Tagged: blood cancer

Oncotarget

Genetic Study Identifies Potential Diagnostic Marker for Rare Blood Cancer BPDCN

October 22, 2025

“Blastic plasmacytoid dendritic cell neoplasm (BPDCN) is a rare hematological malignancy with poorly characterized molecular features.”

Blastic plasmacytoid dendritic cell neoplasm (BPDCN) is a rare blood cancer that primarily affects older adults. One of the key challenges in diagnosing and treating BPDCN is that it closely resembles other forms of leukemia in both appearance and behavior. This overlap often leads to delays or uncertainty in diagnosis, especially since currently there is no single, reliable marker that clearly distinguishes BPDCN from related diseases.

To address this issue, researchers from the City of Hope Comprehensive Cancer Center investigated the genetic profile of BPDCN.  Their study, titled “Genetic characteristics of blastic plasmacytoid dendritic cell neoplasm: A single institution experience,” was published in Oncotarget (Volume 16).

Understanding BPDCN: A Rare and Aggressive Blood Cancer

BPDCN is an aggressive cancer that commonly affects the skin, bone marrow, and lymph nodes. Diagnosing it remains difficult due to its overlap with other blood cancers. Although targeted therapies and stem cell transplantation have led to some progress, overall outcomes remain poor. Most patients survive only one to two years after diagnosis, emphasizing the need for earlier detection and more effective treatment options.

The Study: Genetic Sequencing in BPDCN Patients

Led by first author Fei Fei and corresponding author Michelle Afkhami, from the City of Hope Comprehensive Cancer Center, researchers performed targeted DNA and RNA next-generation sequencing (NGS) on samples from 21 patients with BPDCN—nineteen male and two female.

Their goal was to better understand the genetic mutations associated with this disease and evaluate whether any of these changes could be used to improve diagnosis or predict disease progression.

The Results: Genetic Alterations in BPDCN

The study revealed frequent mutations in genes such as TET2 (57%) and ASXL1 (33%), both of which are involved in regulating DNA activity. These mutations were often associated with shorter survival, particularly when multiple mutations occurred in a single patient. Other mutated genes were NRAS (29%), SRSF2 (14%), ZRSR2 (14%), and KMT2D (14%).

Another important finding was the gene CCDC50, which showed significantly higher expression in BPDCN compared to related cancers like acute myeloid leukemia (AML) and chronic monomyelocytic leukemia (CMML). In patients who responded well to treatment, CCDC50 levels declined, suggesting its potential usefulness in monitoring treatment response.

The Impact: CCDC50 as a Diagnostic Marker

The study highlights CCDC50 as a potential marker for BPDCN. Its high expression in this cancer—and not in related blood malignancies—suggests it could support both diagnosis and monitoring of treatment response. If validated in larger studies, it could become a valuable tool for clinicians seeking earlier and more accurate diagnoses.

Additionally, the association between mutations in genes like TET2 and ASXL1 and patient outcomes may help guide risk assessment and inform more personalized treatment decisions.

Future Perspectives and Conclusion

While these findings offer important insights, the study was based on a relatively small patient group. Further research is needed to confirm the role of CCDC50 and increase the understanding of how genetic mutations affect BPDCN progression. Nonetheless, this study represents a step toward more precise diagnostic tools and tailored treatments for a disease that remains challenging to manage.

Click here to read the full research paper published by Oncotarget.

_______

Oncotarget is an open-access, peer-reviewed journal that has published primarily oncology-focused research papers since 2010. These papers are available to readers (at no cost and free of subscription barriers) in a continuous publishing format at Oncotarget.com

Oncotarget is indexed and archived by PubMed/Medline, PubMed Central, Scopus, EMBASE, META (Chan Zuckerberg Initiative) (2018-2022), and Dimensions (Digital Science).

Click here to subscribe to Oncotarget publication updates.

For media inquiries, please contact media@impactjournals.com.

Oncotarget

Targeting Fatty Acid Binding Proteins in Multiple Myeloma

September 21, 2023

In a recent editorial, researchers discuss targeting fatty acid binding proteins to fight multiple myeloma.

