ELP3: Elp3, a yeast A-type HAT, appears to have a direct role in transcription in that it is part of the RNA polymerase II holoenzyme and is involved in transcriptional elongation. In S. cerevisiae, the three-subunit elongator complex binds tightly to RNA polymerase II and its hyperphosphorylated C-terminal repeat domain (CTD), participating in an elongation-competent form of holoenzyme. Elp3, the smallest elongator subunit, was identified by peptide mass spectrometry and found to have GNAT homology. Because of its GNAT homology, recombinant Elp3 was produced from insect cells and tested for HAT activity in in-gel assays. Under these conditions, Elp3 was able to acetylate all four core histones when presented with them individually (1)
Reference
1. Sterner, D.E.&Berger, S.L.Acetylation of histones and transcription-related factors. Microbiol. Mol. Biol. Rev.2000;64(2):435-459. PMID: 10839822.
MYST: The MYST family, which was named after the initials of the founding members: MOZ, Ybf2/Sas3, Sas2, and Tip60, is the largest family of acetyltransferases with diverse biological functions. In the budding yeast, Esa1 of the NuA4 complex is known to be an essential HAT required for DNA repair and cell cycle progression. In animal systems, the role of MYST family HATs in stem cells, development and cancer have been thoroughly documented. It is of note that MYST family HAT complexes are known to have the broadest range of substrates including non-histone targets. The regulatory role and the ubiquity of protein acetylation had long been suspected to be comparable that of phosphorylation. (1)
Reference
1. Jeon J. H., Lee Y. H.Histone acetylation in fungal pathogens of plants. Plant Pathol.J.2014;30(1):1-9. PMID: 25288980.