LIBRETTO-531: a phase III study of selpercatinib in multikinase inhibitor-naïve RET-mutant medullary thyroid cancer.

Selpercatinib is a first-in-class, highly selective and potent, central nervous system-active RET kinase inhibitor. In the phase I/II trial, selpercatinib demonstrated clinically meaningful antitumor activity with manageable toxicity in heavily pre-treated and treatment-naive patients with RET-mutant medullary thyroid cancer (MTC). LIBRETTO-531 (NCT04211337) is a multicenter, open-label, randomized, controlled, phase III trial comparing selpercatinib to cabozantinib or vandetanib in patients with advanced/metastatic RET-mutant MTC. The primary objective is to compare progression-free survival (per RECIST 1.1) by blinded independent central review of patients with progressive, advanced, multikinase inhibitor-naive, RET-mutant MTC treated with selpercatinib versus cabozantinib or vandetanib. Key secondary objectives are to compare other efficacy outcomes (per RECIST 1.1) and tolerability of selpercatinib versus cabozantinib or vandetanib.

Selpercatinib (also known by the brand name Retevmo^®/Retsevmo^®) is a new treatment available in multiple countries for people with advanced or metastatic RET-mutant medullary thyroid cancer (MTC). Thyroid cancer starts in your thyroid gland and may spread or metastasize to other parts of the body, including lungs, bones, and occasionally the brain, which means the cancer is likely to be advanced. Advanced thyroid cancer can be driven by a gene in your body, one of which is RET. This is a summary of the LIBRETTO-531 study which compares selpercatinib, which is a strong and selective inhibitor of RET, with two approved drugs, cabozantinib and vandetanib. Patients with advanced or metastatic RET-mutant MTC who have not already received treatment with kinase inhibitors are being enrolled. This trial will evaluate how long people during and after treatment live with the disease without it getting worse. Selpercatinib may affect both healthy cells and tumor cells, which can result in side effects, which will also be evaluated in this study. This study is active and currently recruiting new patients. Clinical Trial Registration: NCT04211337 (ClinicalTrials.gov).

LIBRETTO-432, a phase III study of adjuvant selpercatinib or placebo in stage IB-IIIA RET fusion-positive non-small-cell lung cancer.

Selpercatinib, a first-in-class, highly selective and potent central nervous system-active RET kinase inhibitor demonstrated clinically meaningful activity with manageable toxicity in pretreated and treatment-naive advanced/metastatic RET fusion-positive non-small-cell lung cancer (NSCLC). LIBRETTO-432 is a global, randomized, double-blind, phase III trial evaluating selpercatinib versus placebo in stage IB-IIIA, RET fusion-positive NSCLC, previously treated with definitive surgery or radiation; participants must have undergone available anti-cancer therapy (including chemotherapy or durvalumab) or not be suitable for it, per investigator's discretion. The primary end point is investigator-assessed event-free survival (EFS) in the primary analysis population (stage II-IIIA RET fusion-positive NSCLC). Key secondary end points include EFS in the overall population, overall survival, and time to distant disease recurrence in the central nervous system.

Selpercatinib is approved in multiple countries for the treatment of advanced or metastatic RET-altered lung cancers. Selpercatinib has shown promising efficacy and safety results in patients with advanced/metastatic RET fusion-positive NSCLC. This is a summary of the LIBRETTO-432 study which compares selpercatinib with placebo in patients with earlier stages (stage IB-IIIA) of RET fusion-positive NSCLC, who have already undergone surgery or radiotherapy and applicable adjuvant chemotherapy. This study is active and currently recruiting new participants. This trial will evaluate how long people live without evidence of cancer recurrence, both during and after treatment. Side effects will also be evaluated in this study. Clinical Trial Registration: NCT04819100 (ClinicalTrials.gov).

Molecular dynamics study of enhanced autophosphorylation by S904F mutation of the RET kinase domain.

