Mechanochemical Solvent-Free Catalytic C-H Methylation.

The mechanochemical, solvent-free, highly regioselective, rhodium-catalyzed C-H methylation of (hetero)arenes is reported. The reaction shows excellent functional-group compatibility and is demonstrated to work for the late-stage C-H methylation of biologically active compounds. The method requires no external heating and benefits from considerably shorter reaction times than previous solution-based C-H methylation protocols. Additionally, the mechanochemical approach is shown to enable the efficient synthesis of organometallic complexes that are difficult to generate conventionally.

Integrated multi-omics analyses reveal homology-directed repair pathway as a unique dependency in near-haploid leukemia.

Whole chromosome losses resulting in near-haploid karyotypes are found in a rare subgroup of treatment-refractory acute lymphoblastic leukemia. To systematically dissect the unique physiology and uncover susceptibilities that can be exploited in near-haploid leukemia, we leveraged single-cell RNA-Seq and computational inference of cell cycle stages to pinpoint key differences between near-haploid and diploid leukemia cells. Combining cell cycle stage-specific differential expression with gene essentiality scores from a genome-wide CRISPR-Cas9-mediated knockout screen, we identified the homologous recombination pathway component RAD51B as an essential gene in near-haploid leukemia. DNA damage analyses revealed significantly increased sensitivity of RAD51-mediated repair to RAD51B loss in the G2/M stage of near-haploid cells, suggesting a unique role of RAD51B in the homologous recombination pathway. Elevated G2/M and G1/S checkpoint signaling was part of a RAD51B signature expression program in response to chemotherapy in a xenograft model of human near-haploid B-ALL, and RAD51B and its associated programs were overexpressed in a large panel of near-haploid B-ALL patients. These data highlight a unique genetic dependency on DNA repair machinery in near-haploid leukemia and demarcate RAD51B as a promising candidate for targeted therapy in this treatment-resistant disease.

The use of informatics and automation to remove bottlenecks in drug discovery.

Advances in molecular biology and genetics have furnished more targets than could be reasonably progressed, forcing the pharmaceutical industry to invest in increasing chemistry and screening throughput. Combinatorial chemistry, automation and miniaturization are described as the keys to success. Many pharmaceutical companies assisted by the vendor community have risen to the challenges, delivering more functional and reliable robotics; a number of recent developments are described. These, in turn, have highlighted other deficiencies, for example in target selection, integration and scheduling, and assay and reaction optimization. These areas provide the challenges for the future and have already sparked several new initiatives, a number of which are described.