Targeting DCPS in myeloid malignancies: The path from biomarker discovery to clinical utility
Published in Cancer, Biomedical Research, and Pharmacy & Pharmacology
We previously published a link between Acute Myeloid Leukemia cells expressing low levels of the tumor suppressor FHIT and sensitivity to loss of the decapping scavenger enzyme DCPS [1]. In the current study we asked whether that link holds in primary AML samples, how common FHIT-low disease may be across AML cohorts, whether myelodysplastic syndrome (MDS) also fits within this biomarker framework, and whether a more clinically accessible proxy biomarker could be found. The core finding was both encouraging and cautionary: low FHIT expression did predict sensitivity to the DCPS inhibitor RG3039, but hydroxyurea pretreatment confounded that signal in primary AML samples by reducing their sensitivity to treatment. At the same time, the broader cohort analyses showed that FHIT-low biology is relevant in a meaningful subset of disease, including 5–24% of AML, with the highest prevalence reported in pediatric AML (24.4%). FHIT promoter methylation was present in 35.8% of MDS and, notably, remained stable during azacitidine treatment, suggesting that FHIT-low predictive value may be feasible beyond AML. Most importantly, IDH2 mutation status emerged as a clinically accessible proxy biomarker for FHIT-linked DCPS sensitivity in AML [2].
That shift, from an interesting biomarker to a usable one, is really the story behind the paper. Biomarkers matter in oncology because they can reduce biological heterogeneity that can hide a real treatment effect in a clinical study. The numbers back this up: one large analysis of oncology drug-development programs found that biomarker-selected trials succeeded at roughly seven times the rate of unselected ones (10.7% versus 1.6%) [3]. A separate large-scale analysis across several major cancer types reported a nearly fivefold higher likelihood of approval when biomarkers were used [4]. These studies are retrospective rather than predictive for any single program, but they make a clear case for why biomarker-guided drug development has become so central in oncology.
However, a biomarker is only helpful if it can be used prospectively. That is where many promising ideas stall. A novel marker may be biologically compelling but practically difficult because it requires a specialized assay, an impractical measurement, or a workflow that most diagnostic labs simply do not run. The FDA’s enrichment guidance puts it plainly: to use a predictive biomarker to select patients who are more likely to respond to treatment, that marker has to work reliably enough to tell responders from nonresponders in a clinical setting [5].
This is where proxy biomarkers become valuable. They do not replace the underlying biology; they provide a more practical way in. FHIT remains the informative signal, but IDH2 mutation offers a cleaner clinical handle because it is already part of routine diagnostic testing. That means easier screening, tighter eligibility, and robust patient selection across multiple sites. In other words, the scientific question stays the same, but the path to testing it becomes less complicated.
This logic also affects trial design and cost. The FDA frames predictive enrichment as a way to improve efficiency by focusing on patients most likely to respond, which means a smaller study can still detect a real treatment effect. The math is striking: if only 25% of patients carry the relevant marker and the rest are unlikely to benefit, an unenriched trial may need up to 16 times more patients than an enriched one [5]. In practice, that translates to fewer patients to screen, fewer sites, faster recruitment, and much cheaper path to a proof-of-concept outcome.
For us, this is what made this paper satisfying. It started with a mechanistic biomarker hypothesis around FHIT and became a much more practical question: how do you carry elegant biology into a real clinical trial? Not by stepping away from the science, but by building a bridge between biology and deployment. IDH2 is that bridge: not a replacement for FHIT, but a clinically actionable way to reach it. In oncology drug development, this is the kind of bridge that often separates an interesting finding from a strategy that can be actually tested.
