A groundbreaking study from the National Cancer Research Centre (CNIO) has unveiled an extraordinary biochemical peculiarity in the oncogenic fusion protein known as CCDC6-RET, which has profound implications for targeted cancer therapies. This protein, implicated in thyroid cancer and pulmonary adenocarcinoma, exhibits a highly unconventional mechanism of self-activation that defies the norms established by typical protein kinases. Such discoveries not only challenge existing paradigms of kinase biology but also potentially revolutionize therapeutic strategies aimed at halting tumor progression.
For over thirty years, CCDC6-RET has been recognized as a potent driver of malignancies, but the intricate molecular underpinnings governing its activation remained elusive. Unlike canonical kinases that rely exclusively on ATP (adenosine triphosphate) hydrolysis to propagate phosphorylation cascades, CCDC6-RET demonstrates a dual capacity to harness both ATP and its metabolic byproduct, ADP (adenosine diphosphate), as phosphate donors. This duality suggests a remarkable fuel efficiency, enabling the kinase to sustain its oncogenic signaling even under metabolically compromised conditions typical of tumor microenvironments.
At the molecular level, protein kinases generally proceed through a sequential activation involving the transfer of phosphate groups from ATP molecules to specific amino acid residues, predominantly serine, threonine, or tyrosine. This process modulates substrate activity and propagates intracellular signals essential for diverse cellular functions. However, CCDC6-RET diverges sharply by simultaneously phosphorylating multiple domains, a phenomenon that accelerates its activation kinetics compared to native RET kinase. Such accelerated phosphorylation amplifies the downstream signaling outputs, intensifying the oncogenic drive and contributing to rapid tumor cell proliferation.
The fusion protein arises from a gene rearrangement event whereby the RET gene aberrantly fuses with the CCDC6 gene, producing a chimeric oncoprotein with altered structural properties. This fusion event is emblematic of a broader class of oncogenic mutations characterized by gene fusions that bestow neomorphic properties upon the resultant proteins. These fusion proteins often exhibit heightened enzymatic activity, altered substrate specificity, or novel subcellular localization, all contributing to malignant transformation. The CCDC6-RET chimera exemplifies these trends but stands out due to its unprecedented energy utilization flexibility.
Researchers employed an integrative approach combining crystallography, cryo-electron microscopy, and artificial intelligence-driven protein modeling to resolve the three-dimensional structures of both the inactive and active forms of CCDC6-RET. Their structural insights reveal the conformational rearrangements facilitating its unique dual ATP/ADP-dependent kinase activity. This comprehensive structural characterization lays a foundation for rational drug design aimed at selectively inhibiting this fusion protein, which traditional RET inhibitors may inadequately target due to their inability to account for the ADP-utilization mechanism.
The recognition that ADP functions not merely as a metabolic waste product but also as an active cofactor in kinase activation opens novel conceptual frameworks in cellular bioenergetics and signal transduction. It suggests that tumor cells might exploit metabolic intermediates to sustain oncogenic signaling pathways, thereby circumventing nutrient deprivation or pharmacological inhibition. In this context, CCDC6-RET can be viewed as a molecular exemplar of metabolic adaptability, harnessing energy substrates beyond the canonical ATP pool to maintain its function.
Clinically, this discovery prompts a reassessment of existing therapies targeting RET fusions. Current inhibitors predominantly focus on blocking ATP-binding sites; however, the ability of CCDC6-RET to functionalize ADP suggests that these approaches might only partially suppress its kinase activity. Therefore, the development of novel modulators capable of disrupting both ATP- and ADP-mediated activation states could yield more effective therapeutic responses, reducing resistance and improving patient outcomes.
The study also provokes broader inquiries into the prevalence of similar dual nucleotide-utilizing kinases within the human kinome and their roles in cancer metabolism. If such mechanisms are more widespread, they could signify an underappreciated avenue of metabolic flexibility exploited by cancer cells, warranting comprehensive screening and functional assays across various oncogenic kinases.
Moreover, these findings underscore the interplay between oncogenic signaling and metabolic regulation within the tumor milieu. Tumor cells are known to reprogram their metabolism to sustain rapid growth, often under hypoxic or nutrient-scarce environments. The dual reliance on ATP and ADP by CCDC6-RET could represent a survival mechanism allowing continuous signaling despite fluctuating intracellular energy states, a feature that might be critical in tumor progression and resistance to therapy.
Looking ahead, the CNIO research team envisions leveraging the detailed structural and mechanistic insights obtained to design next-generation kinase inhibitors with enhanced specificity and potency against RET fusion proteins. Such drugs could potentially exhibit novel modes of action, including allosteric inhibition or disruption of ADP binding, thereby overcoming limitations of current ATP-competitive therapies.
In summary, the elucidation of CCDC6-RET as a dual ATP- and ADP-dependent kinase redefines our understanding of kinase activation, particularly in the context of oncogenic fusion proteins. This paradigm-shifting discovery not only deepens the molecular knowledge of cancer biology but also catalyzes innovative therapeutic development aimed at some of the most refractory malignancies driven by RET fusions.
Subject of Research: Cells
Article Title: The oncogenic CCDC6-RET fusion protein is a dual ATP- and ADP-dependent kinase
News Publication Date: 6-Mar-2026
Web References: https://www.nature.com/articles/s41467-026-69833-y#data-availability
References: DOI: 10.1038/s41467-026-69833-y
Image Credits: Christian Esposito / Madmoviex / CNIO
Keywords: Oncogenes, Cancer genome sequencing, Proteins, Mutant proteins, Kinase activity, Kinase signaling, Protein activation, Receptor activation, Personalized medicine, Target proteins
