posted on 2019-12-23, 09:29authored byFarid
A. Siddiqui, Catharina Alam, Petja Rosenqvist, Mikko Ora, Ahmed Sabt, Ganesh babu Manoharan, Lakshman Bindu, Sunday Okutachi, Marie Catillon, Troy Taylor, Omaima M. Abdelhafez, Harri Lönnberg, Andrew G. Stephen, Anastassios C. Papageorgiou, Pasi Virta, Daniel Abankwa
The trafficking chaperone PDE6D (also referred to as
PDEδ)
has been nominated as a surrogate target for K-Ras4B (hereafter K-Ras).
Arl2-assisted unloading of K-Ras from PDE6D in the perinuclear area
is significant for correct K-Ras localization and therefore activity.
However, the unloading mechanism also leads to the undesired ejection
of PDE6D inhibitors. To counteract ejection, others have recently
optimized inhibitors for picomolar affinities; however, cell penetration
generally seems to remain an issue. To increase resilience against
ejection, we engineered a “chemical spring” into prenyl-binding
pocket inhibitors of PDE6D. Furthermore, cell penetration was improved
by attaching a cell-penetration group, allowing us to arrive at micromolar
in cellulo potencies in the first generation. Our model compounds,
Deltaflexin-1 and -2, selectively disrupt K-Ras, but not H-Ras membrane
organization. This selectivity profile is reflected in the antiproliferative
activity on colorectal and breast cancer cells, as well as the ability
to block stemness traits of lung and breast cancer cells. While our
current model compounds still have a low in vitro potency, we expect
that our modular and simple inhibitor redesign could significantly
advance the development of pharmacologically more potent compounds
against PDE6D and related targets, such as UNC119 in the future.