The HER2 transmembrane tyrosine kinase plays critical roles in human homeostasis, and its deregulation has been linked to certain types of cancer (Holbro & Hynes, ; Arteaga et al, ; Esparis-Ogando et al, ). In fact, elevated levels of HER2 were initially reported in a subset of breast tumors and such elevated levels correlated with poor clinical outcome (Slamon et al, ). These studies, together with preclinical data that corroborated a pro-oncogenic role of HER2 (Di Fiore et al, ), promoted the development of agents that specifically act on this tyrosine kinase. Two types of such agents have reached the oncology clinic. On one hand, antibodies targeting the extracellular region of HER2, such as pertuzumab, trastuzumab, and its derivatives, which include trastuzumab biosimilars and trastuzumab-emtansine (T-DM1), a derivative that belongs to the antibody–drug conjugate (ADC) type of anti-tumorals (Arteaga et al, ; Burris et al, ; Garcia-Alonso et al, ). These antibodies act through a complex, yet incompletely understood set of mechanisms which include downregulation of HER2 and its signaling (Lane et al, ), inhibition of dimer formation in the case of pertuzumab (Agus et al, ), or recruitment of the immune system to sites of antibody abundance, triggering antibody-dependent cellular cytotoxicity (Clynes et al, ). In the case of trastuzumab-emtansine, internalization and release of the cytotoxic payload appear critical for its action (Burris et al, ; Garcia-Alonso et al, ). The second group of clinically approved agents that target HER2 is the small molecule membrane-permeable kinase inhibitors (TKIs) neratinib and lapatinib (Geyer et al, ; Zhang et al, ; Chan et al, ). Despite the clinical efficacy, patients with advanced disease often become refractory to the available anti-HER2 drugs (Pernas & Tolaney, ). Therefore, new strategies are required to overcome resistance to those therapies.

Resistance to anti-HER2 therapies may be caused by various mechanisms, including lack or truncation of HER2 (Parra-Palau et al, ), activation of downstream signaling routes, such as the PI3K pathway (Majewski et al, ), or compensatory activation of cell proliferation signals mediated by other receptor tyrosine kinases (Shattuck et al, ; Schwarz et al, ). In this respect, particular attention has been devoted to the related ErbB family receptor HER3 (Baselga & Swain, ). In fact, HER3 has been reported to play a pathophysiological role in resistance to anti-HER therapies (Sergina et al, ; Narayan et al, ; Garrett et al, ). Moreover, expression of several ligands of HER receptors causes resistance to trastuzumab by augmenting dimerization of HER2 with either HER3 or EGFR (Motoyama et al, ; Ritter et al, ; Phillips et al, ). Analogously, in cells made resistant to T-DM1, increased levels of the HER3 ligand neuregulin caused resistance to that ADC (Phillips et al, ). Together, these evidences indicate that acting on HER3 may be of therapeutic value for HER2⁺ tumors, particularly in circumstances in which these tumors become refractory to the action of approved anti-HER2 drugs. Indeed, dysregulation of HER3 trafficking, as well as the ability of this receptor to interact with other receptor tyrosine kinases to modulate the sensitivity of targeted therapeutics in different cancers, has prompted the use of anti-HER3 antibodies, both as single agent or in combination with anti-cancer drugs to overcome resistance (Chakrabarty et al, ; Abel et al, ; Ma et al, ; Capone et al, ; Gaborit et al, ; Black et al, ). Several naked antibodies have been developed and tested in clinical trials. However, this approach turned out to have modest therapeutic activity (Jacob et al, ; Mishra et al, ; Liu et al, ).

Here, we report the anti-tumoral action of the HER3 antibody–drug conjugate EV20/MMAF (Capone et al, ). This ADC consists of the humanized EV20 anti-HER3 antibody (Sala et al, , ; Prasetyanti et al, ) coupled with a non-cleavable linker to monomethyl auristatin F (MMAF), a synthetic compound that blocks tubulin polymerization. This antibody has been shown to block HER3/AKT signaling (Sala et al, ) and to be rapidly and efficiently internalized by cells expressing HER3 (Sala et al, ). Moreover, the antibody impaired ligand-induced signaling and clonogenic growth in vitro and tumor growth in BRAF-V600E mutant colon cancer (Prasetyanti et al, ). We show that EV20/MMAF exerts a potent and efficient anti-tumoral effect in different HER2⁺ models including cells resistant to classical anti-HER2 therapeutics. Moreover, single-dose treatment with EV20/MMAF of mice implanted with HER2⁺ cells made resistant to trastuzumab, resulted in long-lasting complete remission of tumors generated by these cells. The results encourage the clinical study of EV20/MMAF to treat HER2⁺ tumors.

The principal aim of this study was to explore the value of EV20/MMAF to overcome resistance to anti-HER2 drugs used in the clinic. Since trastuzumab-based therapies represent the gold standard for the therapy of patients with HER2⁺ breast tumors in the neoadjuvant as well as the adjuvant settings (Ocana et al, ), we started the study focusing on resistance to trastuzumab. Several models of primary or secondary resistance to trastuzumab were used. One of the models of secondary resistance was created by continuous exposure of the HER2⁺ human cell line BT474 to 50 nM trastuzumab (Fig A). These cells, which are sensitive to trastuzumab (Schwarz et al, ), represent a preclinical model that has been prototypically used to analyze the biology of HER2, including therapies that act on that receptor. BT474 cells chronically treated with trastuzumab (50 nM) resulted in the selection of cells that survived such treatment (Rios-Luci et al, ). Under such drug pressure, pools of cells, termed BTRH from BT474 Resistant to Herceptin™, or single clones were isolated and their response to the drug compared to that of wild-type BT474 cells. While proliferation of naïve BT474 cells was sensitive to trastuzumab (Figs B and EV1A), little effect of the drug was observed in the pooled BTRH cells or in a representative resistant clone (BTRH#10). Such resistance to the action of trastuzumab was not caused by loss of total or phosphorylated (Fig C) or cell surface (Figs D and EV1B) HER2.

