Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0038187 (starvation)
 24,951 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Based on a functional categorization, proteins may be grouped into three types and sorted to either the proteasome or the macroautophagy pathway for degradation. The two pathways are mechanistically connected but their capacity seems different. Macroautophagy can degrade all forms of misfolded proteins whereas proteasomal degradation is likely limited to soluble ones. Unlike the bulk protein degradation that occurs during starvation, autophagic degradation of misfolded proteins can have a degree of specificity, determined by ubiquitin modification and the interactions of p62/SQSTM1 and HDAC6. Macroautophagy is initiated in response to endoplasmic reticulum (ER) stress caused by misfolded proteins, via the ER-activated autophagy (ERAA) pathway, which activates a partial unfolded protein response involving PERK and/or IRE1, and a calcium-mediated signaling cascade. ERAA serves the function of mitigating ER stress and suppressing cell death, which may be explored for controlling protein conformational diseases. Conversely, inhibition of ERAA may be explored for sensitizing resistant tumor cells to cytotoxic agents.
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PMID:Sorting, recognition and activation of the misfolded protein degradation pathways through macroautophagy and the proteasome. 1798 70

The ubiquitin-proteasome system (UPS) and autophagy are two major intracellular protein degradation pathways. The UPS mediates the removal of soluble abnormal proteins as well as the targeted degradation of most normal proteins that are no longer needed. Autophagy is generally responsible for bulky removal of defective organelles and for sequestering portions of cytoplasm for lysosomal degradation during starvation. Impaired or inadequate protein degradation in the heart is associated with and may be a major pathogenic factor for a wide variety of cardiac dysfunctions, while enhanced protein degradation is also implicated in the development of cardiac pathology. It was generally assumed that the UPS and autophagy serve distinct functions. Therefore, the functional roles of the UPS and autophagy in the hearts have been largely investigated separately. However, recent advances in understanding the shared mechanisms contributing to UPS alteration and the induction of autophagy have helped reveal the link and interplay between the two proteolytic systems in the heart. These links are exemplified by scenarios in which inadequate UPS proteolytic function leads to activation of autophagy, helping alleviate proteotoxic stress. It is becoming increasingly clear that a coordinated and complementary relationship between the two systems is critical to protect cells against stress. Several proteins including p62, NBR1, HDAC6, and co-chaperones appear to play an important role in harmonizing and mobilizing the consortium formed by the UPS and autophagy.
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PMID:Autophagy and the ubiquitin-proteasome system in cardiac dysfunction. 2022 23

Autophagy has been predominantly studied as a nonselective self-digestion process that recycles macromolecules and produces energy in response to starvation. However, autophagy independent of nutrient status has long been known to exist. Recent evidence suggests that this form of autophagy enforces intracellular quality control by selectively disposing of aberrant protein aggregates and damaged organelles--common denominators in various forms of neurodegenerative diseases. By definition, this form of autophagy, termed quality-control (QC) autophagy, must be different from nutrient-regulated autophagy in substrate selectivity, regulation and function. We have recently identified the ubiquitin-binding deacetylase, HDAC6, as a key component that establishes QC. HDAC6 is not required for autophagy activation per se; rather, it is recruited to ubiquitinated autophagic substrates where it stimulates autophagosome-lysosome fusion by promoting F-actin remodeling in a cortactin-dependent manner. Remarkably, HDAC6 and cortactin are dispensable for starvation-induced autophagy. These findings reveal that autophagosomes associated with QC are molecularly and biochemically distinct from those associated with starvation autophagy, thereby providing a new molecular framework to understand the emerging complexity of autophagy and therapeutic potential of this unique machinery.
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PMID:Quality control autophagy: a joint effort of ubiquitin, protein deacetylase and actin cytoskeleton. 2040 88

