Covalent drugs are a thing these days: as long as you can
get selectivity, there’s nothing like a covalent bond to juice up affinity for
a target. Screening for covalent fragments is thus a reasonable approach, and multiple
researchers have assembled libraries of fragments containing either
irreversible or reversible covalent “warheads”. The latest example, by Marion
Lanier, Mark Hixon, and collaborators at Takeda, appears in J. Med. Chem.
Boronic acids can form reversible covalent bonds with the
side chains of serines or threonines in proteins, with a predilection for the
highly reactive active-site residues found in hydrolytic enzymes. Indeed, three
approved drugs – bortezomib, tavaborole, and ixazomib – contain boronic acids.
When medicinal chemists think of boronic acids, they
probably think of them as reagents for the Suzuki coupling, a useful method for
forming carbon-carbon bonds. Because the reaction is so popular, some 6000
boronic acids are commercially available, many of them fragment-sized. Thus,
the researchers assembled a set of 650 into a boronic acid library (BAL).
To determine whether this BAL would be useful, the
researchers screened it against autotaxin, a phospholipase with anti-cancer and
anti-inflammatory potential. Fragments were tested at 100 µM in a functional
assay, with hits retested in 11-point dose-response curves. This yielded a
whopping 51 molecules with IC50 values better than 10 µM, some as good as
200 nM.
The researchers also screened autotaxin against a set of
1750 non-boronic acid containing fragments, this time at 500 µM. Not
surprisingly, hits tended to be significantly weaker despite the similar sizes
of the fragments. The BAL fragments had average ligand efficiencies of 0.61
kcal mol-1 per heavy atom, while the conventional fragments averaged
a lower but still respectable 0.41. Some of the BAL fragments were also
crystallized bound to autotaxin, revealing that they do in fact form bonds with
the catalytic threonine.
This is a nice paper, though I do wish that the researchers had tried to
calculate the inherent reactivities of the boronic acids to determine how these
differences affected their affinities for the protein, as has been done for other
warheads such as aryl acrylamides. Also, it would be interesting to see how a
docking program such as DOCKovalent performs against this target with the same
set of fragments. Hopefully we’ll see these questions addressed in the future.
In the meantime, expect to see commercial vendors start offering libraries of boronic
acid fragments.
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3 comments:
Hi Dan, it’s not straightforward to calculate (or even define) ‘inherent reactivity’ in a meaningful way for warheads that form covalent bonds with targets because non-covalent interactions between target and ligand can potentially influence both on-rate and affinity. I believe that it can be useful to label warheads as ‘reversible’ or ‘irreversible’ but it’s important to bear in mind that optimization of fragment hit affinity is likely to lead to a decrease in off-rate.
Hi Pete,
Actually, it's quite common to assess the inherent reactivity of warheads using a common nucleophile. In the case of thiol-reactive warheads this is usually glutathione or some other cysteine derivative. The Amgen paper I mentioned above does this for aryl acrylamides, and the researchers found a linear Hammett correlation. They also got good agreement between experimental results and density functional theory calculations.
Another paper from Pfizer looks at a more diverse set of irreversible warheads.
The reason this is important is that if you have the same fragment with different warheads, and the warheads differ significantly in reactivity, you may think you are optimizing molecular complementarity when in fact you are just tweaking reactivity. Alexander Statsyuk has a nice discussion of this, covered here.
All of this also holds true for reversible covalent inhibitors, as discussed here.
You are absolutely correct that "non-covalent interactions between target and ligand can potentially influence both on-rate and affinity", and these interactions can in fact be improved during lead optimization.
Thanks for the review Dan,
In fact, as you speculated, now several chemical suppliers offer boronic acid fragment libraries
Enamine - BAF-640-X-50 https://enamine.net/index.php?option=com_content&view=article&id=614&Itemid=1110
Key Organics - Key Organics have over 500 in-stock boronic acids available in small mg amounts for Fragment/HTS screening https://www.keyorganics.net/services/bionet-products/fragment-libraries/
On the topic of inherent reactivity of boronic acids - water, by its abundance, typically out competes non-specific hydroxyls. Remember, these covenant interactions are reversible.
A target with a complementary binding pocket, a serine or threonine with a hot hydroxyl and an oxyanion hole out-competes water
Some bidentate hyroxyls such as pinenediol are tough for water to out-compete
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