Photodynamic
therapy (PDT) involves use of a photosensitizer, whose
activation with light leads to the production of singlet oxygen (SOS),
generation of reactive oxygen species (ROS), and initiation of associated
cell toxicity. Because a cell’s mitochondria constitute sites
where oxygen levels are high, ROS can be readily produced, and apoptosis
is commonly initiated. Therefore, an ideal PDT agent might be a potent
photosensitizer that could naturally accumulate in mitochondria. Although
a number of mitochondria-targeting moieties, including triphenylphosphine,
guanidinium, and bisguanidium, have been identified, a quantitative
comparison of their efficacies in targeting mitochondria has not been
performed. In this study, we have prepared triphenylphosphine, guanidinium,
and bisguanidium derivatives of the FDA-approved PDT agent verteporfin
(Visudyne, benzoporphyrin derivative-monoacid ring A: BPD-MA) and compared their abilities to induce the intracellular perturbations
common to potent PDT agents. Cellular parameters examined included
subcellular localization of the verteporfin, real-time monitoring
of SOS production, quantitation of reactive oxygen species (ROS) generation,
analysis of mitochondria and chromatin integrity, characterization
of cytoskeletal disruption and evaluation of cytochrome C release as a measure of apoptosis. An analysis of these parameters
demonstrates that the triphenylphosphine derivative (0323) has better mitochondria-targeting efficacy, SOS production, and
mitochondria membrane toxicity than either unmodified verteporfin
or its guanidinium derivatives. Consistent with this potency, 0323 also induced the most prominent mitochondria swelling,
actin depolymerization, pyknosis, and cytochrome C release. We conclude that triphenylphosphine has a better mitochondria-targeting
moiety than guanidinium or bis-guanidinium and those PDT photosensitizers
with improved cytotoxicities can be prepared by conjugating a mitochondria-targeting
moiety to the desired photosensitizer.
