New targeted therapies have been heralded as ‘smart drugs’ that can be tailored to specific cancer subtypes without the adverse toxicity associated with standard chemotherapies. However, clinical studies of many targeted agents in solid tumours have generally failed to produce durable clinical responses, or cure, largely due to compensatory and redundancy mechanisms operating in complex tumours [1]. Thus, combinations of targeted agents may be more effective in treating solid tumours, assuming we can identify the signalling networks, often termed rewiring, that permit cancer cells to subvert the activity of single agents. Understanding dynamic compensatory bypass signalling mechanisms may be able to guide rational drug combinations; with the recent advances in sensitivity, throughput and resolution of transcriptomic and proteomic technologies, we are beginning to understand how chronic drug exposure rewires tumour cell signalling to permit survival. c-SRC (hereafter SRC) is the well-known prototype of a large family of nonreceptor tyrosine kinases that promotes cancer cell migration, invasion, proliferation and survival in different contexts [2,3]. SRC activation is widely observed in many types of cancer, such as in solid tumours arising from the colon, breast, lung, liver and pancreas. While SRC is rarely mutated in cancer, it often functions downstream of oncogenic drivers in signalling cascades including those initiated by receptor tyrosine kinases (RTKs) and at integrin-linked focal adhesions [4]. SRC has been a target for drug discovery projects for decades with multiple small-molecule ATP-competitive inhibitors being tested in clinical trials [2,5–11]. Dasatinib, a multi-kinase SRC inhibitor, is currently approved for the treatment of chronic myeloid and acute lymphoblastic leukaemias [12]. While phase I clinical trials have shown that most SRC inhibitors are well tolerated as single agents, trials have generally failed to show significant benefit in advanced solid cancers such as colorectal (for example, [9]), despite strong implicating evidence from preclinical data [13–18]. It is therefore becoming evident that preclinical models are failing to predict SRC inhibitor clinical efficacy, most likely because tumour cells are not solely dependent on SRC activity for survival and they can switch to other models of survival and growth signalling. Thus, more unbiased investigations of drugs across genetically distinct cancer cell models, incorporating 2-dimensional(D) and 3-D cell culture and in vivo systems, at both phenotypic and pathway network levels are needed to demonstrate drug sensitivity and resistance, and drug synergies.

Advanced solid tumours, such as metastatic colorectal cancer (CRC), are more likely to harbour combinations of activating mutations in oncogenic driver genes coupled with loss of function of tumour suppressor genes [19]; therefore, it is not surprising that a single-agent targeted therapy is unlikely to succeed. In addition, the tumour microenvironment can influence how tumour cells respond to targeted therapy [20,21]. Such genetic and environmental factors may better be overcome by using combinations of anti-cancer agents that target additional, compensatory or parallel signalling pathways [14,15,17,21].

EGFR is overexpressed in approximately 80% of CRCs and correlates with increased propensity to metastasis and decreased patient survival [19,22] and EGFR-targeted therapeutic monoclonal antibodies, cetuximab and panitumumab, are approved for the treatment of metastatic disease [23]. However, 35%–40% of CRC patients have activating mutations of RAS, most frequently of codons 12 or 13 of the KRAS isoform [24]. Mutation of KRAS bypasses EGFR signalling, nullifying anti-EGFR-targeted therapy and so patients with CRC tumours harbouring mutant RAS do not generally receive anti-EGFR therapy [25,26]. Cells treated with drugs targeting oncogenic RAS-RAF-MEK signalling can also exhibit inherent and acquired resistance [27]. Mechanisms in different contexts include reactivation of EGFR signalling following MAPK pathway blockade [23,28,29], reactivation of MAPK pathway itself [30], activation of parallel pathways (e.g. HER2, MET or PI3K) [31] or activation of focal adhesion kinase (FAK) to promote tumour cell survival [32]. Therefore, understanding how tumour cells respond to putative targeted therapies over time is important to predict how tumour cells escape and survive specific therapies and guide rational combination hypotheses for clinical testing.

AZD0424 is an orally available potent inhibitor of SRC and ABL with in vitro kinase inhibition of ~ 4 nm [6]. In a phase I clinical trial, SRC inhibition was achieved with daily doses ≥ 20mg AZD0424, though no responses were observed as a single agent and only 7 patients (16%) achieved stable disease of 6 weeks or more [6]. In this report, we characterise the effect of SRC inhibition by AZD0424 across preclinical models of breast, prostate and CRC cell lines. We demonstrate that AZD0424 induces a G1 cell cycle arrest in sensitive tumour cell lines, but it does not induce apoptosis. Using reverse-phase protein array (RPPA) analysis, we found that SRC signalling is activated in response to MAPK pathway inhibition by MEK inhibitors in HCT116 CRC cells. We show that in HCT116 cells simultaneous combination of MEK and SRC inhibitors can synergise to reduce cell viability in vitro and tumour growth in vivo. Finally, we show that while AZD0424 treatment does not resensitise trametinib-resistant HCT116 cells (TRAMR) to trametinib treatment with respect to inhibiting cell proliferation, combining AZD0424 and trametinib blocks cancer cell invasion.

