ROS1 tyrosine kinase inhibitors (TKI) have been approved (crizotinib and entrectinib) or explored (lorlatinib, taletrectinib, and repotrectinib) for the treatment of ROS1 fusion–positive cancers, although none of them simultaneously address the need for broad resistance coverage, avoidance of clinically dose-limiting TRK inhibition, and brain penetration. NVL-520 is a rationally designed macrocycle with >50-fold ROS1 selectivity over 98% of the kinome tested. It is active in vitro against diverse ROS1 fusions and resistance mutations and exhibits 10- to 1,000-fold improved potency for the ROS1 G2032R solvent-front mutation over crizotinib, entrectinib, lorlatinib, taletrectinib, and repotrectinib. In vivo, it induces tumor regression in G2032R-inclusive intracranial and patient-derived xenograft models. Importantly, NVL-520 has an ∼100-fold increased potency for ROS1 and ROS1 G2032R over TRK. As a clinical proof of concept, NVL-520 elicited objective tumor responses in three patients with TKI-refractory ROS1 fusion–positive lung cancers, including two with ROS1 G2032R and one with intracranial metastases, with no observed neurologic toxicities.

Significance:

The combined preclinical features of NVL-520 that include potent targeting of ROS1 and diverse ROS1 resistance mutations, high selectivity for ROS1 G2032R over TRK, and brain penetration mark the development of a distinct ROS1 TKI with the potential to surpass the limitations of earlier-generation TKIs for ROS1 fusion–positive patients.

This article is highlighted in the In This Issue feature, p. 517

ROS1 is an orphan receptor tyrosine kinase encoded by the ROS1 proto-oncogene (1). Chromosomal rearrangements joining the 3′ region of ROS1, which encodes the kinase domain, with the 5′ region of partner genes produce constitutively active ROS1 fusion kinases. These fusions drive aberrant downstream signaling and transformation and are recurrent oncogenic drivers in human cancers (1). ROS1 fusions are present in 1% to 3% of advanced non–small cell lung cancer (NSCLC), in which CD74–ROS1 is the most prevalent fusion (2), and in other solid tumors such as cholangiocarcinoma (3), glioblastoma (4), angiosarcoma (5), and ovarian cancer (6). More than 50 ROS1 fusion partners have been identified (7), including CD74, CEP85L, EZR, GOPC(L), GOPC(S), SDC4, and SLC34A2. Each fusion partner may exert a different effect on subcellular localization, signaling, metastatic capacity, and drug sensitivity (8–10).

The tyrosine kinase inhibitors (TKI) crizotinib (11) and entrectinib (12) are approved by multiple regulatory agencies for the treatment of patients with TKI-naive ROS1 fusion–positive NSCLC. The National Comprehensive Cancer Network Clinical Practice Guidelines in Oncology list lorlatinib (13) as a treatment option for TKI-treated ROS1 fusion–positive NSCLC (14). The investigational TKIs taletrectinib (15) and repotrectinib (16) are undergoing clinical evaluation for the treatment of ROS1 fusion–positive cancers. Despite the availability of these options, each TKI has key deficiencies that can limit the likelihood and durability of therapeutic response.

Crizotinib has limited brain penetrance (17), an important deficiency given that 20% to 40% of patients with ROS1 fusion–positive NSCLC present with central nervous system (CNS) metastases at diagnosis (18), and CNS metastases represent the sole site of progression in half of crizotinib-treated patients (19). Furthermore, the efficacy of crizotinib, entrectinib, and lorlatinib is limited by acquired mutations in the ROS1 kinase domain (20, 21). The G2032R “solvent-front” substitution, identified in 30% to 40% of patients after crizotinib or lorlatinib progression (20), is particularly recalcitrant. Other clinically observed ROS1 resistance mutations include S1986F (22), S1986Y (22), F2004C (23), F2004I (21), F2004V (24), L2026M (25), D2033N (26), and G2101A (27).

Although responses to taletrectinib and repotrectinib have been reported in patients with tumors harboring ROS1 G2032R, both agents are associated with toxicities including gastrointestinal and neurologic adverse events (15, 28, 29). Many neurologic adverse events are attributed to the inhibition of tropomyosin-related kinases (TRK): TRKA, TRKB, and TRKC (30). Entrectinib, lorlatinib, taletrectinib, and repotrectinib inhibit both ROS1 and TRKA/B/C (12, 15, 31, 32) due to structural similarities between these kinases. TRKB inhibition has been associated with cognitive impairment, mood/sleep disturbance, dizziness, ataxia, orthostasis, and weight gain—side effects that can be dose limiting and affect quality of life (33).

These experiences underscore the need for a ROS1 inhibitor that surpasses the limitations of earlier-generation agents. We describe the discovery of a novel ROS1-selective TKI, NVL-520. Preclinical characterization in biochemical assays, cell-based assays, and in vivo cancer models indicates that NVL-520 potently inhibits diverse ROS1 fusions and resistance mutations, is brain penetrant, and spares TRK inhibition. These preclinical findings are supported by three case studies presented here from an ongoing first-in-human study of NVL-520. Among these cases, which include two patients with detectable ROS1 G2032R, intracranial and/or extracranial RECIST 1.1 partial responses were observed in the absence of neurologic toxicities.

Design and Structure

NVL-520 is a macrocyclic small molecule (Fig. 1A). Computational modeling suggested that NVL-520 binds ROS1 in a manner similar to lorlatinib (PDB: 4UXL; ref. 34), with the aminopyridine moiety of NVL-520 forming two hydrogen bonds with Glu2027 and Met2029 in the hinge region (Fig. 1B). Besides binding ROS1, NVL-520 was rationally designed to address the three following medical needs.

Activity for ROS1 Resistance Mutations

The chemical structures of crizotinib, entrectinib, and lorlatinib have atoms that partially or fully occupy the solvent-front region of the binding pocket. Mutations in this region, particularly G2032R, have been hypothesized to cause a steric clash between protein and inhibitor, reducing TKI affinity and conferring TKI resistance (32, 35). NVL-520 was designed to minimize bulk in this region, potentially reducing steric clashes and thereby preserving affinity for ROS1 G2032R. Consistent with this design, free energy perturbation (FEP) calculations (36, 37) predicted larger binding energy shifts and ligand movement upon direct computational mutation of Gly2032 to arginine for crizotinib, entrectinib, and lorlatinib (ΔΔGFEP ≥ 3.6 kcal/mol and ΔRMSD ≥ 0.4 Å) compared with NVL-520 (ΔΔGFEP = 1.5 kcal/mol and ΔRMSD = 0 Å; Supplementary Fig. S1A and S1B). Additionally, FEP simulations revealed a hydrogen bond between the N-ethyl pyrazole of NVL-520 and Arg2032 (Fig. 1B). FEP results were further supported by biochemical assays and a resistant allele study (vide infra), as well as by predictions for repotrectinib that are consistent with its reported ROS1 G2032R activity (ref. 32; ΔΔGFEP = 0.2 kcal/mol and ΔRMSD = 0.1 Å; Supplementary Fig. S1A and S1B).

Avoiding TRK Inhibition

The ROS1 TKIs entrectinib, taletrectinib, and repotrectinib cross-interact with TRK because of structural similarities between the kinases. Based on a crystal structure (PDB: 4UXL; ref. 34), amino acids that lie within 4.5 Å of the ROS1 ligand binding pocket have >70% identity with analogous residues on TRKA. To improve selectivity, we performed structural overlays and identified a potential differentiating residue at Leu2028 of ROS1, which corresponds to a sterically larger tyrosine residue at the equivalent position in TRK (TRKA Y591, TRKB Y619, and TRKC Y619; Fig. 1C). The N-ethyl pyrazole of NVL-520 was found to potentially clash with the larger tyrosine residue in TRKA/TRKB/TRKC (Fig. 1C) while avoiding a negative interaction with the smaller Leu2028 in ROS1, which could result in preferential binding to ROS1 over TRK.

Brain Penetrance

The physicochemical properties of NVL-520 (molecular weight: 419 g/mol; calculated logD7.4: 2.8; topological polar surface area: 97 Å2; predicted basic pKa: 5.7; and two hydrogen bond donors; Supplementary Fig. S1C) suggested that the compound exists within CNS drug chemical space. A CNS multiparameter score of 4.5 was derived, consistent with the potential for brain penetrance and activity (38).

Biochemical Activity

Wild-type ROS1

Six ROS1 TKIs (crizotinib, entrectinib, lorlatinib, taletrectinib, repotrectinib, and NVL-520) were profiled in a biochemical phosphorylation assay using the purified wild-type ROS1 kinase domain. The assay was performed in the presence of 1 mmol/L ATP to simulate competitive inhibition against a physiologic ATP concentration. All compounds potently inhibited wild-type ROS1 (IC50 = 0.3–12 nmol/L; Fig. 1D), with NVL-520 exhibiting subnanomolar potency (IC50 = 0.7 nmol/L; Fig. 1D; Supplementary Fig. S2A).

ROS1 G2032R

G2032R is the most frequent ROS1 substitution that confers clinical resistance to ROS1 TKIs after disease progression on crizotinib, entrectinib, or lorlatinib (20, 21). Consistent with these observations, purified ROS1 G2032R was resistant to crizotinib, entrectinib, and lorlatinib (IC50 = 790–5,700 nmol/L; Fig. 1D), corresponding to a >100-fold loss in potency compared with wild-type ROS1 (IC50 = 0.3–12 nmol/L). Taletrectinib and repotrectinib had moderate activity against ROS1 G2032R (IC50 = 30–100 nmol/L). By contrast, NVL-520 demonstrated single-digit nanomolar potency against ROS1 G2032R (IC50 = 7.9 nmol/L), representing a potency improvement of 4-fold over repotrectinib (IC50 = 30 nmol/L), 13-fold over taletrectinib (IC50 = 100 nmol/L), and >100-fold over crizotinib, entrectinib, and lorlatinib (IC50 = 790–5,700 nmol/L; Fig. 1D; Supplementary Fig. S2B). The biochemical potency shifts between wild-type ROS1 and ROS1 G2032R (ΔΔGbiochem) correlated well with binding energy shifts predicted by FEP calculations (ΔΔGFEP; Supplementary Fig. S1B).

Kinome Selectivity

In a biochemical screen against 335 wild-type human kinase domains, NVL-520 was highly selective (Fig. 1E; Supplementary Fig. S3A). ROS1 was the most strongly inhibited target, followed by ALK which had 2-fold weaker IC50 than ROS1 (Supplementary Fig. S3B). Besides ALK, no other kinases were inhibited within 10-fold of the IC50 of NVL-520 for ROS1. NVL-520 had a >50-fold selectivity for ROS1 over 97.9% (328/335) of the tested kinome, with only five additional targets (LTK, FAK, PYK2, FER, and TRKB) inhibited with IC50 between 10- and 50-fold of ROS1 (Supplementary Fig. S3B). Because TRKB scored in this assay as a weak hit (IC50 = 28-fold above ROS1) and was a key off-target of concern, we further profiled TRKB using additional assays (see the “Selectivity for ROS1 over TRK” section).

