Abstract
Understanding resistance to selective FGFR inhibitors is crucial to improve the clinical outcomes of patients with FGFR2-driven malignancies.
We analyzed sequential ctDNA, ± whole-exome sequencing, or targeted next-generation sequencing on tissue biopsies from patients with tumors harboring activating FGFR2 alterations progressing on pan-FGFR–selective inhibitors, collected in the prospective UNLOCK program. FGFR2::BICC1 Ba/F3 and patient-derived xenograft models were used for functional studies.
Thirty-six patients were included. In cholangiocarcinoma, at resistance to both reversible inhibitors (e.g., pemigatinib and erdafitinib) and the irreversible inhibitor futibatinib, polyclonal FGFR2 kinase domain mutations were frequent (14/27 patients). Tumors other than cholangiocarcinoma shared the same mutated FGFR2 residues, but polyclonality was rare (1/9 patients). At resistance to reversible inhibitors, 14 residues in the FGFR2 kinase domain were mutated—after futibatinib, only the molecular brake N550 and the gatekeeper V565. Off-target alterations in PI3K/mTOR and MAPK pathways were found in 11 patients, often together with on-target mutations. At progression to a first FGFR inhibitor, 12 patients received futibatinib or lirafugratinib (irreversible inhibitors), with variable clinical outcomes depending on previous resistance mechanisms. Two patients with TSC1 or PIK3CA mutations benefited from everolimus. In cell viability assays on Ba/F3 and in pharmacologic studies on patient-derived xenografts, irreversible inhibitors retained better activity against FGFR2 kinase domain mutations, with lirafugratinib active against the recalcitrant V565L/F/Y.
At progression to FGFR inhibitors, FGFR2-driven malignancies are characterized by high intra- and interpatient molecular heterogeneity, particularly in cholangiocarcinoma. Resistance to FGFR inhibitors can be overcome by sequential, molecularly oriented treatment strategies across FGFR2-driven tumors.
The clinical benefit generated by selective FGFR inhibitors in patients with FGFR2-driven cancer is hampered by the inevitable occurrence of resistance. We analyzed postprogression ctDNA and tissue biopsies from 36 patients suffering from FGFR2-driven cholangiocarcinoma or other tumor types, at resistance to FGFR inhibitors. We were therefore able to recognize molecular traits and characteristics of resistance to reversible inhibitors versus the irreversible agent futibatinib, especially in terms of variety of FGFR2 kinase domain mutations involved in resistance. Compared with FGFR2-driven cholangiocarcinomas, polyclonal FGFR2 kinase domain mutations were less frequent in other tumor types. Twelve patients were treated with an additional FGFR irreversible inhibitor (futibatinib or lirafugratinib), and two derived benefit from everolimus. We integrated longitudinal molecular data with the clinical outcomes on these sequential targeted treatments, with functional evidence using Ba/F3 cellular models and patient-derived xenografts, aiming to propose molecular treatment strategies to overcome resistance.
Introduction
Molecular alterations of FGFR family members (FGFR1/2/3/4) are frequent across cancers (1, 2). FGFR amplifications are the most frequent alterations observed, yet their inconsistent oncogenic potential raises questions about their suitability as targets for selective inhibition (3). FGFR2 gene fusions occur in 10% to 15% of intrahepatic cholangiocarcinoma cases, whereas activating mutations in the extracellular domain account for only a minor fraction of this malignancy (4–6). Recent research has highlighted the importance of deletions in the extracellular domain and truncations in the intracellular C-terminal domain of FGFR2 as key drivers and therapeutic targets in intrahepatic cholangiocarcinoma (6, 7). Of note, the same molecular alterations can be found, with a lower incidence, across a variety of solid tumors, of almost any histology (7).
The development and availability of selective FGFR inhibitors for treating FGFR2-driven intrahepatic cholangiocarcinoma are transforming the therapeutic landscape for patients with this molecular subtype (8–10). Selective FGFR inhibitors can be categorized into reversible (e.g., infigratinib, pemigatinib, erdafitinib, derazantinib, zoligratinib, and fexagratinib) and irreversible (e.g., futibatinib and lirafugratinib), based on their binding to the tyrosine kinase domain. Erdafitinib has demonstrated effectiveness in inhibiting FGFR3 in urothelial cancer (11, 12) and shows activity across various FGFR2-driven tumors, reflecting the concept of molecularly driven, tumor-agnostic targeted therapy (13). Similarly, pemigatinib and the two irreversible FGFR inhibitors, initially developed for FGFR2-driven intrahepatic cholangiocarcinoma, have shown efficacy across multiple tumor types in dose-expansion cohorts of phase I/II clinical trials (14–17).
Studies have identified frequent on-target, polyclonal mutations in the tyrosine kinase domain of FGFR2 as common mechanisms of resistance to selective FGFR inhibitors in FGFR2-driven cholangiocarcinoma (18, 19). These findings are supported by functional validation of specific FGFR2 kinase domain mutations that confer resistance, with irreversible FGFR inhibitors designed to be effective against these mutations (20–26). Recently, off-target resistance mechanisms have been explored; pathogenic variants in the MAPK and PI3K/mTOR pathways have been detected at progression on selective FGFR inhibitors in patients with cholangiocarcinoma (21, 23, 27).