References
- Grassi F, Singh M, Moussaud S, Vazquez Rodruguez G, Ali Z, et al. DCPS is a synthetic lethal therapeutic target in acute myeloid leukemia expressing low levels of FHIT. Leukemia39, 2021–2025 (2025). DOI: 10.1038/s41375-025-02661-z
- Grassi F, Bast L, Singh M, Tobiasson M, Walfridsson J, de Milito A, et al. Integrated FHIT and IDH2 biomarker profiling predicts lethal sensitivity to DCPS inhibition in Acute Myeloid Leukemia and Myelodysplastic syndrome. Discover Oncology. 2026. DOI: 10.1007/s12672-026-04880-x
- Wong CH, Siah KW, Lo AW. Estimation of clinical trial success rates and related parameters. Biostatistics. 2019;20(2):273–286. DOI: 10.1093/biostatistics/kxx069
- Parker JL, et al. Does biomarker use in oncology improve clinical trial failure risk? A large-scale analysis. Cancer Medicine. 2021;10(6):1955–1963. DOI: 10.1002/cam4.3732
- U.S. Food and Drug Administration. Enrichment Strategies for Clinical Trials to Support Determination of Effectiveness of Human Drugs and Biological Products. Guidance for Industry. March 2019. Official FDA guidance (PDF)
Follow the Topic
-
Discover Oncology
This is a fully open access general oncology journal that aims to provide a unified forum for researchers and clinicians. The journal spans from basic and translational science, to preclinical, clinical, and epidemiology, and welcomes content that interfaces at all levels of cancer research.
Your space to connect: The Myeloid cell function and dysfunction Hub
A new Communities’ space to connect, collaborate, and explore research on Clinical Medicine and Cell Biology!
Continue reading announcementRelated Collections
With Collections, you can get published faster and increase your visibility.
Immune Checkpoint Inhibitors in Cancer: Mechanisms, Clinical Applications, and Future Directions
Immune checkpoint inhibitors (ICIs) have revolutionized cancer treatment by harnessing the body's immune system to target and eliminate tumor cells. These inhibitors, which include antibodies targeting CTLA-4, PD-1, and PD-L1, have shown remarkable efficacy in various cancer types, leading to durable responses and prolonged survival in patients who had limited treatment options. The success of ICIs in oncology has sparked a surge in research focused on understanding their mechanisms of action, identifying biomarkers for response, managing immune-related adverse events, and expanding their application to a broader range of malignancies.
However, despite the transformative impact of ICIs, many challenges remain. The majority of patients do not achieve complete responses, resistance to therapy is common, and the long-term effects of immune modulation are not fully understood. Ongoing research is crucial to optimize the use of ICIs, overcome resistance, and develop combination therapies that can enhance their efficacy.
This Collection aims to compile cutting-edge research and reviews on immune checkpoint inhibitors in cancer, encompassing a wide range of topics that reflect the current state and future directions of this rapidly evolving field. The issue will include but is not limited to the following themes:
Mechanisms of Action: Exploration of how ICIs modulate immune responses against cancer, including molecular and cellular mechanisms.
Clinical Applications: Studies on the efficacy and safety of ICIs in various cancer types, including ongoing clinical trials and real-world evidence.
Biomarkers of Response and Resistance: Research on predictive biomarkers for ICI efficacy, including genetic, proteomic, and immunological factors.
Combination Therapies: Investigations into the synergistic effects of ICIs with other treatment modalities, such as chemotherapy, radiation, targeted therapy, and other immunotherapies.
Management of Immune-Related Adverse Events (irAEs): Studies focusing on the identification, prevention, and management of irAEs associated with ICIs.
Emerging Targets and Future Directions: Reviews and original research on novel immune checkpoint targets beyond PD-1/PD-L1 and CTLA-4, and innovative therapeutic strategies in development.
Ethical, legal, and regulatory challenges arising from the ever-growing implementation of highly innovative techniques, and how to best meet such challenges in order to ensure equitable, patient-centered access to the most effective personalized/precision medicine-based diagnostics/therapeutics approaches as they become available.
We believe that this Collection will not only provide valuable insights into the current challenges and opportunities associated with ICIs but also serve as a comprehensive resource for researchers and healthcare professionals dedicated to improving cancer outcomes.
Keywords: immune checkpoint inhibitors, cancer treatment, biomarkers, immune-related adverse events, immune checkpoint targets
Publishing Model: Open Access
Deadline: Jun 30, 2026
Biomarkers and Therapeutic Targets for Central Nervous System Tumors
Keywords: CNS tumors, biomarkers, therapeutic targets, neuro-oncology, immunotherapy, tumor microenvironment, precision medicine, targeted therapy, drug resistance.
Publishing Model: Open Access
Deadline: Jun 30, 2026
Please sign in or register for FREE
If you are a registered user on Research Communities by Springer Nature, please sign in