The aberrant kinase activity of RET (rearranged during transfection), a transmembrane tyrosine kinase, is associated with human cancer. A point mutation caused by the replacement of solvent-front hydrophilic S904, located on the activation loop (A-loop), with a bulky hydrophobic phenylalanine residue can induce resistance to the type I kinase inhibitor vandetanib. A possible mechanism of this drug resistance is the release of a cis-autoinhibited conformation of RET for autophosphorylation, which activates RET kinase. Because the association between S904F mutation and enhanced autophosphorylation is unclear, we conducted molecular modeling analysis to compare unphosphorylated apo wild-type and S904F mutant structures. The structural compactness of the A-loop promoted ATP binding. When the A-loop is extended, the αC helix moves toward the glycine-rich loop, resulting in the protrusion of F735. The extruded F735 connects with E734 and R912 and constrains the ATP pocket entrance. Contrarily, a contracted A-loop pulls the αC helix away from the glycine-rich loop, burying F734 and making the ATP pocket accessible. The mutated F904 stabilizes the contracted A-loop and releases the autoinhibited conformation of RET, thereby facilitating autophosphorylation. We also simulated two ATP-bound systems. The binding free energies of ATP, estimated through the molecular mechanics with a generalized Born and surface area solvation approach, revealed that the S904F mutant was bound more tightly than was the wild type with the ATP. The findings support the premise of autophosphorylation promotion in the S904F mutant.

Phase III study of selpercatinib versus chemotherapy ± pembrolizumab in untreated RET positive non-small-cell lung cancer.

Selpercatinib, a novel, highly selective and potent, inhibitor of RET, demonstrated clinically meaningful antitumor activity with manageable toxicity in heavily pretreated and treatment-naive RET fusion-positive non-small-cell lung cancer patients in a Phase I/II clinical trial. LIBRETTO-431 (NCT04194944) is a randomized, global, multicenter, open-label, Phase III trial, evaluating selpercatinib versus carboplatin or cisplatin and pemetrexed chemotherapy with or without pembrolizumab in treatment-naive patients with locally advanced/metastatic RET fusion-positive nonsquamous non-small-cell lung cancer. The primary end point is progression-free survival by independent review. Key secondary end points include overall survival, response rate, duration of response and progression-free survival. Clinical trial registration: NCT04194944 (ClinicalTrials.gov).

Discovery of 4-chloro-3-(5-(pyridin-3-yl)-1,2,4-oxadiazole-3-yl)benzamides as novel RET kinase inhibitors.

A series of novel 4-chloro-benzamides derivatives containing substituted five-membered heteroaryl ring were designed, synthesized and evaluated as RET kinase inhibitors for cancer therapy. Most of compounds exhibited moderate to high potency in ELISA-based kinase assay. In particular, compound I-8 containing 1,2,4-oxadiazole strongly inhibited RET kinase activity both in molecular and cellular level. In turn, I-8 inhibited cell proliferation driven by RET wildtype and gatekeeper mutation. The results implied that 4-chloro-3-(5-(pyridin-3-yl)-1,2,4-oxadiazole-3-yl)benzamides are promising lead compounds as novel RET kinase inhibitor for further investigation.

[Precision medicine in endocrinology exemplified by medullary thyroid cancer]. / Präzisionsmedizin in der Endokrinologie am Beispiel des medullären Schilddrüsenkarzinoms.

Medullary thyroid cancer (MTC) is a prime example for precision medicine in endocrinology and underlines the immediate benefits of basic, translational and healthcare research for patients with a rare disease in clinical . A mutation in the rearranged during transfection (RET) proto-oncogene that codes for a transmembrane receptor protein tyrosine kinase, leads to constitutive activation of the kinase, which is the decisive pathomechanism for the disease. The MTC occurs in a sporadic (somatic RET mutation) or hereditary form (RET germline mutation, multiple endocrine neoplasia types 2 and 3). For germline mutation carriers the timing of preventive thyroidectomy depends on the RET genotype. For advanced metastasized RET-mutant MTC, selective RET kinase inhibitors are available, which are currently considered to be game changers in the treatment. Based on the specific tumor marker calcitonin, MTC can be identified at an early stage during the differential diagnosis of thyroid nodules. The preoperative calcitonin level even enables statements on the degree of dissemination of the disease and on the probability of a cure through surgery. A new development is the consideration of desmoplasia as a histopathological biomarker for the metastatic potential of a MTC, which could possibly modify the operative approach as well as the future MTC nomenclature. Furthermore, the postoperative calcitonin level and the calcitonin doubling time are highly valid prognostic markers for tumor burden and biological aggressiveness of MTC and therefore decisive for patient follow-up. Biochemical, molecular and histological markers enable a risk-adapted surgical treatment and together with new targeted systemic treatments have contributed to a paradigm shift in the diagnostics, prognosis and treatment of MTC in recent years. Endocrine precision medicine for MTC therefore enabled a change from the previous purely symptom-oriented to a modern preventive and individualized treatment.

