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Main Author: Savani, Milan
Format: Recurso digital
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Published: Zenodo 2026
Online Access:https://doi.org/10.5281/zenodo.18736712
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author Savani, Milan
author_facet Savani, Milan
contents <p>Stable isotope tracing assays track few metabolites, yet cells use many nutrients to sustain nitrogen metabolism. Here, we create a platform for tracing 30 nitrogen isotope-labeled metabolites in parallel to enable a system-level understanding of cellular nitrogen metabolism. This platform reveals that while primitive cells engage both de novo and salvage pyrimidine synthesis pathways, differentiated cells nearly exclusively salvage uridine. This link between cell state and pyrimidine synthesis pathway preference persists in murine and human tissues. Mechanistically, we find that S1900 phosphorylation of CAD, the first enzyme of the de novo pathway, is induced by uridine deprivation in differentiated cells and constitutively enriched in primitive cells. Mimicking CAD S1900 phosphorylation in differentiated cells constitutively activates de novo pyrimidine synthesis, while blocking this modification impairs the cellular response to uridine starvation. Collectively, we establish a method for nitrogen metabolism profiling and define a mechanism of cell state-specific pyrimidine synthesis pathway choice.</p>
format Recurso digital
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institution Zenodo
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publishDate 2026
publisher Zenodo
record_format zenodo
spellingShingle Nitrogen metabolism profiling reveals cell state-specific pyrimidine synthesis pathway choice
Savani, Milan
<p>Stable isotope tracing assays track few metabolites, yet cells use many nutrients to sustain nitrogen metabolism. Here, we create a platform for tracing 30 nitrogen isotope-labeled metabolites in parallel to enable a system-level understanding of cellular nitrogen metabolism. This platform reveals that while primitive cells engage both de novo and salvage pyrimidine synthesis pathways, differentiated cells nearly exclusively salvage uridine. This link between cell state and pyrimidine synthesis pathway preference persists in murine and human tissues. Mechanistically, we find that S1900 phosphorylation of CAD, the first enzyme of the de novo pathway, is induced by uridine deprivation in differentiated cells and constitutively enriched in primitive cells. Mimicking CAD S1900 phosphorylation in differentiated cells constitutively activates de novo pyrimidine synthesis, while blocking this modification impairs the cellular response to uridine starvation. Collectively, we establish a method for nitrogen metabolism profiling and define a mechanism of cell state-specific pyrimidine synthesis pathway choice.</p>
title Nitrogen metabolism profiling reveals cell state-specific pyrimidine synthesis pathway choice
url https://doi.org/10.5281/zenodo.18736712