WES of the sample. To the right of the main biopsy heat map, samples with low tumor content (middle) and samples from resected cases (rightmost) are shown. B, Liver gene expression score (y-axis) is plotted versus the ABSOLUTE purity of each sample (x-axis). The linear regression shown includes only samples from the liver. C, A composite stromal score is displayed for each sample, with samples binned according to the biopsy site. Box plots represent first, second, and third quartiles, and whiskers depict the furthest sample from the median which is within 1.5 times the interquartile range.

In addition to neoplastic subtypes of PDAC, two stromal subtypes have been identified: “normal” and “activated” stromal subtypes (14). To capture a single composite stroma signature, we generated a merged “stroma score” reflecting the combined total expression of the top 25 activated and top 25 normal expressed stroma genes. Notably, biopsies from metastatic liver lesions on average demonstrated lower stroma scores than those from other sites or compared with primary tumor resection specimens (Fig. 3C). Comparison of ABSOLUTE neoplastic cellularity derived from WES revealed a trend toward higher neoplastic cellularity for liver lesions (mean 0.39) versus pancreatic biopsies or resections (mean 0.30; two sample t test, P = 0.07; Supplementary Fig. S2B). Despite liver metastases showing on average lower stroma scores, many samples did show elevated scores at a level similar to those seen in primary resections or biopsies of other sites. Thus, the stroma score shows important differences according to site of biopsy but also significant interpatient variability within each biopsy site.

Clinically Relevant Genomic Events

Genomic analyses of primary specimens have suggested that approximately 40% of patients with PDAC may harbor clinically relevant genomic events that could potentially affect treatment decisions (12). However, most patients with PDAC do not undergo timely genomic analysis to identify these events for clinical decision-making. Leveraging our rapid turnaround CLIA-certified sequencing program, we performed real-time assessment of genomic data for use in clinical decision-making (Supplementary Fig. S6A; Supplementary Table S4). Excluding common events in KRAS or CDKN2A, 48% (34/71) of patients within this cohort had cancers with at least one genomic alteration that could potentially confer eligibility for current clinical trials or support off-label usage of an agent approved for another indication (Supplementary Fig. S6A). Furthermore, 11% (8/71) of the patients had cancers with two or more such events, suggesting a potential basis for genotype-driven combination therapy trials.

KRAS mutations were observed in 90% (64/71) of patients in our cohort. Although this alteration has been used to enroll patients onto clinical trials of MAPK-directed therapy, these trials have demonstrated limited efficacy to date (22). However, in the subset of KRAS wild-type tumors, we observed mutations and CNAs in additional MAPK pathway activating genes, such as BRAF mutations (see below), a ROS1 translocation and high-level FGFR1 amplification (Fig. 1; Supplementary Fig. S6A). Across the entire cohort, we observed multiple other alterations that could warrant experimental therapies, including RNF43 mutation (e.g., porcupine inhibitor), AKT2 amplification (e.g., AKT inhibitor), TSC2 mutation (e.g., MTOR inhibitor), MYC amplification (e.g., bromodomain inhibitor), and CDK4 amplification (e.g., CDK4 inhibitor; Supplementary Fig. S6A). Moreover, sequencing identified other lesions that may contraindicate therapy with certain agents, such as RB1 mutations (n = 4 patients) and CDK4/6 inhibition.

A total of 24% (17/71) of patients enrolled on the PancSeq study were treated with an experimental agent, either through enrollment onto a clinical trial or through off-label use of an approved agent (Table 2). In particular, genomic information from WES dictated the choice of experimental agent in 15% (11/71) of cases. Moreover, 18% (13/71) of patients had a clinically relevant germline mutation necessitating referral for genetic counseling (Table 1). Thus, accounting for both new therapeutic options and genetic counseling indications, a total of 30% (21/71) of patients enrolled on the PancSeq protocol experienced a change in clinical management as a result of the obtained genomic data (Tables 1 and 2).