Importantly, resistance to FGFR inhibitors in the setting of FGFR2-driven disease has been predominantly reported in cholangiocarcinoma, except in four cases of FGFR2-driven tumors that progressed on pemigatinib (15, 28). The broader application of FGFR inhibitors across different histologies underscores the need to identify and address resistance mechanisms in non-cholangiocarcinoma tumors, potentially offering universal strategies to counteract resistance.
In this study, we report on- and off-target resistance mechanisms to reversible and irreversible FGFR inhibitors across FGFR2-driven tumor types, validated through functional studies. Furthermore, the outcomes from sequential molecular treatments, applied to one-third of the patients with longitudinal monitoring of molecular alterations, provide insights into strategies to overcome resistance across a spectrum of FGFR2-driven solid tumors.
Materials and Methods
Patients and treatments
UNLOCK is an institutional program which aims to decipher mechanisms of action and resistance to innovative drugs
To be included in this cohort of the UNLOCK program, patients had to satisfy the following criteria: (i) diagnosis of an advanced solid tumor requiring systemic treatment; (ii) molecular detection of an activating alteration (i.e., fusions/rearrangements and mutations) in the FGFR2 gene; (iii) having received a selective FGFR inhibitor, either reversible (pemigatinib, erdafitinib, infigratinib, derazantinib, zoligratinib, rogaratinib, and fexagratinib) or irreversible (futibatinib or lirafugratinib); and (iv) having postprogression molecular analyses performed on ctDNA and/or tissue biopsies. In two cases showing primary resistance to futibatinib (ST4455 and MR719), in the lack of the availability of postprogression samples, pretreatment tissue biopsy and ctDNA were analyzed.
The molecular analyses were performed within four institutional studies at Gustave Roussy, whose aim is the molecular characterization of tumors: MATCH-R (NCT02517892; ref. 29), MOSCATO (NCT01566019; ref. 30), STING (NCT04932525), and CTC (NCT02666612).
Patients were treated in the setting of clinical trials or compassionate use programs allowing treatment with FGFR inhibitors on the basis of molecular selection. Disease response was measured according to RECIST 1.1, and progression-free survival (PFS) was calculated from the date of targeted inhibitor start to the day of radiologic evidence of progression.
All patients participating in the mentioned studies were fully informed and signed a written informed consent. The studies have been approved by ethics committees in France (French National Agency for Medicines and Health Products Safety) and are being conducted in accordance with the Declaration of Helsinki.
Molecular analyses
Postprogression tissue biopsies, when possible, underwent whole-exome sequencing (WES), with or without concomitant RNA sequencing (RNA-seq). The lower limit for WES performance was a proportion of tumor cells ≥30% in the tissue sample. In cases with a proportion of tumor cells between 10% and 30%, molecular analyses with targeted next-generation sequencing panels (Mosc-4, Oncomine v3) were performed. For WES, the mean coverage was 140×.
With regard to ctDNA analyses, they were performed with Guardant Health, Illumina, Foundation Medicine, or IntegraGen liquid biopsy panels. For each patient with longitudinal ctDNA assessment, only analyses performed with the same platform were reported.
Site-directed mutagenesis
Lentiviral vectors expressing FGFR2:BICC1 fusions were created using the pLenti6/V5 directional TOPO Cloning Kit (#K495510, Thermo Fisher Scientific) according to the manufacturer’s instructions. Point mutations in the FGFR2 kinase domain of the FGFR2::BICC1 fusion were introduced using the QuickChange XL Site-Directed Mutagenesis Kit (#200516, Agilent) according to the manufacturer’s protocol.
Cell lines
Ba/F3 cells were infected with lentiviral constructs, as reported previously (33), to express the FGFR2::BICC1 fusion, this latter with or without FGFR2 kinase domain mutations. Ba/F3 cells harboring the fusion were selected in the presence of blasticidin (14 μg/mL) and IL3 (0.5 ng/mL) until recovery, and a second selection by culturing the cells in the absence of IL3. FGFR2 fusion and FGFR2 kinase domain mutations were confirmed on the established cell lines by Sanger sequencing. The cells were not tested for Mycoplasma contamination, but cells were not maintained in culture for more than 2 months after establishment or thawing.
Cell viability assays were performed in 96-well plates using the CellTiter Glo Luminescent Cell Viability Assay (G7570, Promega). We seeded 4,000 cells/well, and we treated cells for 48 hours. IC50 values were derived using GraphPad Prism software.
Reagents
Lirafugratinib was provided by Relay Therapeutics. Erdafitinib, infigratinib, fexagratinib, zoligratinib, derazantinib, and futibatinib were purchased from Selleck Chemicals. Pemigatinib and rogaratinib were purchased from MedChemExpress.