Cellular Activity

Six ROS1 TKIs (crizotinib, entrectinib, lorlatinib, taletrectinib, repotrectinib, and NVL-520) were profiled in cell viability assays against a collection of two patient-derived cell lines, one human cancer cell line, and 18 engineered Ba/F3 cell lines (Fig. 2AC; Supplementary Fig. S4A and S4B). These cell lines encompassed six ROS1 fusion partners [SLC34A2, EZR, CD74, GOPC(L), GOPC(S), and CEP85L] and eight ROS1 mutational variants (wild-type, G2032R, S1986F, F2004C, F2004V, L2026M, D2033N, and G2101A).

Wild-type ROS1

In seven cell lines expressing wild-type ROS1 fusions, all six TKIs had growth inhibitory activity albeit with differing levels of potency (Fig. 2A and D). NVL-520 and lorlatinib were the most potent (average IC50 = 0.4 nmol/L and 0.5 nmol/L, respectively; Fig. 2D), with potency exceeding that of repotrectinib by 7-fold (IC50 = 3.3 nmol/L) and that of crizotinib, entrectinib, or taletrectinib by >19-fold (IC50 = 9.7–30 nmol/L). To confirm that the antiproliferative activity of NVL-520 correlated with inhibition of ROS1 signaling, we measured ROS1 pathway activity in the MGH193-1 patient-derived cell line (EZR–ROS1). NVL-520 completely inhibited ROS1 autophosphorylation and downstream AKT/ERK signaling at 3 nmol/L, the lowest tested concentration (Supplementary Fig. S5A and S5B), supporting an on-target mechanism of action.

ROS1 G2032R

In six cell lines harboring ROS1 fusions with the G2032R mutation, NVL-520 was the only TKI to achieve single-digit nanomolar potency (average IC50 = 1.6 nmol/L; Fig. 2B and E), which exceeded repotrectinib and taletrectinib by >10-fold (IC50 = 18–44 nmol/L), lorlatinib by >60-fold (IC50 = 98 nmol/L), and crizotinib and entrectinib by >500-fold (IC50 = 850–920 nmol/L). Consistent with on-target activity, NVL-520 potently inhibited ROS1 signaling (Supplementary Fig. S5C and S5D) in the MGH9018-1 patient-derived cell line harboring CD74–ROS1 G2032R derived from a patient after crizotinib progression.

To measure the effects of G2032R substitution on TKI sensitivity, we analyzed the IC50 shifts from wild-type ROS1 to ROS1 G2032R for six TKIs in three matched fusion pairs (Supplementary Fig. S6). The analysis revealed two distinct groups of ROS1 TKIs based on their tolerance to G2032R. For the first group comprising crizotinib, entrectinib, and lorlatinib, G2032R caused an IC50 loss of 60- to 220-fold compared with wild-type ROS1, consistent with G2032R being observed in patients progressing on these drugs (20, 21). The second group comprising taletrectinib, repotrectinib, and NVL-520 was more tolerant of G2032R, showing an IC50 loss of 3- to 4-fold compared with wild-type ROS1 (Supplementary Fig. S6).

Other ROS1 Resistance Mutations

Besides G2032R, other substitutions observed after disease progression on crizotinib and/or entrectinib include S1986F, F2004C, F2004V, L2026M, D2033N, and G2101A (22–27). We expressed CD74–ROS1 or EZR–ROS1 fusion proteins harboring these mutations in Ba/F3 cells and tested them in cell viability assays against six TKIs. NVL-520 potently inhibited the non-G2032R ROS1 mutants with IC50 ≤ 1.5 nmol/L (Fig. 2C; Supplementary Fig. S7A). IC50 shift analysis revealed that most non-G2032R mutations caused ROS1 to become more resistant to crizotinib and entrectinib (Supplementary Fig. S7B), but the degree of resistance was modest (IC50 shift = 0.7–5.7-fold; Supplementary Fig. S7C, red box) and smaller in magnitude compared with G2032R (IC50 shift = 24–110-fold). Conversely, the non-G2032R mutations did not confer resistance to lorlatinib, taletrectinib, repotrectinib, and NVL-520 (IC50 shift = 0.01–1.3-fold; Supplementary Fig. S7C, green box).

Fusion Partners

Given the diversity of upstream ROS1 fusion partners (7–10), we interrogated ROS1 TKIs in Ba/F3 cells expressing CD74–, EZR–, GOPC(L)–, GOPC(S)–, CEP85L–, or SLC34A2–ROS1 fusions, with a wild-type kinase domain or with the G2032R mutation. NVL-520 showed potent activity across all ROS1 fusions evaluated (IC50 < 10 nmol/L; Fig. 2D and E).

ROS1 On-Target Activity

We determined that the ROS1 L2086F mutation desensitized Ba/F3 cells to NVL-520, shifting its IC50 from 1.3 nmol/L for CD74–ROS1 to 6.8 μmol/L for CD74–ROS1 L2086F (Supplementary Fig. S8A–S8C). ROS1 L2086F is an on-target resistance mutation observed in cancers from patients who progressed on lorlatinib (20). A steric clash was postulated between L2086F and lorlatinib based on a cocrystal structure of lorlatinib and ROS1 (PDB: 4UXL; ref. 20). The shift in potency observed with NVL-520 is consistent with this steric clash hypothesis. This drug-resistant allele indicates that the activity of NVL-520 in ROS1-driven cells is a consequence of direct pharmacologic inhibition of ROS1. NVL-520 also did not inhibit the growth of ROS1-independent cell lines including A549 (KRAS G12S lung carcinoma), A431 (EGFR-amplified epidermoid carcinoma), NCI-H1975 (EGFR L858R/T790M NSCLC), engineered Ba/F3 cells (EGFR L858R/T790M/C797S), and IL3-supplemented parental Ba/F3 cells (IC50 > 8.5 μmol/L in all cases; Supplementary Fig. S8A), further supporting the activity of NVL-520 in ROS1-driven cells as on target. Consistent with kinome profiling, NVL-520 inhibited the viability of ALK fusion–positive cell lines (Supplementary Fig. S8A).

Anchorage-Independent Growth

Anoikis avoidance is a hallmark of cancer and is potentially indicative of migratory or metastatic propensity (39, 40). To study the effect of ROS1 inhibition on anoikis, we performed anchorage-independent colony formation assays in NIH3T3 cells expressing CD74–ROS1 or EZR–ROS1 fusions. ROS1-transformed NIH3T3 cells lost contact inhibition and formed colonies on soft agar. For NIH3T3 cells expressing wild-type ROS1 fusions, all ROS1 TKIs evaluated suppressed colony formation by >80% at ≤100 nmol/L, with NVL-520 and lorlatinib having the highest potency, followed by crizotinib and then entrectinib (Supplementary Fig. S9A–S9C). This potency trend correlated with the degree of target engagement and signaling modulation measured by Western blotting (Supplementary Fig. S9D and S9E). In contrast, for NIH3T3 cells expressing ROS1 fusions with G2032R, only NVL-520 was able to inhibit colony formation by ≥90% at 100 nmol/L, whereas other TKIs (crizotinib, entrectinib, and lorlatinib) had weaker effects at the same concentration (Supplementary Fig. S10A–S10C). This potency trend was confirmed by pathway analysis (Supplementary Fig. S10D and S10E). Although we did not evaluate taletrectinib in the colony formation assay, Western blot analysis indicated that NVL-520 was more potent than taletrectinib in ROS1-driven NIH3T3 cells (Supplementary Fig. S9D and S10D), consistent with our observations in cell culture.

Selectivity for ROS1 over TRK

Avoiding TRK inhibition was a primary goal in designing NVL-520. TRK inhibitory potency was measured in biochemical, cell viability, and cellular phosphorylation assays. Rather than absolute potency, we focused our analysis on the relative potency between TRK and ROS1 and defined a “selectivity window” as the IC50 ratio of TRK to ROS1 (wild-type or G2032R). A selectivity window > 1 implied higher potency for ROS1 than TRK, whereas a selectivity window < 1 indicated higher potency for TRK than ROS1. We profiled six ROS1 TKIs and calculated their selectivity windows in the below three assays.

Biochemical Assay

TKIs were assayed against purified TRKA, TRKB, and TRKC kinase domains. Individual potency against each TRK and the average potency across three TRK proteins are shown in Supplementary Fig. S11A. Entrectinib, taletrectinib, and repotrectinib inhibited all three TRK proteins with equal or even greater potency than ROS1 (average TRK IC50 < 5 nmol/L), resulting in relatively narrow selectivity windows (range: <0.0001–2.6-fold; Supplementary Fig. S11B). NVL-520 and lorlatinib were not potent TRK inhibitors (average IC50 = 130 nmol/L). Although lorlatinib was selective for wild-type ROS1 over TRK, this selectivity window was lost in the presence of G2032R (decreased from 433-fold to 0.2-fold; Supplementary Fig. S11B). By contrast, NVL-520 demonstrated selectivity for both wild-type ROS1 and ROS1 G2032R over TRK (185-fold and 16-fold, respectively; Supplementary Fig. S11B).

Cell Viability Assay

We expressed oncogenic TPM3–TRKA, ETV6–TRKB, or ETV6–TRKC fusion proteins in Ba/F3 cells and used antiproliferative activity as a surrogate for TRK inhibition. Consistent with the results from the biochemical assays, NVL-520 was the only TKI to demonstrate selectivity for both wild-type ROS1 and ROS1 G2032R over TRK in cell viability assays (210-fold and 75-fold, respectively; Supplementary Fig. S12A and S12B).

Cellular Phosphorylation Assay

TRK-related neurologic toxicities are most consistent with the known functions of the TRKB signaling pathway (30, 33). We therefore developed an additional assay that uses Ba/F3 cells stably expressing full-length TRKB. Stimulation of this cell line with the brain-derived neurotrophic factor (BDNF) promotes TRKB autophosphorylation (pTRKB). Consistent with our results in biochemical and cell viability assays, NVL-520 only weakly inhibited cellular TRKB phosphorylation (IC50 = 850 nmol/L; Fig. 3A), affording a wide selectivity window for both wild-type ROS1 and ROS1 G2032R over pTRKB (670-fold and 240-fold, respectively; Fig. 3B) that was not achieved with any other ROS1 TKI tested.

In Vivo Activity

Wild-type ROS1 Xenografts

In subcutaneous CTG-0848 (CD74–ROS1) and Lu01-0414 (SDC4—ROS1) xenograft models derived from patients with ROS1 fusion–positive NSCLC, NVL-520 induced tumor regression at all doses ≥ 0.2 mg/kg twice daily (b.i.d.), showing a 77% to 95% average reduction in tumor volume on day 20 or 28, respectively (Fig. 4A and B). Even at the lowest dose evaluated (0.04 mg/kg b.i.d., corresponding to a plasma-free drug concentration at dosing trough or Cmin,free of only 0.2 to 0.7 nmol/L; Supplementary Fig. S13A and S13B), NVL-520 suppressed tumor growth in both models (Fig. 4A and B), consistent with its subnanomolar in vitro potency. Maximal efficacy was achieved at 0.2 to 1 mg/kg b.i.d.; no additional tumor suppression was observed at higher doses (Fig. 4A and B). At maximally efficacious doses of 5 and 15 mg/kg b.i.d. of NVL-520, treatment was continued until day 42, followed by treatment withdrawal and monitoring for an additional 42 days. Tumor volumes continually declined in both models during the 42 days of NVL-520 treatment. After treatment cessation, tumor volumes continued to be suppressed in the CTG-0848 model but increased in the Lu01-0414 model (Supplementary Fig. S13C and S13D).