DDR Mutations and PARP Inhibitor Therapy

In 20% of patients, we observed germline and/or somatic alterations in one or more of the following DDR genes: BRCA1, BRCA2, PALB2, ATM, and CHEK2 (Fig. 1; Supplementary Fig. S6B). When considering mutations in a wider spectrum of genes across several DDR classes, as well as specific mutational signatures consistent with HRD, we identified a total of 44% (31/71) of patients displaying genomic evidence of potential DDR deficiency (Table 1; Supplementary Fig. S6B). DDR gene mutations may confer increased sensitivity to platinum chemotherapy (9). Moreover, BRCA1 or BRCA2 gene mutations have been reported to confer sensitivity to poly-ADP polymerase (PARP) inhibition in preclinical models and early clinical trials of PDAC (9, 23, 24). All 6 patients in the cohort with germline or somatic mutations in the BRCA1 or BRCA2 genes demonstrated evidence of the HRD/COSMIC3 mutational signature (Supplementary Fig. S6B). By contrast, none of the patients with mutations in ATM, ATR, or CHEK2 demonstrated enrichment of the HRD/COSMIC3 signature. All six patients with BRCA mutations received an oxaliplatin-based chemotherapy regimen (FOLFIRINOX or FOLFOX) in the first or second-line setting, and all demonstrated some degree of radiographic response to these regimens (Fig. 1; Supplementary Table S4). Two of these patients with a germline BRCA1 mutation were subsequently enrolled onto a randomized trial of the PARP inhibitor olaparib versus placebo for maintenance therapy after receipt of 4 to 6 months of FOLFIRINOX (NCT02184195). Two further patients with a BRCA2 mutation received off-label olaparib, including 1 patient with a germline mutation and 1 with a somatic mutation. Besides patients with these BRCA1/2 mutations, 2 other patients with DDR gene mutations were treated with a PARP inhibitor (Table 2). Eight of 10 patients with ATM, ATR or CHEK2 mutations were treated with an oxaliplatin-based chemotherapy regimen and 5 patients demonstrated clinical benefit as defined by partial response or stable disease at first radiographic follow-up scans.

As noted above, 2 patients with BRCA2 alterations were treated with off-label olaparib. The patient harboring a somatic BRCA2 mutation was a 45-year-old man who presented with jaundice and abdominal pain and was diagnosed with metastatic PDAC involving the liver and lymph nodes, with a serum CA19–9 of 3,592 U/mL on presentation. He underwent biopsy of a metastatic liver lesion which confirmed a poorly differentiated PDAC. Genome sequencing on the PancSeq protocol revealed KRAS (p.G12R), TP53 (p.M246fs), and somatic BRCA2 (p.LS298fs) mutations (Fig. 4A). He received first-line therapy with the platinum-containing regimen FOLFIRINOX and experienced normalization of serum CA19-9 levels (Fig. 4B) and a complete radiographic response to therapy within 5 months of treatment (Fig. 4C). FOLFIRINOX was discontinued after a total of 13 two-week cycles due to transaminitis and neuropathy. The patient chose to forego further cytotoxic chemotherapy and was initiated on off-label olaparib 300 mg twice daily as maintenance therapy. He remains free of radiographically detectable disease 28 months after diagnosis and 20 months after beginning olaparib (Fig. 4C).

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Figure 4.

Patient with somatic BRCA2-mutant PDAC demonstrates a radiographic complete response to platinum chemotherapy and subsequent olaparib maintenance therapy. A, A 45-year-old man presented with jaundice and abdominal pain, was diagnosed with metastatic PDAC involving the liver and lymph nodes, and underwent the depicted treatment course. B, Serum CA19-9 measurements from diagnosis throughout the patient's treatment course. The arrow indicates transition from FOLFIRINOX chemotherapy to olaparib (PARP inhibitor) maintenance therapy. C, Computed tomography (CT) scans are shown at diagnosis demonstrating liver metastases (left; yellow arrows) and at the time of cessation of FOLFIRINOX chemotherapy (middle) with resolution of liver metastases. Hepatic toxicity of FOLFIRINOX resulted in fatty infiltration of the liver, as noted by severe diffuse attenuation of the liver parenchyma seen in the 5-month scan. Areas of focal fat sparing in this scan represent treatment effect at the site of liver metastases (middle; yellow arrow), denoting a complete response to therapy. The follow-up magnetic resonance imaging scan at 21 months after diagnosis, on olaparib maintenance therapy for 13 months, is shown with complete regression of liver metastases (right). The patient remains on olaparib therapy without evidence of disease now 28 months after diagnosis.

BRAF-Mutant PDAC and Response to MAPK Inhibition

Within our CLIA-certified cohort, we discovered 2 patients with in-frame deletions in the BRAF oncogene (Fig. 5A). This class of deletions near the alphaC-helix region of the kinase domain has recently been shown to occur in KRAS wild-type PDAC and activates the protein to drive MAPK signaling (12, 25, 26). Furthermore, PDAC cell lines grown in vitro or as in vivo xenografts have been shown to be sensitive to MAPK inhibition, although this approach had not been tested in humans (26). To further define the frequency of this BRAF alteration in PDAC, we investigated a larger collection of samples (N = 406) profiled with a targeted genome sequencing panel at Dana-Farber Cancer Institute (27, 28) and found four KRAS wild-type tumors that harbored the same in-frame deletion (p.N486_P490del) and one additional KRAS wild-type tumor with a small, likely oncogenic in-frame insertion (p.T599dup). Thus, BRAF in-frame insertions or deletions occurred in approximately 10% of our patients with KRAS wild-type PDAC or 1% of all patients with PDAC (12, 25, 26).

