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Cascade which Activates Cell Protection Programs
(Graphic: Clemens Schmitt)
Cells have two different protection programs to safeguard them from getting out of control under stress and from dividing without stopping and developing cancer. Until now, researchers assumed that these protective systems were prompted separately from each other. Now for the first time, using an animal model for lymphoma, cancer researchers of the Max Delbrück Center (MDC) Berlin-Buch and the Charité – University Hospital Berlin in Germany have shown that these two protection programs work together through an interaction with normal immune cells to prevent tumors. The findings of Dr. Maurice Reimann and his colleagues in the research group led by Professor Clemens Schmitt may be of fundamental importance in the fight against cancer (Cancer Cell, Vol. 17, Issue 3, 16 March 2010, pp. 262-272; DOI 10.1016/j.ccr.2009.12.043)*.
Researchers
have known for some time that – paradoxically – oncogenes themselves can activate
these cell protection programs in an early developmental stage of the disease. This
may explain why some tumors take decades to develop until the outbreak of the
disease. The Myc oncogene triggers apoptosis (programmed cell death), inducing
damaged cells to commit suicide in order to protect the organism as a whole. By
means of chemotherapy, physicians activate this protection program to treat
cancer.
The second
protection program – not as well understood as apoptosis – is senescence
(biological aging). This program is triggered by another oncogene, the ras gene. Senescence stops the cell
cycle, and the cell can no longer divide. But in contrast to apoptosis the cell
continues to live and is still metabolically active. Professor Schmitt, physician
at Charité University Hospital
and research group leader at the MDC, was able to show on an animal model for
lymphoma that senescence can block the development of early-stage malignant
tumors.
Myc oncogene triggers cascade to activate both protection
programs
Now, for
the first time, Dr. Reimann, Dr. Soyoung Lee, Dr. Christoph Loddenkemper, Dr. Jan
R. Dörr, Dr. Vedrana Tabor and Professor Schmitt have provided evidence that
the Myc oncogene plays a key role in the activation of both protection programs
– without the presence of the ras oncogene.
“What is remarkable about this finding is that an oncogene can first trigger
apoptosis and interact with the tumor stroma – the tissue that surrounds the
tumor which also contains healthy cells – and with the immune system and then is
able to switch on signals which lead to tumor senescence,” Professor Schmitt
said, summarizing how the interaction works.
“Fundamental significance”
According
to the researchers’ findings, the cascade occurs as follows: First the Myc
oncogene triggers apoptosis in the lymphoma cells. The dying, apoptotic cells attract
macrophages of the immune system, which devour and dispose of the dead lymphoma
cells. The thus activated macrophages in turn secrete messenger molecules (cytokines),
including the cytokine TGF-beta. It can block the growth of cancer cells in the
early stage of a tumor disease. The MDC and Charité researchers discovered that
the cytokines in the tumor cells that had escaped apoptosis switch on the
senescence program and suppress the cancer cells.
“Our
findings promise to have fundamental significance for elucidating the pathogenesis
not only of lymphoma cancers, but of cancer in general. Our results indicate that
senescence triggered by the immune system’s messenger molecules may be a
further important active principle, apart from apoptosis induced by
chemotherapy.”
At present
the researchers in Professor Schmitt’s group are focusing intensively on
chemotherapy-mediated senescence. “If by inducing senescence we could obtain a
sustained suppression of the cancer cells we can no longer destroy, this would
mean exciting new possibilities for therapy,” Professor Schmitt said.
*Tumor Stroma-Derived TGF-b Limits Myc-Driven Lymphomagenesis via
Suv39h1-Dependent Senescence
Maurice Reimann1,6,
Soyoung Lee1,2,6, Christoph Loddenkemper3,6, Jan R. Dörr1,6,
Vedrana Tabor2,6, Peter Aichele4, Harald Stein3,
Bernd Dörken1,2, Thomas Jenuwein5, and Clemens A. Schmitt1,2
1Charité - Universitätsmedizin Berlin/Molekulares
Krebsforschungszentrum der Charité - MKFZ, Berlin, Germany
2Max-Delbrück-Center for Molecular Medicine,
Berlin, Germany
3Charité - Universitätsmedizin Berlin/Department of Pathology, Campus
Benjamin Franklin, Berlin, Germany
4University Hospital Freiburg, Department
of Immunology, 79104 Freiburg,
Germany
5Research Institute of Molecular Pathology, Vienna,
Austria (present address:
Max-Planck-Institute of Immunology, Freiburg,
Germany)
6These authors contributed equally to this work
Correspondence:
clemens.schmitt@charite.de. Fon +49-30-450 553 687; Fax +49-30-450 553 986