Phosphatidylserine (PS) biomarker for pancreatic cancer has been identified by scientists.
These findings, being published in the Oct. 4, 2013, online edition of PLOS ONE,
also show that the use of a biotherapy consisting of lysosomal protein,
known as saposin C (SapC), and a phospholipid, known as
dioleoylphosphatidylserine (DOPS), can be combined into tiny cavities,
or nanovesicles, to target and kill pancreatic cancer cells. Lysosomes are membrane-enclosed organelles that contain enzymes capable
of breaking down all types of biological components; phospholipids are a
major components of all cell membranes and form lipid bilayers—or cell
membranes. "Only a small number of promising drugs target pancreatic cancer, which
is the fourth-leading cause of cancer deaths, with a five-year survival
of less than 5 percent," says Xiaoyang Qi, PhD, associate professor of
hematology oncology at UC and lead researcher on the study. "Pancreatic cancer is usually asymptomatic in the early stages, while
frequently invading lymph nodes and the liver, and less often the lungs
and visceral organs. Current treatments, including surgery, chemotherapy
and radiation therapy, have failed to improve long-term survival." Qi says his lab and collaborators previously found that the combination
of two natural cellular components, called SapC-DOPS, which were
assembled and delivered using cancer-selective nanovesicles, caused cell
death in other cancer cell types, including brain, lung, skin,
prostate, blood and breast cancer, while sparing normal cells and
tissues. "We also investigated the efficacy and systemic biodistribution of
SapC-DOPS nanovesicles in animal models and found that it targeted and
halted growth of certain cancer cells and showed no toxic effects in
non-tumor tissues. In this study, we selectively targeted the cell
membrane of pancreatic tumors to see if we could destroy malignant
pancreatic cells without harming normal tissues and cells." Qi says a distinguishing feature of SapC-DOPS is its ability to bind to
phosphatidylseriine (PS), a lipid, which is found on the membrane
surfaces of pancreatic tumor cells. "To evaluate the role of external cell PS, we used PS exposure in human
tumor and non-tumor cells via culture," he says. "We also introduced
these cells into animal models and then injected the SapC-DOPS vesicles
to see if changes were observed. " In some portions of the experiment, the SapC-DOPS nanovesicles were
fluorescently labeled with a dye which could be followed using an
imaging device. To track tumor cells, human pancreatic tumor cells were illuminated with
dye as well, and the same imaging device was used to identify and
monitor them. "We observed that the nanovesicles selectively killed human pancreatic
cancer cells, and the noncancerous, or untransformed cells, remained
unaffected," he says. "This toxic effect correlated to the surface
exposure level of PS on the tumor cells." Qi adds that animals treated with SapC-DOPS showed clear survival benefits and their tumors shrank or disappeared. "Furthermore, using a double-tracking method in live models, we showed
that the nanovesicles were specifically targeted to the tumors," he
says. "These data suggest that the acidic phospholipid PS is a biomarker
for pancreatic cancer that can be effectively targeted for therapy
using cancer-selective SapC-DOPS nanovesicles. "This study provides convincing evidence in support of developing a new
therapeutic approach to pancreatic cancer. This technology is now being
licensed and will hopefully be available in clinical trials soon." "Dr. Qi 's discovery has great potential to be developed into
diagnostics and therapies for pancreatic cancer," says Shuk-mei Ho, PhD,
director of the Cincinnati Cancer Center and Jacob G. Schmidlapp
Professor and Chair of Environmental Health. "This type of research
helps fulfill the mission of the National Cancer Institute to promote
translation of research from the bench to the bedside."
Source: PLOS ONE
No comments:
Post a Comment