This is a new experimental
protocol that will be certainly applied to other variations on the same
problem. It allows us to see the effect
of a test protein in real time which is a rather uncommon occurrence I am sure.
It also shows just how much
progress we have made on dealing with this topic.
If we could learn to simply
suppress the aggressive phase of cancer, we can turn most cancers into chronic conditions
in which a portion of a large tumor is merely removed every few years as often
happens with other annoying growths. It
is not a cure but it certainly preserves the life of the patient.
Researchers Engineer a Switch to Tame Aggressive Cancers
ScienceDaily (Jan. 20, 2012) —
When cancers become aggressive and spread they are the most deadly.
Unfortunately, little is known about how to stop this development. A new
imaging platform developed by Lawson Health Research Institute's Drs. Ann
Chambers and John Lewis is providing insight into just that -- the exact moment
when cancer cells turn deadly.
Certain proteins, such as E-cadherin, are important for the maintenance
of normal tissue structure. When tumors become more aggressive, they often lose
E-cadherin, resulting in dramatic changes to their structure, function and
ability to spread. But when cancer cells are forced to express E-cadherin,
research suggests they behave less aggressively and revert back to normal.
Unfortunately, limitations in our ability to directly monitor these effects
have made it difficult for scientists to assess the full impact.
In a new study in PLoS ONE, Drs. Chambers and Lewis reveal a new
imaging platform that can modulate and monitor how the effects of a particular
protein can affect the entire tumor in real-time. The approach uses a
shell-less chick embryo model implanted with human cancer cells. "This
accessible set-up allows us to introduce E-cadherin directly into the tumor
environment, where it has immediate and dramatic effects," says Dr. Hon
Leong, the lead author of this study. "Using 3D time-lapse imaging, the
impact of this protein can be visualized and the subsequent effects on cancer
cell structure, function and aggressiveness can be monitored in real time for
up to 48 hours."
Drs. Chambers and Lewis hope this approach will allow scientists to
determine how proteins like E-cadherin can exert their tumor-suppressive
properties on the deadly spread of cancer. Through further research, they
believe their approach could provide valuable information to help moderate
aggressive cancers and improve patient outcomes.
"The insights afforded by this technology will help scientists
revisit other proteins thought to be important in metastatic spread, but whose
modes of action are not understood, and to watch how they actually function in
real-time," says Dr. Chambers.
"Although genomics technology has revealed many new proteins that
could force cancers to 'switch' back to their less aggressive state, these new
targets have not yet been validated in preclinical models like mice because it
is difficult to determine the molecular effects on each individual cancer
cell," Dr. Lewis says. "This novel platform allows us to produce
compelling photographic evidence of how these anti-cancer proteins work and gain
insight into their mechanisms."
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