Screening ubiquitin specific protease activities using chemically synthesized ubiquitin and ubiquitinated peptides.

Ubiquitin, a 76 amino acid protein, is a key component that contributes to cellular protein homeostasis. The specificity of this modification is due to a series of enzymes: ligases, attaching the ubiquitin to a lysine, and deubiquitinases, which remove it. More than a hundred of such proteins are implicated in the regulation of protein turnover. Their specificities are only partially understood. We chemically synthesized ubiquitin, attached it to lysines belonging to the protein sequences known to be ubiquitinated. We chose the model protein "murine double minute 2" (mdm2), a ubiquitin ligase, itself ubiquitinated and deubiquitinated. We folded the ubiquitinated peptides and checked their tridimensional conformation. We assessed the use of these substrates with a series of fifteen deubiquitinases to show the potentiality of such an enzymological technique. By manipulating the sequence of the peptide on which ubiquitin is attached, we were able to detect differences in the enzyme/substrate recognition, and to determine that these differences are deubiquitinase-dependent. This approach could be used to understand the substrate/protein relationship between the protagonists of this reaction. The methodology could be customized for a given substrate and used to advance our understanding of the key amino acids responsible for the deubiquitinase specificities.

Heating and microwave assisted SPPS of C-terminal acid peptides on trityl resin: the truth behind the yield.

Despite correct purity of crude peptides prepared on trityl resin by Fmoc/tBu microwave assisted solid phase peptide synthesis, surprisingly, lower yields than those expected were obtained while preparing C-terminal acid peptides. This could be explained by cyclization/cleavage through diketopiperazine formation during the second amino acid deprotection and third amino acid coupling. However, we provide here evidence that this is not the case and that this yield loss was due to high temperature promoted hydrolysis of the 2-chlorotrityl ester, yielding premature cleavage of the C-terminal acid peptides.

Recycling the versatile Pipecolic linker.

The Pipecolic linker is a new highly versatile handle which immobilizes on solid support through a carboxylic acid function a wide range of amines, alcohols, and hydrazines. The anchoring step on pipecolic resin is very easy and efficient, and compounds are released with high purities upon acidic treatment. During this treatment, an oxazolonium intermediate is hydrolyzed, yielding the cleavage of ester or amide bond and the release of free carboxylic acid of the starting linker. In this study, we report the possibility of recycling the pipecolic resin after the use of several trifluoroacetic acid (TFA) cleavage cocktails. We demonstrate that it can be reused up to five times without significant loading decrease.