Recent studies have implicated multipotential mesenchymal stem cells (MSCs) as an aid to breast cancer cell proliferation and metastasis, partly as a result of the MSCs secretome. As the tumor gets beyond 2 mm in diameter, the stromal cells could undergo starvation due to the lack of sufficient nutrients in solid tumor microenvironment. In this study, we investigated the survival mechanisms used by stressed stromal cells in breast cancers. We used serum-deprived mesenchymal stem cells (SD-MSCs) and MCF-7 breast cancer cells as model system with a hypothesis that stromal cells in the nutrient-deprived core utilize survival mechanisms for supporting surrounding cells. We tested this hypothesis using in vivo tumor xenografts in immunodeficient mice, which indicated that SD-MSCs supported MCF-7 tumor growth by protection from apoptosis. Histochemical assays showed that SD-MSCs-injected tumors exhibited higher cellularity, decreased apoptosis and decreased differentiation. Beclin-1 staining indicated autophagic areas surrounded by actively proliferating cells. Furthermore, in vitro studies demonstrate that SD-MSCs survive using autophagy and secrete paracrine factors that support tumor cells following nutrient/serum deprivation. Western blot and immunocytochemistry analysis of SD-MSCs demonstrated upregulation and perinuclear relocation of autophagy key regulators such as beclin-1, ATG10, ATG12, MAP-LC3 and lysosomes. Electron microscopic analysis detected a time-dependent increase in autophagosome formation and HDAC6 activity assays indicated the upregulation of autophagy. Taken together, these data suggest that under nutrient-deprived conditions that can occur in solid tumors, stromal cells utilize autophagy for survival and also secrete anti-apoptotic factors that can facilitate solid tumor survival and growth.
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PMID:Activation of autophagy in mesenchymal stem cells provides tumor stromal support. 2131

Histone deacetylases (HDACs) are chromatin modifiers that alter gene expression but also exert a broad range of functions outside the nucleus by deacetylating non-histone target proteins. They gained growing attention for their implications in disease treatment, mainly through research using HDAC-inhibiting compounds. Understanding the effects of HDAC function and deregulation has therefore become an important focus for both basic and applied research. One of the described effects of HDAC inhibition is induction of autophagy. Autophagy is a ubiquitous process of recycling cellular components in response to starvation or stress and therefore crucial for cell homeostasis. Because of its role in managing anomalous protein overloads, autophagy is of great interest for neurodegenerative disease research. However, autophagy can also promote cell death, which puts it in the focus of cancer research. This review provides an overview of what we know of the impact of HDACs on the autophagy pathway and describes the fields where promising progress has been achieved, although one has to state that the work to illuminate the connections has just begun. Therefore, one focus is the effect of HDAC inhibition on autophagy in several types and models of cancer, which aims to find combinations of treatments that circumvent the ability of cancer cells to escape from cell death. Another recently emerged aspect is the direct involvement of the cytosolic deacetylase HDAC6 in autophagy progression, which is of great potential for revealing disease mechanisms in neurodegeneration.
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PMID:Interplay between histone deacetylases and autophagy--from cancer therapy to neurodegeneration. 2212 72

Fasting and glucose shortage activate a metabolic switch that shifts more energy production to mitochondria. This metabolic adaptation ensures energy supply, but also elevates the risk of mitochondrial oxidative damage. Here, we present evidence that metabolically challenged mitochondria undergo active fusion to suppress oxidative stress. In response to glucose starvation, mitofusin 1 (MFN1) becomes associated with the protein deacetylase HDAC6. This interaction leads to MFN1 deacetylation and activation, promoting mitochondrial fusion. Deficiency in HDAC6 or MFN1 prevents mitochondrial fusion induced by glucose deprivation. Unexpectedly, failure to undergo fusion does not acutely affect mitochondrial adaptive energy production; instead, it causes excessive production of mitochondrial reactive oxygen species and oxidative damage, a defect suppressed by an acetylation-resistant MFN1 mutant. In mice subjected to fasting, skeletal muscle mitochondria undergo dramatic fusion. Remarkably, fasting-induced mitochondrial fusion is abrogated in HDAC6-knockout mice, resulting in extensive mitochondrial degeneration. These findings show that adaptive mitochondrial fusion protects metabolically challenged mitochondria.
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PMID:MFN1 deacetylation activates adaptive mitochondrial fusion and protects metabolically challenged mitochondria. 2527 Oct 58

Autophagy has been evolved as one of the adaptive cellular processes in response to stresses such as nutrient deprivation. Various cellular cargos such as damaged organelles and protein aggregates can be selectively degraded through autophagy. Recently, the lipid storage organelle, lipid droplet (LD), has been reported to be the cargo of starvation-induced autophagy. However, it remains largely unknown how the autophagy machinery recognizes the LDs and whether it can selectively degrade LDs. In this study, we show that Drosophila histone deacetylase 6 (dHDAC6), a key regulator of selective autophagy, is required for the LD turnover in the hepatocyte-like oenocytes in response to starvation. HDAC6 regulates LD turnover via p62/SQSTM1 (sequestosome 1)-mediated aggresome formation, suggesting that the selective autophagy machinery is required for LD recognition and degradation. Furthermore, our results show that the loss of dHDAC6 causes steatosis in response to starvation. Our findings suggest that there is a potential link between selective autophagy and susceptible predisposition to lipid metabolism associated diseases in stress conditions.
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PMID:HDAC6 regulates lipid droplet turnover in response to nutrient deprivation via p62-mediated selective autophagy. 3107 36