Development of patient-derived xenografts and in vivo pharmacologic studies
All animal procedures and studies have been approved by the French Ministry of “Enseignement supérieur, de la Recherche et de lʼInnovation” (APAFIS#2790-2015112015055793 and APAFIS#2328-2015101914074846). Fresh tumor fragments were implanted in the subrenal capsule of 6-week-old female NOD/SCID gamma mice obtained from Charles River Laboratories. Patient-derived xenograft (PDX)–bearing NOD/SCID gamma mice were treated with the indicated doses of pemigatinib, erdafitinib, futibatinib, and lirafugratinib. Eight mice per group were treated for up to 50 days, and tumor volume and mouse weight were measured twice weekly.
Data availability
WES/RNA-seq raw data files from this study are deposited at the European Genome–phenome Archive (EGA) using the accession code EGAD50000000439. Access to this shared dataset is controlled by the institutional Data Access Committee, and requests for access can be sent to the corresponding author. Further information about EGA can be found at https://ega-archive.org/. Any additional information required to reanalyze the data reported in this article is available upon request from the corresponding author.
Results
Patient population and molecular treatments
We studied 36 patients with advanced solid tumors driven by FGFR2, all of whom were progressing on selective FGFR inhibitors (Supplementary Table S1). This cohort included 27 patients with intrahepatic cholangiocarcinoma and nine patients with various other tumor types: two with high-grade serous ovarian cancer, and one each with lung adenocarcinoma, urothelial cancer, triple-negative breast cancer, duodenal cancer, pancreatic ductal adenocarcinoma, adrenocortical carcinoma, and cancer of unknown primary. The majority, 31 patients, had tumors harboring FGFR2 fusions, whereas five had tumors driven by FGFR2 mutations located in the extracellular domain (specifically, three with FGFR2 C383R, one with FGFR2 S267P, and one with FGFR2 Y376C). FGFR2 fusion partners included BICC1 in five cases (all in intrahepatic cholangiocarcinomas), TACC2 in three cases (n = 1 intrahepatic cholangiocarcinoma, n = 2 other tumor types), and STRN4 and CCSSER2 in two cases, one from each cohort. Other unique fusion partners were found in the remaining 19 tumors, detailed in Supplementary Tables S2 and S3.
Twenty-three patients received a reversible FGFR inhibitor (n = 13 pemigatinib, n = 8 erdafitinib, n = 1 derazantinib, n = 1 zoligratinib), and 13 the irreversible inhibitor futibatinib (Supplementary Table S1). In the cholangiocarcinoma group, patients treated with reversible inhibitors and futibatinib showed 61% and 67% objective response rate, with median PFS of 8.7 and 11.1 months, respectively (Supplementary Table S4). Given the diversity in tumor origin, detailed clinical data of the non-cholangiocarcinoma patients are provided in Supplementary Table S3.
All patients underwent postprogression ctDNA analysis. Twenty-one of them had further molecular analyses performed on postprogression tissue biopsies, 16 via WES with or without RNA-seq, and five via targeted next-generation sequencing.
After disease progression on the first FGFR inhibitor, 12 patients received sequential targeted treatments. Eight patients with cholangiocarcinoma received futibatinib following a reversible inhibitor, with three receiving the mTOR inhibitor everolimus based on molecular findings. Two patients with cholangiocarcinoma and two with other tumor types, progressing respectively on pemigatinib and futibatinib, were switched to the FGFR2-selective inhibitor lirafugratinib (Supplementary Table S1).
Molecular alterations observed at resistance to selective FGFR inhibitors
In order to better approach the specificities of resistance mechanisms to reversible inhibitors versus the irreversible inhibitor futibatinib, and between intrahepatic cholangiocarcinoma and other tumor types, we separated below the different groups of patients analyzed at progression after a first FGFR inhibitor.
Intrahepatic cholangiocarcinoma on reversible inhibitors
The molecular alterations detected in 17 patients with intrahepatic cholangiocarcinoma progressing on reversible inhibitors are reported in Fig. 1A. Polyclonal kinase domain mutations (≥2 FGFR2 mutations in the same blood sample) were detected in 10 of these patients (59%).
In three additional patients, a single FGFR2 mutation was detected either in the tissue biopsy (MR408 and MR313) or in ctDNA (MR822; FGFR2 N550T). Specifically, FGFR2 D651H was detected in both pre- and posttreatment biopsies of one patient (MR313). Another unique case (MR488) had two concurrent FGFR2 kinase domain mutations in a single tissue biopsy (E566A and K642R). Concurrent pathogenic alterations in the MAPK and PI3K/mTOR pathways, suggesting off-target resistance mechanisms, were observed in five patients.
Other tumor types on reversible inhibitors
Five patients with non-cholangiocarcinoma FGFR2-driven tumors exhibited diverse resistance patterns after initial tumor shrinkage (Fig. 1B).
FGFR2 kinase domain mutations were detected in three of these patients, with one exhibiting polyclonal mutation. The latter (patient ST1056) was a FGFR2::TACC2 rearranged lung adenocarcinoma that progressed on erdafitinib with FGFR2 N550K, V565L/F, C632Y, D651Y mutations, as well as KRAS G12A (Fig. 1C; Supplementary Fig. S1).
Intrahepatic cholangiocarcinoma on futibatinib
Among nine patients with intrahepatic cholangiocarcinoma progressing on futibatinib, fewer FGFR2 kinase domain mutations were observed than in those on reversible inhibitors, involving key regions like the molecular brake (N550) and gatekeeper (V565; Fig. 2A). Only three patients had polyclonal mutations, which were limited to N550K and V565F/L/Y.
