N-epsilon-acetylation of porcine mature erythrocytes ubiquitin

Highly purified of porcine mature erythrocytes ubiquitin were obtained according to the experimental procedure reported by Jabusch and Deutsch (1983). N-epsilon-acetylation in vitro of internal lysyl residues of ubiquitin by p-nitro-phenyl-acetate at pH 8.0 was performed. The extent of acetylation of ubiquitin was determined: about 4-5 residues (4.5 residues) of N-epsilon-lysine groups of ubiquitin were acetylated. We have assigned by Edman degradation the sites of acetylation and the sites of remaining free internal N-epsilon-lysine residues in the sequence: fully acetylated: Lys-6, Lys-11 and Lys-33. Partially free N-epsilon-lysine: Lys-27 and Lys-29 and probably Lys-48 and Lys-63. 50 cycles Edman degradation were performed on porcine ubiquitin and the first 45 N-terminal residues were identified. We have partially determined that the molecular conservation of 45 amino acid sequence of ubiquitin between cattle, man and swine since the 45 amino acid sequence out of 76 residues are identical. The amino acid composition between human and porcine ubiquitin are also identical.     

c-Abl acetylation by histone acetyltransferases regulates its nuclear-cytoplasmic localization

c-Abl function is strictly dependent on its subcellular localization. Using an in vitro approach, we identify c-Abl as a new substrate for p300, CBP (CREB-binding protein) and PCAF (p300/CBP-associated factor) histone acetyltransferases. Remarkably, acetylation markedly alters its subcellular localization. Point mutagenesis indicated that Lys 730, located in the second nuclear localization signal, is the main target of p300 activity. It has previously been reported that c-Abl accumulates in the cytoplasm during myogenic differentiation. Here, we show that c-Abl protein is acetylated at early stages of myogenic differentiation. Indeed, acetylation on Lys 730 drives c-Abl accumulation in the cytoplasm and promotes differentiation. Thus, Lys 730 acetylation is a novel post-translational modification of c-Abl and a novel mechanism for modulating its subcellular localization that contributes to myogenic differentiation.     

Influence of the sequence environment and properties of neighboring amino acids on amino‐acetylation: Relevance for structure‐function analysis

Proteins function is regulated by co‐translational modifications and post‐translational modifications (PTMs) such as phosphorylation, glycosylation, and acetylation, which induce proteins to perform multiple tasks in a specified environment. Acetylation takes place post‐translationally on the ε‐amino group of Lys in histone proteins, allowing regulation of gene expression. Furthermore, amino group acetylation also occurs co‐translationally on Ser, Thr, Gly, Met, and Ala, possibly contributing to the stability of proteins. In this work, the influence of amino acids next to acetylated sites has been investigated by using MAPRes (Mining Association Patterns among preferred amino acid residues in the vicinity of amino acids targeted for PTMs). MAPRes was utilized to examine the sequence patterns vicinal to modified and non‐modified residues, taking into account their charge and polarity. The PTMs data were further sub‐divided according to their sub‐cellular location (nuclear, mitochondrial, and cytoplasmic), and their association patterns were mined. The association patterns mined by MAPRes for acetylated and non‐acetylated residues are consistent with the existing literature but also revealed novel patterns. These rules have been utilized to describe the acetylation and its effects on the protein structure‐function relationship. J. Cell. Biochem. 114: 874–887, 2013. © 2012 Wiley Periodicals, Inc.     

Specific antibodies reveal ordered and cell-cycle-related use of histone-H4 acetylation sites in mammalian cells

Antibodies specific for the acetylated forms of histone H4 (H4) were produced in rabbits with a synthetic peptide corresponding to the 18 N-terminal residues of tetra-acetylated H4 (i.e. with acetyllysine at positions 5, 8, 12 and 16). Specificity was determined by inhibition assays using four additional peptides, each acetylated at only a single site. Using an antiserum (R6) specific for the acetylation site at Lys-5 we have estimated the proportion of Lys-5 sites acetylated in the mono-, di- and tri-acetylated forms of H4 from randomly growing human HL-60 cells. The values obtained (7%, 29% and 61% respectively) differ from those expected if acetylation were random (i.e. 25%, 50% and 75%) or if site usage followed a set order for all H4 molecules (i.e. a jump from 0% to 100%). Antibodies from a second animal (R5) bound preferentially to peptides acetylated at Lys-12 and also bound to mono-acetylated H4 relatively weakly in several cell types. In contrast, mono-acetylated H4 from metaphase HeLa cells labelled more strongly with both antisera, indicating significant acetylation at Lys-5 and Lys-12. We conclude that (1) the sites at Lys-5 and Lys-12 are under-used in mono-acetylated H4 from a variety of mammalian cell types and Lys-8 and/or Lys-16 are therefore the first to be acetylated, (2) more than one order of site usage is possible and (3) there is a metaphase-specific shift in site usage. These results suggest that H4 acetylation plays a role in the modulation of chromatin structure in mammalian cells.     

The dual-specificity phosphatase CDC14B bundles and stabilizes microtubules

The Cdc14 dual-specificity phosphatases regulate key events in the eukaryotic cell cycle. However, little is known about the function of mammalian CDC14B family members. Here, we demonstrate that subcellular localization of CDC14B protein is cell cycle regulated. CDC14B can bind, bundle, and stabilize microtubules in vitro independently of its catalytic activity. Basic amino acid residues within the nucleolar targeting domain are important for both retaining CDC14B in the nucleolus and preventing microtubule bundling. Overexpression of CDC14B resulted in the formation of cytoplasmic CDC14B and microtubule bundles in interphase cells. These microtubule bundles were resistant to microtubule depolymerization reagents and enriched in acetylated alpha-tubulin. Expression of cytoplasmic forms of CDC14B impaired microtubule nucleation from the microtubule organization center. CDC14B is thus a novel microtubule-bundling and -stabilizing protein, whose regulated subcellular localization may help modulate spindle and microtubule dynamics in mitosis.