Western blot analysis of tumor samples confirmed ROS1 inhibition in vivo, supporting an on-target mechanism of action (Supplementary Fig. S13A and S13B). NVL-520 promoted PARP cleavage, a marker of tumor cell apoptosis (Supplementary Fig. S13B), and induced a reduction in total ROS1 after 5 days of dosing (Supplementary Fig. S13A and S13B) in agreement with a previous report (41). Plasma drug concentrations upon a single dose or short-term repeat dosing (b.i.d. × 5 days) were similar, and drug exposure increased linearly between the two doses examined (5 mg/kg yielded plasma drug concentrations approximately 100-fold that of the 0.04 mg/kg dose; Supplementary Fig. S13A and S13B). Plasma drug concentrations at different doses and time points correlated with the degree of ROS1 inhibition (Supplementary Fig. S13A and S13B).

ROS1 G2032R Xenografts

CTG-2532 and MGH9018-1 xenograft models were established from patients with NSCLC after crizotinib relapse; both patient-derived xenografts (PDX) harbor CD74–ROS1 with the G2032R resistance substitution. In both models, NVL-520 induced near-maximal regression at 5 mg/kg b.i.d., with an 88% to 94% average reduction in tumor volume (Fig. 4C and D). Western blot analysis revealed exposure-dependent ROS1 inhibition in tumors similar to that seen with our wild-type ROS1 xenografts, supporting on-target activity (Supplementary Fig. S14A and S14B). Furthermore, NVL-520 induced regression in the Ba/F3 CD74–ROS1 G2032R xenograft model that displayed a highly aggressive tumor growth behavior (13-fold tumor volume increase over 14 days in the vehicle group; Fig. 4E). No meaningful reductions in body weight were observed for NVL-520 in any of the studies at doses ranging from 0.04 to 15 mg/kg b.i.d. (Supplementary Fig. S15A–S15E). Taken together, our studies demonstrated the strong in vivo efficacy of NVL-520 against tumors driven by ROS1 fusions with or without the G2032R resistance substitution.

In the CTG-2532 and Ba/F3 xenograft models harboring CD74–ROS1 G2032R, we included repotrectinib treatment groups at 15 and 75 mg/kg b.i.d. following previously reported doses (32). Repotrectinib was not as efficacious or well tolerated as NVL-520 in the CTG-2532 model; it achieved tumor stasis at 15 mg/kg b.i.d. for most of the treatment period (Fig. 4D) but was not tolerated at 75 mg/kg b.i.d., as evidenced by a rapid ∼20% body weight loss from days 6 to 13 (Supplementary Fig. S15D; no animals survived to the day 17 time point). However, both doses of repotrectinib induced regression in the Ba/F3 model (Fig. 4E). Of note, different mouse strains were utilized in the CTG-2532 model (athymic Nude-Foxn1nu mice) and the Ba/F3 model (Balb/c nude mice).

Preclinical Intracranial Activity

NVL-520 exhibited a Kp,uu (unbound brain-to-plasma partitioning) of 0.16 measured at 1 hour after a single oral 10 mg/kg dose in Wistar Han rats, which was comparable to that of lorlatinib (Kp,uu = 0.11 in the same assay), a TKI with high CNS penetration (42–44). To assess intracranial antitumor activity, we generated a Ba/F3 CD74–ROS1 G2032R luciferase model that permitted monitoring of the brain tumor burden via live-animal bioluminescence imaging. We intracranially injected Ba/F3 CD74–ROS1 G2032R luciferase cells into mice and observed rapid tumor growth (Fig. 5A and B). All vehicle-treated mice lost body weight (Supplementary Fig. S15F) and succumbed to disease by day 19 with a median overall survival (mOS) of 16.5 days (Fig. 5C). In contrast, NVL-520 at 2 mg/kg suppressed intracranial tumor growth, with mean body weight loss <10% and all mice surviving to study termination (mOS > 61 days), corresponding to a >4-fold survival extension over vehicle treatment (Fig. 5AC; Supplementary Fig. S15F). These results indicated that NVL-520 had intracranial antitumor activity.

Proof-of-Concept Clinical Activity

In the ongoing dose-escalation portion of the ARROS-1 first-in-human study of NVL-520, intracranial and extracranial activity has been observed in patients with TKI-pretreated ROS1 fusion–positive NSCLC with and without the G2032R mutation (45).

Case Study 1

A 54-year-old patient with metastatic lung adenocarcinoma that responded to two cycles of carboplatin, paclitaxel, bevacizumab, and atezolizumab tested positive for ROS1 fusion by fluorescence in situ hybridization on tumor tissue. The patient received crizotinib for 2 months, complicated by pneumonitis, and subsequently received lorlatinib with an initial partial response (PR). Intrathoracic disease progression followed after 32 months. She then received two cycles of carboplatin and pemetrexed with continued lorlatinib and had stable disease. Next-generation sequencing (NGS) of a lorlatinib-resistant lung nodule revealed a CD74–ROS1 fusion with ROS1 G2032R. The patient initiated NVL-520 at the lowest dose level of 25 mg once daily (q.d.). A clinical response was achieved within 2 weeks of therapy, with marked improvement in the patient's dyspnea. Imaging after 4 weeks showed a PR with a decrease in multiple bilateral lung metastases (−31% by RECIST 1.1), consistent with the plasma exposure level of NVL-520 (Supplementary Fig. S16A and S16B). The patient's NVL-520 dose was escalated to 75 mg q.d. after 8 weeks as permitted by the protocol, and she remained on therapy for approximately 6 months with an ongoing confirmed PR (−60% by RECIST 1.1; Fig. 6A) and with no reported neurologic toxicities as of the data cutoff.

Case Study 2

In addition to extracranial antitumor activity, intracranial activity was observed in another patient with metastatic NSCLC harboring EZR–ROS1 G2032R. A 65-year-old patient with stage IV lung adenocarcinoma and multiple brain metastases had EZR–ROS1 identified by circulating tumor DNA (ctDNA) testing. Entrectinib was initiated with an initial response, but the patient's disease progressed 9 months later. A biopsy of a growing liver lesion confirmed the known EZR–ROS1 fusion and identified a ROS1 G2032R mutation. The patient was transitioned to a clinical trial of repotrectinib. The patient quickly required a change in systemic therapy due to progressive disease and began a combination of carboplatin, pemetrexed, bevacizumab, and entrectinib. Unfortunately, a mixed response, growing brain metastases, and new liver metastases were observed. Repeat ctDNA testing again detected ROS1 G2032R. NVL-520 was initiated at 50 mg q.d. At week 4, regression of a right occipital lobe metastasis was observed in addition to a decrease in several metastases in the liver and lung (−38% by RECIST 1.1), consistent with the plasma exposure level of NVL-520 and a reduction in allele frequencies of EZR–ROS1 and ROS1 G2032R by ctDNA (Supplementary Fig. S16A–S16C). The NVL-520 dose was escalated to 75 mg q.d. after 12 weeks. She remained on therapy at approximately 5 months with a confirmed PR, further disease regression in the brain and liver (−58% by RECIST 1.1; Fig. 6B), and no reported neurologic toxicities as of the data cutoff.

Case Study 3

The antitumor activity of NVL-520 extended to a case without known ROS1 resistance mutations. A 75-year-old patient with a metastatic EZR–ROS1 fusion–positive lung adenocarcinoma was initially treated by a referring physician with alectinib, an ALK TKI. Primary progression was observed, and treatment was transitioned to crizotinib. A clinical and radiologic response was maintained until 39 months, when bilateral growing lung nodules were noted on imaging. ctDNA analysis did not reveal any ROS1 kinase domain mutations. NVL-520 was initiated at 25 mg q.d. and escalated to 75 mg q.d. after 24 weeks. Treatment was well tolerated with no evidence of dizziness, orthostasis, or paresthesia. A PR (−33% by RECIST 1.1), consistent with the plasma exposure level of NVL-520, was observed at week 4; this was confirmed and maintained with ongoing treatment of approximately 8 months (−48% by RECIST 1.1; Supplementary Fig. S16A, S16B, and S16D) as of the data cutoff.

TKIs have achieved increasing success in oncogene-driven cancers due to generational improvements in rational drug design. In metastatic disease, coverage of on-target resistance and increased intracranial activity have enabled sequential TKI therapy paradigms, whereby a later-generation TKI can reestablish disease control after progression on an early-generation TKI. Importantly, later-generation TKIs have replaced early-generation TKIs as care standards in metastatic, treatment-naive EGFR-mutant and ALK fusion–positive lung cancers due to improvements in durable disease control (46, 47). Increased tolerability is a critical design feature that permits longer term dosing.

A structure-based approach was used to design NVL-520, a novel, brain-penetrant ROS1 TKI that is generationally distinct from other ROS1 TKIs. NVL-520 combines the advantages of potent inhibition of ROS1 G2032R resistance mutation with limited TRK inhibition, resulting in increased selectivity for ROS1 G2032R over TRK compared with other ROS1 TKIs. By minimizing clashing interactions and forming a putative positive interaction in the solvent-front region, NVL-520 retains single-digit nanomolar potency against diverse ROS1 fusions and ROS1 kinase domain resistance substitutions. NVL-520's potency exceeded that of approved or investigational agents (crizotinib, entrectinib, lorlatinib, taletrectinib, and repotrectinib) by 1 to 3 orders of magnitude for ROS1 G2032R. This strategy for targeting ROS1 solvent-front resistance parallels the recent report of a lorlatinib analogue (LA9) with preclinical activity against ALK solvent-front resistance resulting from a productive interaction hypothesized between its lactam carbonyl and ALK G1202R (48). Identification of the ROS1 L2086F mutation that confers resistance to NVL-520 in vitro is consistent with direct ROS1 pharmacologic inhibition by NVL-520 and modeling of NVL-520 binding to ROS1. It also suggests that on-target resistance to NVL-520 may emerge in the clinic.

The biochemical and cellular profiles of NVL-520 translated into potent antitumor activity across a diverse range of ROS1 fusion–driven preclinical models, including PDXs, with and without the recalcitrant ROS1 G2032R mutation. Tumor regressions were evident in all models, and on-target activity was supported by measured reductions in phospho-ROS1. Concordant with these results, NVL-520 induced partial responses in three patients reported here with TKI-refractory, ROS1 fusion–positive NSCLCs. Importantly, these confirmed responses were achieved with tumors refractory to a wide generational variety of ROS1 TKIs (i.e., crizotinib, entrectinib, lorlatinib, and repotrectinib).

NVL-520 was specifically designed to address the competing challenges of potent ROS1 G2032R inhibition and the avoidance of TRK inhibition—either or both of which represent liabilities associated with existing ROS1 inhibitors. As an example, although repotrectinib inhibits ROS1 G2032R (49), it was initially designed to treat ROS1-, ALK-, and TRK-driven tumors, including ALK and TRK G-to-R solvent-front mutants analogous to ROS1 G2032R. Such multikinase activity may be acceptable for targets such as ROS1 or ALK without substantial known on-target toxicities. Unfortunately, it is problematic when it includes targets such as TRK with dose-limiting on-target toxicities. Potential TRK-related toxicities reported for repotrectinib include dizziness, dysgeusia, paresthesia, and ataxia (32, 50). Furthermore, 34% and 10% of patients had treatment-emergent adverse events that led to dose reduction and discontinuation, respectively (29). TRK inhibition represents a liability that is also evident in the safety profiles of entrectinib, lorlatinib, and taletrectinib (44, 51, 52).