One patient (MR553) showed pretreatment FGFR2 kinase domain mutations that disappeared during response and re-emerged at progression (Fig. 2B; Supplementary Fig. S2).
Interestingly, the patient MR332 first experienced an isolated bone progression, whose biopsy revealed a FGFR2 V565L mutation (not detectable in blood), followed by a hepatic progression harboring a FGFR2 V565F mutation (Fig. 2C).
Other tumor types on futibatinib
Global analysis of candidate resistance mechanisms
Comparing the spectrum of putative resistance mechanisms occurring in FGFR2-driven cholangiocarcinoma or other tumor types, we hypothesized that the two entities converged toward overlapping ways to escape targeted FGFR2 inhibition. We therefore pooled the molecular data of the two populations to allow a global view on resistance to a first FGFR inhibitor among FGFR2-driven tumor types (Fig. 3).
Across the 36 patients, 14 residues in the FGFR2 kinase domain (K527, G543, I549, N550, L551, A568, S569, V565, E566, L618, C623, K642, D651, and K660) were found mutated at progression. For six of them (N550, V565, E566, L618, D651, and K660), at least two possible substitutions were observed, thus representing 24 possible mutations (Fig. 3A). FGFR2 C623Y and L551F were the only mutations found exclusively in non-cholangiocarcinoma cases (Fig. 1B). FGFR2 C623Y has not previously been reported, whereas L551F has been described in the setting of cholangiocarcinoma progressing on infigratinib (19).
Polyclonal kinase domain mutations were detected in half (11/22) of the patients progressing on reversible inhibitors, almost exclusively with cholangiocarcinoma, whereas only three patients (23%) revealed polyclonal FGFR2 mutations after futibatinib (Fig. 3B and C). When assessable due to amplicon sizes, the polyclonal FGFR2 kinase domain mutations were always detected in trans (i.e., on different alleles).
Overall, 61 FGFR2 kinase domain mutations were detected after reversible inhibitors, whereas only nine mutations were observed after futibatinib (Fig. 3A). The most frequently mutated residues were the molecular brake N550 and the gatekeeper V565.
In 13/22 (59%) of the patients progressing on reversible inhibitors, at least one mutation affecting either of these two residues was found, whereas the two residues were comutated in eight cases (36%). N550 and V565 were also the residues with the highest number of different substitutions, as N550D/H/K/T and V565F/I/L. L618V/M occurred in nine cases, followed by E566 (E566A/G) that was mutated in six patients.
In contrast, the N550 and V565 residues were the unique sites of FGFR2 kinase domain mutations found at progression to futibatinib, namely N550K (n = 2), V565F (n = 2), V565L (n = 4), and V565Y (n = 1; Figs. 2A and 3A). Of note, the mentioned molecular brake and gatekeeper mutations have been previously reported, with the exception of FGFR2 V565Y (34). This mutation is a novel entity, emerging from a double-base substitution in the corresponding valine codon GTT, for which we hypothesize the sequential occurrence of single-nucleotide substitutions, from V565F (F being coded by the codon TTT) to V565Y (Y being coded by TAT).
Off-target mutations that are potentially implicated in resistance, such as those affecting the MAPK (i.e., HRAS, KRAS, NRAS, and MEK) and PI3K/mTOR pathways (i.e., PIK3CA, PTEN, and TSC1), were found in 8/22 (36%) and 3/13 (23%) cases progressing on reversible inhibitors and futibatinib, respectively (Figs. 1A, B, 2A, 3B, and C). In eight patients (23%), these mutations co-occurred with FGFR2 kinase domain mutations. In two patients with other tumor types progressing on erdafitinib, they emerged without concomitant on-target alterations (Fig. 1B).
Sequential treatment strategies
Within our study cohort, 33% of the patients (n = 12, including 10 with intrahepatic cholangiocarcinoma and one each from pancreatic and duodenal cancers) underwent sequential targeted therapy regimens (with longitudinal sampling) that included irreversible FGFR inhibitors and the mTOR inhibitor everolimus.
Sequential treatments including futibatinib and everolimus
After progressing on reversible inhibitors, three patients with intrahepatic cholangiocarcinoma received a sequential treatment with futibatinib and everolimus based on specific molecular findings (Fig. 4A).
Patient MR379 suffered from a tumor harboring both FGFR2::BICC1 fusion and a TSC1 frameshift mutation in the baseline tissue sample. At progression to pemigatinib, the two alterations were found in ctDNA together with 13 different FGFR2 kinase domain mutations, KRAS and MEK1 mutations (Fig. 4B). Futibatinib did not induce any clinical benefit (stable disease; PFS 2.7 months), whereas everolimus, administered due to the TCS1 loss-of-function alteration, led to stable disease with a PFS of 7.6 months. The clinical benefit was accompanied by the reduction of the allele frequencies of all the alterations in ctDNA (Fig. 4B).
