Vincent Rondeau, Jacob M. Berman, Tianyi Ling, Cristiana O’Brien, Rachel Culp-Hill, Julie A. Reisz, Mark Wunderlich, Yun Chueh, Karina E. Jiménez-Camacho, Christina Sexton, Katharine M. Carter, Cody Stillwell, Jonathan St-Germain, Duhan Yendi, Aarushi Gupta, Mary Shi, Aleksandra Bourdine, Vikram R. Paralkar, Soheil Jahangiri, Kristin J. Hope, Anastasia N. Tikhonova, Andrea Arruda, Mark D. Minden, Brian Raught, Angelo D’Alessandro, Courtney L. Jones
{"title":"在患者衍生小鼠模型中,精胺代谢通过 KAT7 的表达调节白血病干细胞和祖细胞的功能","authors":"Vincent Rondeau, Jacob M. Berman, Tianyi Ling, Cristiana O’Brien, Rachel Culp-Hill, Julie A. Reisz, Mark Wunderlich, Yun Chueh, Karina E. Jiménez-Camacho, Christina Sexton, Katharine M. Carter, Cody Stillwell, Jonathan St-Germain, Duhan Yendi, Aarushi Gupta, Mary Shi, Aleksandra Bourdine, Vikram R. Paralkar, Soheil Jahangiri, Kristin J. Hope, Anastasia N. Tikhonova, Andrea Arruda, Mark D. Minden, Brian Raught, Angelo D’Alessandro, Courtney L. Jones","doi":"10.1126/scitranslmed.adn1285","DOIUrl":null,"url":null,"abstract":"<div >Acute myeloid leukemia (AML) is a devastating disease initiated and maintained by a rare subset of cells called leukemia stem cells (LSCs). LSCs are responsible for driving disease relapse, making the development of new therapeutic strategies to target LSCs urgently needed. The use of mass spectrometry–based metabolomics profiling has enabled the discovery of unique and targetable metabolic properties in LSCs. However, we do not have a comprehensive understanding of metabolite differences between LSCs and their normal counterparts, hematopoietic stem and progenitor cells (HSPCs). In this study, we used an unbiased mass spectrometry–based metabolomics analysis to define differences in metabolites between primary human LSCs and HSPCs, which revealed that LSCs have a distinct metabolome. Spermidine was the most enriched metabolite in LSCs compared with HSPCs. Pharmacological reduction of spermidine concentrations decreased LSC function but spared normal HSPCs. Polyamine depletion also decreased leukemic burden in patient-derived xenografts. Mechanistically, spermidine depletion induced LSC myeloid differentiation by decreasing eIF5A-dependent protein synthesis, resulting in reduced expression of a select subset of proteins. KAT7, a histone acetyltransferase, was one of the top candidates identified to be down-regulated by spermidine depletion. Overexpression of KAT7 partially rescued polyamine depletion–induced decreased colony-forming ability, demonstrating that loss of KAT7 is an essential part of the mechanism by which spermidine depletion targets AML clonogenic potential. Together, we identified and mechanistically dissected a metabolic vulnerability of LSCs that has the potential to be rapidly translated into clinical trials to improve outcomes for patients with AML.</div>","PeriodicalId":21580,"journal":{"name":"Science Translational Medicine","volume":"16 766","pages":""},"PeriodicalIF":15.8000,"publicationDate":"2024-09-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Spermidine metabolism regulates leukemia stem and progenitor cell function through KAT7 expression in patient-derived mouse models\",\"authors\":\"Vincent Rondeau, Jacob M. Berman, Tianyi Ling, Cristiana O’Brien, Rachel Culp-Hill, Julie A. Reisz, Mark Wunderlich, Yun Chueh, Karina E. Jiménez-Camacho, Christina Sexton, Katharine M. Carter, Cody Stillwell, Jonathan St-Germain, Duhan Yendi, Aarushi Gupta, Mary Shi, Aleksandra Bourdine, Vikram R. Paralkar, Soheil Jahangiri, Kristin J. Hope, Anastasia N. Tikhonova, Andrea Arruda, Mark D. Minden, Brian Raught, Angelo D’Alessandro, Courtney L. Jones\",\"doi\":\"10.1126/scitranslmed.adn1285\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div >Acute myeloid leukemia (AML) is a devastating disease initiated and maintained by a rare subset of cells called leukemia stem cells (LSCs). LSCs are responsible for driving disease relapse, making the development of new therapeutic strategies to target LSCs urgently needed. The use of mass spectrometry–based metabolomics profiling has enabled the discovery of unique and targetable metabolic properties in LSCs. However, we do not have a comprehensive understanding of metabolite differences between LSCs and their normal counterparts, hematopoietic stem and progenitor cells (HSPCs). In this study, we used an unbiased mass spectrometry–based metabolomics analysis to define differences