To limit TRK inhibition, NVL-520 was designed to present an N-ethyl substituent to clash with TRKA Y591 and TRKB/C Y619, a feature that also improves broad kinome selectivity as 60% of kinases contain a tyrosine at this hinge-preceding residue (43). NVL-520 has an approximately 100-fold increased potency for ROS1 and ROS1 G2032R over TRK in vitro. Such a differential in effective concentrations may enable the selection of a clinical dose of NVL-520 that would fully inhibit diverse TKI-sensitive and TKI-resistant ROS1-driven tumors without significantly inhibiting endogenous TRK in the CNS, hence providing the potential for efficacy without inducing TRK-related neurologic toxicities. Consistent with its selectivity for ROS1 and against TRK, NVL-520 did not induce TRK-associated neurologic toxicities in the patients in this report, such as dizziness or ataxia.

Because de novo (18) and acquired (19) CNS metastases are frequent limiting factors in patients with ROS1 fusion–positive lung cancers and primary brain tumors or other cancers that metastasize to the CNS harbor ROS1 fusions (1), brain penetrance was a key design goal for NVL-520. The drug was efficacious in an intracranial model of CD74–ROS1 G2032R, providing a >4-fold mOS extension relative to vehicle. In keeping with these results, intracranial activity was observed at 4 weeks and maintained thereafter in a patient with a ROS1 fusion and G2032R mutation–positive NSCLC refractory to entrectinib (a drug with putatively improved CNS penetrance compared with crizotinib), repotrectinib, and platinum doublet chemotherapy.

Since the discovery of oncogenic ROS1 fusions in lung cancer in 2007 (53), our collective understanding of optimal ROS1 targeting has continued to evolve with each generation of ROS1 inhibitors. In the landscape of currently available ROS1 TKIs, NVL-520 offers best-in-class features that are anchored in selectivity, resistance mutation coverage, and CNS penetrance. These features have the potential to improve outcomes in patients with ROS1 fusion–positive tumors, and the early reports of clinical activity presented here and elsewhere (45) are highly encouraging. The ongoing ARROS-1 clinical trial, inclusive of a basket trial strategy, will further define the potential benefit of NVL-520 in patients with advanced ROS1 fusion–positive NSCLCs and other ROS1 fusion–positive cancers (45).

Compounds

Reference compounds were purchased from commercial sources: crizotinib (Combi-Blocks, #QE-4059; MedChemExpress, #HY-50878; SelleckChem), entrectinib (Ark Pharm Inc., #AK547001; Advanced Chemblocks, #K13380; SelleckChem), taletrectinib (MedChemExpress, #HY-131003), repotrectinib (Ark Pharm Inc., #AK689211; MedChemExpress, #HY-103022; SelleckChem, #S8583; DC Chemicals, #DC10463), and lorlatinib (Ark Pharm Inc., #AK175603; eNovation Chemicals, #Y0975931; SelleckChem). NVL-520 was identified from a structure–activity relationship (SAR) effort to discover kinase inhibitors potent against wild-type and mutant ROS1 and selective against the TRK family of receptor tyrosine kinases. Refer to the International Patent Application Publication WO 2021/226208, Example 5, for the synthetic preparation of NVL-520. Calculator Plugins were used for structure property prediction and calculation, Marvin 19.20.0, 2019, ChemAxon (http://www.chemaxon.com): logD7.4, topological polar surface area, and predicted basic pKa.

Computational Modeling

Sequence Similarity.

ROS1 and TRKA pocket sequence identity was calculated by selecting the residues that are in proximity (4.5 Å) to the ligand in the 4UXL structure of ROS1. There are 21 residues in this set (ROS1: LGVEAKLLELMEGGDRNCLGD) compared with the analogous residues on TRKA (TRKA: LGVLAKVFEYMKHGDRNCLGD) obtained through Clustal Omega sequence alignment. Of the 21 residues in ROS1 and TRKA, 15 (71.4%) are identical and 16 (76.2%) are similar using the following similarity grouping: GAVLI, FYW, CM, ST, KRH, DENQ, P.

System Preparation for FEP+ Calculations.

The initial modeling orientation of NVL-520 was prepared using the MOE docking protocol into the 4UXL structure of ROS1 (34). Model orientations of the other ligands were obtained by direct superposition of the published crystal structures of those ligands in ROS1 [lorlatinib: 4UXL (34); crizotinib: 3ZBF (35)], ALK (entrectinib: 5FTO; ref. 54), or TRKA (repotrectinib: 7VKN; ref. 55) onto the 4UXL structure. These superpositions were created using the default protein preparation wizard in Maestro 13.3 and served as the starting point for the subsequent FEP+ calculations. This preparation included adding hydrogens, filling missing side chains, and assigning proper ionization states for the amino acids and the ligands at physiologic pH. Prior to running the FEP+ simulations, missing ligand torsion parameters for all compounds were computed with the Force Field Builder that utilized the M06-2X/cc-pVTZ9(-f) functional. Crizotinib and entrectinib were simulated in their cation form with a +1 charge.

FEP+ Calculations.

FEP+ (36) in the 2022–3 release with the OPLS4 force field (56) was used to predict the relative binding free energies for the ROS1–ligand complexes. A detailed description of the FEP+ methodology (36, 37, 57–59) and its use to predict ligand selectivity (60, 61) have been reported. The Desmond molecular dynamics calculations and FEP+ processing of results were accomplished on the Schrodinger-hosted AWS GPU server. During these calculations, the atoms of the arginine side chain were grown via the windowed perturbation scheme from glycine. Default values of 5 nanoseconds per lambda window and 24 lambda windows were used.

The Pose of NVL-520 in TRKB.

The snapshot of NVL-520 in ROS1 from FEP simulations was used as a starting point. TRKB (PDB: 4AT3, ref. 62) was superimposed using the Schrodinger Maestro binding-site alignment protocol to illustrate the proximity between NVL-520 and TRKB Y619. NVL-520 was not separately docked onto TRKB.

Biochemical Kinase Activity Assay

Activity of purified kinases was measured using the PhosphoSens assay (AssayQuant Technologies; ref. 63). Test compounds were dissolved in DMSO to 100-fold over the desired concentration and dispensed at 250 nL into a 384-well plate in a 3-fold dilution series. A 12.5 μL solution containing 2 mmol/L ATP with 26 μmol/L fluorogenic peptide substrate AQT0101 (AssayQuant Technologies, #AQT0101) or AQT0104 (AssayQuant Technologies, #AQT0104) in buffer (50 mmol/L HEPES pH 7.5, 0.01% Brij-35, 0.5 mmol/L EGTA, 10 mmol/L MgCl2) was added to the plate. The reaction was triggered by the addition of a 12.5 μL solution containing 0.5 nmol/L ROS1 (Carna, #08-163), 2 nmol/L ROS1 G2032R (SignalChem, #R14-12BG), 1 nmol/L TRKA (BPS Bio, #40280), 3 nmol/L TRKB (SignalChem, #N17-11G), or 0.5 nmol/L TRKC (BPS Bio, #40282) kinase domains in buffer (50 mmol/L HEPES pH 7.5, 0.01% Brij-35, 2% glycerol, 0.4 mg/mL BSA, 0.5 mmol/L EGTA, 10 mmol/L MgCl2). The final concentrations were 1 mmol/L ATP, 13 μmol/L peptide substrate (AQT0101 for ROS1 and ROS1 G2032R or AQT0104 for TRKA, TRKB, and TRKC), 0.25 to 1.5 nmol/L kinase (0.25 nmol/L ROS1; 1 nmol/L ROS1 G2032R; 0.5 nmol/L TRKA; 1.5 nmol/L TRKB; or 0.5 nmol/L TRKC), 50 mmol/L HEPES pH 7.5, 0.01% Brij-35, 1% glycerol, 0.2 mg/mL BSA, 0.5 mmol/L EGTA, and 10 mmol/L MgCl2. The plate was sealed, and fluorescence signal was recorded by a plate reader at λemission = 485 nm every 2 minutes for 120 minutes at 30°C. The change in fluorescence intensity over time during the initial, linear phase of the reaction is initial velocity (v). IC50 was calculated from the plot of initial velocity versus log (inhibitor concentration) regressed to the four-parameter logistic equation.

Kinase Panel Screening

Inhibition of kinase activity was measured using radiolabeled [γ-33P]-ATP (Reaction Biology). A solution containing [γ-33P]-ATP was mixed with NVL-520, each of the 335 kinases, and the corresponding kinase substrate. NVL-520 was assayed at two concentrations: 100 nmol/L and 1 μmol/L. The concentration of ATP in this assay was close to the Michaelis–Menten constant (KM) for each kinase. The reaction was stopped after 1 hour, and the incorporation of 33P was quantified using a scintillation counter. Inhibition was measured by the residual activity of 33P: Lower residual activity indicated higher inhibitor potency for the specific kinase. Based on the 335-kinase screen, 24 kinases showing >50% inhibition were selected for focused IC50 determination using the same assay at 10 concentrations of NVL-520 in semilogarithmic steps (3 μmol/L, 900 nmol/L, 300 nmol/L, 90 nmol/L, …, 0.09 nmol/L). IC50 was determined from the plot of residual activity against log (inhibitor concentration) regressed to a four-parameter logistic equation. Kinome map illustration reproduced courtesy of Cell Signaling Technology, Inc. (www.cellsignal.com; ref. 64).

Cell Culture

All cells were maintained at 37°C with 5% CO2. Ba/F3 cells were provided by the RIKEN BRC through the National Bio-Resource Project of the MEXT, Japan. Ba/F3 cells were maintained in RPMI 1640 + 10% FBS. Genes encoding human CD74–ROS1 (with wild-type kinase domain or with S1986F, L2026M, G2032R, D2033N, or L2086F mutation), TPM3–TRKA, ETV6–TRKB, ETV6–TRKC, or TRKB (full length), or EGFR L858R/T790M/C797S were synthesized, cloned into a retroviral vector with a puromycin resistance marker, and packaged into retroviral particles. The virus was used to infect Ba/F3 cells. Stable cell lines were selected by IL3 withdrawal and with puromycin for at least 7 days. The polyclonal culture was used in assays directly, or monoclonal cultures were established through limiting dilution before being used in assays. Successful transformants were confirmed by Sanger sequencing and Western blot. All cells were confirmed to express the full desired protein. Ba/F3 CD74–ROS1 contained a small C-terminal truncation, and Ba/F3 ETV6–TRKC contained a small C-terminal frameshift. Both were confirmed by orthogonal assays to have no discernible effects on inhibitor activity. HCC78, A431, NCI-H1975, NCI-H2228, NCI-H3122, and A549 cell lines were obtained at Pharmaron. The MGH193-1 (41) cell line was developed from a malignant pleural effusion of a treatment-naive patient with NSCLC harboring EZR–ROS1 rearrangement and was verified by detection of the EZR–ROS1 fusion transcript by RT-PCR (both EZR1–ROS1 fusion junction and ROS1 kinase domain). The MGH9018-1 (65) cell line was developed from malignant pleural effusion of a patient with crizotinib-resistant NSCLC harboring CD74–ROS1 G2032R rearrangement and was verified by detection of the CD74–ROS1 fusion transcript by RT-PCR (both CD74–ROS1 fusion junction and ROS1 kinase domain) and detection of the G2032R mutation by Sanger sequencing. Methods of cell line generation have been previously published (66). Prior to model generation, the patients provided written informed consent to participate in a Dana-Farber and Harvard Cancer Center Institutional Review Board–approved protocol giving permission for research to be performed on their samples. Cell lines were cultured in RPMI 1640 with 10% FBS and were sequenced to confirm the presence of ROS1 rearrangement and mutation. Additional authentication was performed by SNP fingerprinting.