All reagents were from Sigma-Aldrich (St. Louis, MO, USA) unless otherwise stated. Antibodies were from Cell Signalling Technologies (Danvers, MA, USA) unless otherwise stated.

HCT116, HKH2, DLD1 cell lines were provided by S. Van Schaeybroeck (Queens University Belfast, UK). Breast cancer cell lines (BT-549, HCC1954 and SKBR3) were provided by S. Langdon (University of Edinburgh, UK), and MDA-MB-231, PC3, LNCaP and DU145 cells were purchased from ATCC. Cell lines were cultured in DMEM supplemented with 10% FCS and 2 mm l-glutamine. TRAMR were generated by treating HCT116 cells with 5 nm trametinib for 2 months in culture and were routinely cultured in 5 nm trametinib thereafter. For experimental drug treatments, TRAMR cells were seeded without trametinib.

For cell viability assay, 1000–1500 cells were seeded per well of a 96-well plate and grown for 2 days to allow cells to reach exponential growth phase. Media was replaced containing drug with DMSO at a final concentration of 0.1%. Cells were incubated with compounds for 24–72 h; untreated cells were incubated with 0.1% DMSO.

MTT was added to a final concentration of 1 mg·mL⁻¹ or Alamar Blue added (10-fold dilution) and incubated for 3 h. For MTT assay, the media was removed, the formazan crystals solubilised in DMSO, and the optical density was measured at 490 nm on a Bio-Rad plate reader (Hercules, CA, USA). For the Alamar Blue assay and fluorescence emission was read on an EnVision 2101 multilabel plate reader (PerkinElmer, Waltham, MA, USA; excitation = 540 nm, emission = 590 nm). Results were day 0 subtracted and normalised to control wells for analysis in Prism (GraphPad, San Diego, CA, USA) to calculate EC50 values using a sigmoidal dose response (variable slope).

Following drug treatments, cells were fixed in 4% formaldehyde for 10 min, washed three times with PBS and permeabilised with 0.1% Triton X-100 for 5 min. Cells were labelled with Hoechst (final concentration 2 µg·mL⁻¹) for 30 min and finally washed three times with PBS. Hoechst-labelled nuclei were imaged on a ScanR microscope (Olympus) using a 20× objective, capturing ≥ 4 fields of view per well. Nuclei were classified into different stages of the cell cycle using the ScanR (Olympus, Southend-on-Sea, UK) analysis software.

Cells were seeded with IncuCyte^® Caspase-3/7 green apoptosis assay reagent (Sartorius, Royston, UK; #4440). Plates were imaged in an IncuCyte Zoom (Sartorius, Royston, UK) acquiring images every 3 h over a 72-h period using the ‘phase’ and ‘green’ channels. Images were analysed using the IncuCyte zoom software (Sartorius).

Organotypic co-cultures were performed as previously described [33]. Briefly, dermal fibroblasts were allowed to contract collagen gels over 6–8 days. Tumour cells (4 × 10⁴ cells per gel) were seeded on top of collagen/fibroblast gels. Collagen gels were moved to the air–liquid interface on top of a metal grid and allowed to proliferate/invade over a period of 7–9 days. Throughout cells were cultured in 10% FBS/DMEM. Collagen gels were fixed in paraformaldehyde, processed for paraffin embedding and sections cut and stained with H&E.

Experiments involving animals were carried out in accordance with the UK Coordinating Committee on Cancer Research guidelines by approved protocol (HO PL 70/8897). Briefly, mice were housed in individually vented cages (IVC) (Techniplast) and kept at 22 °C, 56% relative humidity and cleaned weekly. Mice were housed with Tapvei Aspen bedding with shredded tissue (Kleenex) nesting material, for environmental enrichment, an LBS aspen chew block and half dome home. Mice were given SDS RM1 diet and filtered water. Handling of mice was performed using either tube or cupping methods. For tumour formation, HCC1954 (5 × 10⁶), HCT116 (2 × 10⁶) or DLD1 cells (1 × 10⁶), suspended in Hank’s balanced salt solution, were subcutaneously injected into both flanks of 6- to 8-week-old female CD-1 Nude mice (Charles River) and allowed to form palpable tumours (> 50 mm³). Mice were randomised (4/5 per group) and dosed daily by oral gavage with AZD0424, trametinib or a combination made up in 80 mm citrate buffer, pH 3.1, supplemented with 10% cremophor EL/10% PEG400. Tumours were monitored twice weekly by calliper measurements and tumour volumes calculated using the following formula V = (W² × L)/2, where V is tumour volume, W is tumour width, and L is tumour length. Animals were sacrificed when tumours reached their maximum allowable size or when tumour ulceration occurred. Tumours were fixed overnight in formalin and processed for paraffin embedding and sections cut and stained for H&E using standard techniques.

Immunohistochemistry reagents were from DAKO (Agilent Technologies, Santa Clara, CA, USA). IHC was performed using standard techniques. Briefly, sections were de-waxed in xylene and antigen retrieval performed in 10 mm citrate buffer using a pressure cooker. Sections were blocked [Peroxidase Block Dako Kit (K4011) and Dako Total Protein Block (X0909)] and incubated with primary antibody overnight (SRC pTyr419 1 : 200, pERK1/2 1 : 400). Sections were washed in TBS and incubated with DAB reagent (#K3468) for 5 min, and finally, sections were counter-stained with eosin, dehydrated, and mounted using DPX mounting medium (#44581).

