Gigaxonin glycosylation regulates intermediate filament turnover and may impact giant axonal neuropathy etiology or treatment
Po-Han Chen, Jimin Hu, Jianli Wu, Duc T. Huynh, Timothy J. Smith, Samuel Pan, Brittany J. Bisnett, Alexander B. Smith, Annie Lu, Brett M. Condon, Jen-Tsan Chi, Michael Boyce
Po-Han Chen, Jimin Hu, Jianli Wu, Duc T. Huynh, Timothy J. Smith, Samuel Pan, Brittany J. Bisnett, Alexander B. Smith, Annie Lu, Brett M. Condon, Jen-Tsan Chi, Michael Boyce
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Research Article Cell biology

Gigaxonin glycosylation regulates intermediate filament turnover and may impact giant axonal neuropathy etiology or treatment

Abstract

Gigaxonin (also known as KLHL16) is an E3 ligase adaptor protein that promotes the ubiquitination and degradation of intermediate filament (IF) proteins. Mutations in human gigaxonin cause the fatal neurodegenerative disease giant axonal neuropathy (GAN), in which IF proteins accumulate and aggregate in axons throughout the nervous system, impairing neuronal function and viability. Despite this pathophysiological significance, the upstream regulation and downstream effects of normal and aberrant gigaxonin function remain incompletely understood. Here, we report that gigaxonin is modified by O-linked β-N-acetylglucosamine (O-GlcNAc), a prevalent form of intracellular glycosylation, in a nutrient- and growth factor–dependent manner. MS analyses of human gigaxonin revealed 9 candidate sites of O-GlcNAcylation, 2 of which — serine 272 and threonine 277 — are required for its ability to mediate IF turnover in gigaxonin-deficient human cell models that we created. Taken together, the results suggest that nutrient-responsive gigaxonin O-GlcNAcylation forms a regulatory link between metabolism and IF proteostasis. Our work may have significant implications for understanding the nongenetic modifiers of GAN phenotypes and for the optimization of gene therapy for this disease.

Authors

Po-Han Chen, Jimin Hu, Jianli Wu, Duc T. Huynh, Timothy J. Smith, Samuel Pan, Brittany J. Bisnett, Alexander B. Smith, Annie Lu, Brett M. Condon, Jen-Tsan Chi, Michael Boyce

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Figure 2

Generation of GAN model cell systems by CRISPR/Cas9 genome engineering.

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Generation of GAN model cell systems by CRISPR/Cas9 genome engineering. ...
(A) SH-SY5Y cells were subjected to control or GAN gRNA genome editing. Lysates from single cell–derived clones were analyzed by WB, confirming loss of gigaxonin (arrow) and increased vimentin levels (arrows) in GAN–/– cells, as compared with controls. ns, nonspecific. (B) Quantification of GAN mRNA expression in control and GAN–/– (gRNA) cells by qPCR (n = 3; black dots represent individual biological replicates). (C) Vimentin forms ovoid, perinuclear aggregates in GAN–/– cells. Endogenous vimentin (green) and nuclei (DAPI, blue) were visualized by IFA in control and GAN–/– cells derived from 3 independent gRNAs. Scale bars: 10 μm. (D) Quantification of ovoid and perinuclear aggregates in GAN–/– cells. The number of ovoid aggregates and counted cells associated with each sgRNA is shown.