Development of fluorescent peptide substrates and assays for the key autophagy-initiating cysteine protease enzyme, ATG4B.

An efficient assay for monitoring the activity of the key autophagy-initiating enzyme ATG4B based on a small peptide substrate has been developed. A number of putative small fluorogenic peptide substrates were prepared and evaluated and optimized compounds showed reasonable rates of cleavage but required high enzyme concentrations which limited their value. A modified peptide substrate incorporating a less sterically demanding self-immolative element was designed and synthesized and was shown to have enhanced properties useful for evaluating inhibitors of ATG4B. Substrate cleavage was readily monitored and was linear for up to 4h but enzyme concentrations of about ten-fold higher were required compared to assays using protein substrate LC3 or analogs thereof (such as FRET-LC3). Several known inhibitors of ATG4B were evaluated using the small peptide substrate and gave IC50 values 3-7 fold higher than previously obtained values using the FRET-LC3 substrate.

Development of fluorescent substrates and assays for the key autophagy-related cysteine protease enzyme, ATG4B.

The cysteine protease ATG4B plays a role in key steps of the autophagy process and is of interest as a potential therapeutic target. At an early step, ATG4B cleaves proLC3 isoforms to form LC3-I for subsequent lipidation to form LC3-II and autophagosome membrane insertion. ATG4B also cleaves phosphatidylethanolamine (PE) from LC3-II to regenerate LC3-I, enabling its recycling for further membrane biogenesis. Here, we report several novel assays for monitoring the enzymatic activity of ATG4B. An assay based on mass spectrometric analysis and quantification of cleavage of the substrate protein LC3-B was developed and, while useful for mechanistic studies, was not suitable for high throughput screening (HTS). A doubly fluorescent fluorescence resonance energy transfer (FRET) ligand YFP-LC3B-EmGFP (FRET-LC3) was constructed and shown to be an excellent substrate for ATG4B with rates of cleavage similar to that for LC3B itself. A HTS assay to identify candidate inhibitors of ATG4B utilizing FRET-LC3 as a substrate was developed and validated with a satisfactory Z' factor and high signal-to-noise ratio suitable for screening small molecule libraries. Pilot screens of the 1,280-member library of pharmacologically active compounds (LOPAC(™)) and a 3,481-member library of known drugs (KD2) gave hit rates of 0.6% and 0.5% respectively, and subsequent titrations confirmed ATG4B inhibitory activity for three compounds, both in the FRET and mass spectrometry assays. The FRET- and mass spectrometry-based assays we have developed will allow for both HTS for inhibitors of ATG4B and mechanistic approaches to study inhibition of a major component of the autophagy pathway.