Cells were seeded in 6-well plates and allowed to grow over 2 days to ensure cells were in log phase growth. Drug was added in fresh media and cells were lysed in lysis buffer (1% Triton X-100, 50 mm HEPES, pH 7.4, 150 mm NaCl, 1.5 mm MgCl₂, 1 mm EGTA, 100 mm NaF, 10 mm Na₄P₂O₇, 1 mm sodium orthovanadate, 10% glycerol, containing freshly added protease and phosphatase inhibitor cocktails). Lysates were clarified by centrifugation and protein was normalised. Lysates, typically 30 µg, were resolved using 4%–15% Mini-PROTEAN^® TGX™ gels and transferred to Hybond-P 0.45µm PVDF membrane (GE Healthcare, Chicago, IL, USA). Membranes were blocked in Roche block and incubated with primary antibodies overnight or for 3 h at room temperature. Membranes were washed in TBS-Tween and incubated with anti-rabbit linked HRP secondary antibodies for an hour. Membranes were developed using the BM Chem-Lum substrate (POD) and imaged on a Bio-Rad ChemiDoc MP imaging system. Antibodies were used as per manufacturer’s instructions and listed in Table S1.

Quantitative protein expression and phosphorylation profiles were calculated using the Zeptosens reverse-phase protein microarray platform [34]. The Zeptosens method has been described previously [35]. Briefly, cells were rinsed x2 in PBS and lysed in CLB1 buffer (Zeptosens-Bayer Technology Services, Leverkusen, Germany) for 30 min and centrifuged in microcentrifuge at 21 000 × g for 5 min at room temperature. Supernatants were collected and subjected to total protein determination (Coomassie protein assay). Tumour lysates were normalised to a uniform protein concentration with spotting buffer CSBL1 (Zeptosens-Bayer Technology sevices) prior to preparing a final fivefold concentration series of 0.2; 0.15; 0.1 and 0.075 mg·mL⁻¹. The diluted concentration series of each sample was printed onto Zeptosens protein microarray chips (ZeptoChipTM, Zeptosens-Bayer) under environmentally controlled conditions (constant 50% humidity and 14OC temperature) using a non-contact printer (Nanoplotter 2.1e, GeSiM). A single 400 Pico litre droplet of each lysate concentration was deposited onto the Zeptosens chip in duplicate spots (thus representing 8 spots per single biological replicate). A reference grid of Alexa Fluor 647 conjugate BSA consisting of 4 columns by 22 rows was spotted onto each sub-array; each sample concentration series were spotted in between reference columns. After array printing, the arrays were blocked with an aerosol of BSA solution using a custom designed nebuliser device (ZeptoFOGTM, Zeptosen-Bayer) for 1 h. Blocked chips were rinsed extensively with water (Milli-Q quality) and dried by centrifugation at 200 × g for 5 min. Using the built-in micro flow Zeptocarrier system (Zeptosens), the arrays were incubated with different primary antibodies overnight at room temperature. After rinsing the system with assay buffer, the secondary detection antibody (anti-rabbit Alexa Fluor 647) was applied for 2.5 h at room temperature in the dark. The excess secondary antibody was removed by washing with assay buffer and fluorescence readout of the arrays was performed on the ZeptoReader (Zeptosens) at an extinction wavelength of 635 nm and an emission wavelength of 670 nm. The fluorescence signal was integrated over a period of 1–10 s, depending on the signal intensity. Array images were stored as 16-bit TIFF files and analysed with the ZeptoView Pro software package (version 3.1, Zeptosens). Each sample is spotted onto the microarray chip in 2 × 4 dilutions between Alexa Fluor conjugated BSA standards. Fluorescence intensity signals of each sample are calculated by optimised image analysis algorithms and normalised to intensity values of BSA standards through a local 2D quadratic function. A single relative fluorescence intensity (RFI) value is obtained by a weighted linear fit through sample dilutions. RPPA-validated antibodies used in the study can be found in Table S1 and data from RPPA studies can be found in Table S2.

For synergy calculations, normalised measurements were averaged (n from ≥ 3 independent experiments) and analysed using SynergyFinder [36] using the Bliss, Loewe and ZIP synergy models.

RNA was extracted from HCT116 and TRAMR cells using an RNAse Easy kit (QIAGEN, Hilden, Germany) as per the manufacturers protocol, normalised and equal amounts of the purified RNA, 100 ng were used as input for amplification-free RNA quantification by the NanoString nCounter Analysis System with the Human PanCancer pathways panels as previously described [37]. Raw counts were normalised to the internal positive controls and housekeeping genes, using the nSolver 4.0 software (NanoString, Seattle, WA, USA).