Targeting Fatty Acid Binding Proteins in Multiple Myeloma

Multiple myeloma (MM) is a type of blood cancer that affects plasma cells, which are responsible for producing antibodies. MM is characterized by the accumulation of abnormal plasma cells in the bone marrow, leading to bone damage, kidney failure, anemia, and increased susceptibility to infections. MM is a heterogeneous disease with different subtypes and genetic mutations that affect the prognosis and response to treatment. Therefore, there is a need for new biomarkers and therapeutic targets that can improve the outcomes of MM patients.

One of the potential targets that has recently emerged is the fatty acid binding protein (FABP) family. FABPs are proteins that bind and transport fatty acids, which are essential for energy production, cell signaling and membrane synthesis. FABPs are expressed in various tissues and organs, and have different roles depending on their location and type. There are nine members of the FABP family, but FABP5 seems to be the most relevant for MM.

In a recent editorial paper, researchers Heather Fairfield and Michaela R. Reagan from Maine Health Institute for Research, University of Maine and Tufts University School of Medicine summarized previous findings from their 2023 study and the current evidence on the role of FABPs in MM. On June 19, 2023, their editorial was published in Oncotarget, entitled, “The hope for targeting fatty acid binding proteins in multiple myeloma.”

“The FABPs hold promise as new therapeutic targets in multiple myeloma (MM), as described by our laboratory, and supported by in silico analyses [2] and other data [3, 4].”

Editorial Summary

The authors found that FABP5 expression is higher in MM cells than in normal plasma cells, and that high FABP5 levels are associated with worse survival and progression in MM patients. They also show that FABP inhibitors can reduce MM cell growth, survival and proliferation by affecting various pathways and processes, such as:

  • The unfolded protein response and ER stress response, which are activated by the high protein production in MM cells
  • The reactive oxygen species (ROS) generation, which can cause oxidative damage and apoptosis
  • The MYC oncogene expression and activity, which is essential for MM cell survival and proliferation
  • The mitochondrial function and metabolism, which are altered in MM cells to favor fatty acid oxidation
  • The DNA methylation patterns, which can affect gene expression and epigenetic regulation
  • The immune cell infiltration and cytokine production in the bone marrow microenvironment, which can modulate the tumor-host interactions

The researchers also highlighted findings from other studies that support the importance of FABPs in MM. For example, Jia et al. found that FABP5 expression correlates with immune cell changes in the MM microenvironment. Liang et al. found that FABP4 expression is increased in MM patients and that FABP4 knockout or inhibition can improve survival and reduce tumor burden in mice models.

“We reported studies showing either decreased tumor burden or no effect of FABP inhibition in vivo, and thus further optimization of in vivo targeting of FABPs, FABP inhibitor design, or overcoming FABP inhibitor resistance in the bone marrow is still required before translation to the clinic can materialize [1].”

Conclusion

The authors conclude that FABPs are promising prognostic markers and therapeutic targets in MM, and that further research is needed to elucidate their mechanisms of action and to develop specific inhibitors. They also suggest that targeting both tumor cell-derived and microenvironment-derived FABPs may be more effective than targeting either one alone.

This editorial provides a concise overview of the current state of knowledge on FABPs in MM, and highlights the potential benefits of targeting them for MM treatment. It also raises some interesting questions for future research, such as:

  • How do FABPs interact with other metabolic pathways and regulators in MM cells?
  • How do FABPs affect the bone remodeling process and osteolytic lesions in MM?
  • How do FABPs influence the drug resistance and relapse in MM?
  • How do different types of FABPs cooperate or compete with each other in MM?
  • How can FABP inhibitors be combined with other therapies for optimal efficacy and safety?

“Still, we are hopeful that by targeting FABPs, or following the science to other related pathways, it will be possible to revolutionize the therapy regimes currently used for MM patients.”

Click here to read the full editorial in Oncotarget.

Oncotarget is an open-access, peer-reviewed journal that has published primarily oncology-focused research papers since 2010. These papers are available to readers (at no cost and free of subscription barriers) in a continuous publishing format at Oncotarget.com. Oncotarget is indexed/archived on MEDLINE / PMC / PubMed.

Click here to subscribe to Oncotarget publication updates.

For media inquiries, please contact media@impactjournals.com.