What question did this study set out to answer?

The research aims to understand how changes in mitochondrial copy number and lipid metabolism contribute to busulfan resistance in acute myeloid leukemia (AML) cells.

February 26, 2026Open Access

Busulfan resistance in AML is associated with changes in mitochondrial copy number and lipid metabolism

Puntos clave

The research aims to understand how changes in mitochondrial copy number and lipid metabolism contribute to busulfan resistance in acute myeloid leukemia (AML) cells.
Investigated MOLM13 myeloid leukemia cells subjected to multiple rounds of busulfan treatment to develop resistant cell lines.
Assessed mitochondrial DNA copy number using RT-qPCR targeting the MTND1 gene.
Utilized bulk RNA-sequencing to analyze global gene expression before and after resistance acquisition.
Determined busulfan 50% inhibitory concentration (BU-IC50) relative to mtDNA-CN in MOLM13 and lymphoblastoid cells.
Conducted additional experiments to examine resistance dynamics after cytarabine treatment.
MOLM13 cells exhibited a progressive increase in resistance to busulfan from 1.86-fold to 2.87-fold after three and five cycles of treatment, respectively.
An increase in mtDNA-CN was observed in BU-resistant cells after treatment cycles, specifically a 1.42-fold rise after 3 and 5 cycles of busulfan.
Cytarabine treatment led to an increase in resistance to both cytarabine and busulfan, with a 1.90-fold and 1.60-fold increase, respectively.
Transcriptomic analysis indicated dysregulation in pathways related to cholesterol and fatty acid transport and synthesis following busulfan resistance.

Resumen

Busulfan (BU) is DNA-damaging and also a reactive oxygen species (ROS) generating agent. Both mitochondrial DNA copy number (mtDNA-CN) and ROS levels have been associated with the sensitivity of solid tumor cells to ROS-generating cisplatin. However, the changes of mtDNA-CN during the development of resistance to other ROS-generating agents or chemotherapeutics remain unclear. In this study, we investigated how the resistance of acute myeloid leukemia (AML) cell lines to the BU or the DNA synthesis inhibitor cytarabine (Cyt) is associated with alterations in mtDNA-CN and global gene expression. To follow BU resistance acquisition, MOLM13 myeloid leukemia cells, which are sensitive to BU, were subjected to five consecutive BU treatment rounds, generating BU-resistant cells (5TBU). Both parental control cells and the 5TBU cells underwent five consecutive Cyt treatments to generate cells resistant to both Bu and Cyt. We assessed mtDNA-CN using RT-qPCR targeting the mitochondrial gene MTND1 and investigated global gene expression profiles using bulk RNA-sequencing before and after resistance acquisition. We estimated the BU 50% inhibitory concentration (BU-IC50) relative to mtDNA-CN both in MOLM13-derived cells and 28 lymphoblastoid cells (LCLs). MOLM13 cells showed a progressive increase in resistance from 1.86-fold (p 50 also showed increased mtDNA-CNs. Transcriptomic analysis revealed that BU resistance was associated with dysregulation in cholesterol and fatty acid transport and synthesis pathways. Expression profiling of the BU-resistant AML cell line revealed significant changes in cholesterol transport and fatty acid biosynthesis, along with alterations in mtDNA-CNs. These changes could represent key adaptations resulting from long-term exposure to the electrophilic agent BU. The current findings thus provide new insights into the molecular mechanisms underlying BU resistance and suggest potential targets for preventing or overcoming this resistance in future therapeutic strategies.

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