The Ubiquitin SystemUbiquitin is a small 76eamino acid protein and is among the most highly conserved proteins ever described. Ubiquitin is Supported by the NIH Early Independence Award DP5-OD019800 (J.H.). Disclosures: J.H. receives royalties from Harvard Medical School related to US patent 9,201,073.The American Society for Investigative Pathology (ASIP) Cotran Early Career Investigator Award recognizes early career investigators with demonstrated excellence as an investigator with recently established or emerging independence and with a research focus leading to an improved understanding of the conceptual basis of disease. John Hanna, recipient of the ASIP 2019 Cotran Early Career Investigator Award, delivered a lecture entitled "Protein Degradation and the Pathologic Basis of Disease" on October 22, 2018, at the Pathobiology for Investigators, Students, and Academicians (PISA) meeting in Ann Arbor, MI.
Phosphorylation of Bfa1 by Kin4 creates a docking site on Bfa1 for the 14-3-3 family protein Bmh1, which in turn weakens Bfa1–centrosome association and promotes symmetric Bfa1 localization to engage the spindle position checkpoint.
The abundance of cell surface glucose transporters must be precisely regulated to ensure optimal growth under constantly changing environmental conditions. We recently conducted a proteomic analysis of the cellular response to trivalent arsenic, a ubiquitous environmental toxin and carcinogen. A surprising finding was that a subset of glucose transporters was among the most downregulated proteins in the cell upon arsenic exposure. Here we show that this downregulation reflects targeted arsenic-dependent degradation of glucose transporters. Degradation occurs in the vacuole and requires the E2 ubiquitin ligase Ubc4, the E3 ubiquitin ligase Rsp5, and K63-linked ubiquitin chains. We used quantitative proteomic approaches to determine the ubiquitinated proteome after arsenic exposure, which helped us to identify the ubiquitination sites within these glucose transporters. A mutant lacking all seven major glucose transporters was highly resistant to arsenic, and expression of a degradation-resistant transporter restored arsenic sensitivity to this strain, suggesting that this pathway represents a protective cellular response. Previous work suggests that glucose transporters are major mediators of arsenic import, providing a potential rationale for this pathway. These results may have implications for the epidemiologic association between arsenic exposure and diabetes.
Increasing evidence suggests that lipid homeostasis is critical for protein quality control. Very-long-chain fatty acids (VLCFA) are rare and poorly understood species. Here, it is shown that dysregulation of VLCFA metabolism causes increased membrane saturation, endoplasmic reticulum stress, and unfolded protein response induction.
The equine hoof inner epithelium is folded into primary and secondary epidermal lamellae which increase the dermo-epidermal junction surface area of the hoof and can be affected by laminitis, a common disease of equids. Two keratin proteins (K), K42 and K124, are the most abundant keratins in the hoof lamellar tissue of Equus caballus. We hypothesize that these keratins are lamellar tissue-specific and could serve as differentiation- and disease-specific markers. Our objective was to characterize the expression of K42 and K124 in equine stratified epithelia and to generate monoclonal antibodies against K42 and K124. By RT-PCR analysis, keratin gene (KRT) KRT42 and KRT124 expression was present in lamellar tissue, but not cornea, haired skin, or hoof coronet. In situ hybridization studies showed that KRT124 localized to the suprabasal and, to a lesser extent, basal cells of the lamellae, was absent from haired skin and hoof coronet, and abruptly transitions from KRT124-negative coronet to KRT124-positive proximal lamellae. A monoclonal antibody generated against full-length recombinant equine K42 detected a lamellar keratin of the appropriate size, but also cross-reacted with other epidermal keratins. Three monoclonal antibodies generated against N- and C-terminal K124 peptides detected a band of the appropriate size in lamellar tissue and did not cross-react with proteins from haired skin, corneal limbus, hoof coronet, tongue, glabrous skin, oral mucosa, or chestnut on immunoblots. K124 localized to lamellar cells by indirect immunofluorescence. This is the first study to demonstrate the localization and expression of a hoof lamellar-specific keratin, K124, and to validate anti-K124 monoclonal antibodies.
The yeast stress-activated protein kinase Hog1 is best known for its role in mediating the response to osmotic stress, but it is also activated by various mechanistically distinct environmental stressors, including heat shock, endoplasmic reticulum stress, and arsenic. In the osmotic stress response, the signal is sensed upstream and relayed to Hog1 through a kinase cascade. Here, we identified a mode of Hog1 function whereby Hog1 senses arsenic through a direct physical interaction that requires three conserved cysteine residues located adjacent to the catalytic loop. These residues were essential for Hog1-mediated protection against arsenic, were dispensable for the response to osmotic stress, and promoted the nuclear localization of Hog1 upon exposure of cells to arsenic. Hog1 promoted arsenic detoxification by stimulating phosphorylation of the transcription factor Yap8, promoting Yap8 nuclear localization, and stimulating the transcription of the only known Yap8 targets, ARR2 and ARR3, both of which encode proteins that promote arsenic efflux. The related human kinases ERK1 and ERK2 also bound to arsenic in vitro, suggesting that this may be a conserved feature of some members of the mitogen-activated protein kinase (MAPK) family. These data provide a mechanistic basis for understanding how stress-activated kinases can sense distinct threats and perform highly specific adaptive responses.
The compartmentalization of cellular function is achieved largely through the existence of membrane‐bound organelles. However, recent work suggests a novel mechanism of compartmentalization mediated by membraneless structures that have liquid droplet‐like properties and arise through phase separation. Cytoplasmic stress granules (SGs) are the best characterized and are induced by various stressors including arsenite, heat shock, and glucose deprivation. Current models suggest that SGs play an important role in protein homeostasis by mediating reversible translation attenuation. Protein phosphatase‐1 (PP1) is a central cellular regulator responsible for most serine/threonine dephosphorylation. Here, we show that upon arsenite stress, PP1's catalytic subunit Glc7 relocalizes to punctate cytoplasmic granules. This altered localization requires PP1's recently described maturation pathway mediated by the multifunctional ATPase Cdc48 and PP1's regulatory subunit Ypi1. Glc7 relocalization is mediated by its regulatory subunit Reg1 and its target Snf1, the AMP‐dependent protein kinase. Surprisingly, Glc7 granules are highly specific to arsenite and appear distinct from canonical SGs. Arsenite induces potent translational inhibition, and translational recovery is strongly dependent on Glc7, but independent of Glc7's well‐established role in regulating eIF2α. These results suggest a novel form of stress‐induced cytoplasmic granule and a new mode of translational control by Glc7.
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