SCA 14 mutation V138E leads to partly unfolded PKC γ associated with an exposed C‐terminus, altered kinetics, phosphorylation and enhanced insolubilization

The protein kinase C γ ( PKC γ) undergoes multistep activation and participates in various cellular processes in Purkinje cells. Perturbations in its phosphorylation state, conformation or localization can disrupt kinase signalling, such as in spinocerebellar ataxia type 14 ( SCA 14) that is caused by missense mutations in PRKCG encoding for PKC γ. We previously showed that SCA 14 mutations enhance PKC γ membrane translocation upon stimulation owing to an altered protein conformation. As the faster translocation did not result in an increased function, we examined how SCA 14 mutations induce this altered conformation of PKC γ and what the consequences of this conformational change are on PKC γ life cycle. Here, we show that SCA 14‐related PKC γ‐V138E exhibits an exposed C‐terminus as shown by fluorescence resonance energy transfer‐fluorescence lifetime imaging microscopy in living cells, indicative of its partial unfolding. This conformational change was associated with faster phorbol 12‐myristate 13‐acetate‐induced translocation and accumulation of fully phosphorylated PKC γ in the insoluble fraction, which could be rescued by coexpressing PDK 1 kinase that normally triggers PKC γ autophosphorylation. We propose that the SCA 14 mutation V138E causes unfolding of the C1B domain and exposure of the C‐terminus of the PKC γ‐V138E molecule, resulting in a decrease of functional kinase in the soluble fraction.Here, we show that the mutation V138E of the protein kinase C γ (PKCγ) C1B domain (PKCγ‐V138E), which is implicated in spinocerebellar ataxia type 14, exhibits a partially unfolded C‐terminus. This leads to unusually fast phorbol 12‐myristate 13‐acetate‐induced membrane translocation and accumulation of phosphorylated PKCγ‐V138E in the insoluble fraction, causing loss of the functional kinase. In contrast to general chaperones, coexpression of PKCγ's ‘natural chaperone’, PDK1 kinase, could rescue the PKCγ‐V138E phenotype.