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EV20/MMAF efficiently acts on naïve and trastuzumab-resistant cells

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Action of trastuzumab, EV20, and EV20/MMAF on different HER2+ cell lines EV1. ADose–response analyses of the effect of trastuzumab (7 days of treatment) on the proliferation of BT474, BTRH, and BTRH#10 cells. Data represent mean + SD of triplicates of an experiment that was repeated at least four times and normalized to untreated controls. When error bars are invisible, that is because they are small and are covered by the graphic's symbols.BCell surface levels of HER2 and HER3 in BT474, BTRH, and BTRH#10 cells analyzed by surface immunoprecipitation.CHER3 level was quantitatively analyzed in BT474 and BTRH cells by flow cytometry using EV20/MMAF as primary antibody and Cy3 anti-human secondary antibody.DCell surface levels of HER2 and HER3 in PDX118, TR1, and TR2 cells analyzed by surface immunoprecipitation.EAction of the nude EV20 antibody or EV20/MMAF (10 nM each, 5 days) in HER2-positive breast cancer cell lines. Data represent mean + SD of triplicates of an experiment that was repeated two times and normalized to untreated controls. ***P [less than] 0.001. Exact P-values of all comparisons and the statistical test used are indicated in Appendix Table S10.FCell lines were treated without or with EV20 (10 nM) for 5 days and lysed. HER3 (25 μg of protein) and pHER3 (60 μg of protein) were analyzed by Western, the latter with the pHER3-specific antibody.GQuantitative analysis of the effect of EV20 on the levels of HER3 and pHER3 in each cell line, using data presented in (F) and other experiment. Intensity values of the untreated samples were taken as 100%.HEffect of neuregulin on the action of EV20/MMAF. Cell lines were treated with EV20/MMAF (1 nM) and/or neuregulin (10 nM) for 5 days and proliferation analyzed by cell counting. Data represent mean + SD of triplicates (normalized to untreated controls) of an experiment representative of three. **P [less than] 0.01. *P [less than] 0.05. Exact P-values of all comparisons and the statistical test used are indicated in Appendix Table S11.

The effect of EV20/MMAF on BT474, BTRH, and BTRH#10 cells, which present analogous levels of total and phosphorylated and cell surface HER3 (Figs C and D, and EV1B and C), was then evaluated. Dose–response studies demonstrated that the drug potently affected the proliferation of these cells, assessed by cell counting after 120 h of treatment (Fig E). The anti-proliferative action of EV20/MMAF reached a maximum inhibitory effect at 1 nM. We next explored the sensitivity of these cells to the separate components used to generate EV20/MMAF, i.e., the EV20 anti-HER3 antibody or the cytotoxic drug MMAF. In contrast to EV20/MMAF, the nude antibody EV20 did not affect the proliferation of BT474, BTRH, or BTRH#10 cells (Fig F). In the case of free MMAF, the drug inhibited the proliferation of BT474 and BTRH cells (Fig G). However, the potency of MMAF was around three orders of magnitude lower than that of EV20/MMAF.

We complemented the above studies by using another model of secondary resistance to trastuzumab derived from a PDX (PDX118) initially sensitive to trastuzumab (Rios-Luci et al, ). To that end, a PDX118 tumor grown in a mouse was dissected and cells disaggregated and placed in culture. These cultures were propagated in the absence or presence of trastuzumab. Two clones growing in the presence of trastuzumab (named TR1 and TR2) were isolated and tested for their sensitivity to trastuzumab. As shown in Fig A, parental PDX118 cells were highly sensitive to trastuzumab. In contrast, clones TR1 and TR2 presented substantial resistance to the action of the drug. TR1 and TR2 clones expressed levels of HER2 similar to those of the parental PDX118 cells (Fig B), excluding changes in HER2 as the cause of their resistance to trastuzumab. Additional analyses indicated that all the PDX118-derived cell lines expressed similar levels of total and cell surface HER3 and HER2, independently of their sensitivity to trastuzumab (Figs B and EV1D). Moreover, their HER3 levels paralleled those of BT474 and BTRH cells. EV20/MMAF exerted a strong anti-proliferative effect, being equipotent in PDX118, TR1, and TR2 as well as in BT474 and BTRH cells (Fig C). Levels of pHER3 were higher in PDX118 cells as compared to TR1 or TR2 (Fig B).

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Action of EV20/MMAF on various models of primary and secondary resistance to trastuzumab

With the aim of analyzing whether cells with de novo resistance to trastuzumab were also sensitive to EV20/MMAF, we explored the effect of trastuzumab on several human HER2⁺ cells. The criteria for sensitivity or resistance to trastuzumab were established from the responses of BT474 and BTRH cells to the drug (Fig A and B). As shown in Fig D, SKBR3 cells responded to trastuzumab similarly to wild-type BT474 cells. On the other side, MDA-MB-361, HCC1419, HCC1569, and HCC1954 had a response to trastuzumab similar to that of BTRH cells and were therefore considered resistant cells. All the cell lines expressed HER3, in addition to HER2 (Fig E), confirming their reported HER2 positivity (Neve et al, ). Dose–response analyses showed that all the cell lines responded to EV20/MMAF (Fig F), but not to the nude EV20 antibody (Fig EV1E). The nude EV20 antibody, however, reduced the levels of HER3 and/or pHER3 in several of the treated cell lines (Fig EV1F and G).

Since the presence of the HER3 ligand neuregulin has been shown to impair the action of other ADCs such as T-DM1 (Phillips et al, ), the impact of that ligand on the anti-proliferative effect of EV20/MMAF was analyzed. As shown in Fig EV1H, incubation with neuregulin slightly affected the anti-proliferative action of EV20/MMAF, although most of the action of the ADC was preserved.

Whether expression of HER3 was required for the action of EV20/MMAF was then evaluated. Linear regression studies showed correlation between the levels of HER3 and the response to EV20/MMAF (R² = 0.677, P = 0.044, Fig EV2A and B), suggesting that the amount of the receptor is one of the factors dictating sensitivity to the drug. In fact, the antibody had a poor effect on the human stromal cell line HS5 (Fig EV2C), a non-tumoral non-breast cell line that expresses very low levels of HER3 or pHER3 (Fig EV2D). Similarly, the antibody did not affect the proliferation of MDA-MB-231 and BT549, two triple-negative breast cancer cell lines with very low HER3 or pHER3 (Fig EV2C and D). No correlation was found between the levels of pHER3 and the potency of EV20/MMAF (R² = 0.135, P = 0.474, Fig EV2E and F).

