Abstract
Many histone acetyltransferases undergo autoacetylation, either through chemical or enzymatic means, to potentiate enzymatic cognate substrate lysine acetylation, although the mode and molecular role of such autoacetylation is poorly understood. The MYST family of histone acetyltransferases is autoacetylated at an active site lysine residue to facilitate cognate substrate lysine binding and acetylation. Here, we report on a detailed molecular investigation of Lys-274 autoacetylation of the human MYST protein Males Absent on the First (hMOF). A mutational scan of hMOF Lys-274 reveals that all amino acid substitutions of this residue are able to bind cofactor but are significantly destabilized, both in vitro and in cells, and are catalytically inactive for cognate histone H4 peptide lysine acetylation. The x-ray crystal structure of a hMOF K274P mutant suggests that the reduced stability and catalytic activity stems from a disordering of the residue 274-harboring a α2-β7 loop. We also provide structural evidence that a C316S/E350Q mutant, which is defective for cognate substrate lysine acetylation; and biochemical evidence that a K268M mutant, which is defective for Lys-274 chemical acetylation in the context of a K274-peptide, can still undergo quantitative K274 autoacetylation. Together, these studies point to the critical and specific role of hMOF Lys-274 autoacetylation in hMOF stability and cognate substrate acetylation and argues that binding of Ac-CoA to hMOF likely drives Lys-274 autoacetylation for subsequent cognate substrate acetylation.
Highlights
Each mutant was tested for catalytic activity, and to ensure that the Lys-274 mutation was not merely affecting catalysis by changing the pKa of the active site of the enzyme, activity was tested over a range of pH values (Fig. 2)
The results described here reveal that an autoacetylated lysine residue at position 274 of hMOF contains the essential specific chemical properties to promote hMOF stability and activity
We find that hMOF Lys-274 autoacetylation cannot be mimicked by other residues, arguing for the unique chemical properties of an autoacetylated Lys-274 residue in hMOF catalysis
Summary
The most extensively studied of these enzymes are the histone acetyltransferases (HATs), which are divided into at least five subfamilies based on sequence homology and substrate preferences. They are HAT1, GCN5/PCAF, MYST, p300/CBP, and Rtt109. All but the MYST family of HATs have been demonstrated to proceed through a ternary catalytic mechanism whereby both Ac-CoA and cognate lysine substrates must simultaneously bind for acetyl-transfer (6 –9). MYST proteins have been demonstrated to acetylate cognate substrates through a ping-pong catalytic mechanism, whereby Ac-CoA binds first to transfer the acetyl group to an active site cysteine residue (Cys316 in hMOF) to form an acetyl-enzyme intermediate prior to acetyl-transfer to the cognate lysine substrate. Autoacetylation of lysine 290 of Rtt109, located about 8 Å away from the enzyme active site, potentiates Rtt109 catalytic activity by decreasing the Km for Ac-CoA and increasing the rate of catalysis [19]
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