Alternatively, Ba/F3 cells expressing the following genes were made separately. ROS1 fusion mutants were made using site-directed mutagenesis (Agilent, New England Biolabs). Platinum-E cells (Cell Biolabs, Inc.) were transfected with pBABE CD74–ROS1, pMIG CEP85L–ROS1, pCX4 EZR–ROS1, pBABE GOPC(S)–ROS1, pCX4 GOPC(S)–ROS1, pBABE GOPC(L)–ROS1, pCX4 GOPC(L)–ROS1, or pMIG SLC34A2–ROS1 wild-type or mutant constructs using Biotool DNA transfection reagent to generate replication incompetent, ecotropic retrovirus. Ba/F3 parental cells were infected with retrovirus. Cells were treated with puromycin to select for cells stably expressing the respective fusions. Cells that survived IL3 withdrawal were used for in vitro assays. All transformed cell lines were sequenced to verify the presence of desired mutations. Cells were harvested and pelleted, and DNA was extracted using QuickExtract DNA Extraction Solution (Lucigen). The ROS1 kinase and C-terminal domains were PCR amplified. Benchling software was used to align chromatographs to confirm the presence of desired mutations and verify that no undesired mutations were introduced during viral transduction.

All cells were inspected for Mycoplasma contamination using the ABM PCR Mycoplasma Detection Kit (cat. #G238) or the Lonza MycoAlert Detection Kit (LT07-710) at a frequency of at least once every 3 months.

Cell Viability Assay

Protocols varied slightly with the testing site. For testing site A, A549 or stable Ba/F3 cells were seeded into 384-well plates, and test compounds were added in a 3-fold dilution series in complete culture medium containing 10% FBS. After a 72-hour incubation with the inhibitor, cell viability was measured using the CellTiter-Glo reagent (Promega). Untreated wells served as negative controls (no inhibition of proliferation), whereas wells treated with high concentrations of the nonspecific kinase inhibitor staurosporine served as positive controls (full inhibition of proliferation). IC50 was calculated from percent inhibition and log (inhibitor concentration) using four-parameter logistic regression.

For testing site B, all inhibitors were prepared as 1 mmol/L stocks in DMSO. Plates were preseeded with 25 μL per well of complete medium using a Multidrop Combi Reagent Dispenser (Thermo Scientific). Inhibitors were distributed onto 384-well plates at 2-fold of the indicated concentrations into 25 μL per well of complete medium using a D300 Digital Dispenser (Hewlett-Packard). Ba/F3 cell lines expressing wild-type or mutant ROS1 fusions were seeded at 1,000 cells per well in a volume of 25 μL using a Multidrop Combi Reagent Dispenser (Thermo Scientific). Plates were incubated for 72 hours. Viability was measured using a WST-8 [2-(2-methoxy-4-nitrophenyl)-3-(4-nitrophenyl)-5-(2,4-disulfophenyl)-2H-tetrazolium, monosodium salt]–based assay (Bimake) and read on a Biotek Synergy 2 plate reader. Each condition was assayed in triplicate. Data were normalized using Microsoft Excel, and IC50 values were calculated using a nonlinear regression analysis in GraphPad Prism.

For testing site C, MGH193-1 and MGH9018-1 cells were plated at 4,000 cells/well in triplicate into 96-well plates. Cells were incubated with CellTiter-Glo (Promega) after 5-day drug treatment, and luminescence was measured with a SpectraMax M5 Multimode Microplate Reader (Molecular Devices, LLC). GraphPad Prism (GraphPad Software) was used to graphically display data and determine IC50 values by a nonlinear regression model utilizing a four-parameter analytic method.

In some human cancer cell lines, we observed that NVL-520 showed biphasic dose–response behavior. We attributed the first dose response to on-target growth inhibition caused by ROS1 inhibition and the second dose response to off-target cytotoxicity caused by pathways beyond ROS1 inhibition. In such cases, only the first IC50 values are reported and indicate on-target ROS1 inhibition.

Cellular Phosphorylation Assay

For the Ba/F3 TRKB cell phosphorylation assay, cells were seeded into 384-well plates, and test compounds were added in a 3-fold dilution series in full culture medium + 10% FBS. Cells were stimulated with 100 ng/mL BDNF for 20 minutes. TRK phosphorylation was measured using the phospho-TRKA (Tyr674/675)/phospho-TRKB (Tyr706/Tyr707) AlphaLISA reagent (PerkinElmer, #ALSU-PTRKAB). Untreated wells served as negative controls (no inhibition), whereas wells treated with high concentrations of the nonspecific kinase inhibitor staurosporine served as positive controls (full inhibition). IC50 was calculated from percent inhibition and inhibitor concentration using four-parameter logistic regression.

NIH3T3 cells expressing EZR–ROS1 wild-type or mutant fusions were treated with the indicated concentrations of inhibitor for 3 hours prior to harvest. Cells were washed with phosphate-buffered saline (PBS) and harvested with cell lysis buffer supplemented with 0.25% deoxycholate, 0.05% SDS, and protease and phosphatase inhibitors. Protein concentrations were determined using the Pierce BCA Protein Assay (Thermo Fisher Scientific). Lysates were extracted using Laemelli sample buffer supplemented with beta-mercapto­ethanol for 10 minutes at 75°C, and lysates were run on 4% to 20% precast gradient Bis-tris gels (Invitrogen; Thermo Fisher Scientific). Proteins were transferred to nitrocellulose membranes (Prometheus) and probed with phospho-ROS1 Y2274 (3078; 1:1,000; Cell Signaling Technology), DYKDDDDK [Flag] (8H8L17; 1:1,000; Invitrogen), phospho-SHP2 (A5278; 1:1,000; Bimake), phospho-ERK1/2 (9101; 1:1,000; Cell Signaling Technology), ERK2 (sc-1647; 1:1,000; Santa Cruz), phospho-S6 (4858; 1:1,000; Cell Signaling Technology), S6 (2216; 1:1,000, Cell Signaling Technology), phospho-Akt (4060; 1:1,000, Cell Signaling Technology), Akt (9272; 1:1,000, Cell Signaling Technology), or Actin (JLA-20; 1:5,000; Developmental Studies Hybridoma Bank). Signal was detected using HRP-conjugated or IRDye secondary antibodies on a Bio-Rad ChemiDoc imaging station or a LI-COR Odyssey imaging station, respectively.

MGH193-1 and MGH9018-1 were treated for 6 hours. Total protein lysates were analyzed by Western blotting with the following antibodies (all from Cell Signaling Technology): phospho-ROS1 Y2274 (3078), ROS1 (3287), phospho-AKT S473 (4060), AKT (4691), phospho-ERK1/2 T202/Y204 (9101), ERK1/2 (9102), phospho-S6 S240/244 (5364), S6 (2217), and β-Actin (4970).

Colony Formation Assay

Plates were preseeded with 0.8% agarose in complete medium with either DMSO or inhibitor (crizotinib, entrectinib, lorlatinib, or NVL-520 at 10, 100, or 1,000 nmol/L). Each inhibitor was paired with its own DMSO condition to serve as an accurate control. NIH3T3 cells expressing CD74–ROS1 or EZR–ROS1 wild-type or mutant fusions were plated in 0.4% agarose in complete medium at a density of 2,000 cells per 0.5 mL of agarose with DMSO or inhibitor at an identical concentration to the bottom layer. Plates were incubated for 4 weeks, and each well was fed 3× per week with 75 μL of complete medium with or without inhibitor to match each plated condition to prevent drying of the agarose. Plates were read after 3 and 4 weeks using GelCount (Oxford Optronix). Colony counts were averaged by condition and normalized to the colony counts from paired DMSO conditions. Data analysis and visualization were performed using Microsoft Excel and GraphPad Prism.

In Vivo Studies

Subcutaneous Xenograft Studies.

CTG-0848 PDX.

The experimental procedures were performed according to the guidelines approved by the Institutional Animal Care and Use Committee (IACUC) of Champions Oncology, accredited by the Association for Assessment and Accreditation of Laboratory Animal Care (AAALAC). Female athymic Nude-Foxn1nu mice were implanted subcutaneously into the left flank with tumor fragments from the CTG-0848 model. In the efficacy study, after tumors grew to 150 to 300 mm3, mice (n = 3–5/group) were randomized and administered vehicle or NVL-520 by oral gavage b.i.d. (12-hour intervals). In a separate pharmacokinetic (PK) and pharmacodynamic (PD) study, after tumors grew to 350 to 500 mm3, mice received a single dose or b.i.d. × 5 days of vehicle or NVL-520, and tumor and blood were collected at 1 hour and 12 hours (treatment only) after dose. The model was verified by vendor-provided NGS to contain a heterozygous CD74–ROS1 fusion.

Lu01-0414 PDX.

All the procedures related to animal handling, care, and treatment in study were performed according to the guidelines approved by the IACUC of WuXi AppTec following the guidance of the AAALAC. Female Balb/c nude mice were implanted subcutaneously into the right flank with tumor slices (∼30 mm3) from the Lu01-0414 model. In the efficacy study, after tumors grew to an average tumor volume of 160 mm3, mice (n = 3–5/group) were randomized and administered by oral gavage b.i.d. (12-hour intervals) vehicle or NVL-520. In a separate PK and PD study, after tumors grew to an average tumor volume of 492 mm3, mice received a single dose or b.i.d. × 5 days of vehicle or NVL-520, and tumor and blood were collected at 1 hour and 12 hours (treatment only) after dose. The model was verified by vendor-provided NGS to contain a heterozygous SDC4–ROS1 fusion with a linkage between the SDC4 L66 residue and the ROS1 A1750 residue.

MGH9018-1 PDX.

The study was conducted in accordance with the guidelines as published in the Guide for the Care and Use of Laboratory Animals and was approved by the IACUC of Massachusetts General Hospital. Xenografts were implanted subcutaneously into the flanks of female athymic nude (Nu/Nu) mice ages 6 to 8 weeks. Mice were maintained in laminar flow units in sterile filter-top cages with Alpha-Dri bedding. Mice were randomized into groups once the tumors had attained a volume of 150 mm3. The treatment groups were treated with drug solution dissolved in acid water once a day (crizotinib) or drug solution dissolved in 20% hydroxypropyl-b-cyclodextrin (HP-β-CD) twice a day at 9/15-hour intervals (NVL-520) by oral gavage. Tumor volumes were measured twice weekly and calculated using the formula: mm3 = 0.52 × L × W2. For protein assays, tumor-bearing mice were administered drugs for 3 days according to the above dosing schedule, and tumors were harvested 3 hours after the last treatment for Western blotting.

CTG-2532 PDX.