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Correlation analyses between HER3, pHER3, and sensitivity to EV20/MMAF EV2. ALevels of HER3 in the HER2+ cell lines (BTRH, BT474, HCC1419, HCC1569, HCC1954, SKBR3, and MD-MB-361). Twenty-five μg of protein of the indicated cell lines was loaded in gels and HER3 analyzed by Western.BCorrelation analysis between IC50 of EV20/MMAF and HER3 levels in the HER2+ cell lines. The bands corresponding to HER3 in blots shown in (A), with analogous exposure times and signals, were quantitated. Data are represented as mean ± SD of four Westerns and IC50 of EV20/MMAF.CEffect of a 5 days treatment with EV20/MMAF on cell proliferation of cell lines expressing different levels of HER3 (BT474, BTRH, HS5, MDA-MB-231, and BT549). Data represent mean + SD of triplicates (normalized to untreated controls) of an experiment that was repeated at least twice.DHER3 and pHER3 levels in the cells shown in (C). The levels of pHER3 were assessed by Western blotting of cell lysates (60 μg) using a specific pHER3 antibody.E, FCorrelation analysis between IC50 and pHER3 levels in the HER2+ cell lines, analyzed as in (A and B). Data are represented as mean ± SD of four Westerns quantification (the first from top is the one also used for Fig E) and IC50 of EV20/MMAF.Data information: Pearson correlation data are shown in (B and F).Source data are available online for this figure.

To explore further the dependency of the action of EV20/MMAF on HER3 expression levels, knockdown experiments were carried out in BT474 cells. For these experiments, we selected two sequences that interfered with the expression of HER3, which also decreased pHER3 and pAKT levels (Fig G). The knockdown of HER3 caused by both sequences had an inhibitory effect on the anti-proliferative action of EV20/MMAF (Fig H).

Immunofluorescence experiments showed that EV20/MMAF stained the cell surface at early incubation times and that staining evolved into a dotted pattern with time (Fig A). The accumulation of EV20/MMAF in those dots was already observed at early times (30 min) but was more clearly evidenced at 3 h or beyond. The presence of such dotted pattern was suggestive of internalization of the antibody. To verify whether EV20/MMAF was in fact internalized, the antibody was labeled with a cleavable biotin form that is sensitive to the reducing agent glutathione (GSH). If the antibody is exposed at the extracellular medium, the biotin label can be released by GSH (Esparis-Ogando et al, ). However, internalized biotinylated EV20/MMAF is protected from the reducing action of GSH, rendering biotinylated EV20/MMAF detectable by Western blotting. Internalization of biotinylated EV20/MMAF in BT474 and BTRH cells was detected at the earliest time point analyzed and reached a maximum at 60 min (Fig B and C). The biotinylated antibody signal decreased thereafter, indicating recycling or degradation of the internalized antibody. In both cell lines, internalization kinetics were similar.

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Internalization of EV20/MMAF in BT474 and BTRH

Internalization of EV20/MMAF is expected to drive the ADC-HER3 complex to the lysosomes, where acidic proteases may cleave the ADC. To verify that EV20/MMAF reached such an acidic environment, the ADC was labeled with pHrodo, a red fluorogenic dye that is almost non-fluorescent at neutral pH, but which fluoresces in acidic environments (Nath et al, ). Cells were incubated with 10 nM pHrodo-EV20/MMAF for 24 h, and fluorescent signals analyzed by in vivo microscopy. In BT474 and BTRH cells, fluorescence progressively accumulated intracellularly (Movie EV1 and EV2), demonstrating that pHrodo-EV20/MMAF reached acidic compartments. Moreover, complementary immunofluorescence studies showed colocalization of EV20/MMAF with the lysosomal marker LAMP-1 (Figs D and EV3A and B). Finally, to confirm that arrival of the ADC-HER3 complex to the lysosomes promoted its degradation, HER3 levels were analyzed after different treatment times with EV20/MMAF. In BT474 and BTRH cells, treatment with EV20/MMAF caused a decrease in total HER3, which was detectable between 1 and 3 h (Fig E and F). In contrast, the antibody did not affect the total amount of HER2. Parallel experiments performed with trastuzumab showed that this antibody did not significantly affect the levels of HER2 or HER3 (Fig EV3C and D).

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Colocalization of EV20/MMAF and LAMP-1, and effect of trastuzumab on HER2 and HER3 levels in BT474 and BTRH cells EV3. AColocalization of EV20/MMAF (10 nM, red) with LAMP1 (green) is shown in white (second row) in BT474 and BTRH cells. Scale bar: 20 μm. Colocalization analysis was done with Leica Application Suite Advanced Fluorescence, which generated the scatter plots of acquired images (last row). Pure red and green pixels are between abscissa/ordinate and white lines. Colocalizating pixels are found inside the central region of the plot, within the white lines.BQuantitation of the colocalization in 20 photographs, representative of treatment with EV20/MMAF for 0 (black bars) or 24 h (red bars) in BT474 and BTRH cells. Data are represented as mean + SD.CWestern studies of the levels of HER2 or HER3 in BT474 and BTRH cells treated with trastuzumab (50 nM) for the indicated times. Lysates were prepared and equal amounts of protein (10 μg for HER2 and 25 μg for HER3) loaded in gels.DQuantitative analyses of the experiments shown in (C).

To gain insights into the anti-tumoral mechanism of action of EV20/MMAF, whether such action involved a decrease in cell cycle progression, augmented cell death, or both was explored. Cell cycle assessment using propidium iodide staining revealed that EV20/MMAF increased the proportion of cells in the G2/M region of the histograms, and such increase was accompanied by a concomitant decrease in the G1 phase (Fig A). These changes in the cell cycle pattern caused by EV20/MMAF were similar in both cell lines. Western blotting analyses showed that EV20/MMAF caused a substantial and persistent accumulation of pHistone H3, which is used as a marker of cells in mitosis (Fig B). Moreover, the drug also increased the levels of pBubR1, another protein whose phosphorylation marks cells in that cell cycle phase. These Western studies also confirmed a decrease in the levels of HER3 and pHER3 upon continued treatment with EV20/MMAF in both cell lines.

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Mechanism of action of EV20/MMAF

The above data were consistent with induction of mitotic arrest caused by EV20/MMAF. Stalling of cells in the M phase of the cell cycle by cytotoxic payloads has been reported to provoke cell death through mitotic catastrophe (Garcia-Alonso et al, ). Such effect is caused by the action of drugs on the microtubular system required for adequate cell cycle progression. Immunofluorescence analyses showed that mitotic spindles of BT474 and BTRH cells treated with EV20/MMAF offered an abnormal aspect (Fig C and D). Moreover, accumulation of death cells was observed over time in cultures of cells treated with the drug (Fig E). Biochemical studies confirmed the induction of apoptotic cell death by EV20/MMAF since it augmented cleavage (Fig F) and activation (Fig G) of caspase 3 in BT474 and BTRH cells.