AZD0424 is an orally available inhibitor of SRC and ABL kinases (in vitro SRC kinase IC50 ~ 4 nm; [6]), similar to other SRC kinase inhibitors (saracatinib = 2.7 nm, dasatinib = 0.8 nm, bosutinib = 1.2 nm, eCF506 < 0.5 nm) [16,38–40]. We sought to first characterise AZD0424 phenotypic and pathway activity across a panel of cancer cell lines with a view to identifying potential indications for drug combination strategies. AZD0424 treatment over 72 h did not induce potent inhibition of proliferation of the majority of cell lines tested, 11 out of 16 cell lines had EC50 values > 5 µm and of the 5 sensitive cell lines only the colorectal cell line LS174t, displayed an EC50 < 1 µm (Fig. 1A). In our hands, LS174t cells displayed high sensitivity to many therapeutic classes in addition to AZD0424, potentially due to reported low expression and high promotor methylation of the ATP‑binding cassette sub‑family G member 2 (ABCG2) involved in drug resistance [41]. We therefore decided to further characterise AZD0424 in the three sensitive (MDA-MB-231, BT549 and HCC1954) breast cancer cell lines and one that was insensitive (SKBR3). Cell cycle profiling of breast cancer cell lines treated with a range of AZD0424 concentrations for 24 h revealed, at best, a modest G1-arrest at concentrations > 1 µm (Fig. 1B) and which is in agreement with other SRC inhibitors such as saracatinib or dasatinib [38,42]. Finally, we observed no change in the induction of apoptosis using an activated caspase 3/7 assay (Fig. 1C).

We next determined the ability of AZD0424 to inhibit cellular SRC kinase activity by performing RPPA analysis across compound dose–response and time-series studies performed in the breast cancer cell line panel (Fig. 2A). Increasing concentrations of AZD0424 rapidly elevated SRC protein levels within 3 h of treatment which was sustained over a 24-h period (Fig. 2B,C). Concomitantly, we observed a concentration-dependent decrease in SRC-family kinase activation, as measured by the phosphorylation of Tyr419 (Fig. 2B,C). AZD0424 induced SRC inhibition with a cellular EC50 of ~ 100 nm. RPPA profiling of AZD0424 response revealed a number of pathway markers that were also inhibited in a concentration-dependent manner demonstrating the wider impact of SRC inhibition on cellular signalling (Fig. 2D). AZD0424 treatment induced reduction of phosphorylation of the SRC kinase target STAT5 (Tyr694) in addition to EGFR family (Tyr1248/Tyr1173), PLCγ (Tyr783) and SHP2 (Tyr542) signalling.

Additionally, we tested the ability of AZD0424 to inhibit SRC activation and tumour growth of one of the sensitive breast cancer cell lines (HCC1954) in vivo. HCC1954 cells were injected subcutaneously into the flanks of CD-1 Nude mice and tumour-bearing mice were dosed with AZD0424 daily (Fig. S1). AZD0424 did not affect the growth of HCC1954 tumour xenografts even though SRC was effectively inhibited using daily dosing of mice with concentrations of ≥ 10 mg·kg⁻¹ (Fig. S1B). These studies clearly demonstrate that despite potent inhibition of intracellular SRC activity, AZD0424 has minimal impact upon cancer cell survival in these models.

As SRC inhibitors perform poorly as single anti-cancer agents in most cancers tested (for example [9]), we next sought to identify potential resistance mechanisms that rely upon SRC that could be targeted with drug combination therapy using AZD0424. To inform a phase I clinical trial containing predominantly patients with CRC (a total number of 19 CRC patients representing 47% of all patients recruited to this phase I trial [6]) for potential combination treatments with AZD0424, we applied RPPA to profile the response of four CRC cell lines with mutations in the KRAS gene, a common mutation in CRC, to treatment with the MEK inhibitor trametinib and AZD6244. Treatment of HCT116, and to a lesser extent of DLD1 cells, with trametinib or AZD6244 induced the activation of SRC, as measured by an increase in phosphorylation of Tyr419 (Fig. 3A–C). In addition, MEK inhibitor treatment also resulted in a compensatory induction in phosphorylation of a number of other proteins involved in EGFR/RTK signalling including STAT5 (Tyr694; Fig. 3A), EGFR (Tyr1068/Tyr1173; Fig. 3A,B), PLCγ (Tyr783; Fig. 3A,B), IGF-1R β (Tyr1162/Tyr1163; Fig. 3B) and SHP2 (Tyr542; Fig. 3A,B). Of these proteins, STAT5 [43], PLCγ [44] and SHP2 [45] are all targets of SRC while EGFR Tyr1068/Tyr1173 and IGF-1R β Tyr1162/1163 are receptor autophosphorylation sites whose phosphorylation can be promoted indirectly by SRC activity [46,47]. Notably, the activation of EGFR was greater in the DLD1 cells compared to the HCT116 cells. We next tested whether co-treatment with AZD0424 could inhibit the activation of compensatory signalling induced by either trametinib or AZD6244 in HCT116 or DLD1 cells (Fig. 3B). Treatment with either MEK inhibitor reduced the activation of ERK1/2 and also elevated phosphorylation of MEK1 (Ser21/Ser221) itself, and FAK (Tyr397). MEK inhibitor treatment also blocked the phosphorylation of S6 ribosomal protein and the cell cycle regulator Rb, characteristic of a cell cycle arrest. HCT116 and DLD1 cells treated with a combination of AZD0424 and a MEK inhibitor blocked the activation of EGFR, SHP2, PLCγ suggesting that reactivation of signalling through the EGFR pathway in response to MEK inhibition requires SRC activity. Combined AZD0424 and MEK inhibitor treatment of HCT116 and DLD1 cells did not block the autophosphorylation of FAK on Tyr397 as this is mediated by its own kinase function and so is independent of SRC activity [48]. However, MEK inhibitor treatment of HCT116, and to a lesser extent DLD1 cells, increased the phosphorylation of FAK on Tyr861, a SRC kinase substrate, which could be inhibited by AZD0424 treatment (Fig. 3C,D). Interestingly, the pattern of compensatory pathway signalling in response to MEK inhibitor treatment is cell type dependent and HCT116 and DLD1 cells displayed differences in their response to MEK inhibitor treatment; for example, HCT116 cells did not activate the EGFR pathway or activate AKT (phosphorylation of Ser473) as strongly as DLD1 cells (Fig. 3B,C).