The experimental procedures were performed according to the guidelines approved by the IACUC of Champions Oncology, accredited by AAALAC. Female athymic Nude-Foxn1nu mice were implanted subcutaneously into the left flank with tumor fragments from model CTG-2532. In the efficacy study, after tumors grew to 150 to 300 mm3, mice (n = 5/group) were administered vehicle, NVL-520, or repotrectinib by oral gavage b.i.d. (12-hour intervals) for up to 21 days (b.i.d. × 21 days) if tolerated. Repotrectinib (DC Chemicals) was dosed as a suspension solution containing 0.5% carboxymethylcellulose and 1% Tween-80. The dosing suspension was stored 2–8°C in the dark for up to 7 days with continuous stirring. In a separate PK and PD study, CTG-2532 tumors were subcutaneously implanted in mice and allowed to grow to 350 to 550 mm3 before a single dose of the vehicle or NVL-520 was administered. Tumor and blood were collected at 1 hour and 12 hours (treatment only) after dose for PK and PD analysis. The model was verified by vendor-provided NGS to harbor a CD74–ROS1 G2032R.

Ba/F3 CD74–ROS1 G2032R CDX.

All the procedures related to animal handling, care, and treatment in this study were performed according to guidelines approved by the IACUC of Pharmaron following the guidance of the AAALAC. Six- to 8-week-old female Balb/c nude mice were inoculated subcutaneously on the right flank with 1 × 106 Ba/F3 CD74–ROS1 G2032R cells. After the tumors reached a mean tumor volume of approximately 128 mm3, treatment was initiated, and tumors and body weight were measured at regular intervals.

Plasma drug concentrations were determined by LC/MS. Free drug concentrations were calculated by multiplying the total concentration values determined from PK experiments with the corresponding fraction unbound in mouse plasma (= 7.7% for NVL-520 and = 7.6% for crizotinib; Pharmaron).

Kp,uu and Intracranial Studies

All the procedures related to animal handling, care, and treatment in these studies were performed according to guidelines approved by the IACUC of Pharmaron following the guidance of AAALAC.

NVL-520 was formulated as 1 mg/mL suspension in 20% HP-β-CD in deionized water. Lorlatinib was formulated as a 1 mg/mL solution in two equivalents of HCl + 20% HP-β-CD in deionized water. Compounds were administered orally to male Wistar Han rats (n = 3 each). After 1 hour, brain samples and plasma were collected, and brain samples were homogenized in PBS. Brain and plasma samples were precipitated by acetonitrile and centrifugation (4,700 rpm, 15 minutes). Drug concentrations in the supernatants were quantified by LC/MS-MS. Unbound fractions were determined using rapid equilibrium dialysis. Kp,uu was calculated as the ratio between unbound drug concentration in the brain and unbound drug concentration in the plasma.

Ba/F3 CD74–ROS1 G2032R cells were transduced with viral particles containing the firefly luciferase gene and a neomycin resistance marker. Infected cells were selected on neomycin, and monoclonal cultures were established through limiting dilution. Successful transformants were confirmed by Sanger sequencing and bioluminescence. For the in vivo study, 1 × 105 Ba/F3 CD74–ROS1 G2032R luciferase cells were stereotactically implanted into the right forebrains of 6- to 8-week-old female Balb/c nude mice. After 5 days, mice were randomized based on mean bioluminescence signal into three groups of n = 7–10 mice each and received vehicle or NVL-520, 2 mg/kg, orally, b.i.d. Bioluminescence and body weight were measured at regular intervals until the end of the study (61 days after treatment start) or until animals met the criteria for euthanasia.

Clinical Study

ARROS-1 (NCT05118789) is a first-in-human, tumor-agnostic phase I/II trial of NVL-520 in patients with solid tumors harboring ROS1 rearrangements (45). All patients provided written informed consent for participation. The study was conducted in accordance with the ethical principles of Good Clinical Practice and the Declaration of Helsinki and was approved by the institutional review board/independent ethics committee at each participating site. Case studies are reported as of the data cutoff date of September 13, 2022. The ctDNA NGS assay was conducted with plasma from whole blood collected at pre-dose on C1D1 and C1D15 using the Guardant360 assay (Guardant Health). Patient blood samples for PK analysis were collected at predose and then 0.25, 0.5, 1, 2, 4, 6, and 24 hours after dose. Blood samples were processed to plasma and analyzed using a validated LC/MS-MS method.

Data Availability

No datasets were generated or analyzed in this study.

A. Drilon reports personal fees from Nuvalent, Inc. during the conduct of the study; personal fees from Ignyta, Genentech, Roche, MORE Health, AXIS, Loxo, Eli Lilly, Bayer, AbbVie, EPG Health, Takeda, Ariad, Millenium, 14ner, Elevation Oncology, Harborside Nexus, TP Therapeutics, ArcherDX, Liberum, AstraZeneca, Monopteros, RV More, Pfizer, Novartis, Ology, Blueprint Medicines, EMD Serono, Amgen, Helsinn, Medendi, TouchIME, BeiGene, Repare RX, Janssen, BergenBio, Entos, Hengrui Therapeutics, Merus, Treeline Bio, Exelixis, Chugai Pharmaceutical, Prelude, Tyra Biosciences, Remedica Ltd., Applied Pharmaceutical Science, Inc., Verastem, mBrace, Treeline, MonteRosa, AXIS, AiCME, I3 Health, Innocare, and Boundless Bio outside the submitted work; a patent for osimertinib–selpercatinib pending; prior research funding from Foundation Medicine; associated research paid to institution from Pfizer, Exelixis, GSK, Teva, Taiho, and PharmaMar; royalties from Wolters Kluwer; other (food/beverage) from Merck, Puma, Merus, and Boehringer Ingelheim; and CME honoraria from Medscape, OncLive, PeerVoice, Physicians’ Education Resources, Targeted Oncology, Research to Practice, Axis, Peerview Institute, Paradigm Medical Communications, WebMD, MJH Life Sciences, AXIS, EPG Health, JNCC/Harborside, I3 Health, Liberum, Remedica Ltd., and Lungevity. J.C. Horan reports employment with and ownership interest in Nuvalent, Inc., and a patent for WO 2021/226208 pending and a patent for PCT/US2022/077323 pending. A. Tangpeerachaikul reports employment with and ownership interest in Nuvalent, Inc., and a patent for WO 2021/226208 pending and a patent for CT/US2022/077364 pending. B. Besse reports grants from 4D Pharma, AbbVie, Amgen, Aptitude Health, AstraZeneca, BeiGene, Blueprint Medicines, Boehringer Ingelheim, Celgene, Cergentis, Chugai Pharmaceutical, Cristal Therapeutics, Daiichi Sankyo, Eli Lilly, Eisai, Genzyme Corporation, GSK, Inivata, Ipsen, Janssen, Onxeo, OSE Immunotherapeutics, Pfizer, Roche/Genentech, Sanofi, Takeda, Tolero Pharmaceuticals, Turning Point Therapeutics, and Nuvalent, Inc. during the conduct of the study. S.-H.I. Ou reports grants from Nuvalent, Inc. during the conduct of the study, as well as personal fees from Pfizer, Johnson & Johnson/Janssen, Eli Lilly, BeiGene, and Merus, personal fees and nonfinancial support from Elevation Oncology, and nonfinancial support from Turning Point Therapeutics, BlossomHill Therapeutics, and MBrace Therapeutics outside the submitted work. S.M. Gadgeel reports grants from Nuvalent, Inc. during the conduct of the study, as well as consultancy for AstraZeneca, Pfizer, Takeda, Merck, Blueprint, Mirati, Genentech/Roche, Merck, Esai, Eli Lilly, and GSK, travel support to ESMO from Mirati, and independent data monitoring committee member for AstraZeneca. D.R. Camidge reports personal fees from Nuvalent, Inc. during the conduct of the study, as well as personal fees from Anheart, Pfizer, Turning Point, and Roche outside the submitted work. A.J. van der Wekken reports grants and other support from AstraZeneca, Boehringer Ingelheim, Pfizer, Roche, and Takeda, and other support from Janssen and Eli Lilly outside the submitted work. C. Keddy reports grants and nonfinancial support from Nuvalent, Inc. during the conduct of the study. K.S. Nicholson reports grants and nonfinancial support from Nuvalent, Inc. during the conduct of the study. S. Yoda reports grants from Nuvalent, Inc. during the conduct of the study, as well as grants and personal fees from Nuvalent Inc., and personal fees from Pfizer Japan and Tango Therapeutics outside the submitted work. S. Mente reports employment with and ownership interest in Nuvalent, Inc., and a patent for WO 2021/226208 pending. Y. Sun reports employment with and ownership interest in Nuvalent, Inc. J.R. Soglia reports employment with and ownership interest in Nuvalent, Inc., and a patent for PCT/US2022/077364 pending. N.E. Kohl reports personal fees from Nuvalent, Inc. during the conduct of the study. J.R. Porter is a board member and employee of and has ownership interest in Nuvalent, Inc., and reports a patent for PCT/US2022/077364 pending. M.D. Shair is a consultant/board member of and has ownership interest in Nuvalent, Inc. during the conduct of the study; has employment with Harvard University outside the submitted work; and reports a patent for WO 2021/226208 pending. V. Zhu reports employment with and ownership interest in Nuvalent, Inc. during the conduct of the study, as well as other support from AstraZeneca, BeiGene, Blueprint, Roche/Foundation Medicine, Roche/Genentech, Takeda, Xcovery, and TP Therapeutics outside the submitted work. M.A. Davare reports grants from Nuvalent, Inc. during the conduct of the study. A.N. Hata reports grants and personal fees from Nuvalent, Inc. during the conduct of the study, as well as grants from Pfizer, Amgen, Eli Lilly, Roche/Genentech, Blueprint Medicines, C4 Therapeutics, BridgeBio, Novartis, Bristol Myers Squibb, and Scorpion Therapeutics and personal fees from TigaTx, Engine Biosciences, and Tolremo Therapeutics outside the submitted work. H.E. Pelish reports employment with and ownership interest in Nuvalent, Inc., and a patent for WO 2021/226208 pending and a patent for PCT/US2022/077364 pending. J.J. Lin reports personal fees and other support from Nuvalent, Inc. during the conduct of the study, as well as personal fees and other support from Roche/Genentech, Bayer, Elevation Oncology, Novartis, Pfizer, and Turning Point Therapeutics, personal fees from Regeneron, Blueprint Medicines, and Mirati Therapeutics, and other support from Hengrui Therapeutics, Neon Therapeutics, Relay Therapeutics, and Linnaeus Therapeutics outside of the submitted work. No disclosures were reported by the other authors.

A. Drilon: Resources, supervision, investigation, writing–original draft, writing–review and editing. J.C. Horan: Conceptualization, data curation, software, formal analysis, investigation, project administration, writing–review and editing. A. Tangpeerachaikul: Conceptualization, formal analysis, supervision, investigation, visualization, methodology, writing–original draft, writing–review and editing. B. Besse: Data curation, investigation, writing–review and editing. S.-H.I. Ou: Resources, data curation, investigation, writing–review and editing. S.M. Gadgeel: Data curation, investigation, writing–review and editing. D.R. Camidge: Data curation, investigation, writing–review and editing. A.J. van der Wekken: Data curation, investigation, writing–review and editing. L. Nguyen-Phuong: Investigation. A. Acker: Investigation. C. Keddy: Formal analysis, validation, investigation, methodology. K.S. Nicholson: Formal analysis, validation, investigation, methodology. S. Yoda: Conceptualization, formal analysis, validation, investigation. S. Mente: Formal analysis, visualization, methodology, writing–review and editing. Y. Sun: Investigation, visualization. J.R. Soglia: Validation, investigation. N.E. Kohl: Conceptualization, supervision, methodology, writing–review and editing. J.R. Porter: Conceptualization, supervision, funding acquisition, project administration, writing–review and editing. M.D. Shair: Conceptualization, supervision, funding acquisition, writing–review and editing. V. Zhu: Conceptualization, data curation, formal analysis, validation, investigation, writing–review and editing. M.A. Davare: Conceptualization, resources, formal analysis, supervision, validation, writing–review and editing. A.N. Hata: Conceptualization, resources, supervision, funding acquisition, validation, writing–review and editing. H.E. Pelish: Conceptualization, supervision, funding acquisition, investigation, methodology, project administration, writing–review and editing. J.J. Lin: Conceptualization, resources, supervision, investigation, visualization, writing–original draft, writing–review and editing.