The in vivo anti-tumoral effect of EV20/MMAF on BTRH cells was analyzed by orthotopically implanting these cells in the caudal mammary fat pads of female nude mice. Once tumors reached 500 mm³, mice were randomized into four groups: (i) control, (ii) EV20 (10 mg/kg), (iii) EV20/MMAF (3.3 mg/kg), and (iv) EV20/MMAF (10 mg/kg). A single intraperitoneal injection with each treatment was performed and tumor size monitored twice a week. As shown in Fig A, treatment with the nude antibody EV20 was unable to prevent tumor growth. In contrast, treatment of mice with EV20/MMAF provoked tumor shrinkage, at either 3.3 or 10 mg/kg. In mice-bearing tumors created by injection of BTRH cells, weekly in vivo treatment with trastuzumab initially provoked tumor shrinkage, followed by tumor relapse. Because of the initial sensitivity to trastuzumab of BTRH-derived tumors in vivo, we also explored the in vivo anti-tumoral effect of EV20/MMAF on two additional resistant models. One of them, created by injecting BTRH#10 cells, represented an alternative secondary resistance model to trastuzumab, while the other, created by injecting HCC1954 cells, represented a primary resistance model. Both models showed in vivo resistance to weekly administered trastuzumab (Fig B and C). Tumors in mice injected with BTRH#10 or HCC1954 cells were sensitive to the action of single-dose EV20/MMAF, confirming the effectiveness of that drug in causing tumor regression. EV20 did not affect the growth of tumors in mice injected with BTRH#10 cells, in line with the lack of effect of this antibody observed in mice injected with other BT474-derived models such as BTRH (Fig A) or BT-TDM1R#6 cells (Fig EV5D). In HCC1954 cells, EV20 caused tumor growth stalling, but no regression of tumors was observed (Fig C).

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In vivo effect of EV20/MMAF

Some mice were euthanized to assess the tissue distribution of EV20/MMAF. To that end, untreated mice-bearing BTRH tumors were treated with EV20/MMAF and euthanized after 24 h or after 2 weeks. Twenty-four hours after the initial injection, EV20/MMAF could be detected in all the 11 tissues explored (Fig EV4A). The levels of the antibody were higher in lung, kidney, heart, skin, and ovary than in the tumor derived from BTRH. However, 2 weeks after the initial injection, EV20/MMAF mainly accumulated in the tumoral tissue, and its presence in most other tissues was lower or undetectable (Fig EV4B). Cleaved caspase-3 and pHistone H3 accumulated in tumors treated for 2 weeks with EV20/MMAF (Fig D). Total HER3 levels were lower in the samples of tumors processed after 2 weeks as compared to the samples harvested 24 h after the treatment. Different remodeling of the tissue microenvironment in both sets of samples may underlie such differences. Tumors treated with EV20/MMAF for 2 weeks presented lower levels of HER3 and pHER3 as compared to the levels present in untreated tumors (Fig D).

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Tissue distribution of EV20/MMAF and follow-up of tumor size in xenografted mice injected with BTRH cells EV4. A, BTwenty-four hours (A) or 2 weeks (B) after treatment with EV20/MMAF, tumors and indicated organs were dissected from animals. EV20/MMAF was precipitated from equal amounts of protein (500 μg) with protein A-Sepharose. EV20/MMAF was detected by Western using anti-human-HRP. The bottom part of panels (A and B) include graphical representations of the quantitation of EV20/MMAF levels shown in the Westerns, obtained as follows: signal of the band of a tissue of a treated animal minus signal of the band of the respective tissue of the untreated animal.CMonitorization of two mice-bearing BTRH tumors treated every 3 weeks with EV20/MMAF 3.3 mg/kg.DMean animal weight of animals represented in Fig A.

Given the tumor regression observed after treatment with a single dose of the EV20/MMAF antibody (Fig A), we decided to keep some of the mice under observation to explore whether tumors relapsed over time. All mice treated with a single dose of 10 mg/kg and followed along 1 year did not show recurrences of their initial tumors (Fig E). In the case of mice treated with 3.3 mg/kg, three out of five tumors relapsed. In these mice, new injections of EV20/MMAF were able to reduce tumor masses (Fig E). Having observed relapses in mice treated with a single dose of EV20/MMAF at 3.3 mg/kg, an alternative dosing scheme was followed in attempting to reduce the likelihood of such relapses. To that end, mice-bearing BTRH tumors were treated for several months with 3.3 mg/kg of EV20/MMAF, administered every 3 weeks. As shown in Fig EV4C, this treatment schedule resulted in full regression of the tumors, without relapses. Doses of 3.3 or 10 mg/kg of EV20/MMAF did not substantially affect the weight of the animals, suggesting that the drug was well tolerated (Fig EV4D). However, it should be pointed out that EV20 does not interact with murine HER3 (Capone et al, ), leaving open the possibility of potential secondary effects of EV20/MMAF due to the targeting of autochthonous HER3.