Having confirmed that AZD0424 might block potential compensatory signalling induced by MEK inhibitors in KRAS-mutant HCT116 and DLD1 cells, we next tested whether the combination could reduce cell viability (Fig. 4A). Measurement of cell viability following inhibitor treatment revealed that DLD1 cells were resistant to MEK inhibitor treatment (trametinib, EC50 > 300 nm; AZD6244, EC50 > 3000 µm), HCT116 cells in contrast were sensitive (trametinib, EC50 = 1.5 nm; AZD6244, EC50 = 127 nm) consistent with previous reports [30,31]. Conversely, DLD1 cells were more sensitive to AZD0424 treatment than HCT116 (Fig. 4A), though at much higher concentrations (3 µm) than that required to inhibit cellular SRC (Fig. 2A). Treatment of cells with AZD0424 in combination with either trametinib or AZD6244 resulted in synergistic inhibition of cell viability at sub-µM doses in both cell lines (Fig. 4A,B). Finally, we confirmed that SRC inhibition using dasatinib in combination with either trametinib or AZD6244 also resulted in a synergistic inhibition of cell viability in both cell lines (Fig. S2A–C). Notably, the combination of AZD0424 or dasatinib with MEK inhibitors did not induce apoptosis in any of the cell lines tested (Fig. 3).

We next tested whether AZD0424 combined with MEK inhibitors could inhibit tumour growth in xenograft models using both DLD1 and HCT116 cells. Mice-bearing tumours formed by injecting HCT116 cells subcutaneously on the flanks of CD-1 nude mice were dosed by oral gavage daily with trametinib (Fig. S2D). Trametinib was very effective at blocking HCT116 tumour growth in a concentration-dependent manner and so we selected 0.3 mg·kg⁻¹ as a dose of trametinib that did not achieve complete growth inhibition to test in combination with AZD0424 (Fig. 4C). Treatment with AZD0424 alone had no effect on HCT116 or DLD1 tumour growth, while HCT116 tumours treated with AZD0424 in combination with 0.3 mg·kg⁻¹ trametinib showed a significant reduction of tumour growth compared to trametinib alone (Fig. 4C). Strikingly, DLD1 tumours were not only resistant to treatment with AZD0424, but also to trametinib alone and in combination (Fig. 4C), despite strong in vitro synergy (Fig. 4A,B). We confirmed that trametinib treatment activates SRC in HCT116 tumours in vivo and that SRC activation is effectively inhibited using AZD0424 alone or in combination with trametinib (Fig. 4D). Trametinib, at 0.3 mg·kg⁻¹, only partially inhibited ERK1/2 activation as expected at this submaximal dose in both HCT116 and DLD1 tumours and the addition of AZD0424 did not alter this (Fig. 4D). DLD1 tumours treated with trametinib also exhibited pockets of strong pERK1/2 staining which appeared undiminished by trametinib, alone or in combination with AZD0424. As DLD1 cells are resistant to MEK inhibitors and display a stronger activation of EGFR signalling upon treatment with MEK inhibitors, we hypothesised that DLD1 cells were more dependent on EGFR signalling for survival. We therefore tested DLD1 cells with drug combinations targeting MEK inhibition (trametinib) and either EGFR (AZD8931 and lapatinib) signalling or AKT (AZD5363), as this cell line also has an activating mutation in the PI3KCA gene (amino acid E545K) (Fig. S2E,F). Combined treatment of trametinib with AZD5363, AZD8931 or lapatinib synergistically inhibited DLD1 cell viability. Interestingly, this could be further enhanced by the addition of AZD0424 as a triple combination suggesting the involvement of SRC signalling (Fig. S2E,F).