Concurrent KRAS p.G12C mutation and ANK3::RET fusion in a patient with metastatic colorectal cancer: a case report.

BACKGROUND: Colorectal cancer (CRC) frequently involves mutations in the KRAS gene, impacting therapeutic strategies and prognosis. The occurrence of KRAS mutations typically precludes the presence of RET fusions, with current medical literature suggesting a mutual exclusivity between these two genetic alterations. We present a unique case that challenges this notion. CASE PRESENTATION: An 85-year-old female with metastatic CRC was found to have a combination of genetic anomalies that is to the best of our knowledge not yet described in the medical literature: a KRAS p.G12C mutation, associated with oncogenesis and treatment resistance, and an ANK3::RET fusion, an infrequent but targetable mutation in CRC. This molecular profile was uncovered through comprehensive genomic sequencing after the patient experienced metachronous tumor dissemination. The presence of both genetic events complicates the treatment approach. CONCLUSIONS: The identification of both a KRAS p.G12C mutation and an ANK3::RET fusion in the same CRC patient adds a new layer to the oncogenic landscape and treatment considerations for CRC. It highlights the intricate decision-making required in the era of precision medicine, where targeted therapies must be carefully chosen and potentially combined to combat complex genetic profiles. The case emphasizes the urgency of investigating the clinical effects of concurrent or sequential use of KRAS p.G12C and RET inhibitors to inform future therapeutic guidelines and improve patient outcomes in similar cases.

Design and development of photoswitchable DFG-Out RET kinase inhibitors.

REarranged during Transfection (RET) is a transmembrane receptor tyrosine kinase that is required for development of multiple human tissues, but which is also an important contributor to human cancers. RET activation through rearrangement or point mutations occurs in thyroid and lung cancers. Furthermore, activation of wild type RET is an increasingly recognized mechanism promoting tumor growth and dissemination of a much broader group of cancers. RET is therefore an attractive therapeutic target for small-molecule kinase inhibitors. Non-invasive control of RET signaling with light offers the promise of unveiling its complex spatiotemporal dynamics in vivo. In this work, photoswitchable DFG-out RET kinase inhibitors based on heterocycle-derived azobenzenes were developed, enabling photonic control of RET activity. Based on the binding mode of DFG-out kinase inhibitors and using RET kinase as the test model, we developed a photoswitchable inhibitor with a quinoline "head" constituting the azoheteroarene. This azo compound was further modified by three different strategies to increase the difference in biological activity between the E-isomer and the light enriched Z-isomer. Stilbene-based derivatives were used as model compounds to guide in the selection of substituents that could eventually be introduced to the corresponding azo compounds. The most promising quinoline-based compound showed more than a 15-fold difference in bioactivity between the two isomers in a biochemical assay. However, the same compound showed a decreased Z/E (IC50) ratio in the cellular assay, tentatively assigned to stability issues. The corresponding stilbene compound gave a Z/E (IC50) ratio well above 100, consistent with that measured in the biochemical assay. Ultimately, a 7-azaindole based photoswitchable DFG-out kinase inhibitor was shown to display more than a 10-fold difference in bioactivity between the two isomers, in both a biochemical and a cell-based assay, as well as excellent stability even under reducing conditions.

Efficacy and safety of selpercatinib in Chinese patients with advanced RET-altered thyroid cancers: results from the phase II LIBRETTO-321 study.