The action of EV20/MMAF on models of acquired resistance to other anti-HER2 drugs was also explored. To that end, we generated BT474 cells resistant to lapatinib, neratinib, or T-DM1 (Fig EV5A–C). These other resistant models were prepared following a protocol similar to that illustrated in Fig A, using doses of 1 or 5 μM of lapatinib, 10 nM of neratinib, or 5 nM of T-DM1 (Rios-Luci et al, ). After 3 months of treatment, pools or single clones of resistant cells were prepared and tested for their in vitro sensitivity to these drugs. In the case of neratinib, several clones showed sustained resistance to the drug along several months in culture. Treatment of two of these clones (BTRN#5 and BTRN#24) with EV20/MMAF had a similar effect on their proliferation as it had on the BT474 naïve cells (Fig A). As occurred with the other previously mentioned models of secondary resistance, the levels of HER2 and HER3 in the resistant clones were similar to those of the parental cells (Fig B). Levels of pHER2 and pHER3 in the neratinib-resistant clones were lower than those present in the parental cells, while those of pAKT were higher. In the case of lapatinib, the action of EV20/MMAF was tested in a pool of resistant cells (BTRL) as well as in two lapatinib-resistant clones (BTRL#3 and BTRL#109). The effect of EV20/MMAF on BTRL and BTRL#109 was similar to parental BT474 cells (Fig C). EV20/MMAF was slightly less potent in the BTRL#3 clone. Western blotting analyses indicated that the cells made resistant to lapatinib, either the pooled one or the clones, expressed similar levels of HER2 and HER3 and retain pHER2, pHER3, and pAKT, although at different levels (Fig D). Finally, we tested the efficacy of EV20/MMAF on cells resistant to T-DM1. EV20/MMAF was indeed active in these T-DM1-resistant clones, even though in clone BT-TDM1R#1, which presents deficient lysosomal processing of ADCs (Rios-Luci et al, ), the effect of EV20/MMAF was less potent (Fig E). HER2 and HER3 levels in T-DM1-resistant clones were similar to those of parental cells, while pHER2 levels were lower in BT-TDM1R#6 (Fig F). We explored the in vivo action of EV20/MMAF on tumors created by injecting mice with BT-TDM1R#6 cells. As shown in Fig EV5D, T-DM1 was unable to cause regression of those tumors, in agreement with previously reported data (Rios-Luci et al, ). In contrast, EV20/MMAF caused tumor regression similar to the effect observed in tumors derived from BTRH and BTRH#10 cells. EV20 did not affect the growth rate of these tumors.

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Response of resistant models to the drugs against which they were raised and in vivo evaluation of EV20/MMAF on tumor growth of a T-DM1-resistant model EV5. A–CDose–response analyses of the effect of neratinib (A, 48 h, BTRN#5 and BTRN#24), lapatinib (B, 48 h, BTRL, BTRL#109, and BTRL#3), or T-DM1 (C, 5 days, BT-TDM1R#1 and BT-TDM1R#6) on the proliferation of the cells indicated in the panels. Data represent mean + SD of triplicates (normalized to untreated controls) of an experiment that was repeated at least three times. When error bars are invisible, that is because they are small and are covered by the graphic's symbols.DIn vivo effect of single-dose EV20 (10 mg/kg, n = 2), untreated control (PBS, n = 3), single-dose EV20/MMAF (10 mg/kg, n = 3), or single-dose T-DM1 (3 mg/kg, n = 4) on tumor growth in mice injected with BT-TDM1R#6 cells. Data are represented as mean + SEM. Exact P-values of all comparisons of the last measurements and the statistical test used are indicated in Appendix Table S12.

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Effect of EV20/MMAF in cells resistant to neratinib, lapatinib, and T-DM1

Anti-HER2-based therapies represent the gold standard choice for the treatment of patients bearing HER2⁺ breast tumors. While introduction of these therapies has substantially improved the prognostic landscape of that type of tumors, some patients may not respond to these therapies. Therefore, identification of alternative ways to fight these resistant tumors is a medical need. Some precedents indicate that targeting HER3 may be of therapeutic value for patients whose tumors become refractory to available anti-HER2 therapies. In fact, it has been reported that tumors refractory to HER-targeted therapies, either directed to HER2 or the EGFR, express elevated levels of HER3 (Sergina et al, ; Narayan et al, ; Garrett et al, ). In the recent past, HER3-targeting agents, mainly naked antibodies, have been clinically evaluated both as single agent and in combination with other targeted therapeutics. However, their therapeutic activity has proven to be limited, although tolerability was favorable (Gaborit et al, ; Jacob et al, ; Mishra et al, ; Black et al, ; Liu et al, ). More recently, we and others have provided evidence that ADCs targeting HER-3 possess potent and specific activity in metastatic melanoma as well as EGFR inhibitor-resistant lung carcinoma, pancreatic, and colorectal carcinoma (Capone et al, ; Bourillon et al, ; Hashimoto et al, ; Koganemaru et al, ; Yonesaka et al, ; Haratani et al, ). One of these novel HER3 targeting immunoconjugates is U3-1402, composed of the anti-HER3 antibody patritumab and the novel topoisomerase I inhibitor DX-8951 (Koganemaru et al, ). U3-1402 entered phase I/II study for the treatment of HER3⁺ non-small-cell lung cancer and metastatic breast cancer. Preliminary data from these studies were encouraging, as partial responses and tumor shrinkage were observed suggesting that targeting HER3 with an ADC may be advantageous respect to targeting with naked antibody (Kogawa et al, ).

Because of these precedents and the fact that HER3 is frequently expressed in breast cancer (Vollmann-Zwerenz et al, ), we decided to explore the potential therapeutic value of the HER3 targeting ADC EV20/MMAF in HER2⁺ breast cancer, with particular focus on the action of that drug on cells resistant to trastuzumab and other anti-HER2 therapies. EV20/MMAF had a potent anti-proliferative effect on HER2⁺ breast cancer cells. In contrast, addition of the nude antibody EV20 did not affect the proliferation of these cells in vitro demonstrating that the mere action on HER3 is inefficient from the therapeutic point of view. Moreover, free MMAF had a much lower anti-proliferative action than EV20/MMAF, indicating that the sum of MMAF and EV20 optimally increases the potency with respect to the individual drugs. The in vivo models derived from BT474 cells confirmed the lack of effectiveness of EV20. It is relevant to comment that previous studies showing that EV20 may induce delay in tumor growth were based on a different schedule which included administration of the naked antibody twice a week for a more prolonged period (4–5 weeks; Sala et al, , ). Moreover, in those studies EV20 was administered to mice-bearing tumors much smaller than the ones used in the present study (100 mm³ vs. 500 mm³). In the case of tumors in mice injected with HCC1954 cells, EV20 exerted a visible anti-proliferative effect. The fact that EV20 did not affect the proliferation of HCC1954 cells in vitro, but inhibited tumor growth of xenografted HCC1954 cells in mice, suggests that factors present in the tissue microenvironment may favor tumor growth, and they are sensitive to antibody treatment. In any case, comparison of single-dose treatment with either EV20 or EV20/MMAF demonstrated the superior in vivo anti-tumoral effect of the latter in all the secondary and primary anti-HER2 drug-resistant models.