As AZD0424 did not sensitise DLD1 tumours that were inherently resistant to MEK inhibitor treatment, we next asked whether SRC inhibition could (re)sensitise cells that had acquired resistance to MEK inhibitors following prolonged treatment with trametinib. We generated HCT116 trametinib-resistant cells (TRAMR) by long-term exposure to 5 nm trametinib in cell culture and compared their sensitivity to trametinib to the parental HCT116 cells and an isogenic cell line (HKH2), where the copy of the mutant KRAS gene has been deleted (Fig. 5A). Both the HKH2 and TRAMR cell lines were less sensitive to trametinib treatment (EC50 = 5.9 and 28 nm, respectively) compared with parental HCT116 cells (1.2 nm) as measured by cell viability (Fig. 5A); however, co-treatment with the combination of AZD0424 and trametinib still synergistically inhibited cell viability in the HKH2 cells while it was only additive in the TRAMR cells (Fig. 5B). Short-term exposure to trametinib (24 h) resulted in strong activation of SRC signalling across HCT116, HKH2 and TRAMR cells, as demonstrated by elevated phosphorylation of Src Tyr419 and FAK Tyr861 and this was prevented by co-treatment with AZD0424 (Fig. 5C). AZD0424 treatment alone blocked phosphorylation of SRC Tyr419, FAK Tyr861, in all cells and partially ERK1/2 in HKH2 cells (Fig. 5C). The basal activation of ERK1/2 was elevated in TRAMR cells and was insensitive to treatment with AZD0424 and only partially sensitive to trametinib. Drug-induced resistance to MEK inhibitors in vitro can be driven by amplification of the KRAS gene resulting in reactivation of the MAPK pathway [30,49], and transcriptomic analysis of the TRAMR cells demonstrated elevated expression of KRAS mRNA and the upregulation of genes in the MAPK, PI3K, JAK-STAT and Wnt pathways (Fig. S4). To further profile trametinib-induced resistance at the post-translational pathway level, we treated HCT116 and TRAMR cells for 24 h with AZD0424, trametinib and AZD6244 and profiled some post-translational modifications using RPPA analysis (Fig. 5D). Compared to parental HCT116 cells, TRAMR cells had elevated levels of phosphorylated MEK1 (Ser217/Ser221) and ERK1/2 confirming stimulation of the MAPK pathway as a likely mechanism of resistance to trametinib. TRAMR cells also had elevated IRS-1 expression, phosphorylation of AKT (Ser473), and to a lesser extent phosphorylation of GSK3α/β (Ser9, Ser21), p90 S6 kinase (Thr359, Ser363), and Rb (Ser780). Treatment of TRAMR cells with trametinib or AZD6244 increased phosphorylation of EGFR (Tyr1068/Tyr1173), FAK (Tyr397), PLCγ (Tyr783), SHP2 (Tyr542) and STAT5 (Tyr694), as previously observed in HCT116 cells (Fig. 3). Further, in TRAMR cells, AZD0424 could effectively block the activation of many of these compensatory signalling proteins but not elevated expression of IRS-1 or amplified phosphorylation of MEK1/2 (Ser217/221), c-Jun (Ser7) and Akt (Ser473; Fig. 5D). Therefore, MEK inhibitor resistance driven by increased MAPK signalling pathway is unlikely to benefit from SRC inhibitor combination therapy alone.

SRC and ERK1/2 regulate cancer cell migration, invasion and metastasis [13] and, therefore, we tested whether combinations of MEK and SRC inhibitors could synergise to block invasion using a 3D organotypic collagen I invasion assay [33]. As observed in the cell viability assay (Fig. 4A), trametinib treatment inhibited proliferation of HCT116, but not DLD1 cells, where combined treatment with trametinib and AZD0424 was required (Fig. 6A,B). Both HCT116 and DLD1 cells invaded into organotypic collagen I matrices, and invasion was readily inhibited by treatment with either AZD0424 or trametinib and this was enhanced by combining the two agents (Fig. 6A,B).

As KRAS mutation is also known to drive cancer cell invasion and metastasis, we next tested the invasive ability of the HCT116 cells that lack KRAS mutation (HKH2) or that are resistant to MEK inhibitor treatment (TRAMR) cells (Fig. 6A,B). As observed in the cell viability assay (Fig. 5B), trametinib inhibited proliferation of HKH2 cells but not TRAMR cells. HKH2 cells displayed an epithelial-like morphology and some invasive capacity despite lacking a mutant KRAS signalling while TRAMR cells were morphologically more mesenchymal and more highly invasive (Fig. 6A,B). Invasion of HKH2 cell invasion was blocked by either AZD0424 or trametinib treatment while TRAMR cell invasion was not significantly sensitive to AZD0424 treatment. However, when these were combined, there was further inhibition of invasion of TRAMR cells. Therefore, while proliferation in trametinib-induced resistant TRAMR cells relies on enhanced MAPK pathway activity, and not SRC activity, the switch to a more invasive phenotype is sensitive to AZD0424 when combined with submaximal anti-proliferative concentrations of trametinib. Therefore, it is likely that this combination would have maximal effect in reducing invasion of CRC cells, rather than reducing their proliferation.

Here, we evaluated the SRC/ABL kinase inhibitor, AZD0424, and its potential use as an anti-cancer combination therapy by testing across a diverse range of in vitro and in vivo cancer models in parallel with quantitative pathway profiling at the post-translational level. We sought to characterise how AZD0424, and by extension SRC inhibitors in general, may be employed as part of anti-cancer combination therapy in CRC as AZD0424 treatment could repress transducers of downstream signalling from EGFR, a key driver of metastatic CRC [25,26]. Previous studies indicate that inhibition of MEK in mutant KRAS breast or colorectal cell lines (re)activates many RTKs, sensitising them to RTK targeted therapy [50,51]. De novo KRAS mutations reduce the sensitivity of colorectal cells to EGFR-targeted therapy [29] and CRC tumours also develop resistance to anti-EGFR therapy by acquiring mutations in RAS [14,25,26].