We thank the patients, caregivers, advocates, physicians, nurses, and research staff for their participation in the ongoing ARROS-1 clinical trial. This work was funded by Nuvalent, Inc. A. Drilon was supported in part by the P30 CA008748 grant from the NCI of the NIH. J.J. Lin was supported in part by NIH/NCI R01CA164273.

The publication costs of this article were defrayed in part by the payment of publication fees. Therefore, and solely to indicate this fact, this article is hereby marked “advertisement” in accordance with 18 USC section 1734.

Note: Supplementary data for this article are available at Cancer Discovery Online (http://cancerdiscovery.aacrjournals.org/).

1.
Drilon
A
,
Jenkins
C
,
Iyer
S
,
Schoenfeld
A
,
Keddy
C
,
Davare
MA
.
ROS1-dependent cancers — biology, diagnostics and therapeutics
.
Nat Rev Clin Oncol
2021
;
18
:
35
55
.
2.
Lin
JJ
,
Shaw
AT
.
Recent advances in targeting ROS1 in lung cancer
.
J Thorac Oncol
2017
;
12
:
1611
25
.
3.
Gu
TL
,
Deng
X
,
Huang
F
,
Tucker
M
,
Crosby
K
,
Rimkunas
V
, et al
.
Survey of tyrosine kinase signaling reveals ROS kinase fusions in human cholangiocarcinoma
.
PLoS One
2011
;
6
:
e15640
.
4.
Charest
A
,
Lane
K
,
McMahon
K
,
Park
J
,
Preisinger
E
,
Conroy
H
, et al
.
Fusion of FIG to the receptor tyrosine kinase ROS in a glioblastoma with an interstitial del(6)(q21q21)
.
Genes Chromosomes Cancer
2003
;
37
:
58
71
.
5.
Marks
EI
,
Pamarthy
S
,
Dizon
D
,
Birnbaum
A
,
Yakirevich
E
,
Safran
H
, et al
.
ROS1-GOPC/FIG: a novel gene fusion in hepatic angiosarcoma
.
Oncotarget
2019
;
10
:
245
51
.
6.
Birch
AH
,
Arcand
SL
,
Oros
KK
,
Rahimi
K
,
Watters
AK
,
Provencher
D
, et al
.
Chromosome 3 anomalies investigated by genome wide SNP analysis of benign, low malignant potential and low grade ovarian serous tumours
.
PLoS One
2011
;
6
:
e28250
.
7.
Ou
SHI
,
Nagasaka
M
.
A catalog of 5’ fusion partners in ROS1-positive NSCLC circa 2020
.
JTO Clin Res Rep
2020
;
1
:
100048
.
8.
Li
Z
,
Shen
L
,
Ding
D
,
Huang
J
,
Zhang
J
,
Chen
Z
, et al
.
Efficacy of crizotinib among different types of ROS1 fusion partners in patients with ROS1-rearranged non-small cell lung cancer
.
J Thorac Oncol
2018
;
13
:
987
95
.
9.
Neel
DS
,
Allegakoen
DV
,
Olivas
V
,
Mayekar
MK
,
Hemmati
G
,
Chatterjee
N
, et al
.
Differential subcellular localization regulates oncogenic signaling by ROS1 kinase fusion proteins
.
Cancer Res
2019
;
79
:
546
56
.
10.
Keddy
C
,
Shinde
P
,
Jones
K
,
Kaech
S
,
Somwar
R
,
Shinde
U
, et al
.
Resistance profile and structural modeling of next-generation ROS1 tyrosine kinase inhibitors
.
Mol Cancer Ther
2022
;
21
:
336
46
.
11.
Shaw
AT
,
Riely
GJ
,
Bang
YJ
,
Kim
DW
,
Camidge
DR
,
Solomon
BJ
, et al
.
Crizotinib in ROS1-rearranged advanced non-small-cell lung cancer (NSCLC): updated results, including overall survival, from PROFILE 1001
.
Ann Oncol
2019
;
30
:
1121
6
.
12.
Drilon
A
,
Siena
S
,
Dziadziuszko
R
,
Barlesi
F
,
Krebs
MG
,
Shaw
AT
, et al
.
Entrectinib in ROS1 fusion-positive non-small-cell lung cancer: integrated analysis of three phase I–2 trials
.
Lancet Oncol
2020
;
21
:
261
70
.
13.
Shaw
AT
,
Solomon
BJ
,
Chiari
R
,
Riely
GJ
,
Besse
B
,
Soo
RA
, et al
.
Lorlatinib in advanced ROS1-positive non-small-cell lung cancer: a multicentre, open-label, single-arm, phase 1–2 trial
.
Lancet Oncol
2019
;
20
:
1691
701
.
14.
National Comprehensive Cancer Network
.
NCCN clinical practice guidelines in oncology (NCCN Guidelines®) non–small cell lung cancer
[
cited 2022 Nov 16
].
Available from
: https://www.nccn.org.
15.
Ou
SHI
,
Fujiwara
Y
,
Shaw
AT
,
Yamamoto
N
,
Nakagawa
K
,
Fan
F
, et al
.
Efficacy of taletrectinib (AB-106/DS-6051b) in ROS1+ NSCLC: An updated pooled analysis of U.S. and Japan phase 1 studies
.
JTO Clin Res Rep
2021
;
2
:
100108
.
16.
Drilon
A
,
Cho
BC
,
Kim
DW
,
Lee
J
,
Lin
JJ
,
Zhu
V
, et al
.
Safety and preliminary clinical activity of repotrectinib in patients with advanced ROS1/TRK fusion-positive solid tumors (TRIDENT-1 study)
.
Ann Oncol
2019
;
30 Suppl 5
:
v162
.
Abstract nr 444PD.
17.
Aldea
M
,
Besse
B
,
Hendriks
LEL
.
ALK inhibitors in ALK-positive NSCLC with central nervous system metastases
.
Eur Oncol Haematol
2020
;
16
:
18
21
.
18.
Ou
SHI
,
Zhu
VW
.
CNS metastasis in ROS1+ NSCLC: An urgent call to action, to understand, and to overcome
.
Lung Cancer
2019
;
130
:
201
7
.
19.
Patil
T
,
Smith
DE
,
Bunn
PA
,
Aisner
DL
,
Le
AT
,
Hancock
M
, et al
.
The incidence of brain metastases in stage IV ROS1-rearranged non-small cell lung cancer and rate of central nervous system progression on crizotinib
.
J Thorac Oncol
2018
;
13
:
1717
26
.
20.
Lin
JJ
,
Choudhury
NJ
,
Yoda
S
,
Zhu
VW
,
Johnson
TW
,
Sakhtemani
R
, et al
.
Spectrum of mechanisms of resistance to crizotinib and lorlatinib in ROS1 fusion-positive lung cancer
.
Clin Cancer Res
2021
;
27
:
2899
909
.
21.
Doebele
R
,
Dziadziuszko
R
,
Drilon
A
,
Shaw
A
,
Wolf
J
,
Farago
A
, et al
.
Genomic landscape of entrectinib resistance from ctDNA analysis in STARTRK-2
.
Ann Oncol
2019
;
30
Suppl 5:v865. Abstract nr LBA28
.
22.
Facchinetti
F
,
Loriot
Y
,
Kuo
M-S
,
Mahjoubi
L
,
Lacroix
L
,
Planchard
D
, et al
.
Crizotinib-resistant ROS1 mutations reveal a predictive kinase inhibitor sensitivity model for ROS1- and ALK-rearranged lung cancers
.
Clin Cancer Res
2016
;
22
:
5983
91
.
23.
Ko
HJ
,
Hsu
CK
,
Yeh
YC
,
Huang
HC
.
ROS-1 TKI for the treatment of concurrent sarcomatoid transformation and acquired ROS-1 F2004C mutation in a lung adenocarcinoma patient
.
Pulmonology
2022
;
28
:
76
9
.
24.
Dimou
A
,
Ou
SHI
,
Doebele
RC
.
Dramatic response to lorlatinib in a patient with CD74-ROS1-positive lung adenocarcinoma with acquired F2004V mutation
.
JCO Precis Oncol
2019
;
3:PO.19.00013
.
25.
McCoach
CE
,
Le
AT
,
Gowan
K
,
Jones
K
,
Schubert
L
,
Doak
A
, et al
.
Resistance mechanisms to targeted therapies in ROS1(+) and ALK(+) non-small cell lung cancer
.
Clin Cancer Res
2018
;
24
:
3334
47
.
26.
Drilon
A
,
Somwar
R
,
Wagner
JP
,
Vellore
NA
,
Eide
CA
,
Zabriskie
MS
, et al
.
A novel crizotinib-resistant solvent-front mutation responsive to cabozantinib therapy in a patient with ROS1-rearranged lung cancer
.
Clin Cancer Res
2016
;
22
:
2351
8
.
27.
Begum
P
,
Cui
W
,
Popat
S
.
Crizotinib-resistant ROS1 G2101A mutation associated with sensitivity to lorlatinib in ROS1-rearranged non-small cell lung cancer: Case Report
.
JTO Clin Res Rep
2022
;
3
:
100376
.
28.
Li
W
,
Yang
N
,
Ma
H
,
Fan
H
,
Li
K
,
Wu
H
, et al
.
The efficacy and safety of taletrectinib in patients with TKI-naïve or crizotinib-pretreated ROS1-positive non–small cell lung cancer (NSCLC)
.
J Clin Oncol
40
,
2022
(suppl 16; abstr 8572)
.
29.
Cho
BC
,
Lin
J
,
Camidge
DR
,
Velcheti
V
,
Solomon
B
,
Lu
S
, et al
.
Pivotal topline data from the phase 1/2 TRIDENT-1 trial of repotrectinib in patients with ROS1+ advanced non-small cell lung cancer (NSCLC)
.
Eur J Cancer
2022
;
174
:
S1
2
.
30.
Cocco
E
,
Scaltriti
M
,
Drilon
A
.
NTRK fusion-positive cancers and TRK inhibitor therapy
.
Nat Rev Clin Oncol
2018
;
15
:
731
47
.
31.
Shaw
AT
,
Bauer
TM
,
de Marinis
F
,
Felip
E
,
Goto
Y
,
Liu
G
, et al
.
First-line lorlatinib or crizotinib in advanced ALK-positive lung cancer
.
N Engl J Med
2020
;
383
:
2018
29
.
32.
Drilon
A
,
Ou
SHI
,
Cho
BC
,
Kim
DW
,
Lee
J
,
Lin
JJ
, et al
.
Repotrectinib (TPX-0005) is a next-generation ROS1/TRK/ALK inhibitor that potently inhibits ROS1/TRK/ALK solvent-front mutations
.
Cancer Discov
2018
;
8
:
1227
36
.
33.
Liu
D
,
Flory
J
,
Lin
A
,
Offin
M
,
Falcon
CJ
,
Murciano-Goroff
YR
, et al
.
Characterization of on-target adverse events caused by TRK inhibitor therapy
.
Ann Oncol
2020
;
31
:
1207
15
.
34.
Zou
HY
,
Li
Q
,
Engstrom
LD
,
West
M
,