The action of the antibody depended on HER3 expression as demonstrated by its lack of activity on cells naturally expressing low levels of HER3 or its decreased anti-proliferative action on cells in which expression of HER3 was genetically reduced. The correlation between HER3 levels and the anti-proliferative action of EV20/MMAF also supported the dependency on HER3. However, the numerical value of that correlation suggests that other factors, in addition to HER3, may dictate the sensitivity to EV20/MMAF. This is a relevant finding since the therapeutic use of EV20/MMAF will rely on the identification of tumors highly sensitive to the ADC. An additional factor that may play a role in EV20/MMAF action relates to its internalization and degradation. In this respect, our immunofluorescence and biochemical analyses indicated that EV20/MMAF rapidly internalized and moved to acidic intracellular compartments, including lysosomes. In the latter, the action of lysosomal acidic proteinases is expected to generate cleaved fragments of EV20/MMAF capable of moving from the lysosomal lumen to the cytosol, where the cytotoxic payload should impair microtubule dynamics. In fact, EV20/MMAF prevented correct assembly of the microtubular machinery responsible for the progression of cells along mitosis. Such action not only affected cell cycle dynamics, but also promoted cell death through mitotic catastrophe, as occurs with other cytotoxic payloads (Montero et al, ; Garcia-Alonso et al, ). Finally, for cells in which HER3 may exert a pro-oncogenic action, its targeting with EV20/MMAF may sum to the mere ADC action as a vehicle to deliver the cytotoxic payload to HER3-expressing cells.

A relevant finding of this work was the strong anti-tumoral effect of EV20/MMAF on cells resistant to trastuzumab and other anti-HER2 therapies. Such action opens the possibility of using EV20/MMAF to fight resistance of HER2⁺ tumors to actual anti-HER2 strategies used in the clinic. In fact, in mice implanted with cells made resistant to trastuzumab, EV20/MMAF had a strong anti-tumoral effect, with interesting characteristics. First, EV20/MMAF caused tumor regression, even from large tumors. Second, such regression was complete and long-lasting after a single dose of 10 mg/kg. Lower doses (3.3 mg/kg) also caused tumor regression but in some mice relapses were observed. However, these relapsed tumors were still sensitive to additional doses of EV20/MMAF. Furthermore, maintenance of the treatment with 3.3 mg/kg every 3 weeks for a year resulted in tumor regression in all mice used, without relapses. Those data, together with the capability to exert anti-tumoral action in cells made resistant to T-DM1, lapatinib, or neratinib and even the effect of EV20/MMAF on naïve HER2⁺ cells offer attractive possibilities of using the anti-HER3 ADC for several indications in the HER2⁺ cancer clinic, even beyond breast cancer. In fact, anti-HER2 therapies such as trastuzumab are used for the therapy of HER2⁺ metastatic gastric tumors. It will be interesting to explore the value of EV20/MMAF for the therapy of these tumors. Moreover, the potent action of EV20/MMAF on HER3 expressing cells opens the possibility of extending its use for the therapy of patients bearing tumors in which HER3 expression is elevated, oncogenically mutated (Kiavue et al, ) or which may become resistant to therapies based on other HER3 ADCs (Garcia-Alonso et al, ). In fact, the development of trastuzumab-deruxtecan for patients which become refractory to previous anti-HER2 therapies, including T-DM1 (Modi et al, ), exemplifies the clinical value of using ADCs bearing different payloads but targeting the same cell surface protein. These clinical opportunities are worth being explored, once adequate biomarkers of sensitivity to the drug are available for correct patient selection.

Monomethyl auristatin F was from Sigma-Aldrich (Madrid, Spain). Lapatinib and neratinib were from Selleckchem (Houston, TX). EV20 and EV20/MMAF were generated by Mediapharma and were available through Dr. Gianluca Sala. Generic chemicals were from Sigma-Aldrich, Roche Biochemicals (St Louis, USA), or Merck (Darmstadt, Germany). Trastuzumab and T-DM1 were purchased from a local pharmacy. The anti-HER3 antibody used for immunoprecipitation or Western was created in rabbits injected with a fusion protein containing a unique intracellular region of HER3 (Sanchez-Martin & Pandiella, ). Other antibodies used are described in Appendix Table S1.

Culture media was from GIBCO BRL (Gaithersburg, MD, USA). The cell lines were cultured either in DMEM (BT474, PDX118, and resistant cells lines derived from them, SKBR3, MDA-MB-361, MDA-MB-231, HS5, and HEK293T) or in RPMI (BT549, HCC1419, HCC1569, HCC1954) supplemented with 10% FBS and antibiotics (penicillin 100 U/ml, streptomycin 100 μg/ml). All the cell lines were obtained from the ATCC except PDX118, TR1, and TR2 which were generously provided by Dr. Joaquin Arribas laboratory (VHIO, Barcelona). Cells resistant to trastuzumab or T-DM1 were generated by continuous exposure to the respective drugs, as described (Rios-Luci et al, , ; Diaz-Rodriguez et al, ). Briefly, for the generation of trastuzumab-resistant BT474 cells, 5,000 parental BT474 cells were plated in 150 mm dishes that were then treated with 50 nM trastuzumab for 12 months (media replaced weekly). Then, pools of resistant cells or individual clones were prepared and maintained in the absence or presence of trastuzumab for an additional 6-month period. The reason to maintain cultures with or without trastuzumab was to explore the stability of the resistant phenotype. In fact, we found unnecessary to maintain trastuzumab once resistance to the drug was established. Generation of T-DM1-resistant cells was achieved by culturing BT474 cells (5,000/150 mm dish) for three months in the presence of 5 nM T-DM1. Resistant clones were isolated by single-cell cloning as described (Rios-Luci et al, ). For the generation of lapatinib or neratinib-resistant cells, BT474 cells were plated at 5,000 cells/150 mm petri dishes and treated with 1, 5, 10, 50, 100, 500, 1,000, or 5,000 nM of the drugs. The best selection was achieved with doses of 1 and 5 μM of lapatinib and 10 nM of neratinib. After 3 months in culture under the continuous presence of the drug (media replaced weekly) pools or clones of resistant cells were obtained and tested for their sensitivity to those drugs, as compared to naïve BT474 cells. The action of trastuzumab or the other anti-HER2 drugs on the resistant cells was explored by cell counting or MTT assays. Knockdown of HER3 was performed by infection with lentiviral particles as described (Seoane et al, ). Briefly, 4 μg of the following plasmids: pMDLg/RRE, pRSV-Rev, and pMD2.G (Addgene, Cambridge, MA, USA), along with 8 μg of the pLKO.1 lentiviral plasmid containing a scramble shRNA (sh-Control) or the indicated shRNA (Sigma-Aldrich, St. Louis, MO, USA) were cotransfected into HEK293T cells using jetPEI^® reagent (Polyplus-transfection, Illkirch, France) following the manufacturer's instructions. Twenty-four hours later, HEK293T medium was replaced with fresh medium, and 48 h after the cotransfection, the medium containing lentiviral particles was collected, filtered, and used to infect cells after the addition of 6 μg/ml polybrene. Cells were cultured for 48 h to allow for efficient protein knockdown and were subsequently selected with 3 μg/ml puromycin (Sigma-Aldrich, St. Louis, MO, USA) for another 48 h. Five different shRNA sequences targeting HER3 were tested and those two that produced higher knockdown were used.

