The misfolding and accumulation of tau protein into intracellular aggregates known as neurofibrillary tangles is a pathological hallmark of neurodegenerative diseases such as Alzheimer’s disease. However, while tau propagation is a known marker for disease progression, exactly how tau propagates from one cell to another and what mechanisms govern this spread are still unclear. Here, we report that cellular internalization of tau is regulated by quaternary structure and have developed a cellular assay to screen for genetic modulators of tau uptake. Using CRISPRi technology we have tested 3200 genes for their ability to regulate tau entry and identified enzymes in the heparan sulfate proteoglycan biosynthetic pathway as key regulators. We show that 6-O-sulfation is critical for tau-heparan sulfate interactions and that this modification regulates uptake in human central nervous system cell lines, iPS-derived neurons, and mouse brain slice culture. Together, these results suggest novel strategies to halt tau transmission.
Lysine acetyltransferases (KATs)
play a critical role in the regulation
of gene expression, metabolism, and other key cellular functions.
One shortcoming of traditional KAT assays is their inability to study
KAT activity in complex settings, a limitation that hinders efforts
at KAT discovery, characterization, and inhibitor development. To
address this challenge, here we describe a suite of cofactor-based
affinity probes capable of profiling KAT activity in biological contexts.
Conversion of KAT bisubstrate inhibitors to clickable photoaffinity
probes enables the selective covalent labeling of three phylogenetically
distinct families of KAT enzymes. Cofactor-based affinity probes report
on KAT activity in cell lysates, where KATs exist as multiprotein
complexes. Chemical affinity purification and unbiased LC–MS/MS
profiling highlights an expanded landscape of orphan lysine acetyltransferases
present in the human genome and provides insight into the global selectivity
and sensitivity of CoA-based proteomic probes that will guide future
applications. Chemoproteomic profiling provides a powerful method
to study the molecular interactions of KATs in native contexts and
will aid investigations into the role of KATs in cell state and disease.
SUMMARY
The finding that chromatin modifications are sensitive to changes in cellular cofactor levels potentially links altered tumor cell metabolism and gene expression. However, the specific enzymes and metabolites that connect these two processes remain obscure. Characterizing these metabolic-epigenetic axes is critical to understanding how metabolism supports signaling in cancer, and developing therapeutic strategies to disrupt this process. Here, we describe a chemical approach to define the metabolic regulation of lysine acetyltransferase (KAT) enzymes. Using a novel chemoproteomic probe, we identify a previously unreported interaction between fatty acyl-CoAs and KAT enzymes. Further analysis reveals that palmitoyl-CoA is a potent inhibitor of KAT activity and that fatty acyl-CoA precursors reduce cellular acetylation levels. These studies implicate fatty acyl-CoAs as endogenous regulators of histone acetylation, and suggest novel strategies for the investigation and metabolic modulation of epigenetic signaling.
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