Structural basis for substrate recognition, ligation and activation by a hyperactive Asn peptide ligase from Viola yedoensis

Peptide asparaginyl ligases (PALs) belong to a limited class of enzymes from cyclotide-producing plants, that perform site-specific ligation reactions after a target peptide Asx (Asn/Asp) binds to the ligase active site. How PALs specifically recognize their polypeptide substrates has remained elusive especially at the prime binding side of the enzyme. Here we captured VyPAL2, a catalytically efficient PAL from Viola yedoensis, in an activated state, with and without a bound substrate. The bound structure shows one ligase with the N-terminal polypeptide tail from another ligase molecule trapped at its active site, revealing how Asx inserts in the enzyme's S1 pocket and why a hydrophobic residue is required at the substrate P2' position. Beside illustrating the role played by P1 and P2' residues as primary anchors for the enzyme reaction, these results provide a mechanistic explanation for the role of the "Gatekeeper" residue at the surface of the S2 pocket, in shifting the non-prime portion of the substrate and, as a result, the activity towards either ligation or hydrolysis. These results detail the molecular events that occur during proenzyme maturation in the plant vacuolar compartment, suggest a mechanism for ligation, and will inform the design of peptide ligases with tailored specificities.

Toxoplasma Cathepsin Protease B and Aspartyl Protease 1 play recessive roles in endolysosomal protein digestion during infection

ABSTRACTThe lysosome-like vacuolar compartment (VAC) is a major site of proteolysis in the intracellular parasite Toxoplasma gondii. Previous studies have shown that genetic ablation of a VAC-residing cysteine protease, cathepsin protease L (CPL), resulted in accumulation of undigested protein in the VAC and loss of parasite viability during the chronic stage of infection. However, since the maturation of another VAC localizing protease, cathepsin protease B (CPB), is dependent on CPL, it remained unknown whether these defects result directly from ablation of CPL or indirectly from a lack of CPB maturation. Likewise, although a previously described cathepsin D-like aspartyl protease 1 (ASP1) could also play a role in proteolysis, its definitive residence and function in the Toxoplasma endolysosomal system was not well defined. Here we demonstrate that CPB is not necessary for protein turnover in the VAC and that CPB deficient parasites have normal growth and viability in both the acute and chronic stages of infection. We also show that ASP1 depends on CPL for correct maturation and it resides in the T. gondii VAC where, similar to CPB, it plays a dispensable role in protein digestion. Taken together with previous work, our findings suggest that CPL is the dominant protease in a hierarchy of proteolytic enzymes within the VAC. This unusual lack of redundancy for CPL in T. gondii makes it a single exploitable target for disrupting chronic toxoplasmosis.

Trafficking modulator TENin1 inhibits endocytosis, causes endomembrane protein accumulation at the pre-vacuolar compartment and impairs gravitropic response in Arabidopsis thaliana

In the present study a detailed characterization of a small molecule inhibitor of protein trafficking and gravitropic response is described. We also identified two Arabidopsis thaliana ecotypes that display resistance to this compound. The ecotypes and chemical provide useful tool to investigate protein trafficking.

Cell-free reconstitution of vacuole membrane fragmentation reveals regulation of vacuole size and number by TORC1

Size and copy number of organelles are influenced by an equilibrium of membrane fusion and fission. We studied this equilibrium on vacuoles—the lysosomes of yeast. Vacuole fusion can readily be reconstituted and quantified in vitro, but it had not been possible to study fission of the organelle in a similar way. Here we present a cell-free system that reconstitutes fragmentation of purified yeast vacuoles (lysosomes) into smaller vesicles. Fragmentation in vitro reproduces physiological aspects. It requires the dynamin-like GTPase Vps1p, V-ATPase pump activity, cytosolic proteins, and ATP and GTP hydrolysis. We used the in vitro system to show that the vacuole-associated TOR complex 1 (TORC1) stimulates vacuole fragmentation but not the opposing reaction of vacuole fusion. Under nutrient restriction, TORC1 is inactivated, and the continuing fusion activity then dominates the fusion/fission equilibrium, decreasing the copy number and increasing the volume of the vacuolar compartment. This result can explain why nutrient restriction not only induces autophagy and a massive buildup of vacuolar/lysosomal hydrolases, but also leads to a concomitant increase in volume of the vacuolar compartment by coalescence of the organelles into a single large compartment.