Background: Selpercatinib, a highly selective and potent REarranged during Transfection (RET) kinase inhibitor, is effective in advanced RET-altered thyroid cancer (TC). However, the efficacy and safety in Chinese patients are unknown. Patients and methods: In the open-label, multi-center phase II LIBRETTO-321 (NCT04280081) study, Chinese patients with advanced solid tumors harboring RET alterations received selpercatinib 160 mg twice daily. The primary endpoint was objective response rate (ORR; RECIST v1.1) by independent review committee (IRC). Secondary endpoints included duration of response (DoR) and safety. Efficacy was assessed in the primary analysis set [PAS; treated patients with RET fusion-positive TC or RET-mutant medullary TC (MTC) confirmed by central laboratory] and all enrolled patients with MTC. Results: Of 77 enrolled patients, 29 had RET-mutant MTC and one had RET fusion-positive TC. In the PAS (n = 26), the ORR by IRC was 57.7% [95% confidence interval (CI), 36.9-76.6]. Median DoR was not reached and 93.3% of responses were ongoing at a median follow-up of 8.7 months. In all enrolled MTC patients (n = 29), the ORR by IRC was 58.6% (95% CI, 38.9-76.5). One RET fusion-positive TC patient treated for 23.4 weeks achieved a partial response at week 8 that was ongoing at cutoff. In the safety population (n = 77), 59.7% experienced grade ⩾3 treatment-emergent adverse events (TEAEs). TEAEs led to dose reductions in 32.5% (n = 25) and discontinuations in 5.2% [n = 4; 3.9% (n = 3) considered treatment related] of patients. Conclusions: Selpercatinib showed robust antitumor activity and was well tolerated in Chinese patients with advanced RET-altered TC, consistent with global data from LIBRETTO-001 (NCT04280081). ClinicalTrialsgov Identifier: NCT04280081 (first posted Feb 21, 2020).

1-Methyl-3-((4-(quinolin-4-yloxy)phenyl)amino)-1H-pyrazole-4-carboxamide derivatives as new rearranged during Transfection (RET) kinase inhibitors capable of suppressing resistant mutants in solvent-front regions.

REarranged during Transfection (RET) is a validated target for anticancer drug discovery and two selective RET inhibitors were approved by US FDA in 2020. However, acquired resistance mediated by secondary mutations in the solvent-front region of the kinase (e.g. G810C/S/R) becomes a major challenge for selective RET inhibitor therapies. Herein, we report a structure-based design of 1-methyl-3-((4-(quinolin-4-yloxy)phenyl)amino)-1H-pyrazole-4-carboxamide derivatives as new RET kinase inhibitors which are capable of suppressing the RETG810 C/R resistant mutants. One of the representative compounds, 8q, potently suppressed wild-type RET kinase with an IC50 value of 13.7 nM. It also strongly inhibited the proliferation of BaF3 cells stably expressing various oncogenic fusions of RET kinase with solvent-front mutations, e.g. CCDC6-RETG810C, CCDC6-RETG810R, KIF5B-RETG810C and KIF5B-RETG810R, with IC50 values of 15.4, 53.2, 54.2 and 120.0 nM, respectively. Furthermore, 8q dose-dependently inhibited the activation of RET and downstream signals and obviously triggered apoptosis in Ba/F3-CCDC6-RETG810 C/R cells. The compound also exhibited significant anti-tumor efficacy with a tumor growth inhibition (TGI) value of 66.9% at 30 mg/kg/day via i. p. in a Ba/F3-CCDC6-RETG810C xenograft mouse model. Compound 8q may be utilized as a lead compound for drug discovery combating acquired resistance against selective RET inhibitor therapies.

How does nintedanib overcome cancer drug-resistant mutation of RET protein-tyrosine kinase: insights from molecular dynamics simulations.

Targeted drug therapies represent a therapeutic breakthrough in the treatment of human cancer. However, the emergence of acquired resistance inevitably compromises therapeutic drugs. Rearranged during transfection (RET) proto-oncogene, which encodes a receptor tyrosine kinase, is a target for several kinds of human cancer such as thyroid, breast, and colorectal carcinoma. A single mutation L881V at the RET kinase domain was found in familial medullary thyroid carcinoma. Nintedanib can effectively inhibit the RET L881V mutant, whereas its analog compound 1 is unable to combat this mutant. However, the underlying mechanism was still unexplored. Here, molecular dynamics (MD) simulations, binding free energy calculations, and structural analysis were performed to uncover the mechanism of overcoming the resistance of RET L881V mutant to nintedanib. Energetic analysis revealed that the L881V mutant remained sensitive to the treatment of nintedanib, whereas it was insensitive to the compound 1. Structural analysis further showed that the distribution of K758, D892, and N879 network had a detrimental effect on the binding of compound 1 to the L881V mutant. The obtained results may provide insight into the mechanism of overcoming resistance in the RET kinase.

