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SLC15A3-mediated dipeptide metabolism confers antimetabolite resistance in lymphoma via mTORC1 activation
Haojun Yang, Vincenzo Andrea Zingaro, Kevin Boardman, Ashish Noronha, Ekin Guney, Lingru Xue, Saishma Hoigebazar, Isabelle Liu, Sohit Miglani, Siyu Chen, Hieu Vu, Kwun Wah Wen, Hao G. Nguyen, Hani Goodarzi, Ralph J. DeBerardinis, Davide Ruggero
Haojun Yang, Vincenzo Andrea Zingaro, Kevin Boardman, Ashish Noronha, Ekin Guney, Lingru Xue, Saishma Hoigebazar, Isabelle Liu, Sohit Miglani, Siyu Chen, Hieu Vu, Kwun Wah Wen, Hao G. Nguyen, Hani Goodarzi, Ralph J. DeBerardinis, Davide Ruggero
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Research Article Hematology Metabolism Oncology

SLC15A3-mediated dipeptide metabolism confers antimetabolite resistance in lymphoma via mTORC1 activation

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Abstract

Antimetabolites, chemotherapy targeting nucleotide biosynthesis, are among the oldest and most widely used cancer treatments, yet resistance remains a daunting barrier, especially in the fight against B cell lymphomas. However, the underlying mechanisms of this resistance have long remained elusive. Using an innovative, integrated omics approach, we unexpectedly identified that the accumulation of dipeptides and upregulation of the dipeptide transporter SLC15A3 underlie resistance to nucleotide deficiency in a Myc-driven large B cell lymphoma mouse model. A similar mechanism occurred after long treatment of human B cell lymphoma cells with the chemotherapeutic purine synthesis inhibitor 6-mercaptopurine (6MP). Mechanistically, we demonstrated that dipeptides containing essential amino acids activated the growth and survival mTOR complex 1 (mTORC1) signaling pathway. Notably, SLC15A3 specifically interacted with mTOR on the lysosome, boosting mTORC1 activity selectively in resistant lymphoma cells but not in parental cancer cells. Silencing SLC15A3 diminished mTORC1 activity and restored resistant lymphoma sensitivity to 6MP. Strikingly, resistant lymphomas, but not primary tumors, exhibited heightened sensitivity to the clinical mTOR inhibitor, rapamycin, in culture and in vivo. We extended these findings in human lymphoma biopsies, which revealed increased SLC15A3 expression following antimetabolite therapy. Together, our study uncovered a metabolic adaptation that fuels cancer resistance to nucleotide deficiency and positions the mTORC1 inhibitor, rapamycin, as a potential therapeutic strategy for transforming the management of chemotherapy-resistant lymphomas.

Authors

Haojun Yang, Vincenzo Andrea Zingaro, Kevin Boardman, Ashish Noronha, Ekin Guney, Lingru Xue, Saishma Hoigebazar, Isabelle Liu, Sohit Miglani, Siyu Chen, Hieu Vu, Kwun Wah Wen, Hao G. Nguyen, Hani Goodarzi, Ralph J. DeBerardinis, Davide Ruggero

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Figure 2

6MP-resistant human lymphomas upregulate SLC15A3 and dipeptide uptake.

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6MP-resistant human lymphomas upregulate SLC15A3 and dipeptide uptake.
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(A) Schematic of the de novo purine biosynthesis pathway starting from ribose-5-phosphate. (B) Relative cell survival of parental Ramos cells and 6MP-resistant (6MPR) Ramos cells treated with varying concentrations of 6MP for 2 days. (C) Relative mRNA expression levels of SLC15A3 and SLC15A4 in parental and 6MPR Ramos cells. (D) Immunoblot analysis of SLC15A3 protein levels in parental and 6MPR Ramos cells. β-Actin serves as the loading control. (E) Quantification of dipeptide-AMCA (7-amino-4-methylcoumarin-3-acetic acid, a fluorescent reference) levels in cell lysates from parental or 6MPR Ramos cells treated with increasing concentrations of dipeptide-AMCA. (F) Relative dipeptide-AMCA in parental and 6MPR Ramos cells or 6MPR with SLC15A3 shRNA in basal condition. (G) Cell viability of parental and 6MPR Ramos cells treated with varying concentrations of Gly-Leu or Gly-Sar in amino acid–free HBSS medium. (H) Cell viability of parental and 6MPR Ramos cells treated with varying concentrations of 1 mM different dipeptides in amino acid–free HBSS medium. (I) Cell viability of parental and 6MPR Ramos cells treated with 1 mM Gly-Leu or histidine in amino acid–free HBSS medium. Individual data and mean ± SEM were presented in B, C, and E–I, and E–I were analyzed using 2-way ANOVA; *P < 0.05, **P < 0.01; ***P < 0.001; ****P < 0.0001.

Copyright © 2026 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)

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