α-Tubulin acetylation from the inside out.

P osttranslational modification of proteins, including phosphorylation, ubiquitylation, and acetylation, is an important means of signaling and functional specialization in the cell. The acetylation of lysine residues is best understood in histone proteins, in which histone acetyltransferases modify histone tail sequences to regulate chromatin structure. However, lysine acetylation has recently become more appreciated as a widely distributed phenomenon regulating diverse proteins and cellular systems (1). One such system is the microtubule (MT) cytoskeleton. MTs are highly dynamic tubular polymers assembled from protofilaments of α/β-tubulin dimers, and are essential for intracellular transport, architectural organization, and force production in eukaryotic cells (2). Acetylation of the conserved lysine 40 (K40) residue of α-tubulin, first reported more than 25 y ago (3), is one of several conserved posttranslational modifications found in the tubulin protein (2, 3). Although MTs generally function as highly dynamic polymers, α-tubulin K40 acetylation is associated with unusually stable MTs. These act as tracks for organelle and macromolecule transport in neurons, and form the structural scaffolds, called axonemes, at the core of beating cilia and flagella (4, 5). α-Tubulin K40 acetylation is catalyzed by a conserved α-tubulin acetyltransferase (α-TAT), but neither the detailed mechanism of tubulin acetylation nor its downstream functional consequences are well understood (6, 7). Now, in parallel studies presented in PNAS, Friedmann et al. (8) and Taschner et al. (9) describe the 3D structure of human α-TAT and the chemical basis for α-tubulin K40 acetylation. The two studies show how α-TAT selectively acetylates α-tubulin K40 and explore α-TAT’s catalytic mechanism through detailed enzymatic analysis (8, 9). MTs are regulated by a host of posttranslational modifications such as polyglutamylation, polyglycylation, detyrosination, and tyrosination, most of which occur at the C termini of αand β-tubulin exposed on the outer MT surface, and directly regulate MT association with motor proteins and so-called plus-end binding proteins (2). In contrast, α-tubulin K40 acetylation occurs on the inner or lumenal surface of the MT and probably affects MT structure and dynamics directly (Fig. 1) (2, 4). Structural modeling suggests that acetylation may stabilize lateral interactions between neighboring tubulin protofilaments, potentially explaining the increased stability of acetylated MTs observed in vivo (10). Acetylation-mediated modification of protofilament interactions may also explain why loss of α-TAT in Caenorhabditis elegans disrupts the tight regulation of MT protofilament number in touch receptor neurons, resulting in shorter MTs with a range of protofilament numbers (10, 11). α-TAT was identified as a component associated with intraflagellar Bardet–Biedl syndrome complex (i.e., BBsome), which is necessary for forming and stabilizing axonemal MTs (7, 12), and α-TAT orthologues are found in all organisms with MT axonemal structures such as cilia and flagella (7). Purified α-TAT is highly specific for α-tubulin K40; it possesses no detectable activity on substrates such as histones. α-TAT also shows a sixfold higher catalytic rate when acetylating α-tubulin K40 in preformed MTs vs. soluble α/β-tubulin dimers (7, 13). To better understand α-TAT mechanism and specificity, Taschner et al. (9) and Friedmann et al. (8) took a combined structural/biochemical approach. Both groups determined the 3D structure of the N-terminal two thirds of the protein (residues 1–195 of 333), which adopts a compact, roughly triangular shape and binds an acetyl CoA (AcCoA) cofactor in its active site (Fig. 1). The structures reveal that α-TAT is distantly related to the GCN5 family of histone acetyltransferases, with the closest structural similarities evident in the cores of the two proteins and the manner of their binding to AcCoA. Outside the conserved core, the most distinctive structural feature of α-TAT is a β-hairpin structure (β4–β5) that is unique to and strictly conserved within the α-TAT protein family (Fig. 1, blue). Although the structures lack a direct visualization of α-tubulin binding, both studies (8, 9) converge on a plausible mechanism for α-TAT’s observed substrate specificity. α-TAT contains a conserved surface pocket close to the active site composed largely of hydrophobic and basic residues, which likely complement the acidic loop containing α-tubulin K40. Consistent with this idea, structure-based mutagenesis of residues in this pocket substantially reduces the enzyme’s catalytic activity (8, 9). Friedmann et al. (8) further identify two mutations in the conserved α-TAT–specific β4–β5 hairpin that actually enhance α-tubulin acetylation activity in vivo and in vitro, suggesting more extensive interactions that may further increase specificity for α-tubulin (Fig. 1). The four known families of histone acetyltransferases—GCN5, Rtt109, CBP300, and MYST—share a common fold, yet they use distinct catalytic mechanisms (14). GCN5 is the most structurally similar to α-TAT and uses an acidic residue in the active site as a general base to deprotonate the incoming substrate lysine amine and catalyze transfer of the acetyl group (15). The other three families use two catalytic residues and catalyze acetylation through a “ping-pong” mechanism Fig. 1. (A) Overview of the structure of human α-TAT (9). Right: Detailed view of the enzyme’s active site shows bound AcCoA cofactor and proposed general base catalytic residues Q58, C120, and D157. (B) α-TAT (brown) acetylates α-tubulin K40, located in the MT lumen, potentially altering its structure and dynamics.