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Figure 5.

BRAF in-frame deletion confers response to MAPK inhibition. A, An in-frame deletion in BRAF was identified leading to a five amino acid deletion in the kinase domain. B, A 66-year-old woman presented with dyspepsia and weight loss and was diagnosed with PDAC and liver metastases and underwent the indicated treatment course. Gem/nab-pac, gemcitabine + nab-paclitaxel. C, CT scans of the liver (large panels) and primary tumor (small panels) at diagnosis (left) and at the time of first restaging scan after 8 weeks of treatment (right) showing partial response to trametinib. D, Serum CA19-9 levels measured throughout the patient's disease course reflect response and resistance to each therapeutic regimen (color coded by regimen). E, Cell-free DNA (cfDNA) measurements for the indicated alleles obtained through ddPCR (BRAF and TP53 alleles) or Guardant360 assay (MEK2 alleles) on plasma collected throughout the patient's treatment course with trametinib and ulixertinib. Top panel depicts the overall mutant allele fraction of each allele in cfDNA. The bottom panel shows the relative frequency of the MEK2 resistance alleles compared with the overall tumor burden (as measured by the total MEK2/TP53 ratio).

In one case, a 66-year-old woman presented with dyspepsia and weight loss and was diagnosed with PDAC and liver metastases. She underwent first-line therapy with FOLFIRINOX but experienced progression of disease after only 5 two-week cycles. She underwent a biopsy and WES on the PancSeq protocol and then began second-line therapy with gemcitabine plus nab-paclitaxel that was discontinued after 6 four-week cycles due to disease progression (Fig. 5B). Sequencing revealed a BRAF in-frame deletion (p.N486-P490del) and TP53 mutation (p.V157G; Fig. 5A and B). Given that cell lines harboring this mutation were sensitive to MEK inhibitors but resistant to selective BRAF inhibitors in preclinical models (26), she was initiated on off-label treatment with the MEK1/2 inhibitor trametinib, which is FDA approved for use in BRAF^V600E-mutant melanoma (Fig. 5B; refs. 29–31). Within 4 weeks of initiating therapy, her serum CA19-9 had fallen from 36,000 to 8,100 U/mL, and the first restaging scan done 8 weeks after initiation of trametinib showed a partial response to therapy (Fig. 5C and D). Serial plasma samples were collected to measure the fractional abundance of BRAF- and TP53-mutant alleles in circulating cell-free DNA (cfDNA) by droplet-digital PCR (ddPCR; refs. 32, 33). cfDNA measurements for BRAF and TP53 alleles (two clonal alterations in this tumor) revealed a dramatic decline in response to trametinib therapy that mirrored the radiographic findings (Fig. 5E). After 5 months on trametinib therapy, a rise in the fractional abundance of the BRAF- and TP53-mutant alleles in cfDNA was observed. After 6 months of therapy, radiographic progression was identified. Evaluation of a more comprehensive panel of genes within cfDNA was pursued through a commercial test (Guardant360) at the time of progression and demonstrated the emergence of multiple subclonal mutations in the MAP2K2 (MEK2) gene (Fig. 5E). Notably, these mutations are homologous to MEK1 mutations that have been previously described to confer resistance to MEK inhibition in vitro in mutagenesis studies in BRAF-mutant melanoma (34). Retrospective analysis of the MEK2 mutations in serial plasma samples collected through the patient's treatment course revealed emergence of these mutant alelles in concert with increases in fractional abundance of mutant BRAF and TP53 alleles (Fig. 5E). Thus, these data likely reflect the emergence of heterogeneous polyclonal resistance mechanisms that evolved under the selective pressure of trametinib therapy.

Given the emergence of MAP2K2 resistance mutations while on trametinib therapy, the patient was subsequently treated with ulixertinib/BVD-523, an inhibitor of ERK1/2 (which signals downstream of MEK1/2), on a single-patient investigational new drug application. After treatment with ulixertinib/BVD-523 for 17 days, cfDNA analysis by ddPCR demonstrated a rapid decline in the fractional abundance of the BRAF- and TP53-mutant alleles (Fig. 5E). The MEK2 resistance alleles also rapidly decreased in absolute frequency and in relative abundance with respect to the overall tumor burden (as measured by the total MEK2/TP53 ratio; Fig. 5E). Unfortunately, the patient's functional status was quickly declining as she initiated therapy with ulixertinib/BVD-523, and this medication was stopped after 3 weeks of therapy. A last blood collection after cessation of ulixertinib/BVD-523 demonstrated rebound of the fractional abundance of the BRAF- and TP53-mutant alleles. The patient expired at home several weeks later with hospice services. This patient's clinical course suggests that a BRAF in-frame deletion may serve as an important biomarker for response to MAPK inhibition in patients with pancreatic cancer.