We’ve written previously about irreversible covalent
fragment-based lead discovery. The nice thing about irreversible inhibitors is
that they have an infinite no off-rate: once they bind and react with a target,
that protein is permanently out of action. A paper published today in Nature by Keriann Backus, Benjamin
Cravatt, and colleagues at Scripps Research Institute takes this approach to a
whole new level.
The researchers assembled a library of just over 50
fragments containing cysteine-reactive electrophiles, such as chloroacetamides
and acrylamides; the average molecular weight was 284 Da. These were then
screened against human cells or cell lysates using a proteomic approach called
isotopic tandem orthogonal proteolysis-activity based protein profiling
(isoTOP-ABPP). This technique, previously developed by the Cravatt laboratory, uses
mass spectrometry to differentiate contents of treated and untreated cells and identify
specific regions of proteins that are modified.
In all, 758 cysteine residues in 637 different proteins were
found to be modified by at least one of the fragments. These included targets
(such as BTK) with known covalent drugs as well as many proteins with no small
molecule inhibitors. Even more exciting, this set included some particularly
challenging classes of proteins, such as transcription factors and various
adapter and scaffolding proteins. Most proteins only had a single modified
cysteine, and these were not necessarily in the active site (see also here).
Happily, computational docking did a good job of (retrospectively) predicting
the modified cysteine residues.
The fragments themselves ranged significantly in how many
cysteines they modified, from < 0.1% to > 15%, with a median of 3.8%.
Interestingly, the correlation with intrinsic electrophilicity – as measured by
reaction with the small molecule thiol glutathione – was fairly weak. This
suggests that the fragments are modifying proteins based on other properties,
such as specific interactions between fragment and protein.
The initial studies were done using cell lysates at high
(500 µM) fragment concentrations. Follow-up studies in whole cells using 50-200
µM fragment gave similar results, with 64% of the cysteines from the lysate
experiments reacting with the same fragments in cells, even at the lower
concentrations. Interestingly though, four fragment-cysteine interactions were
found only in cells and not in lysates.
One class of proteins you might expect reactive fragments to hit
are cysteine proteases, such as the caspases, and indeed one
chloroacetamide-containing fragment reacted with the active site cysteine of
caspase-8 (CASP8). Surprisingly though, this fragment showed only marginal
activity in an inhibition assay, and subsequent experiments revealed that it is
selective for the inactive zymogen (or proenzyme) form of the protein, thereby
preventing activation. This fragment does not react with the related caspases
2, 3, 6, or 9, though it does hit CASP10. Modest modifications led to a
compound that was also selective for CASP8 over CASP10. These two molecules
were used to show that both CASP8 and CASP10 appear to be essential for
extrinsic apoptosis in primary human T cells, but not in the immortalized
Jurkat T-cell line.
Of course, it will be essential to rigorously characterize
any covalent molecules used as probes. Chloroacetamides are well-known
electrophiles – so well known in fact that they are generally excluded from
screening libraries, including those that helped define the original PAINS
filters. A single digit percentage hit rate means that any given covalent
fragment could easily hit hundreds of proteins. The researchers here do careful control
experiments – such as using an inactive enantiomer and extensive proteomic
analyses – but someone less careful could easily mislead themselves and others.
Done rigorously, though, this is an exciting approach that may well increase
the number of ligandable targets.
Sorry for the pedantic remark, but I think you mean "zero off-rate" rather than "infinite off-rate" for covalent compounds. The lifetime of their effect, assuming they are neutralizing, should be the same as the lifetime of the specific target (due to degradation, etc.).
ReplyDeleteSterically hindered epoxides, like Kyprolis™ (Carfilzomib for Injection), can become valuable drugs. Clearly electrophiles need to be judged on a case-by-case basis, whether as probes or drugs.
ReplyDeleteThis study is attracting notice around the web, see: http://blogs.sciencemag.org/pipeline/archives/2016/06/16/covalent-fragments-yield-a-pile-of-information