Oncotarget | 2019
We shall overcome (drug resistance) some day
Abstract
The discovery of the involvement of defined molecular pathway(s) in tumor development and therapeutic targeting of such pathway(s) has revolutionised cancer treatment. More than 50 targeted therapeutic agents have been approved by the Food and Drug Administration (FDA) in the last two decades [1]. Unlike traditional cytotoxic treatments, targeted therapies rely on the dominant gene aberration that drives tumor growth and target only affected/malignant cells while sparing the healthy/non-malignant cells. However, although targeted therapies are highly effective and have improved patients survival, they are rarely curative [2]. In most cases, resistance against targeted therapies arises sooner or later. We now know that most tumors employ a highly complex and interconnected network of genetic alterations to drive their malignant growth and sustain survival, hence, single agent targeted therapies often result into modest long-term effects [3]. A number of mechanisms have been identified that mediate acquired (over time) resistance against the targeted therapies, such as point mutations that alter the binding of the drug to its target, activation of additional parallel or downstream signalling pathways (oncogene independent) as well as lineage changes of the tumor cells. Conversely, why some patients do not respond to the targeted therapies from the beginning (intrinsic resistance) is yet to be understood. Anaplastic Lymphoma Kinase (ALK) exemplifies the use of targeted therapeutic agents in combating cancer, as well as the challenges that arise in terms of resistance mechanisms against such agents in clinical settings [4]. A number of ALK tyrosine kinase inhibitors (TKIs) have been developed and approved for use in ALK+ non-small cell lung cancer (NSCLC) while many are being evaluated in clinical trials for their activity in malignancies other than NSCLC [5]. The latest addition to the class of ALK inhibitor is lorlatinib (PF-06463922) which recently received Breakthrough Therapy Designation from the FDA. Besides improved potency and antitumor efficacy, lorlatinib has also been shown to inhibit one of the most resistant mutants, the solvent-front ALK G1202R mutation. It is also highly permeable through the blood brain barrier and hence effective in targeting central nervous system metastasis. Recently published results of the global phase II study has shown superior objective response rate (ORR) and intracranial ORR in comparison to the first and second generation ALK TKIs [6]. As the trends suggest, despite the potency and efficacy, resistance can be expected against lorlatinib treatment. In fact, the first case of resistance to lorlatinib was reported during its early-phase clinical testing where a double ALK mutation (C1556Y/ L1198F) was detected in an ALK-positive NSCLC patient [7]. Organically, it became interesting to investigate the resistance mechanisms that could potentially arise against lorlatinib. Two studies were published this year shedding a light on the emergence of resistant mutations upon treatment with lorlatinib [8, 9]. One of the main findings of these two studies was that compound rather than single on-target resistant point mutations arise against lorlatinib. Another interesting finding in our case was the different ways different tumors acquired resistance. While ALK-positive anaplastic large cell lymphoma xenografts developed both onand off-target mutations, NSCLC and neuroblastoma cells only showed off-target resistance mechanisms. Several cells that acquired resistance under lorlatinib treatment had alterations in different signalling pathways such as the PI3K/AKT/mTOR, RAS/MAPK and EGFR/ERBB4 signalling contributing to the resistant phenotype (Figure 1). Altogether, the findings point to the idea that with potent inhibitors, complex resistance Editorial