Patient MR422 experienced oligo-progression while on pemigatinib. A liver biopsy revealed a new FGFR2 V565I mutation alongside the preexisting FGFR2::PNX fusion and PIK3CA H1047R mutation (Fig. 4A and C). Despite continued progression, pemigatinib treatment was extended, resulting in increased variant allele frequency (VAF) of PIK3CA H1047R, FGFR2 V565I, N550H, and N550K mutations. Everolimus, initiated due to the PIK3CA mutation, provided stable disease for 11 months, corresponding to a decrease in the VAF of the documented mutations. Their VAF increased again at everolimus progression, and subsequent futibatinib administration allowed the achievement of disease stabilization with a PFS of 7.8 months.
Patient MR408 progressed to pemigatinib with an isolated lung nodule showing a FGFR2 N550K mutation and PTEN loss. Although everolimus showed no clinical activity, subsequent futibatinib treatment led to tumor shrinkage and a PFS of 7.2 months, despite the baseline documentation of a FGFR2 L618V mutation (Supplementary Fig. S3).
Sequential treatments with reversible FGFR inhibitors followed by futibatinib
Five additional patients with FGFR2-driven cholangiocarcinoma were treated with futibatinib after experiencing resistance to reversible FGFR inhibitors (Fig. 4D).
Two patients showed clinical benefit from futibatinib (MR586 and ST1748). Upon progression on futibatinib, FGFR2 V565F/L mutations were identified in patient ST1748, consistent with mutations typically seen in FGFR inhibitor–naïve patients. Three other patients experienced primary resistance to futibatinib after acquired resistance to reversible inhibitors. Of notice, FGFR2 N550D/K and V565L were present at futibatinib baseline in MR174, and could explain its lack of benefit (Fig. 4E).
Sequential treatments with lirafugratinib
Four patients received lirafugratinib after progressing on a previous inhibitor (pemigatinib or futibatinib), without other intervening therapies (Fig. 5A).
Lirafugratinib outcomes were divergent among the two patients with FGFR2-rearranged cholangiocarcinoma progressing on pemigatinib
Patient MR822, with a prolonged initial response to pemigatinib, developed an FGFR2 N550T mutation along with a persistent driver fusion FGFR2::WAC. Lirafugratinib treatment resulted in another prolonged response, highlighting its effectiveness against this specific mutation (Supplementary Fig. S4A). Patient ST3470 encountered primary progression on lirafugratinib despite no detectable FGFR2 kinase domain mutations in ctDNA, suggesting an alternative resistance mechanism (Fig. 5B). Importantly, three FGFR2 mutations V565L, E566G, and K660M present before lirafugratinib were lost at progression, suggesting their sensitivity to lirafugratinib.
Two other patients suffering from tumors other than cholangiocarcinoma also benefited from lirafugratinib after futibatinib progression (Fig. 5A).
Patient MR1271 suffered from a FGFR2::NEK1–driven duodenal carcinoma, who progressed on futibatinib with the acquisition of FGFR2 V565L in ctDNA, and the major disease response was observed with lirafugratinib (Fig. 5C).
Patient MR1154 suffered from a pancreatic carcinoma harboring FGFR2::CCSER2 fusion. No molecular events potentially implicated in resistance to futibatinib were detected, but FGFR2::CCSER2 VAF was no longer detectable 3 weeks after lirafugratinib initiation (Supplementary Fig. S4B).
FGFR2 kinase domain mutations exert a differential spectrum of resistance according to selective FGFR inhibitors
To explore how specific FGFR2 kinase domain mutations affect resistance to FGFR inhibitors, we used 18 Ba/F3 cell lines, engineered to express the FGFR2::BICC1 fusion with various secondary mutations. FGFR2::BICC1 was chosen, being the most frequent fusion observed in our cohort and in other series (35). We exposed each Ba/F3 cell line to increasing concentrations of seven selective, reversible FGFR inhibitors and to the irreversible agents futibatinib and lirafugratinib, in order to establish their IC50 values (Fig. 6A and B; Supplementary Fig. S5).
In our experiments, erdafitinib emerged as the most potent inhibitor across all mutants, followed closely by infigratinib and futibatinib, achieving sub-nanomolar IC50 values against the wild-type FGFR2::BICC1 Ba/F3 cell line (Fig. 6A and B).
The profiles of sensitivity and resistance conferred by individual FGFR2 kinase domain mutations matched with the spectrum of mutations emerging in patients treated with either reversible agents or futibatinib, respectively (Figs. 3A, 6A, and B). FGFR2 D651H did not confer resistance to any of the inhibitors, suggesting its role as a passenger event in patient MR313.
A significant finding from our study was the variable resistance patterns conferred by mutations at key residues within FGFR2, notably the molecular brake N550 and the gatekeeper V565. Mutations at these sites—N550K and V565F/L/Y—broadly conferred resistance across several reversible inhibitors, casting doubt on the effectiveness of using these drugs sequentially in patients with these mutations. However, other mutations like N550T and V565I seemed to result in a lesser degree of resistance. Interestingly, zoligratinib demonstrated relatively lower IC50 values against V565F/Y mutations than those against V565I/L, indicating specific interactions between the inhibitor and variant amino acids at this site.