Pyrrolo[2,3-d]pyrimidine derivatives as inhibitors of RET: Design, synthesis and biological evaluation.

Gene fusions and point mutations of RET kinase are crucial for driving thoracic cancers, including thyroid cancer and non-small cell lung cancer. Various scaffolds based on different heterocycles have been synthesized and evaluated as RET inhibitors. In this work, we investigate pyrrolo[2,3-d]pyrimidine derivatives for inhibition of RET-wt, drug resistant mutant RET V804M and RET gene fusion driven cell lines. Several compounds were synthesized and the structure activity relationship was extensively studied to optimize the scaffold. Thieno[2,3-d]pyrimidine, a bioisostere of pyrrolo[2,3-d]pyrimidine, was also explored for the effect on RET inhibition. We identified a lead compound, 59, which shows low nanomolar potency against RET-wt and RET V804M. Further 59 shows growth inhibition of LC-2/ad cells which RET-CCDC6 driven. We also determined that 59 is a type 2 inhibitor of RET and demonstrated its ability to inhibit migration of tumor cells. Based on computational studies, we proposed a binding pose of 59 in RET pocket and have quantified the contributions of individual residues for its binding. Together, 59 is an important lead compound which needs further evaluation in biological studies.

Structural optimization and structure-activity relationship studies of N-phenyl-7,8-dihydro-6H-pyrimido[5,4-b][1,4]oxazin-4-amine derivatives as a new class of inhibitors of RET and its drug resistance mutants.

The RET tyrosine kinase is an important therapeutic target for medullary thyroid cancer (MTC), and drug resistance mutations of RET, particularly V804M and V804L, are a main challenge for the current targeted therapy of MTC based on RET inhibitors. In this investigation, we report the structural optimization and structure-activity relationship studies of N-phenyl-7,8-dihydro-6H-pyrimido[5,4-b][1,4]oxazin-4-amine derivatives as a new class of RET inhibitors. Among all the obtained kinase inhibitors, 1-(5-(tert-butyl)isoxazol-3-yl)-3-(4-((6,7,8,9-tetrahydropyrimido[5,4-b][1,4]oxazepin-4-yl)amino)phenyl)urea (17d) is a multi-kinase inhibitor and potently inhibits RET and its drug resistance mutants. It showed IC50 (half maximal inhibitory concentration) values of 0.010 µM, 0.015 µM, and 0.009 µM against RET-wild-type, RET-V804M, and RET-V804L, respectively. 17d displayed significant anti-viability potencies against various RET-driving tumor cell lines. In a xenograft mouse model of NIH3T3-RET-C634Y, 17d exhibited potent in vivo anti-tumor activity, and no obvious toxicity was observed. Mechanisms of action were also investigated by Western blot and immunohistochemical assays. Collectively, 17d could be a promising agent for the treatment of MTC, hence deserving a further investigation.

Challenging clinically unresponsive medullary thyroid cancer: Discovery and pharmacological activity of novel RET inhibitors.

It is now known that "gain of function" mutations of RET (REarranged during Transfection) kinase are specific and key oncogenic events in the onset of thyroid gland cancers such as the Medullary Thyroid Carcinoma (MTC). Although a number of RET inhibitors exist and are capable of inhibiting RET variants, in which mutations are outside the enzyme active site, the majority becomes dramatically ineffective when mutations are within the protein active site (V804L and V804M). Pursuing a receptor-based virtual screening against the kinase domain of RET, we found that compound 5 is able to inhibit efficiently both wild type and V804L mutant RET. Compound 5 was able to significantly reduce proliferation of both commercially available TT cell lines and surgical thyroid tissues obtained from patients with MTC and displayed a suitable drug-like profile, thus standing out as a promising candidate for further development towards the treatment of clinically unresponsive MTC.

Identification of a novel 5-amino-3-(5-cyclopropylisoxazol-3-yl)-1-isopropyl-1H-pyrazole-4-carboxamide as a specific RET kinase inhibitor.

