Fragment growing in three dimensions made easy

Nearly a decade ago we highlighted a paper from Astex that exhorted chemists to develop new synthetic methodologies useful for fragment-based drug discovery. Peter O’Brien has taken on the challenge, and he and his collaborators at University of York and AstraZeneca report their progress in a recent (open-access) J. Am. Chem. Soc. paper.

 

The O’Brien group has previously published synthetic routes to shapely fragments, which we wrote about here. These could be useful for expanding fragment collections, but that happens infrequently. The new paper focuses on the far more common challenge of what to do when you have a fragment hit.

 

The idea was to create a “modular synthetic platform for the elaboration of fragments in three dimensions.” The researchers designed a set of bifunctional building blocks that could be coupled to existing fragments. The two functionalities were N-methyliminodiacetic acid boronate (BMIDA) and a Boc-protected amine. The amine is a versatile handle for multiple types of chemistry, while the BMIDA moiety is particularly useful for Suzuki-Miyaura cross-coupling. (Indeed, two separate groups of researchers had previously built libraries suited for cross-coupling using halogen-containing fragments, as we discussed here.)

  

For the new building blocks, the researchers considered azetidines, pyrrolidines, and piperidines with fused or spiro-cyclopropyl groups. These are rigid “three-dimensional” units, and the relative locations of the BMIDA group and the amine could provide very different distances and vectors. After modeling 27 possibilities, the researchers chose nine building blocks based on diversity and predicted ease of synthesis. These were synthesized on gram scale, and all nine are now commercially available.

 

To demonstrate that the building blocks would be generally synthetically useful, the researchers coupled them to a variety of (hetero)aryl bromides, with yields ranging from 10-90%, and most >60%. The Boc group was then deprotected and the crude amine was used in a variety of successful reactions.

 

The building blocks were each also coupled to 5-bromopyrimidine, the Boc-group was deprotected, and the free amines were capped as methanesulfonamides. Small molecule crystallography of the resulting compounds confirmed modeling results that the two vectors had a wide range of orientations and were separated by 1.5-4.4 Å. Moreover, most compounds were rule-of-three compliant, had good measured aqueous solubility, and were even stable in human liver microsomes and rat hepatocytes.

 

As a use-case, the researchers considered the approved drug ritlecitinib, an irreversible JAK3 inhibitor. They imagined that its pyrrolopyrimidine moiety was a fragment hit, and then virtually combined it with their nine scaffolds, each functionalized with an acrylamide. These were then virtually docked, and the best two were synthesized and tested. Compound 96 was quite potent, albeit less so than ritlecitinib.

The question of whether three-dimensionality is desirable as a design feature remains unproven, as we noted recently. However, whether the high Fsp³ of the nine new scaffolds is itself a selling point, they do provide new vectors for fragment growing, and their synthetic enablement justifies including them at least in virtual campaigns.