The irreversible inhibitors generally showed superior activity compared with reversible agents in our Ba/F3 models. Both futibatinib and lirafugratinib exhibited efficacy within the 2 to 20 nmol/L range against various mutations, although they displayed slight differences in activity against certain mutations. Notably, lirafugratinib was particularly effective against FGFR2 V565F/Y mutations, in which futibatinib showed reduced activity due to steric hindrances from bulky amino acids like phenylalanine and tyrosine (IC50 > 200 nmol/L; refs. 25, 36). In contrast, the two irreversible inhibitors showed an opposite profile of activity against FGFR2 V565I and V565L mutants, with futibatinib being more active on V565I and lirafugratinib on V565L. The slight difference in the tridimensional structure between leucine (V565L) and isoleucine (V565I) likely explains the activity of the two inhibitors. In addition, FGFR2 V565I is known to increase basal activity of the kinase domain (37), and the higher potency of futibatinib could prevail in this setting.
The two irreversible inhibitors maintained an IC50 in the 10 to 20 nmol/L range for FGFR2 N550K, the most common mutation arising after a reversible inhibitor. Because FGFR2 N550K occurred in two patients progressing on futibatinib, and in five patients the gatekeeper FGFR2 V565L emerged (Figs. 2A and 4D), we suppose that these two mutations cannot be overcome with clinically achievable concentrations of the agent.
In order to further validate our in vitro preclinical analyses on more clinically relevant models in vivo, we established PDXs from biopsies of patients with cholangiocarcinoma, collected at the time of acquired resistance to FGFR inhibitors. We treated three PDX models with pemigatinib, erdafitinib, futibatinib, and lirafugratinib (Fig. 6C). The FGFR2 N550D mutation in MR174 PDX, established at progression to erdafitinib, could be overcome by futibatinib and lirafugratinib. In addition, a dose effect was noticed for lirafugratinib, with tumor growth abrogated only at the dose of 60 mg/kg (and not 20 mg/kg), which is in line with the IC50 observed in the Ba/F3 models. MR369 PDX, established at progression to pemigatinib, harbored a FGFR2 V565L mutation, whereas MR332 PDX, established at futibatinib resistance, harbored FGFR2 V565F (see Fig. 2C). In both cases, only lirafugratinib (even at low doses) was able to prevent tumor growth in this in vivo model, confirming our suggestion that gatekeeper mutations FGFR2 V565L/F can be difficult to overcome with futibatinib in the clinical setting, while retaining sensitivity to lirafugratinib.
Of note, two of the PDX models (MR174 and MR369) were established from patients progressing with polyclonal FGFR2 kinase domain mutations detected in ctDNA, but only one mutation was found in the corresponding tissue biopsy and PDX (Fig. 6C). These observations underscore the limitation of tissue biopsies to fully recapitulate the molecular spectrum of heterogeneity observed in patients at resistance.
Discussion
FGFR inhibition in FGFR2-driven malignancies marks a significant advance in precision oncology, emphasizing the need to understand molecular mechanisms behind drug resistance to develop new treatment strategies. Our study integrates extensive clinical and molecular data, along with in vitro and in vivo validation assays, to explore resistance mechanisms in patients with FGFR2-driven cancers, including cholangiocarcinoma and other tumor types.
Our findings confirm that polyclonality of FGFR2 kinase domain mutations is commonly observed in ctDNA from patients at progression on reversible inhibitors, particularly in cholangiocarcinoma (18–20). Indeed, FGFR2 kinase domain mutations were undetectable or found as isolated entities in tissue analyses, compared with multiple alterations in ctDNA, highlighting the “polyclonal” nature of tumor progression and the fundamental role of liquid over tissue biopsy. Interestingly, such mutations were less common after treatment with the irreversible inhibitor futibatinib, which primarily affected the molecular brake N550 and gatekeeper V565 residues.
Recently, Wu and colleagues (21) gathered data on resistance mechanisms in patients with FGFR2-driven cholangiocarcinoma, pooling evidence from published articles and meeting abstracts. In our study, we were able to differentiate between resistance to reversible inhibitors and futibatinib, providing clinical proof to their functional observations. As predicted by their evaluation of clinically achievable doses of futibatinib, in our cohort, FGFR2 N550K frequently emerged at progression to the irreversible agent. Interestingly, we did not detect any mutation in the binding site for irreversible inhibitors (FGFR2 C492), in line with the reduced cellular fitness caused by these mutations, which somehow suggests their limited frequency of occurrence, such as the FGFR2 C492F found in the patient reported by Berchuck and colleagues (32). On the other hand, FGFR2 V565L, labeled by Wu and colleagues as sensitive to futibatinib, was the mutation most frequently observed at progression to the irreversible inhibitor in our cohort.
