The Royal Society of Chemistry puts
out RSC Med. Chem., and last year they asked David Rees (Astex), Anna
Hirsch (Helmholtz Institute for Pharmaceutical Research Saarland), and me
whether a special themed issue on FBDD would be useful for the community.
Naturally we said yes, and the results have now been published. You can read
our introduction here.
Unlike olden days, when special
issues were bound between covers, this is a virtual special issue, with
papers published over a period of several months. Indeed, we already wrote
about two of them last year: one on combining DNA-encoded libraries (DEL) with
FBLD and one on inhibitors of PRMT5/MTA. (Both of these were also topics at the CHI FBDD meeting earlier this month.) In the next few paragraphs we highlight the rest.
AstraZeneca has been doing FBDD since
2002, and has gained hard-won wisdom, some of which was shared in a 2016 review we
wrote about here. After years of screening, their fragment library had started
to deteriorate, so they rebuilt it entirely, as described by Simon Lucas and
colleagues. Some of the starting fragments came from their previous library,
but they also considered molecules from their larger collection. Rather than
focusing on the rule of three, they developed their own multiparameter
optimization function, “FragScore,” which incorporates logD7.4,
heavy atom count, number of rotatable bonds, and number of hydrogen bond
donors. All compounds were inspected to make sure they would be synthetically tractable, and quality was assessed by SPR, NMR, redox activity, and
solubility. The final set consists of 2741 fragments, with a subset of 1152
maximally diverse and attractive fragments for ligandability assessments or
screening hard-to-make proteins. They also gathered 16,806 near neighbors for
hit follow-up. So far the effort has paid off, with all four of the targets
screened thus far yielding progressible hits. If you’re building or renovating
a fragment library, you should read this paper.
Continuing on the theme of
libraries, Bradley Doak, Martin Scanlon, and colleagues at Monash University
describe their “MicroFrag” library, a set of 91 tiny (5-8 non-hydrogen atom)
compounds similar to MiniFrags and FragLites. A crystallographic screen (at 1 M
concentration!) of the MicroFrag library against the difficult E. coli
target DsbA yielded a 52% hit rate, compared with a 2% hit rate with a
conventional fragment library. Importantly, the MicroFrag screen identified the
two main hot spots previously discovered from the conventional fragment
library, along with ten others that may be less actionable. Interestingly, a
crystallographic screen of 15 organic solvents at even higher concentrations
(50-80%) was less informative: the primary hot spot did not distinguish itself
from others. In the case of MicroFrags, not only did this hotspot bind the
largest number of fragments, but all the molecular interactions seen for larger
fragments were observed.
Fluorine NMR takes advantage of
its own specialized library, the subject of a paper by Chojiro Kojima (Osaka
University), Midori Takimoto-Kamimura (CBI Research Institute) and
collaborators from several institutions. The researchers describe the
construction of a 220-member library divided into pools of 10-21 compounds.
This library was screened against four diverse proteins, yielding between 3 and
16 hits. The three hits against FKBP were characterized in more detail,
including two-dimensional NMR and isothermal titration calorimetry. The
researchers also discuss using 19F STD experiments to determine the
binding mode of bound fragments.
Fluorine is not the only halogen
of interest for library design. We’ve previously described the halogen-enriched
fragment library (HEFLib, here and here), which consists of chlorine, bromine,
and iodine-containing molecules. Frank Boeckler and collaborators at Eberhard
Karls Universität Tübingen and the Max Planck Institute describe screening this
library against the Y220C mutant of p53 in an expansion of work they first
described back in 2012. Of 14 hits identified by thermal shift or STD NMR, ten
confirmed by two-dimensional 1H-15N-HSQC NMR. Four of
these bound in the cleft created by the Y220C oncogenic mutation. Two other
fragments turned out to be covalent binders, though they reacted with more than
one cysteine residue. Although all the fragments have low affinities, they
could potentially serve as starting points for optimization.
An ongoing debate is whether
there is an advantage to screening more “three dimensional” fragments as
opposed to planar aromatic fragments. If your taste tends towards the former,
the synthetic chemistry can get tricky. According to an analysis we highlighted
last year, the piperidine ring is the third most common scaffold found in drugs.
Now, Peter O’Brien (University of York) and an international group of
collaborators report efficient synthetic routes to all 20 cis- and
trans-piperidines substituted with a methyl group and a methyl ester. A virtual
library of 80 compounds in which the secondary amine is capped with simple
substituents such as methyl or acetyl groups was found to be quite shapely,
particularly compared with the disubstituted pyridyl starting materials.
Moreover, the fragments are still reasonably sized, with no more than 15
non-hydrogen atoms and ClogP values < 2.
Machine learning is gaining
prominence everywhere, not least in drug discovery. In 2021 we highlighted an
“autoencoder” designed for constructing fragment libraries biased towards
“privileged” fragments more likely to generate hits. However, the method
required considerable programming savvy. Now Angelo Pugliese (BioAscent) and
collaborators at the Beatson Institute have implemented their model in the
open-source KNIME platform, making it accessible to a wider range of
researchers. As an example they use the method to construct a GPCR-focused
fragment library, with the structures of all the members provided in the
supporting information.
On the subject of fragment
libraries, please make sure to vote in our 6-question poll on library design
(right side of page; you may need to scroll up).
Not all the papers in this
special issue involve library design. Marko Hyvönen, David Spring, and
collaborators at University of Cambridge and National University of Singapore
describe allosteric inhibitors of the kinase CK2α, which has been implicated in
cancer cell survival. We highlighted some of their work against this target in
2017, in which they used fragment linking to find high nanomolar inhibitors of
the enzyme. In the new paper, the researchers describe additional fragment
binders at the so-called αD pocket, distant from the ATP-binding site. Virtual
screening for analogs led to a fragment with mid-micromolar activity in
biochemical and cell assays, and fragment merging led to low micromolar
inhibitors.
This is a nice collection of
papers, and for those of you without easy literature access make sure
to check them out soon: for the next six months all of them are free to read
after free RSC registration. Enjoy!
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