Dysregulation of protein prenylation
has been implicated
in many
diseases, including Alzheimer’s disease (AD). Prenylomic analysis,
the combination of metabolic incorporation of an isoprenoid analogue
(C15AlkOPP) into prenylated proteins with a bottom-up proteomic analysis,
has allowed the identification of prenylated proteins in various cellular
models. Here, transgenic AD mice were administered with C15AlkOPP
through intracerebroventricular (ICV) infusion over 13 days. Using
prenylomic analysis, 36 prenylated proteins were enriched in the brains
of AD mice. Importantly, the prenylated forms of 15 proteins were
consistently upregulated in AD mice compared to nontransgenic wild-type
controls. These results highlight the power of this in vivo metabolic
labeling approach to identify multiple post-translationally modified
proteins that may serve as potential therapeutic targets for a disease
that has proved refractory to treatment thus far. Moreover, this method
should be applicable to many other types of protein modifications,
significantly broadening its scope.
Dysregulation of protein prenylation has been implicated in many diseases, including Alzheimer's disease (AD). Prenylomic analysis, the combination of metabolic incorporation of an isoprenoid analogue (C15AlkOPP) into prenylated proteins with a bottom-up proteomic analysis, has allowed identification of prenylated proteins in various cellular models. Here, transgenic AD mice were administered with C15AlkOPP through intracerebroventricular (ICV) infusion over 13 days. Using prenylomic analysis, 36 prenylated proteins were enriched in the brains of AD mice. Importantly, the prenylated forms of 15 proteins were consistently upregulated in AD mice compared to non-transgenic wild-type controls. These results highlight the power of this in vivo metabolic labeling approach to identify multiple post-translationally modified proteins that may serve as potential therapeutic targets for a disease that has proved refractory to treatment thus far. Moreover, this method should be applicable to many other types of protein modifications, significantly broadening its scope.
Protein lipidation is a post-translational modification that confers hydrophobicity on protein substrates to control their cellular localization, mediate protein trafficking, and regulate protein function. In particular, protein prenylation is a C-terminal modification on proteins bearing canonical prenylation motifs catalyzed by prenyltransferases. Such types of proteins have been of interest owing to their potential association with various diseases. Chemical proteomic approaches have been pursued over the last decade to define prenylated proteomes (prenylome) and probe their responses to perturbations in various cellular systems. Here, we describe the discovery of prenylation of a non-canonical prenylated protein, ALDH9A1, which lacks any apparent prenylation motif. This enzyme was initially identified through chemical proteomic profiling of prenylomes in various cell lines. Metabolic labeling with an isoprenoid probe using overexpressed ALDH9A1 reveals that this enzyme can be prenylated inside cells but does not respond to inhibition by prenyltransferase inhibitors. Site-directed mutagenesis of the key residues involved in ALDH9A1 activity indicate that the catalytic C288 bears the isoprenoid modification likely through an NAD+-dependent mechanism. Furthermore, the isoprenoid modification is also susceptible to hydrolysis, indicating a reversible modification. We hypothesize that this modification originates from endogenous farnesal or geranygeranial, the established degradation products of prenylated proteins and results in a thioester form that accumulates. This novel reversible prenoyl modification on ALDH9A1 expands the current paradigm on protein prenylation by illustrating a potentially new type of protein-lipid modification that may also serve as a novel mechanism for controlling enzyme function.
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