Studies on the specificity of acetylaminoacyl-peptide hydrolase.

In a continuing attempt to explore the types of specificity determinants that may affect protein-protein (peptide) interactions, a number of short (2-5 residues) acetylated peptides have been compared as substrates for the enzyme acetylaminoacyl-peptide hydrolase (EC 3.4.19.1). The reference substrate was Ac-AAAA, and most of the other substrates were derived from this basic structure by single amino acid substitutions. The Km and kcat for the different substrates were determined by standard steady-state kinetics, and the corresponding delta delta GT++ value derived from kcat/Km was used for the comparison, setting delta detal GT++ for Ac-AAAA equal to 0. The best substrates were found to be those containing negative charges (Asp > Glu) or aromatic residues in positions 1', 2', or 3' (delta delta GT++ values of 2-5 kJ); the negative charge provided by the C-terminus of the substrate also appears to be important, since the amide and O-Me ester derivatives caused a change in delta delta GT++ values of -7 to -8 kJ from the reference peptide. The stimulating effect of the negative charges is consistent with the inhibitory effect of positive charges in similar peptides (Krishna RG, Wold F, 1992, Protein Sci 1:582-589), and the proposed active site model incorporates subsites for both charge-charge and hydrophobic interactions. In assessing all the data, it is clear that the properties of the individual substrates reflect the total make-up of each peptide and not only the effect of a single residue in a given position.(ABSTRACT TRUNCATED AT 250 WORDS)

Specificity studies of the GDP-[L]-fucose: 2-acetamido-2-deoxy-beta-[D]-glucoside (Fuc-->Asn-linked GlcNAc) 6-alpha-[L]-fucosyltransferase from rat-liver Golgi membranes.

The specificity of Golgi-membrane glycoprotein 6-alpha-[L]-fucosyltransferase [GDP-[L]-fucose: 2-acetamido-2-deoxy- beta-[D]-glucoside (Fuc-->Asn-linked GlcNAc) 6-alpha-[L]-fucosyltransferase; EC 2.4.1.68] has been assessed with regard to substrate covalent structures and the effect of a protein matrix on the conformational display of those covalent structures. Specificity was studied by direct comparison of the substrate quality of nine 6-biotinamidohexanoylAsn (= R) derivatives of intermediates and products in the pathway from Man5GlcNAc2-R to a fully sialylated biantennary complex-type glycan. The Man5 derivative and the sialic acid-containing glycans were completely inactive as substrates. The other glycans were all fucosylated; the best substrate was GlcNAcMan3GlcNAc2-R. The protein-matrix effect was studied by comparing the substrate quality of the same 6-biotinamidohexanoylAsn derivatives as well as the corresponding biotinylAsn derivatives free in solution and bound to streptavidin. On the basis of a model derived from the known 3D structure of biotin (biocytin)-saturated streptavidin, it was predicted that the fucosylation site in the substrates would be completely masked in the biotin-binding pocket in the biotinyl derivatives (proximal display), and at least partially masked in the 6-biotinamidohexanoyl derivatives (distal display). The activity measurements were in agreement with these predictions; the glycan structures GlcNAcMan5GlcNAc2-, GlcNAcMan3GlcNAc2-, and GlcNAc2-Man3GlcNAc2- were readily fucosylated as derivatives free in solution, but were totally inert in the proximal complex with streptavidin. In the distal complexes the latter two structures were found to be fucosylated very slowly while the former structure was inactive.

Ubiquitin conjugation to cytochromes c. Structure of the yeast iso-1 conjugate and possible recognition determinants.

Saccharomyces cerevisiae iso-1-cytochrome c was conjugated with ubiquitin (Ub) in vitro in a rabbit reticulocyte extract (Fraction II). By N-terminal protein sequencing, it was found for both the mono- and diubiquitinated products that the major Ub attachment site is on Lys4 (residue 9) of the cytochrome c. Thus, the residue ubiquitinated in iso-1-cytochrome c is identical with that previously determined for the yeast iso-2 form (Sokolik, C. W., and Cohen, R. E. (1991) J. Biol. Chem. 266, 9100-9107). For both cytochromes c, the proportions of diubiquitinated and higher order conjugates are drastically reduced when Ub is replaced with a Lys48----Arg variant, suggesting that the Ub-Ub moieties are linked predominantly through Lys48. Despite close similarities in structure and ubiquitination sites, conjugation to iso-2-cytochrome c is approximately 5-fold faster than for the iso-1 form; vertebrate cytochromes c are even poorer substrates, being ubiquitinated at only approximately 5% of the rate of the iso-2 protein. Comparison of several cytochrome c variants excludes alpha-N-acetylation or the identity of the N-terminal amino acid as the important recognition determinants in these reactions. The results, which include the finding that ferro and ferri-iso-2-cytochromes c are ubiquitinated equally, also are evidence against a simple correlation between ubiquitination efficiency and thermodynamic stability. Rather, the presence of a pair of lysines (Lys4-Lys5) within the relatively unstructured N-terminal extension of the yeast cytochromes c may be responsible for their preferential ubiquitination.

The structures of ubiquitin conjugates of yeast Iso-2-cytochrome c.

Ubiquitin (Ub) conjugates to Saccharomyces cerevisiae iso-2-cytochrome c were formed in vitro in a rabbit reticulocyte extract (Fraction II). In the presence of ubiquitin-aldehyde, used to inhibit ubiquitin-protein isopeptidases in Fraction II, mono-, di-, and triubiquitinated cytochrome c conjugates accumulated in a 1.2:1.0:0.2 molar ratio. CNBr digestions showed that, in all three conjugates, Ub attachment was within the first 73 amino acids of the cytochrome c. For the two most abundant conjugates, this region was further narrowed to the first 30 residues by peptide mapping with Staphylococcus aureus V8 protease. N-terminal protein sequencing identified Lys-13 as the major ubiquitination site in each conjugate. For di- and triubiquitinated iso-2-cytochrome c, this suggested that Ub2 and Ub3 multiubiquitin chains extend from Lys-13. This conclusion was supported by a variation of protein sequencing in which polypeptides recovered after Edman degradation were analyzed to determine at which cycle(s) radiolabeled Ub or Ubn was cleaved from the conjugate. Because of the sensitivity afforded by the use of 125I-Ub in this "stutter-step" sequencing method, minor ubiquitination at Lys-8 also was detected. Thus, Ub2-iso-2-cytochrome c conjugates contain mostly Ub2 at Lys-13 with a small fraction of conjugates having single Ubs on 2 residues, Lys-8 and Lys-13. Similarly, Ub3-iso-2-cytochrome c predominantly has a Ub3 chain on Lys-13, although minor species with combinations of Ub1 and Ub2 distributed on Lys-8 and Lys-13 also may be present. This specificity is discussed in the context of iso-2-cytochrome c structure.