Pro-Pro-Pro

N-degron pathways are proteolytic systems that recognize proteins bearing N-terminal (Nt) degradation signals (degrons) called N-degrons. Our previous work identified Gid4 as a recognition component (N-recognin) of the Saccharomyces cerevisiae proteolytic system termed the proline (Pro)/N-degron pathway. Gid4 is a subunit of the oligomeric glucose-induced degradation (GID) ubiquitin ligase. Gid4 targets proteins through the binding to their Nt-Pro residue. Gid4 is also required for degradation of Nt-Xaa-Pro (Xaa is any amino acid residue) proteins such as Nt-[Ala-Pro]-Aro10 and Nt-[Ser-Pro]-Pck1, with Pro at position 2. Here, we show that specific aminopeptidases function as components of the Pro/N-degron pathway by removing Nt-Ala or Nt-Ser and yielding Nt-Pro, which can be recognized by Gid4-GID. Nt-Ala is removed by the previously uncharacterized aminopeptidase Fra1. The enzymatic activity of Fra1 is shown to be essential for the GID-dependent degradation of Nt-[Ala-Pro]-Aro10. Fra1 can also trim Nt-[Ala-Pro-Pro-Pro] (stopping immediately before the last Pro) and thereby can target for degradation a protein bearing this Nt sequence. Nt-Ser is removed largely by the mitochondrial/cytosolic/nuclear aminopeptidase Icp55. These advances are relevant to eukaryotes from fungi to animals and plants, as Fra1, Icp55, and the GID ubiquitin ligase are conserved in evolution. In addition to discovering the mechanism of targeting of Xaa-Pro proteins, these insights have also expanded the diversity of substrates of the Pro/N-degron pathway.

Naturally occurring cyclic tetrapeptides (CTPs) such as tentoxin (Halloin et al., Plant Physiol 1970, 45, 310-314; Saad, Phytopathology 1970, 60, 415-418), ampicidin (Darkin-Rattray, Proc Natl Acad Sci USA 1996, 93, 13143-13147), HC-toxin (Walton, Proc Natl Acad Sci USA 1987, 84, 8444-8447), and trapoxin (Yoshida and Sugita, Jpn J Cancer Res 1992, 83, 324-328; Itazaki et al., J Antibiot (Tokyo) 1990, 43, 1524-1532) have a wide range of biological activity and potential use ranging from herbicides (Walton, Proc Natl Acad Sci USA 1987, 84, 8444-8447; Judson, J Agric Food Chem 1987, 35, 451-456) to therapeutics (Loiseau, Biopolymers 2003, 69, 363-385) for malaria (Darkin-Rattray, Proc Natl Acad Sci USA 1996, 93, 13143-13147) and cancer (Yoshida and Sugita, Jpn J Cancer Res 1992, 83, 324-328). To elucidate scaffolds that have few low-energy conformations and could serve as semirigid reverse-turn mimetics, the flexibility of CTPs was determined computationally. Four analogs of cyclic tetraproline c[Pro-pro-Pro-pro] with alternating L- and D-prolines, namely c[pro-Pro-pro-NMe-Ala], c[pip-Pro-pip-Pro], c[pro-Pip-pro-Pro], and c[Ala-Pro-pip-Pro] were synthesized and characterized by NOESY NMR. Both molecular mechanics and Density Functional Theory quantum calculations found these head-to-tail CTPs to be constrained to one or two relatively stable conformations. NMR structures, while not always yielding the same lowest energy conformation as expected by in silico predictions, confirmed only one or two highly populated solution conformations for all four peptides examined. c[pro-Pro-pro-NMe-Ala] was shown to have a single all trans-amide bond conformation from both in silico predictions and NMR characterization, and to be a reverse-turn mimetic by overlapping four Calpha-Cbeta bonds with those for approximately 6.5% (Tran, J Comput Aided Mol Des 2005, 19, 551-566) of reverse-turns in the Protein Data Bank PDB with a RMSD of 0.57 A.