Similarly, resistance mechanisms in tumors other than cholangiocarcinoma mirrored those observed in cholangiocarcinoma, involving known FGFR2 residues and off-target resistance mechanisms. If considering the nine patients with other tumor types in our cohort, together with the report from Nicolò and colleagues (ref. 28; FGFR2 V565L detected at pemigatinib progression in a patient with breast cancer), the emergence of polyclonal FGFR2 mutations was limited to only one patient with a lung adenocarcinoma progressing on erdafitinib (Fig. 1C). More recently nevertheless, Rodón and colleagues (15) detected polyclonal FGFR2 mutations in two patients with non-cholangiocarcinoma tumors progressing on pemigatinib. Nevertheless, the overall small number of patients with FGFR2-driven other tumor types evaluated at resistance challenges the conclusion that the propensity of developing polyclonal FGFR2 mutations is a feature more common in FGFR2-driven cholangiocarcinoma.
Furthermore, in concomitance with FGFR2 kinase domain mutations or not, alterations in genes of the PI3K/mTOR pathway were frequently present at progression to reversible inhibitors and futibatinib. Interestingly, in three patients, clinical benefit was obtained from reversible FGFR inhibitors or futibatinib, despite the presence of PI3K/mTOR alterations at baseline (MR379, MR422, and MR553), which were maintained at progression (Figs. 1A and 2A). In line with our clinical observations, Wu and colleagues (21) recently reported that the PI3KCA E545K mutation does not impact futibatinib sensitivity in the context of FGFR2-driven cholangiocarcinoma cell lines.
Here, the mTOR inhibitor everolimus provided clinical benefit in two patients with alterations in TSC1 or PIK3CA at progression to FGFR inhibition. The reduction in VAF of concomitant FGFR2 kinase domain mutations during everolimus treatment suggests that the on-target alterations probably emerged as an early event in a tumor clone already harboring the corresponding TSC1 or PI3KCA mutations (Fig. 4B and C). It therefore seems that the loss of function of TSC1 and the activation of PIK3CA do not represent the bona fide molecular mechanisms responsible for resistance to FGFR inhibitors, still explaining the clinical benefit from everolimus.
The enrichment in MAPK pathway alterations in a setting similar to ours has been recently reported by DiPeri and colleagues (27) in cholangiocarcinoma. Whether these mutations can be overcome by combination treatments in the clinical setting is still to be proven, as according to their data, only an in vitro synergistic effect of FGFR/MEK inhibition was achieved, with no meaningful effect in the in vivo model.
In the present study, irreversible inhibitors were also administered after progression to reversible ones in one third of the patients. We integrated the case-by-case analysis of the clinical response in the presence of precise FGFR2 kinase domain mutations, with the dynamics of resistance mutations in ctDNA during treatment sequencing, and exploring functional data in Ba/F3 cellular models and matched PDX models. Nevertheless, the unique complexity of FGFR2-driven tumors at progression to reversible inhibitors, in terms of high levels of molecular heterogeneity, hampers the definition of precise patterns of resistance suitable for the sequential treatment with an irreversible agent. This is in contrast with single on-target mutations in EGFR- and ALK-driven lung cancer, overcome by the respective third generation inhibitors in the clinical setting (38, 39). In our cohort and in line with other reports (6, 40), in case of progression to a first FGFR inhibitor (reversible or futibatinib) mediated by a unique FGFR2 kinase domain mutation, the clinical activity profiles of futibatinib and lirafugratinib corresponded well to our functional assessment. We were indeed able to overcome resistance to reversible inhibitors and futibatinib due to mutations occurring in the FGFR2 gatekeeper residue (FGFR2 V565F/L). In line with the initial proofs from Subbiah and colleagues (25), the FGFR2-selective inhibitor lirafugratinib was active in our Ba/F3 cellular models, PDX, and in patient MR1271 (FGFR2 V565L).
On the other hand, objective responses to futibatinib and lirafugratinib were observed even in cases with polyclonal FGFR2 kinase mutations (20, 25). The relative abundance of each individual resistance mutation at the baseline of the irreversible inhibitors is suspected to influence the clinical response on a systemic scale. Emblematic in this sense is the evolution of our patient ST3470, experiencing primary resistance to lirafugratinib despite clearance of three FGFR2 kinase domain mutations (Fig. 5B). Considering their better on-target activity, it is possible that progression to irreversible FGFR inhibitors occurs without detectable FGFR2 kinase domain mutations or off-target alterations, suggesting the implication of additional mechanisms, as indicated by the resistance study to futibatinib in our cohort (Fig. 3C).
Given the unpredictability of resistance mechanisms and the corresponding activity of irreversible inhibitors administered in a sequential way, their administration as first anti-FGFR agents seems appropriate, particularly considering the outcomes of clinical activity reported in clinical trials in this setting (9, 10). As shown here in two cases (Fig. 5), switching from an irreversible inhibitor to another can also be a suitable therapeutic option.
This study, however, is not without limitations. Primarily, it relies on genomic analyses, potentially overlooking nongenetic factors like epithelial–mesenchymal transition or activation of alternate resistance pathways, as recently reported for EGFR in FGFR2-driven cholangiocarcinoma (41, 42). Moreover, our focus is mainly on on-target resistance mechanisms, with less emphasis on proving the role of off-target events such as MAPK and PI3K/mTOR alterations. The lack of systematic tissue biopsy and ctDNA analysis at multiple timepoints for all patients may also have constrained the depth of our insights into resistance mechanisms. Finally, the lack of clinical data of resistance to lirafugratinib limits our observations of resistance to irreversible FGFR inhibitors.
