Sex-specific disruptions in PKCγ signaling in a mouse model of spinocerebellar ataxia type 14
Sarah A. Wolfe, Yuliang Ma, Tomer M. Yaron-Barir, Carly Chang, Caila A. Pilo, Majid Ghassemian, Amanda J. Roberts, Sang Ryeul Lee, Benjamin A. Henson, Kristen Jepsen, Jared L. Johnson, Lewis C. Cantley, Susan S. Taylor, George Gorrie, Alexandra C. Newton
Sarah A. Wolfe, Yuliang Ma, Tomer M. Yaron-Barir, Carly Chang, Caila A. Pilo, Majid Ghassemian, Amanda J. Roberts, Sang Ryeul Lee, Benjamin A. Henson, Kristen Jepsen, Jared L. Johnson, Lewis C. Cantley, Susan S. Taylor, George Gorrie, Alexandra C. Newton
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Research Article Cell biology Neuroscience

Sex-specific disruptions in PKCγ signaling in a mouse model of spinocerebellar ataxia type 14

Abstract

Spinocerebellar ataxia type 14 (SCA14) is an autosomal dominant neurodegenerative disease caused by mutations in the gene encoding protein kinase C γ (PKCγ), a Ca2+- and diacylglycerol-dependent Ser/Thr kinase dominantly expressed in cerebellar Purkinje cells. These mutations impair autoinhibitory constraints to increase the basal activity of the kinase, resulting in deficits in the cerebellum that are not observed upon simple deletion of the gene, and severe ataxia. To better understand the impact of aberrant PKCγ signaling in disease pathology, we developed a knockin murine model of the SCA14 mutation ΔF48 in PKCγ. This fully penetrant mutation is severe in humans and is mechanistically informative, as it has high basal activity but is unresponsive to agonist stimulation. Genetic, behavioral, and molecular testing revealed that ΔF48 PKCγ mice have ataxia-related phenotypes and an altered cerebellar phosphoproteome driven primarily by enhanced Ca2+/calmodulin-dependent kinase 2 signaling, effects that were more severe in male mice. Analysis of existing human data revealed that SCA14 has a significantly earlier age of onset for males compared with females. Data from this clinically relevant mutation suggested that enhanced basal activity of PKCγ is sufficient to cause ataxia and that treatment strategies to modulate aberrant PKCγ may be particularly beneficial in males.

Authors

Sarah A. Wolfe, Yuliang Ma, Tomer M. Yaron-Barir, Carly Chang, Caila A. Pilo, Majid Ghassemian, Amanda J. Roberts, Sang Ryeul Lee, Benjamin A. Henson, Kristen Jepsen, Jared L. Johnson, Lewis C. Cantley, Susan S. Taylor, George Gorrie, Alexandra C. Newton

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Figure 8

Sex differences in the SCA14 mouse cerebellar phosphoproteome.

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Sex differences in the SCA14 mouse cerebellar phosphoproteome. Phosphopr...
Phosphoproteomic analysis was carried out as in Figure 5. (A) Volcano plots show change in phosphopeptide abundance between male HET and female HET mice. Color represents phosphopeptides with P value < 0.05. Dot plots indicate the top 10 most significantly enriched for gene ontologies from the differentially abundant phosphopeptides identified in (B) male HET vs. female HET mice, and (C) similarly altered phosphopeptides in HET mice (defined as phosphopeptides with the same trend in males and females with a significant difference in intensity between WT vs. HET in at least one sex). Similarly altered phosphopeptides are shown in heatmaps separated by those that (D) increase or (E) decrease in HET mice compared with WT. (F) Volcano plots show change in phosphopeptide abundance between male HOM and female HOM mice. Color represents phosphopeptides with P value < 0.05. Dot plots indicate the top 10 most significantly enriched for gene ontologies from the differentially abundant phosphopeptides identified in (G) male HOM vs. female HOM mice, and (H) similarly altered phosphopeptides in HOM mice (defined as phosphopeptides with the same trend in males and females with a significant difference in intensity between WT vs. HOM in at least one sex). Similarly altered phosphopeptides are shown in heatmaps separated by those that (I) increase or (J) decrease in HOM mice compared with WT. Dot plot color scale indicates P value, and dot size indicates number of genes per ontology (P < 0.05). Heatmap color scale indicates normalized phosphopeptides intensity, with values centered and scaled by row. Protein names accompanied by a number designate multiple phosphorylation sites for the same protein.