The preparation of cell lysates, immunoprecipitation, and Western blotting procedures has been described previously (Esparis-Ogando et al, ; Seoane et al, ). To prepare cell lysates, cells were washed with phosphate-buffered saline (PBS) (137 mM NaCl, 2.7 mM KCl, 8 mM Na₂HPO₄, 1.5 mM KH₂PO₄) and lysed in ice-cold lysis buffer (20 mM Tris–HCl pH 7.0, 140 mM NaCl, 50 mM EDTA, 10% glycerol, 1% Nonidet P-40, 1 μM pepstatin, 1 μg/ml aprotinin, 1 μg/ml leupeptin, 25 mM β-glycerol phosphate, 50 mM sodium fluoride, 1 mM phenylmethyl sulfonyl fluoride, 1 mM sodium orthovanadate) for 15 min. Lysates were cleared by centrifugation at 17,000 g at 4°C for 10 min and supernatants transferred to new tubes. Protein concentration in the lysates was measured using the BCA Assay (Thermo Fisher Scientific, Madrid, Spain). For immunoprecipitation, equal amounts of protein were incubated with the corresponding antibody and protein A-Sepharose at 4°C for at least 2 h. Immune complexes were recovered by a short centrifugation at 17,000 g for at least 30 s, followed by three washes with 1 ml ice-cold lysis buffer. Samples were then boiled in electrophoresis sample buffer and resolved by sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS–PAGE) gels. The percentage of the gel was chosen based on the molecular weight of the protein to be analyzed. For immunoblotting, proteins in gels were transferred to polyvinylidene difluoride membranes (Millipore Corporation, Bedford, MA, USA) using a wet transfer apparatus (Mini Trans-Blot Cell, Bio-Rad, Hercules, CA, USA). Membranes were then blocked in Tris-buffered saline with Tween (TBST) (20 mM Tris–pH 7.5, 150 mM NaCl, 0.1% Tween 20) containing 1% of bovine serum albumin for at least 1 h and then incubated with the corresponding antibody for 2–16 h at the dilutions indicated in Appendix Table S1. After washing with TBST, membranes were incubated with HRP-conjugated secondary antibodies for 30 min, washed three times, 7 min each time, and bands visualized by enhanced chemiluminescence. Densitometric measurements of the bands were done using ImageJ 1.44 software (National Institutes of Health, Bethesda, MD, USA) or Image Lab Software 6.0.1 (Bio-Rad). GraphpadPrism 6.0 (GraphPad Software, La Jolla, CA, USA) was used to determine IC₅₀ values. In experiments in which a condition was compared to a control, the intensity of the latter was taken as 1.

Cell proliferation was analyzed by cell counting assays (Rios-Luci et al, ). Briefly, cells were seeded in 6-well plates, and 24 h later, the medium was replaced with complete medium containing the desired drugs. Cells were collected and counted using a Z1 Coulter Particle Counter (Beckman Coulter, Pasadena, CA, USA). Cell cycle and apoptosis analyses were performed as described (Montero et al, ). For both assays, cells were cultured in 6-well plates and then were treated with drugs as the indicated time. Then, cell monolayers were collected by pooling together the non-attached and attached.

For cell cycle analysis, cells were fixed in ice-cold 70% ethanol minimum overnight. Then, cells were centrifuged at 300 g for 10 min and resuspended in 500 μl of PBS containing 500 μg/ml DNAse-free RNAse for 2 h at 37°C. After that, propidium iodide (5 μg/ml) was added and DNA content analyzed in an Accuri C6 Flow Cytometer (BD).

For apoptosis assays, the protocol of the FITC-Annexin V Apoptosis Detection Kit I (BD Biosciences) was followed. Attached and non-attached cells were collected and resuspended in 100 μl of ice-cold binding buffer (10 mM HEPES pH 7.4, 140 mM NaCl, 2.5 mM CaCl₂) containing 5 μl of Annexin V-FITC and 5 μl of PI (50 μg/ml). Samples were incubated for 15 min at room temperature, and after this time, 400 μl of binding buffer was added to each tube and cells acquired in an Accuri C6 Flow Cytometer (BD). In both experiments, 50,000 events were collected and analyzed.

To analyze caspase 3 activity, cells were treated as required and lysed in lysis buffer with protease and phosphatase inhibitors. A 50 μg of protein was incubated in the caspase reaction buffer (25 mM HEPES pH 7.4, 150 mM NaCl, 1 mM EDTA, 0.1% CHAPS, 10% sucrose), 10 mM DTT and containing 5 μM of the fluorescent substrate Ac-DEVD-AFC (BD Biosciences) at 37°C for 1 h at dark. The fluorometry signal was measured at 400/505 nm in a multi-well fluorescent reader (BioTek). Analysis of mitotic cells was carried out as described (Rios-Luci et al, ). In brief, cells were seeded at low density, treated with EV20/MMAF, and stained with DAPI and anti-β-tubulin. Then, cells were observed in a Zeiss Axiophot 2 microscope with 63× oil immersion objective. For each condition, at least 2,000 cells were counted. Cell with condensed chromosomes was considered mitotic cells.

Cytometric assessment of cell surface HER3 was performed by incubation for 30 min with 10 nM of EV20/MMAF. The cell-bound antibodies were detected by incubation with a cyanine 3-conjugated anti-human secondary antibody. Mean fluorescence levels were determined using a BD Accuri C6 flow cytometer. For cell surface immunoprecipitation, cells were washed twice with Krebs-Ringer-HEPES buffer(140 mM NaCl, 5 mM KCl, 2 mM CaCl₂, 5 mM MgSO₄, 1.2 mM KH₂PO₄, 50 mM HEPES, pH 7.4) (Cabrera et al, ) and incubated in the same buffer with 10 nM EV20/MMAF or trastuzumab for 2 h at 4°C. Then, cells were lysed and cell-bound antibodies precipitated with protein A-Sepharose. Immunocomplexes were then washed and HER2 or HER3 detected by Western.

