A ground-breaking study by researchers from the CSI at the NUS has revealed crucial insights into the role of the histone methyltransferase NSD2 and its epigenetic target PKCα in causing t(4;14) translocated multiple myeloma(Representational Image: Unsplash) 
Medicine

New Insights To Enhance Treatment and Diagnosis Of Blood Cancer

NUS scientists seek to exploit vulnerabilities in cancer development pathways to revolutionize treatment strategies for high-risk myeloma

MBT Desk

A ground-breaking study by researchers from the Cancer Science Institute of Singapore (CSI Singapore) at the National University of Singapore (NUS) has revealed crucial insights into the role of the histone methyltransferase NSD2 and its epigenetic target PKCα in causing t(4;14) translocated multiple myeloma (MM), a high-risk subtype of blood cancer, to be more aggressive and resistant to treatment.

The study was led by Professor Wee Joo Chng, Senior Principal Investigator at CSI Singapore, and Dr Phyllis Chong Shu Yun, Senior Research Fellow at CSI Singapore. The research team discovered that NSD2 triggers elevated glycolysis through the activation of PKCα, leading to the production of excessive lactate that fuels malignancy and undermines response to immunomodulatory drugs. The findings present potential targets to improve the treatment of myeloma.

Targets for therapeutic intervention

Myeloma is the second most common blood cancer, and t(4;14) myeloma comprises 15 to 20 per cent of MM cases. Compared to other types of myeloma, patients with t(4;14) myeloma have a poorer prognosis with shorter overall survival. Unfortunately, the key deregulated gene in t(4;14) myeloma is not targetable with drugs.

Myeloma is the second most common blood cancer (Wikimedia Commons)

“Our study aims to overcome the limitations of targeting the key deregulated gene in t(4;14) myeloma. It sheds light on the metabolic reprogramming of MM in response to the oxygen- and nutrient-deprived bone marrow microenvironment. By exploring the epigenome and metabolome of NSD2, we sought alternative vulnerabilities that could revolutionise treatment strategies,” said Prof Chng, lead author of the study.

Erythrocyte development from bone marrow (Wikimedia commons)

The unique connection between NSD2 and cellular metabolism, mediated by histone methylation, offers new horizons in the battle against high-risk MM subtypes. The study’s impact is multifaceted, potentially influencing the development of novel medicines and non-invasive diagnostic tests. For patients with t(4;14) myeloma, targeted metabolic interventions could bring promising therapeutic options, whether through dietary modifications or tailored pharmacological approaches. Furthermore, the discovery that lactate levels could serve as predictive biomarkers for drug response highlights the transformative potential of metabolite signatures in personalized medicine.

Striving towards tailored interventions and personalised care

This study, which was published in Cancer Research, American Association for Cancer Research on 18 July 2023, marks a significant stride in unravelling the complexities of MM and holds promise to improving treatment outcomes for patients with high-risk subtypes.

Looking ahead, Prof. Chng and his team plan to leverage the knowledge gained from this study to design therapeutic interventions for t(4;14) myeloma. The success of their metabolic characterization of t(4;14) myeloma also paves the way for the team to extend their metabolomic framework to profile other genetically high-risk MM subtypes such as t(14;16) or with 1q21 amplifications, presenting a path towards tailored interventions and personalized care. (RN/Newswise)

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