in metabolites between primary human LSCs and HSPCs, which revealed that LSCs have a distinct metabolome. Spermidine was the most enriched metabolite in LSCs compared with HSPCs. Pharmacological reduction of spermidine concentrations decreased LSC function but spared normal HSPCs. Polyamine depletion also decreased leukemic burden in patient-derived xenografts. Mechanistically, spermidine depletion induced LSC myeloid differentiation by decreasing eIF5A-dependent protein synthesis, resulting in reduced expression of a select subset of proteins. KAT7, a histone acetyltransferase, was one of the top candidates identified to be down-regulated by spermidine depletion. Overexpression of KAT7 partially rescued polyamine depletion–induced decreased colony-forming ability, demonstrating that loss of KAT7 is an essential part of the mechanism by which spermidine depletion targets AML clonogenic potential. 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Spermidine metabolism regulates leukemia stem and progenitor cell function through KAT7 expression in patient-derived mouse models
Acute myeloid leukemia (AML) is a devastating disease initiated and maintained by a rare subset of cells called leukemia stem cells (LSCs). LSCs are responsible for driving disease relapse, making the development of new therapeutic strategies to target LSCs urgently needed. The use of mass spectrometry–based metabolomics profiling has enabled the discovery of unique and targetable metabolic properties in LSCs. However, we do not have a comprehensive understanding of metabolite differences between LSCs and their normal counterparts, hematopoietic stem and progenitor cells (HSPCs). In this study, we used an unbiased mass spectrometry–based metabolomics analysis to define differences in metabolites between primary human LSCs and HSPCs, which revealed that LSCs have a distinct metabolome. Spermidine was the most enriched metabolite in LSCs compared with HSPCs. Pharmacological reduction of spermidine concentrations decreased LSC function but spared normal HSPCs. Polyamine depletion also decreased leukemic burden in patient-derived xenografts. Mechanistically, spermidine depletion induced LSC myeloid differentiation by decreasing eIF5A-dependent protein synthesis, resulting in reduced expression of a select subset of proteins. KAT7, a histone acetyltransferase, was one of the top candidates identified to be down-regulated by spermidine depletion. Overexpression of KAT7 partially rescued polyamine depletion–induced decreased colony-forming ability, demonstrating that loss of KAT7 is an essential part of the mechanism by which spermidine depletion targets AML clonogenic potential. Together, we identified and mechanistically dissected a metabolic vulnerability of LSCs that has the potential to be rapidly translated into clinical trials to improve outcomes for patients with AML.
期刊介绍:
Science Translational Medicine is an online journal that focuses on publishing research at the intersection of science, engineering, and medicine. The goal of the journal is to promote human health by providing a platform for researchers from various disciplines to communicate their latest advancements in biomedical, translational, and clinical research.
The journal aims to address the slow translation of scientific knowledge into effective treatments and health measures. It publishes articles that fill the knowledge gaps between preclinical research and medical applications, with a focus on accelerating the translation of knowledge into new ways of preventing, diagnosing, and treating human diseases.
The scope of Science Translational Medicine includes various areas such as cardiovascular disease, immunology/vaccines, metabolism/diabetes/obesity, neuroscience/neurology/psychiatry, cancer, infectious diseases, policy, behavior, bioengineering, chemical genomics/drug discovery, imaging, applied physical sciences, medical nanotechnology, drug delivery, biomarkers, gene therapy/regenerative medicine, toxicology and pharmacokinetics, data mining, cell culture, animal and human studies, medical informatics, and other interdisciplinary approaches to medicine.
The target audience of the journal includes researchers and management in academia, government, and the biotechnology and pharmaceutical industries. It is also relevant to physician scientists, regulators, policy makers, investors, business developers, and funding agencies.