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Kinases are enzymes that catalyze the addition of a phosphate group (PO43−) to substrates, usually proteins. The phosphate generally comes from adenosine triphosphate (ATP). Kinases and phosphatases, which remove phosphate groups, are involved in nearly all signal transduction processes, often with cascades of phosphorylation events.
Ferroptosis, a cell death mechanism induced by lipid peroxidation, is pivotal in tumor suppression. A recent study shows that tumor repopulating cells evade ferroptosis and develop resistance to therapy via subverting a lipid metabolism enzyme.
Understanding the role of pyrophosphorylation requires specific analytical strategies to discriminate it from protein phosphorylation. A custom workflow reveals that nucleolar protein pyrophosphorylation in human cells regulates the transcription of ribosomal DNA.
Reprogramming intercellular mechanotransduction and signaling pathways is still challenging. A recent advance uses a plug-and-play DNA nanodevice to allow non-mechanosensitive receptor tyrosine kinase (RTK) to transmit force-induced cellular signals.
Phosphorylation of ACSL4 by mitochondria-located metabolic kinase PCK2 is critical to regulating ferroptosis-associated phospholipid remodeling in tumor-repopulating cells that are resistant to chemotherapy and radiotherapy.
An atlas of the substrate specificities for the human tyrosine kinome reveals diversity of motif specificities and enables identification of kinase–substrate relationships and kinase regulation in phosphoproteomics experiments.
In this work, the authors unveil a mechanism where the Citron homology domain regulates HPK1’s kinase domain, shedding light on the relationship between HPK1’s structure and function. This enhances our understanding of HPK1, an intracellular target for cancer immunotherapy and provides a direction for immuno-oncology drug discovery.
A tailored proteomics workflow to identify endogenous protein pyrophosphorylation in human cells was developed, revealing the dependence of the modification on inositol pyrophosphates and a putative function in rDNA transcription.
Mitochondrial fission, performed by Drp1, is carefully regulated, particularly in neurons. Here, the authors examine Drosophila Cdk8/CDK19 function in mitochondrial fission and uncover a role phosphorylating Drp1 in the cytoplasm and show overexpression suppresses a Parkinson’s disease model.
Ferroptosis, a cell death mechanism induced by lipid peroxidation, is pivotal in tumor suppression. A recent study shows that tumor repopulating cells evade ferroptosis and develop resistance to therapy via subverting a lipid metabolism enzyme.
Understanding the role of pyrophosphorylation requires specific analytical strategies to discriminate it from protein phosphorylation. A custom workflow reveals that nucleolar protein pyrophosphorylation in human cells regulates the transcription of ribosomal DNA.
Reprogramming intercellular mechanotransduction and signaling pathways is still challenging. A recent advance uses a plug-and-play DNA nanodevice to allow non-mechanosensitive receptor tyrosine kinase (RTK) to transmit force-induced cellular signals.
Cells use various metabolic pathways to synthesize the building blocks for growth and proliferation. To ensure balanced growth, these biosynthetic processes must be tightly coordinated. We describe a molecular machinery that senses the cellular capacity to make lipids to regulate other biosynthetic processes — such as protein synthesis — accordingly.