Activating mutations of REarrange during Transfection (RET) kinase frequently occur in human thyroid and lung cancers. An enormous effort has been devoted to discover potent and selective inhibitors of RET. Selective and potent inhibitors against constitutively active RET mutants are rare to date as identification of selective RET inhibitors is challenging. In a recent effort we identified a novel and specific RET inhibitor of 5-aminopyrazole-4-carboxamide scaffold, which was designed to enhance the metabolic stability of the pyrazolopyrimidine scaffold. In the SAR study described in the current report, we identified the 5-aminopyrazole-4-carboxamide analog 15l, which displays high metabolic stability. Compound 15l is potent against gatekeeper mutant (IC50 = 252 nM) of RET as well as against wild-type RET (IC50 = 44 nM). This substance effectively suppresses growth of Ba/F3 cells transformed with wild-type RET and its gatekeeper mutant (V804M), and thyroid-cancer derived TT cells while it does not affect parental Ba/F3 cells and Nthy ori-3-1, normal thyroid cells. Also, the results of a global kinase profiling assay on a panel of 369 kinases, show that 15l exclusively inhibits RET. Based on its exceptional kinase selectivity, great potency and metabolic stability, 15l represents a promising lead for the discovery of RET directed therapeutic agent and should be a key tool in studies aimed at understanding RET biology.

Systematic Analysis of Tyrosine Kinase Inhibitor Response to RET Gatekeeper Mutations in Thyroid Cancer.

The proto-oncogene protein RET is a receptor tyrosine kinase that plays an important role in the development and progress of various human cancers. Currently, targeting RET with small-molecule tyrosine kinase inhibitors (TKIs) has been established as promising therapeutic strategy for thyroid carcinoma (TC). However, two gatekeeper mutations V804M and V804L in RET kinase domain have been frequently observed to cause drug resistance during the targeted therapy, largely limiting the application of reversible TKIs in TC. Here, we described an integrative protocol that combined literature curation, computational analysis, and in vitro kinase assay to systematically investigate the response profile of 9 approved RET TKIs to the two clinical RET gatekeeper mutations. It was revealed that the two mutations exhibit a similar energetic behavior to influence TKI binding, which can moderately decrease competitive inhibitor affinity and modestly increase substrate ATP affinity simultaneously. However, the binding potency of few second-generation kinase inhibitors such as Ponatinib and Alectinib can be improved to overcome the increased ATP affinity, thus restoring their inhibitory activity against the kinase mutants. Subsequently, the established protocol was employed to investigate the response profile of 4 commercially available RET TKIs that are under preclinical or clinical development. Three out of the four TKIs were found to become resistant upon the mutations due to steric hindrance effect introduced by the mutated residues, while the remaining one was moderately sensitized by the mutations since the mutated residues can form additional hydrophobic and van der Waals interactions with the inhibitor.

An orally available tyrosine kinase ALK and RET dual inhibitor bearing the tetracyclic benzo[b]carbazolone core.

Our early structure-activity relationship study has identified benzo[b]carbazolone 6 as a high potency orally bioavailable ALK inhibitor. Further lead profiling disclosed that 6 is active against both ALK resistant and hot spot-activating mutants, and is also highly potent against RET kinase. Tumor stasis and partial tumor regression were achieved with 6 in both NIH/3T3-EML4-ALK and NIH/3T3-EML4-ALK L1196M xenograft models. Based on the optimal in vitro and in vivo antitumor efficacy, compound 6 is now being profiled further in our preclinical settings as a new orally available ALK/RET dual inhibitor.

Identification and characterization of RET fusions in advanced colorectal cancer.

There is an unmet clinical need for molecularly directed therapies available for metastatic colorectal cancer. Comprehensive genomic profiling has the potential to identify actionable genomic alterations in colorectal cancer. Through comprehensive genomic profiling we prospectively identified 6 RET fusion kinases, including two novel fusions of CCDC6-RET and NCOA4-RET, in metastatic colorectal cancer (CRC) patients. RET fusion kinases represent a novel class of oncogenic driver in CRC and occurred at a 0.2% frequency without concurrent driver mutations, including KRAS, NRAS, BRAF, PIK3CA or other fusion tyrosine kinases. Multiple RET kinase inhibitors were cytotoxic to RET fusion kinase positive cancer cells and not RET fusion kinase negative CRC cells. The presence of a RET fusion kinase may identify a subset of metastatic CRC patients with a high response rate to RET kinase inhibition. This is the first characterization of RET fusions in CRC patients and highlights the therapeutic significance of prospective comprehensive genomic profiling in advanced CRC.