Protein N-terminal acetylation: NAT 2007–2008 Symposia

Protein N-terminal acetylation is a very common modification, but has during the past decades received relatively little attention. In order to put this neglected field back on the scientific map, we have in May 2007 and September 2008 arranged two international NAT symposia in Bergen, Norway. This supplement contains selected proceedings from these symposia reflecting the current status of the field, including an overview of protein N-terminal acetylation in yeast and humans, a novel nomenclature system for the N-terminal acetyltransferases (NATs) and methods for studying protein N-terminal acetylation in vitro and in vivo

Aspergillus RabBRab5 Integrates Acquisition of Degradative Identity with the Long Distance Movement of Early Endosomes

Of the two Aspergillus early endosomal Rab5 paralogues, RabB recruits, in its GTP conformation, Vps19, Vps45, and Vps34, and the CORVET complex and couples acquisition of PI(3)P degradative identity with the long-distance movement of early endosomes. RabA also recruits CORVET, albeit less efficiently. The simultaneous loss of RabA and RabB is lethal

The NatA Acetyltransferase Couples Sup35 Prion Complexes to the [PSI+] Phenotype

Protein-only (prion) epigenetic elements confer unique phenotypes by adopting alternate conformations that specify new traits. Given the conformational flexibility of prion proteins, protein-only inheritance requires efficient self-replication of the underlying conformation. To explore the cellular regulation of conformational self-replication and its phenotypic effects, we analyzed genetic interactions between [PSI+], a prion form of the S. cerevisiae Sup35 protein (Sup35[PSI+]), and the three Nα-acetyltransferases, NatA, NatB, and NatC, which collectively modify ∼50% of yeast proteins. Although prion propagation proceeds normally in the absence of NatB or NatC, the [PSI+] phenotype is reversed in strains lacking NatA. Despite this change in phenotype, [PSI+] NatA mutants continue to propagate heritable Sup35[PSI+]. This uncoupling of protein state and phenotype does not arise through a decrease in the number or activity of prion templates (propagons) or through an increase in soluble Sup35. Rather, NatA null strains are specifically impaired in establishing the translation termination defect that normally accompanies Sup35 incorporation into prion complexes. The NatA effect cannot be explained by the modification of known components of the [PSI+] prion cycle including Sup35; thus, novel acetylated cellular factors must act to establish and maintain the tight link between Sup35[PSI+] complexes and their phenotypic effects