Your search keyword '"Messenger RNA -- Health aspects -- Physiological aspects -- Genetic aspects"' showing total 1 results

1. Hotspot SF3B1 mutations induce metabolic reprogramming and vulnerability to serine deprivation

Author

Dalton, W. Brian, Helmenstine, Eric, Walsh, Noel, Gondek, Lukasz P., Kelkar, Dhanashree S., Read, Abigail, Natrajan, Rachael, Christenson, Eric S., Roman, Barbara, Das, Samarjit, Zhao, Liang, Leone, Robert D., Shinn, Daniel, Groginski, Taylor, Madugundu, Anil K., Patil, Arun, Zabransky, Daniel J., Medford, Arielle, Lee, Justin, Cole, Alex J., Rosen, Marc, Thakar, Maya, Ambinder, Alexander, Donaldson, Joshua, DeZern, Amy E., Cravero, Karen, Chu, David, Madero-Marroquin, Rafael, Pandey, Akhilesh, Hurley, Paula J., Lauring, Josh, and Park, Ben Ho

Subjects

Thermo Fisher Scientific Inc., Metabolites -- Health aspects -- Physiological aspects -- Genetic aspects, Genes -- Health aspects -- Physiological aspects -- Genetic aspects, Cells (Biology) -- Health aspects -- Physiological aspects -- Genetic aspects, Enzymes -- Health aspects -- Physiological aspects -- Genetic aspects, Serine -- Health aspects -- Physiological aspects -- Genetic aspects, Messenger RNA -- Health aspects -- Physiological aspects -- Genetic aspects, Glycine -- Health aspects -- Physiological aspects, Scientific equipment industry -- Health aspects -- Physiological aspects -- Genetic aspects, Amino acids, Cancer, RNA, Health care industry, Gene Ontology. Gene Ontology Consortium, Johns Hopkins University. School of Medicine

Abstract

Cancer-associated mutations in the spliceosome gene SF3B1 create a neomorphic protein that produces aberrant mRNA splicing in hundreds of genes, but the ensuing biologic and therapeutic consequences of this missplicing are not well understood. Here we have provided evidence that aberrant splicing by mutant SF3B1 altered the transcriptome, proteome, and metabolome of human cells, leading to missplicing-associated downregulation of metabolic genes, decreased mitochondrial respiration, and suppression of the serine synthesis pathway. We also found that mutant SF3B1 induces vulnerability to deprivation of the nonessential amino acid serine, which was mediated by missplicing-associated downregulation of the serine synthesis pathway enzyme PHGDH. This vulnerability was manifest both in vitro and in vivo, as dietary restriction of serine and glycine in mice was able to inhibit the growth of [SF3B1.sup.MUT] xenografts. These findings describe a role for SF3B1 mutations in altered energy metabolism, and they offer a new therapeutic strategy against [SF3B1.sup.MUT] cancers., Introduction Since their identification in 2011, mutations in spliceosome genes have been found in numerous human malignancies (1). Among the most broadly implicated genes is SF3B1, recurrently mutated in myelodysplastic [...]

Published

2019