In summary, the present work provides a global approach to apprehend resistance mechanisms to FGFR inhibitors across FGFR2-driven diseases, a clinical entity of major current interest given the development of active targeted agents. Our clinical and molecular findings are corroborated by functional analyses of FGFR2 kinase domain mutations in conferring resistance to different FGFR inhibitors. The additional clinical experience with sequential treatment with FGFR inhibitors or everolimus, together with the concomitant longitudinal study on resistance mechanisms, provides further valuable information both on the potential clinical management of patients and on the molecular correlates of resistance in this setting.
Authors’ Disclosures
F. Facchinetti reports personal fees from BeiGene outside the submitted work. Y. Loriot reports personal fees, nonfinancial support, and other support from Janssen during the conduct of the study, as well as personal fees, nonfinancial support, and other support from MSD, Pfizer, Merck KGaA, Astellas, Gilead, Bristol Myers Squibb, and Roche, nonfinancial support and other support from Incyte, other support from Exelixis, and personal fees and other support from Taiho outside the submitted work. S. Michiels reports personal fees from DSMB or scientific committee study membership for Kedrion, Biophytis, Servier, IQVIA, Yuhan, and Roche outside the submitted work. A. Italiano reports grants and personal fees from Bayer, IPSEN, Roche, and Bristol Myers Squibb and grants from MSD, Merck, AstraZeneca, and BeiGene outside the submitted work. C. Smolenschi reports personal fees from Servier and Merck, nonfinancial support from Astellas and Bristol Myers Squibb, and grants from Pierre Fabre outside the submitted work. L. Tselikas reports personal fees from Incyte during the conduct of the study, as well as personal fees from GE Healthcare, Quantum Surgical, and Boston Scientific outside the submitted work. B. Besse reports other support from AbbVie, BioNTech SE, Bristol Myers Squibb, Chugai Pharmaceutical, CureVac AG, Daiichi Sankyo, F. Hoffmann-La Roche Ltd, PharmaMar, Regeneron, Sanofi-Aventis, Turning Point Therapeutics, Eli Lilly and Company, Ellipses Pharma Ltd, Genmab, Immunocore, Janssen, MSD, Ose Immunotherapeutics, Owkin, Taiho Oncology, AstraZeneca, BeiGene, GlaxoSmithKline, Roche-Genentech, Takeda, Hedera Dx, and Springer Healthcare Ltd during the conduct of the study. F. André reports grants from AstraZeneca, Guardant Health, Novartis, Owkin, Pfizer, Eli Lilly and Company, Roche, and Daiichi Sankyo, other support from Boston Pharmaceutics, Gilead, and Servier, and grants and other support from N-Power Medicine outside the submitted work. A. Hollebecque reports personal fees and nonfinancial support from Amgen, personal fees from Basilea, Bristol Myers Squibb, Servier, Relay Therapeutics, Taiho, MSD, Seagen, grants and personal fees from Incyte, and nonfinancial support from Pierre Fabre outside the submitted work, as well as reports being a PI of the TransThera (Tinengotinib) phase III trial. L. Friboulet reports grants from Relay Therapeutics during the conduct of the study, as well as grants from Nuvalent and Sanofi outside the submitted work. No disclosures were reported by the other authors.
Authors’ Contributions
F. Facchinetti: Conceptualization, resources, data curation, formal analysis, investigation, visualization, methodology, writing–original draft. Y. Loriot: Resources, supervision, funding acquisition, investigation, methodology, writing–review and editing. F. Brayé: Resources, data curation, investigation. D. Vasseur: Resources, software, formal analysis, investigation, writing–review and editing. R. Bahleda: Resources. L. Bigot: Resources, investigation, writing–review and editing. R. Barbé: Resources, data curation, software, writing–review and editing. C. Nobre: Resources, investigation, writing–review and editing. D. Combarel: Data curation, validation, writing–review and editing. S. Michiels: Formal analysis, supervision, methodology, writing–review and editing. A. Italiano: Resources, writing–review and editing. C. Smolenschi: Resources, investigation, writing–review and editing. L. Tselikas: Resources, investigation, writing–review and editing. J.-Y. Scoazec: Resources, methodology, writing–review and editing. S. Ponce-Aix: Resources, investigation. B. Besse: Resources, funding acquisition, validation, methodology, writing–review and editing. F. André: Funding acquisition, validation. K.A. Olaussen: Supervision, validation, visualization, writing–review and editing. A. Hollebecque: Conceptualization, resources, funding acquisition, investigation. L. Friboulet: Conceptualization, resources, supervision, funding acquisition, validation, investigation, visualization, methodology, writing–review and editing.
Acknowledgments
We thank Illumina and Guardant Health for performing ctDNA sequencing analysis in the setting of an academic collaboration. The work of F. Facchinetti is supported by a grant from Philanthropia–Lombard Odier Foundation. The work of L. Friboulet is supported by an ERC Consolidator Grant (agreement number 101044047). Financial support was provided by Incyte, Debiopharm, and Relay Therapeutics.
Note: Supplementary data for this article are available at Clinical Cancer Research Online (http://clincancerres.aacrjournals.org/).