New ProteomeXchange dataset PXD076447
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ProteomeCentral Agent
Apr 1, 2026, 5:03:50 AM (23 hours ago) Apr 1
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Dear ProteomeXchange subscriber, a new ProteomeXchange dataset is being announced. To see more information, click here:
https://proteomecentral.proteomexchange.org/dataset/PXD076447
Summary of dataset
Status: new
Identifier: PXD076447
HostingRepository: iProX
Species: Neurospora crassa OR74A
Title: The GET Pathway Modulates Azole Susceptibility through Sterol Metabolic Remodeling and Protein Trafficking in Filamentous Fungi
Submitter: Shuting Ye
LabHead: Xianyun Sun
Description: Azole antifungals are widely used to control fungal infection, yet resistance mechanisms beyond drug efflux and target modification remain insufficiently understood. Here, we identified the Guided Entry of Tail-anchored proteins (GET) pathway as a conserved regulator of azole susceptibility in Neurospora crassa and Aspergillus fumigatus. Deletion or dysfunction of the core GET components Get-3 or Get-4 confers resistance to multiple azoles without impairing hyphal growth or sporulation. Mechanistically, GET deficiency neither reduced intracellular accumulation nor altered drug efflux and target expression or total ergosterol levels. Instead, GET-deficient strains displayed significantly reduced accumulation of the toxic sterol intermediate 14α-methyl-3,6-diol under azole stress, indicating a potential bypass of azole-induced sterol toxicity. Proximity labeling and functional validation indicated that GET deficiency perturbs the trafficking of multiple azole-resistance-a
ssociated proteins, including the key tail-anchored protein transporter Emp-47 and mitochondrial Cox subunits Cox-4 and Cox-15, which deletion enhanced azole resistance. Transcriptomic and functional analysis further revealed that GET disruption altered the expression of some azole resistance-associated genes, which involve in membrane transport, metabolism, and cell wall organization, independent of canonical stress pathways. In this study, a total of 17 new genes that modulate azole susceptibility were identified. Collectively, our findings uncover a non-classical mechanism of azole resistance mediated by GET-dependent protein trafficking and metabolic adaptation, conserved across filamentous fungi.
HTML_URL: https://proteomecentral.proteomexchange.org/dataset/PXD076447
XML_URL: https://proteomecentral.proteomexchange.org/dataset/PXD076447&outputMode=XML
https://proteomecentral.proteomexchange.org/dataset/PXD076447
Summary of dataset
Status: new
Identifier: PXD076447
HostingRepository: iProX
Species: Neurospora crassa OR74A
Title: The GET Pathway Modulates Azole Susceptibility through Sterol Metabolic Remodeling and Protein Trafficking in Filamentous Fungi
Submitter: Shuting Ye
LabHead: Xianyun Sun
Description: Azole antifungals are widely used to control fungal infection, yet resistance mechanisms beyond drug efflux and target modification remain insufficiently understood. Here, we identified the Guided Entry of Tail-anchored proteins (GET) pathway as a conserved regulator of azole susceptibility in Neurospora crassa and Aspergillus fumigatus. Deletion or dysfunction of the core GET components Get-3 or Get-4 confers resistance to multiple azoles without impairing hyphal growth or sporulation. Mechanistically, GET deficiency neither reduced intracellular accumulation nor altered drug efflux and target expression or total ergosterol levels. Instead, GET-deficient strains displayed significantly reduced accumulation of the toxic sterol intermediate 14α-methyl-3,6-diol under azole stress, indicating a potential bypass of azole-induced sterol toxicity. Proximity labeling and functional validation indicated that GET deficiency perturbs the trafficking of multiple azole-resistance-a
ssociated proteins, including the key tail-anchored protein transporter Emp-47 and mitochondrial Cox subunits Cox-4 and Cox-15, which deletion enhanced azole resistance. Transcriptomic and functional analysis further revealed that GET disruption altered the expression of some azole resistance-associated genes, which involve in membrane transport, metabolism, and cell wall organization, independent of canonical stress pathways. In this study, a total of 17 new genes that modulate azole susceptibility were identified. Collectively, our findings uncover a non-classical mechanism of azole resistance mediated by GET-dependent protein trafficking and metabolic adaptation, conserved across filamentous fungi.
HTML_URL: https://proteomecentral.proteomexchange.org/dataset/PXD076447
XML_URL: https://proteomecentral.proteomexchange.org/dataset/PXD076447&outputMode=XML
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