We present strong rationale to implement AZD0424 plus MEK inhibitor combination: phosphorylation of SRC pY419, corresponding to increased SRC activity, is increased in response to treatment with two structurally distinct MEK inhibitors relative to DMSO control samples in colorectal cell lines HCT116 and DLD1 cells (Fig. 3A). In both, these cell lines co-treatment with either SRC inhibitors AZD0424 (Fig. 4B) or dasatinib (Fig. S2C) with trametinib induces synergistic inhibition of cell viability in vitro at 300nM concentrations or lower. The combination of AZD0424 and trametinib also shows positive effects in reducing both the growth and invasion of these cell lines in 3D organotypic co-culture models (Fig. 6) and attenuates tumour growth in vivo in the HCT116 xenograft model. However, such rationale is very much context dependent as the combination of AZD0424 and trametinib does not show added benefit relative to single drug treatment in DLD1 xenografts (Fig. 4C) or in cells which have acquired resistance to trametinib (TRAMR) through long-term in vitro treatments (Fig. 5B). In those cell line assays where significant synergy is only observed at µM concentrations, we believe such activity may reflect off-target activity and these models are not sensitive to the MEK and SRC inhibitor combination treatment.

Currently, patients with CRC are not recommended to receive anti-EGFR therapy if they have mutations in RAS (KRAS, HRAS or NRAS), or BRAF, the exception being when given in combination with drugs (vemurafenib) targeting the BRAF-V600E mutation, in combination with irinotecan and cetuximab [52]. Retrospective analyses of clinical trial data have identified that not all KRAS mutations are equal in CRC; KRAS-G13D mutations are sensitive to anti-EGFR therapy [53]. Mechanistically, RAS-G13D binds poorly to the RAS-GAP protein NF1 and in cells with hemizygous RAS-G13D mutations (i.e. KRAS-WT/KRAS-G13D), this results in EGFR-dependent activation of RAS-WT; RAS-G12 mutations in contrast bind to and block the activity of NF1 making RAS activation insensitive to anti-EGFR therapy [54]. SRC mediates the activation of EGFR (for example [46]) and we found that DLD1 cells strongly activated EGFR signalling following MEK inhibitor treatment and that combined trametinib and AZD0424 treatment inhibited cell viability synergistically in vitro, but it was not sufficient to block DLD1 tumour growth in vivo implying that SRC signalling is dispensible for tumour growth in this model. Indeed, we observed synergistic combination activity upon treatment of DLD1 cells with trametinib and inhibitors of AKT or EGFR family kinases and found that the inhibition of cell viability produced by these combinations was further reduced by the addition of AZD0424 (Fig. S2). In contrast to DLD1 cells, HCT116 cells do not express NF1 [55] making HCT116 cells unable to activate the EGFR-KRAS-WT singalling in response to MEK inhibitor treatment in this manner. The activation of SRC following MEK pathway inhibition was strongest in HCT116 cells in vitro, and this was also observed in vivo correlating with enhanced inhibition of HCT116 tumour growth upon trametinib and AZD0424 combination treatment relative to respective single-agent treatment in vivo. Further investigation will be required to fully explore the molecular mechanisms which confer context-dependent SRC and MEK inhibitor combination response including testing whether CRC cells with RAS-G13D mutations and lacking NF1 represent a subtype sensitive to SRC-MEK inhibitor combinations.

Combinations of SRC and MEK inhibitors have shown benefit in preclinical studies across several tumour types including ovarian, melanoma, non-small-cell lung carcinoma, breast and other solid tumours [56–63]. In high-grade serous ovarian cancer (HGSOC), combination of MEK (AZD6244) and SRC (saracatinib) inhibitors overcomes EGFR-mediated bypass of the RAS-MAPK pathway and targets tumour initiating stem cells [61]. Ovarian cancer cells resistant to saracatinib display activation of the MAPK pathway via reduced NF1 expression or overexpression of HER2 and the insulin receptor [59]. Mutant-KRAS cell lines are also sensitive to the combination of SRC (dasatinib) and MEK (trametinib) inhibitor treatment by downregulating the Hippo pathway effector TAZ, however, 4 out of 11 cell lines tested were insensitive [60] and so further investigation is required to fully understand the mechanism of this combination and context of cell type sensitivity.

The activation of FAK is a multistep process where first FAK is recruited to the plasma membrane at sites of adhesion by binding PIP2 [64], which primes FAK for autophosphorylation on Tyr397. SRC binds to FAK on Tyr397 and can subsequently phosphorylate other sites on FAK such as the activation loop (Tyr576/577) and other tyrosine residues (Tyr861 or Tyr925) [48]. Trametinib treatment of HCT116 cells increased the phosphorylation of FAK on both its autophosphorylation (Tyr397) and SRC phosphorylation (Tyr861) sites (Fig. 5). Thus, the phosphorylation of FAK on Tyr861 may serve as a biomarker for combined MEK and SRC (or FAK) inhibitors in clinical trials. Future work across a broad panel of CRC cell lines is needed to confirm the correlation between the phosphorylation of FAK on Tyr861 with the response to SRC and MEK inhibitor combination.