For immunofluorescence (IF) detection of EV20/MMAF, 100,000 or 150,000 BT474 or BTRH cells were cultured on glass coverslips inserted into 35 mm dishes and treated with 10 nM EV20/MMAF for the indicated times. Then, cells on coverslips washed with PBS/CM (1 mM CaCl₂, 0.5 mM MgCl₂ in PBS), fixed in 2% paraformaldehyde, and then washed with PBS/CM. After that, incubations were quenched with 50 mM NH₄Cl, and cells were permeabilized (0.1% triton, 0.2% BSA) and then coverslips with cells incubated for 1 h in blocking solution, that contained PBS/CM with 0.2% BSA. Before incubation with Cy3-conjugated anti-human antibody, cells were washed in PBS/CM/BSA. Samples were analyzed by confocal IF microscopy using a Leica TCS SP5 system (Leica Microsystems CMS, Wetzlar, Germany). For indirect IF, cells were cultured and processed as above, including an incubation step with primary antibodies against β-tubulin or LAMP1 (Rios-Luci et al, ). Cy2-conjugated goat anti-mouse was used to detect β-tubulin and Cy2-conjugated goat anti-rabbit for LAMP1. Colocalization was analyzed with Leica Application Suite Advanced Fluorescence (LAS AF Version 2.7.3.9723). For live cell microscopy evaluation of EV20/MMAF internalization and targeting to acidic intracellular compartments, the antibody was labeled with pHrodoTMiFL Red Microscale Protein Labeling Kit (Thermo Scientific) according to the manufacturer's instructions and following published procedures (Rios-Luci et al, ). Images were acquired every 15 min for 24 h using a Nikon Eclipse TE2000-E microscope. Videos were prepared with Image J.

EV20/MMAF was biotinylated with EZ-Link NHS-SS-Biotin (Thermo Scientific) according to the manufacturer's instructions and as described (Rios-Luci et al, ). Briefly, 500 μg EV20/MMAF was incubated with a 20-fold molar excess of a 10 mM NHS-SS-Biotin solution in DMSO. The non-reacted NHS-SS-Biotin was quenched with 50 mM of NH₄Cl. Cells were treated with 10 nM biotin-labeled EV20/MMAF for 1 h at 4°C, then washed twice with PBS to remove any unbound biotin-EV20/MMAF, and chased for the indicated times at 37°C. Non-internalized biotin-labeled EV20/MMAF was removed by washing three times with ice-cold freshly prepared cleavage buffer (Rios-Luci et al, ). Cells were then washed twice with PBS and lysed in ice-cold lysis buffer (150 mM NaCl, 1 mM EDTA, 10% glycerol, 40 mM HEPES pH 7.4, 1% Nonidet P-40, and phosphatase and protease inhibitors). Biotin-labeled EV20/MMAF was precipitated with streptavidin-Sepharose high performance (GE Healthcare), for at least 2 h at 4°C. Immunocomplexes were recovered, washed, and resolved by SDS–PAGE and standard Western blotting.

Female BALB/c nu/nu mice (8–9 weeks old) were purchased from Charles River Laboratories and maintained and manipulated at the animal facility of the University of Salamanca following legal and institutional guidelines. A total of 5 × 10⁶ BTRH, BTRH#10, HCC1954, or BT-TDM1R#6 cells resuspended in DMEM and Matrigel (BD Biosciences) were injected orthotopically into the mammary fat pad, at two sites per mice. When tumors reached a volume of 500 mm³, animals were randomized to four groups with similar mean tumor volumes that were intraperitoneally treated with vehicle alone (PBS), EV20 (10 mg/kg), T-DM1 (15 mg/kg), trastuzumab (30 mg/kg), or EV20/MMAF (3.3 mg/kg or 10 mg/kg). Tumor diameters were measured with calipers, and tumor volumes were calculated by the following formula: volume = (width² × length)/2. At the time of sacrifice, some tumor samples or tissues were collected and immediately frozen in liquid nitrogen. They were later lysed using a Dispomix drive tissue homogenizer (Medic tools), and EV20/MMAF was analyzed by immunoprecipitation of 500 μg of protein with protein A-Sepharose and Western blotting with the HRP-conjugated anti-human secondary antibody.

In proliferation experiments, each condition was analyzed in triplicate and data presented as mean + SD of an experiment representative of at least 2 independent experiments. Statistical analyses were carried out using SPSS 25 (SPSS Inc., Chicago, IL, USA). Pearson correlation and regression analyses were used for the correlation studies. Two-way factorial ANOVA with Bonferroni correction was used when more than one factor was present. One-way ANOVA was used to compare more than two groups. The Bonferroni post hoc test or Games–Howell post hoc test was used in case of variance homogeneity or heterogeneity, respectively. Data distributions were checked for normality by the Shapiro–Wilk test, and homogeneity of variances was checked by the Levene test. Welch's t-test was used to compare two groups when the distribution is assumed to be normal, and the samples have unequal variances.

AP: Ministry of Economy and Competitiveness of Spain (BFU2015-71371-R), the Instituto de Salud Carlos III through the Spanish Cancer Centers Network Program (RD12/0036/0003) and CIBERONC, the Scientific Foundation of the Spanish Association Against Cancer (AECC), ALMOM, and the CRIS Cancer Foundation. Work carried out in AP and AO laboratories receives support from the European Community through the Regional Development Funding Program (FEDER). GS: Fondazione-AIRC (IG GRANT 2016, Id 18467). EC is the recipient of an AIRC fellowship. LGS is recipient of a predoctoral contract (BES-2016-077748).

LGS: performed the experiments, interpreted data, read, and corrected the paper. EC: prepared the antibody, read, and corrected the paper; AO: read the paper and suggested ideas; SI: read the paper and suggested ideas; GS: designed the study and the antibody, read, and corrected the paper; AP: designed the study and wrote the paper.

GS and SI are shareholders of Mediapharma s.r.l.; and the other authors declare that they have no conflict of interest in this study.