Exemestane Plus Everolimus and Palbociclib in Metastatic Breast Cancer: Clinical Response and Genomic/transcriptomic Determinants of Resistance in a Phase I/II Trial

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Mar 20

PMID 38503755

Authors

Jorge Gomez Tejeda Zanudo

Romualdo Barroso-Sousa

Esha Jain

Qingchun Jin

Tianyu Li

Jorge E Buendia-Buendia

Alyssa Pereslete

Daniel L Abravanel

Arlindo R Ferreira

Eileen Wrabel

Karla Helvie

Melissa E Hughes

Ann H Partridge

Beth Overmoyer

Nancy U Lin

Nabihah Tayob

Sara M Tolaney

Nikhil Wagle

Affiliations

Soon will be listed here.

Abstract

The landscape of cyclin-dependent kinase 4/6 inhibitor (CDK4/6i) resistance is still being elucidated and the optimal subsequent therapy to overcome resistance remains uncertain. Here we present the final results of a phase Ib/IIa, open-label trial (NCT02871791) of exemestane plus everolimus and palbociclib for CDK4/6i-resistant metastatic breast cancer. The primary objective of phase Ib was to evaluate safety and tolerability and determine the maximum tolerated dose/recommended phase II dose (100 mg palbociclib, 5 mg everolimus, 25 mg exemestane). The primary objective of phase IIa was to determine the clinical benefit rate (18.8%, n = 6/32), which did not meet the predefined endpoint (65%). Secondary objectives included pharmacokinetic profiling (phase Ib), objective response rate, disease control rate, duration of response, and progression free survival (phase IIa), and correlative multi-omics analysis to investigate biomarkers of resistance to CDK4/6i. All participants were female. Multi-omics data from the phase IIa patients (n = 24 tumor/17 blood biopsy exomes; n = 27 tumor transcriptomes) showed potential mechanisms of resistance (convergent evolution of HER2 activation, BRAF), identified joint genomic/transcriptomic resistance features (ESR1 mutations, high estrogen receptor pathway activity, and a Luminal A/B subtype; ERBB2/BRAF mutations, high RTK/MAPK pathway activity, and a HER2-E subtype), and provided hypothesis-generating results suggesting that mTOR pathway activation correlates with response to the trial's therapy. Our results illustrate how genome and transcriptome sequencing may help better identify patients likely to respond to CDK4/6i therapies.

Citing Articles

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