Prostate cancer seed cells discovered
30 July 2010
New treatments for prostate cancer could result from the
discovery of a type of cell in prostate tissue that can turn into cancer
cells.
The research, by scientists at the University of California, Los
Angeles (UCLA) Jonsson Comprehensive Cancer Center, proved that
basal cells found in benign prostate tissue can become human
prostate cancer, a finding that goes against current thinking. It
had been widely believed that luminal cells found in the prostate
turned into prostate cancer cells because the resulting malignancies
closely resembled luminal cells.
Dr Owen Witte, a Jonsson Cancer Center member and director of the
UCLA Broad Stem Cell Research Center, said, “Certainly the dominant
thought is that human prostate cancer arose from the luminal cells
because the cancers had more features resembling luminal cells. But
we were able to start with a basal cell and induce human prostate
cancer and now, as we go forward, this gives us a place to look in
understanding the sequence of genetic events that initiates prostate
cancer and defining the cell signalling pathways that may be at work
fuelling the malignancy, helping us to potentially uncover new
targets for therapy.”
The researchers took healthy tissue from prostate biopsies and
separated the cells based on their surface marker expression into
groups of luminal cells and groups of basal cells. Using viral
vectors as vehicles, they then expressed altered genes known to
cause cancer into both cell populations and placed the cells in mice
to see which developed cancer, said Andrew Goldstein, a UCLA
graduate student and first author of the study.
“Because of the widespread belief that luminal cells were the
root of human prostate cancer, it would have been those cells
examined and targeted to treat the disease,” said Goldstein. “This
study tells us that basal cells play an important role in the
prostate cancer development process and should be an additional
focus of targeted therapies.”
In normal prostate tissue, basal cells have a more stem cell-like
function, Goldstein said, meaning they proliferate more to re-grow
human prostate tissue. Luminal cells don’t proliferate as much, but
rather produce major proteins that are important for reproduction.
Something is going awry in the basal cells that results in cancer
and Witte and Goldstein plan to study those cells to uncover the
mechanisms that result in malignancy.
Currently, there is a dearth of knowledge about how prostate
cancer develops to treat it effectively in a targeted way, as
Herceptin targets an out-of-control production of growth factor
receptors in breast cancer cells. The major targeted therapy used
for prostate cancer is directed at the androgen receptor and it is
not always effective, Witte said.
The new human-in-mouse model system developed in the study –
created by taking healthy human prostate tissue that will induce
cancer once it is placed in mice instead of taking malignant tissue
that is already cancerous and implanting it – can now be used to
evaluate the effectiveness of new types of therapeutics. By using
defined genetic events to activate specific signalling pathways,
researchers can more easily compare therapeutic efficacy. The new
model, by deconstructing tissue and then reconstructing it, also
will aid in analyzing how the cells change during cancer
progression.
“There are very few examples of taking benign cells and turning
them into cancer experimentally,” Goldstein said. “We usually study
cancer cell lines created from malignant tumours. This study
resulted in the creation of a novel model system that is highly
adaptable, such that we can test any cellular pathway and its
interactions with other genes known to induce cancer, and we can
start with any type of cell as long as it can be reproducibly
purified.”
In this system, Witte and Goldstein know the “history” of the
cells that became cancer, unlike the cancer cells lines used in
other work.
“We know those cells are malignant, but we don’t know how they
got there,” Goldstein said. “By starting with healthy cells and
turning them into cancer, we can study the cancer development
process. If we understand where the cancer comes from, we may be
able to develop better predictive and diagnostic tools. If we had
better predictive tools, we could look earlier in the process of
cancer development and find markers that are better than the current
PSA test at catching disease early, when it is more treatable.”
Rising PSA levels can indicate the presence of cancer that is
already developing in the prostate. However, now that it is known
that basal cells are one root of human prostate cancers, scientists
can study pre-malignant basal cells and uncover what they express
that the healthy ones don’t, perhaps revealing a new marker for
early detection, Goldstein said. Also, a therapy directed at the
pre-malignant basal cells about to become malignant could provide a
way to prevent the cancer before it becomes dangerous.