Our studies demonstrate high levels of phosphorylated ERK1/2 at the basal level in HCT116 and DLD1 cells and these high levels persist following AZD0424 SRC inhibitor treatment (Fig. 3C). Furthermore, enhanced phosphorylation of ERK1/2 is observed in trametinib-resistant (TRAMR) cell treatment (Fig. 5C). These studies indicate that selective ERK1/2 inhibitors, such as VTX11e [65], represent a rational drug combination choice with SRC inhibitor in both MEK inhibitor naïve and acquired trametinib-resistant tumour cells. However, the effectiveness of such combination in the light of other compensatory bypass signalling pathways would have to be tested. Targeting different parts of the RAS-MAPK signalling cascade is a common approach to resistance mediated to pathway reactivation and multitargeted inhibitors that reinforce pathway blockade such as VS-6766 which targets both RAF and MEK in the RAS-MAPK cascade can achieve tighter inhibition and reduce pathway reactivation [66]. This is an excellent example of the development of a ‘two-drug’ combination in a single compound and this may be an effective strategy for targeting signalling networks supported by SRC. For example, preliminary results show that trametinib combined with TPX-0005 (a multitarget kinase inhibitor whose targets include SRC and FAK) synergistically inhibits RAS mutant cell growth in vitro and in vivo [67]. Therefore, dual EGFR-SRC or FAK-SRC inhibitors could be a future avenue of drug development to address multiple redundant and compensatory signalling mechanisms.

SRC inhibitors have long been recognised as potential anti-invasive/metastatic agents to help improve progression-free survival and metastasis-free progression [13,56,57,68], yet most clinical trial studies incorporating SRC inhibitors monitor primary tumour growth or regression as a clinical endpoint. Here, we have shown that despite either inherent or drug-induced resistance to MEK inhibitors, inhibition of SRC using AZD0424 can effectively block cancer cell invasion in vitro. MEK inhibitor resistance in HCT116 TRAMR cells promoted an aggressive-invasive cell type, most likely driven by their elevated RAS-MAPK signalling and EMT (Fig. 6). Biomarkers or pathway signatures of SRC activation following MEK inhibition may predict those patients who would benefit from a SRC-MEK inhibitor combination to promote the durability of responses to primary MEK inhibitor therapy in patients with KRAS mutant CRC. This could delay or combat the rise of aggressive MEK inhibitor-resistant, invasive phenotypes induced by prolonged exposure to MEK inhibitors. Clinical trials in metastatic CRC patients using dasatinib combined with chemotherapy, with or without cetuximab, failed to fully inhibit SRC activity [9]. Therefore, efficiently inhibiting SRC activity in a sustainable manner is still a major challenge for the current crop of SRC inhibitors undergoing clinical development. This could be overcome by the development of novel, well-tolerated, highly selective SRC inhibitors (for example [16,69]). Our data suggest that SRC inhibitors may optimally be combined with other agents to inhibit aggressive invasion in contexts where that is relevant. Clinical trials with appropriate endpoints for metastatic disease would need to be defined.

Dynamic signalling networks and pathway switching permit rapid tumour evolution and therapeutic evasion; this requires new and more comprehensive approaches to understand cancer cell signalling networks, ‘driver’ pathways and how best to collapse the robustness of such networks so that tumour cells die in the metastatic niche. Overcoming such dynamic signalling responses may help address high clinical attrition rates associated with target-based drug discovery and improve long-term patient outcomes and cancer mortality rates in advanced tumour settings. Complementing advances in next-generation sequencing, we have applied protein-level analyses via RPPA to characterise the novel SRC inhibitor AZD0424, including at the post-translational level across a number of cell lines to reveal potential molecular mechanistic insight into compensatory and cooperative mechanisms as well as acquired resistance. We have demonstrated that SRC inhibitors can synergise with MEK inhibitors in CRC cell lines that depend on RAS-MAPK signalling for survival and invasion, and inhibiting SRC may form part of wider combination regimens that will be most effective when tailored to the pathway activation status of specific patient tumours, and/or to mitigate against enhanced invasion caused by particular therapies such as those targeting MEK.

This work was supported by a Cancer Research UK grant (C157/A1362) awarded to Valerie G. Brunton, Neil Carragher and Margaret Frame and by Cancer Research UK Programme Awards (C157/A15703 and C157/A24837) awarded to Margaret Frame and Valerie G. Brunton. Graphical abstract was created with BioRender.com.

Robert Williams is an employee of Cancer Research UK which funded this work.

JCD performed the majority of the experiments, analysed and interpreted the data. AM and KM performed NanoString and RPPA studies. MM provided help with in vivo experiments. PT provided training, reagents and advice. RW, MF and VB provided critical feedback throughout the project. JCD and NOC wrote the manuscript. MF, VB and NOC conceived and designed the project.

The peer review history for this article is available at https://publons.com/publon/10.1002/1878-0261.13151.

The data that support the findings of this study are available in the Supplementary Material of this article.