posted on 2016-02-10, 15:48authored byKasey
J. Clear, Kara M. Harmatys, Douglas R. Rice, William R. Wolter, Mark A. Suckow, Yuzhen Wang, Mary Rusckowski, Bradley D. Smith
Cell
death is involved in many pathological conditions, and there
is a need for clinical and preclinical imaging agents that can target
and report cell death. One of the best known biomarkers of cell death
is exposure of the anionic phospholipid phosphatidylserine (PS) on
the surface of dead and dying cells. Synthetic zinc(II)-bis(dipicolylamine)
(Zn2BDPA) coordination complexes are known to selectively
recognize PS-rich membranes and act as cell death molecular imaging
agents. However, there is a need to improve in vivo imaging performance
by selectively increasing target affinity and decreasing off-target
accumulation. This present study compared the cell death targeting
ability of two new deep-red fluorescent probes containing phenoxide-bridged
Zn2BDPA complexes. One probe was a bivalent version of
the other and associated more strongly with PS-rich liposome membranes.
However, the bivalent probe exhibited self-quenching on the membrane
surface, so the monovalent version produced brighter micrographs of
dead and dying cells in cell culture and also better fluorescence
imaging contrast in two living animal models of cell death (rat implanted
tumor with necrotic core and mouse thymus atrophy). An 111In-labeled radiotracer version of the monovalent probe also exhibited
selective cell death targeting ability in the mouse thymus atrophy
model, with relatively high amounts detected in dead and dying tissue
and low off-target accumulation in nonclearance organs. The in vivo
biodistribution profile is the most favorable yet reported for a Zn2BDPA complex; thus, the monovalent phenoxide-bridged Zn2BDPA scaffold is a promising candidate for further development
as a cell death imaging agent in living subjects.