Appleman
V
,
Wong
KA
, et al
.
PF-06463922 is a potent and selective next-generation ROS1/ALK inhibitor capable of blocking crizotinib-resistant ROS1 mutations
.
Proc Natl Acad Sci U S A
2015
;
112
:
3493
8
.
35.
Awad
MM
,
Katayama
R
,
McTigue
M
,
Liu
W
,
Deng
YL
,
Brooun
A
, et al
.
Acquired resistance to crizotinib from a mutation in CD74–ROS1
.
N Engl J Med
2013
;
368
:
2395
401
.
36.
Wang
L
,
Wu
Y
,
Deng
Y
,
Kim
B
,
Pierce
L
,
Krilov
G
, et al
.
Accurate and reliable prediction of relative ligand binding potency in prospective drug discovery by way of a modern free-energy calculation protocol and force field
.
J Am Chem Soc
2015
;
137
:
2695
703
.
37.
Abel
R
,
Wang
L
,
Harder
ED
,
Berne
BJ
,
Friesner
RA
.
Advancing drug discovery through enhanced free energy calculations
.
Acc Chem Res
2017
;
50
:
1625
32
.
38.
Wager
TT
,
Hou
X
,
Verhoest
PR
,
Villalobos
A
.
Central nervous system multiparameter optimization desirability: application in drug discovery
.
ACS Chem Neurosci
2016
;
7
:
767
75
.
39.
Paoli
P
,
Giannoni
E
,
Chiarugi
P
.
Anoikis molecular pathways and its role in cancer progression
.
Biochim Biophys Acta
2013
;
1833
:
3481
98
.
40.
Hanahan
D
,
Weinberg
RA
.
The hallmarks of cancer
.
Cell
2000
;
100
:
57
70
.
41.
Katayama
R
,
Gong
B
,
Togashi
N
,
Miyamoto
M
,
Kiga
M
,
Iwasaki
S
, et al
.
The new-generation selective ROS1/NTRK inhibitor DS-6051b overcomes crizotinib resistant ROS1-G2032R mutation in preclinical models
.
Nat Commun
2019
;
10
:
3604
.
42.
Bauer
TM
,
Shaw
AT
,
Johnson
ML
,
Navarro
A
,
Gainor
JF
,
Thurm
H
, et al
.
Brain penetration of lorlatinib: cumulative incidences of CNS and non-CNS progression with lorlatinib in patients with previously treated ALK-positive non-small-cell lung cancer
.
Target Oncol
2020
;
15
:
55
65
.
43.
Johnson
TW
,
Richardson
PF
,
Bailey
S
,
Brooun
A
,
Burke
BJ
,
Collins
MR
, et al
.
Discovery of (10 R)-7-Amino-12-fluoro-2,10,16-trimethyl-15-oxo-10,15,16,17- tetrahydro- 2H -8,4-(metheno)pyrazolo[4,3- h][2,5,11]- benzoxadiazacyclotetradecine-3-carbonitrile (PF-06463922), a macrocyclic inhibitor of anaplastic lymphoma kinase (ALK) and c-ros oncogene 1 (ROS1) with preclinical brain exposure and broad-spectrum potency against ALK-resistant mutations
.
J Med Chem
2014
;
57
:
4720
44
.
44.
Shaw
AT
,
Felip
E
,
Bauer
TM
,
Besse
B
,
Navarro
A
,
Postel-Vinay
S
, et al
.
Lorlatinib in non-small-cell lung cancer with ALK or ROS1 rearrangement: an international, multicentre, open-label, single-arm first-in-man phase 1 trial
.
Lancet Oncol
2017
;
18
:
1590
9
.
45.
Drilon
A
,
Besse
B
,
Camidge
DR
,
Ou
SHI
,
Gadgeel
SM
,
Johnson
ML
, et al
.
Safety and preliminary clinical activity of NVL-520, a highly selective ROS1 inhibitor, in patients with advanced ROS1 fusion-positive solid tumors
.
Eur J Cancer
2022
;
174
:
S6
7
.
46.
Soria
JC
,
Ohe
Y
,
Vansteenkiste
J
,
Reungwetwattana
T
,
Chewaskulyong
B
,
Lee
KH
, et al
.
Osimertinib in untreated EGFR-mutated advanced non–small-cell lung cancer
.
N Engl J Med
2018
;
378
:
113
25
.
47.
Peters
S
,
Camidge
DR
,
Shaw
AT
,
Gadgeel
S
,
Ahn
JS
,
Kim
D-W
, et al
.
Alectinib versus crizotinib in untreated ALK-positive non–small-cell lung cancer
.
N Engl J Med
2017
;
377
:
829
38
.
48.
Shiba-Ishii
A
,
Johnson
TW
,
Dagogo-Jack
I
,
Mino-Kenudson
M
,
Johnson
TR
,
Wei
P
, et al
.
Analysis of lorlatinib analogs reveals a roadmap for targeting diverse compound resistance mutations in ALK-positive lung cancer
.
Nat Cancer
2022
;
3
:
710
22
.
49.
Lin
JJ
,
Cho
BC
,
Springfeld
C
,
Camidge
DR
,
Solomon
B
,
Baik
C
, et al
.
Update from the phase 2 registrational trial of repotrectinib in TKI-pretreated patients with ROS1+ advanced non-small cell lung cancer and with NTRK+ advanced solid tumors (TRIDENT-1) [abstract]
.
In:
Proceedings of the AACR-NCI-EORTC Virtual International Conference on Molecular Targets and Cancer Therapeutics
;
2021
Oct 7–10
.
Philadelphia (PA)
:
AACR
;
Mol Cancer Ther 2021;20(12 Suppl):Abstract nr P224
.
50.
Drilon
A
.
TRK inhibitors in TRK fusion-positive cancers
.
Ann Oncol
2019
;
30
:
viii23
30
.
51.
Drilon
A
,
Siena
S
,
Ou
SHI
,
Patel
M
,
Ahn
MJ
,
Lee
J
, et al
.
Safety and antitumor activity of the multitargeted pan-TRK, ROS1, and ALK inhibitor entrectinib: combined results from two phase I trials (ALKA-372–001 and STARTRK-1)
.
Cancer Discov
2017
;
7
:
400
9
.
52.
Papadopoulos
KP
,
Borazanci
E
,
Shaw
AT
,
Katayama
R
,
Shimizu
Y
,
Zhu
VW
, et al
.
U.S. phase I first-in-human study of taletrectinib (DS-6051b/AB-106), a ROS1/TRK inhibitor, in patients with advanced solid tumors
.
Clin Cancer Res
2020
;
26
:
4785
94
.
53.
Rikova
K
,
Guo
A
,
Zeng
Q
,
Possemato
A
,
Yu
J
,
Haack
H
, et al
.
Global survey of phosphotyrosine signaling identifies oncogenic kinases in lung cancer
.
Cell
2007
;
131
:
1190
203
.
54.
Menichincheri
M
,
Ardini
E
,
Magnaghi
P
,
Avanzi
N
,
Banfi
P
,
Bossi
R
, et al
.
Discovery of entrectinib: a new 3-aminoindazole as a potent anaplastic lymphoma kinase (ALK), c-ros oncogene 1 kinase (ROS1), and pan-tropomyosin receptor kinases (Pan-TRKs) inhibitor
.
J Med Chem
2016
;
59
:
3392
408
.
55.
Murray
BW
,
Rogers
E
,
Zhai
D
,
Deng
W
,
Chen
X
,
Sprengeler
PA
, et al
.
Molecular characteristics of repotrectinib that enable potent inhibition of TRK fusion proteins and resistant mutations
.
Mol Cancer Ther
2021
;
20
:
2446
56
.
56.
Lu
C
,
Wu
C
,
Ghoreishi
D
,
Chen
W
,
Wang
L
,
Damm
W
, et al
.
OPLS4: Improving force field accuracy on challenging regimes of chemical space
.
J Chem Theory Comput
2021
;
17
:
4291
300
.
57.
Kuhn
B
,
Tichý
M
,
Wang
L
,
Robinson
S
,
Martin
RE
,
Kuglstatter
A
, et al
.
Prospective evaluation of free energy calculations for the prioritization of cathepsin L inhibitors
.
J Med Chem
2017
;
60
:
2485
97
.
58.
Yu
HS
,
Deng
Y
,
Wu
Y
,
Sindhikara
D
,
Rask
AR
,
Kimura
T
, et al
.
Accurate and reliable prediction of the binding affinities of macrocycles to their protein targets
.
J Chem Theory Comput
2017
;
13
:
6290
300
.
59.
Wang
L
,
Deng
Y
,
Wu
Y
,
Kim
B
,
LeBard
DN
,
Wandschneider
D
, et al
.
Accurate modeling of scaffold hopping transformations in drug discovery
.
J Chem Theory Comput
2017
;
13
:
42
54
.
60.
Moraca
F
,
Negri
A
,
de Oliveira
C
,
Abel
R
.
Application of free energy perturbation (FEP+) to understanding ligand selectivity: a case study to assess selectivity between pairs of phosphodiesterases (PDE's)
.
J Chem Inf Model
2019
;
59
:
2729
40
.
61.
Hauser
K
,
Negron
C
,
Albanese
SK
,
Ray
S
,
Steinbrecher
T
,
Abel
R
, et al
.
Predicting resistance of clinical Abl mutations to targeted kinase inhibitors using alchemical free-energy calculations
.
Commun Biol
2018
;
1
:
70
.
62.
Bertrand
T
,
Kothe
M
,
Liu
J
,
Dupuy
A
,
Rak
A
,
Berne
PF
, et al
.
The crystal structures of TrkA and TrkB suggest key regions for achieving selective inhibition
.
J Mol Biol
2012
;
423
:
439
53
.
63.
Shults
MD
,
Imperiali
B
.
Versatile fluorescence probes of protein kinase activity
.
J Am Chem Soc
2003
;
125
:
14248
9
.
64.
Eid
S
,
Turk
S
,
Volkamer
A
,
Rippmann
F
,
Fulle
S
.
KinMap: a web-based tool for interactive navigation through human kinome data
.
BMC Bioinf
2017
;
18
:
16
.
65.
Lin
JJ
,
Langenbucher
A
,
Gupta
P
,
Yoda
S
,
Fetter
IJ
,
Rooney
M
, et al
.
Small cell transformation of ROS1 fusion-positive lung cancer resistant to ROS1 inhibition
.
NPJ Precis Oncol
2020
;
4
:
21
.
66.
Crystal
AS
,
Shaw
AT
,
Sequist
LV
,
Friboulet
L
,
Niederst
MJ
,
Lockerman
EL
, et al
.
Patient-derived models of acquired resistance can identify effective drug combinations for cancer
.
Science
2014
;
346
:
1480
6
.
This open access article is distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International (CC BY-NC-ND 4.0) license.