June 20, 2012 in
Cancer Researchers studying the genetic roots of the most common malignant
childhood brain tumor have discovered missteps in three of the four subtypes of
the cancer that involve genes already targeted for drug development. The most
significant gene alterations are linked to subtypes of medulloblastoma that
currently have the best and worst prognosis. They were among 41 genes
associated for the first time to medulloblastoma by the St. Jude Children's Research Hospital – Washington University
Pediatric Cancer Genome Project. "This study provides new direction for
understanding what drives these tumors and uncovers totally unexpected new drug
targets. There are drugs already in development against these targets aimed at
treating adult cancers and other diseases," said Richard Gilbertson, M.D.,
Ph.D., St. Jude Comprehensive Cancer Center director. Gilbertson and Jinghui
Zhang, Ph.D., an associate member of the St. Jude Department of Computational
Biology, are the study's corresponding authors. The work appears in the June 20
advance online issue of the scientific journal Nature. The results mark
progress toward more targeted therapies against medulloblastoma and other
cancers. While better use of existing drugs and improved supportive care have
helped push long-term survival rates for childhood cancer to about 80 percent,
drug development efforts have largely stalled for more than two decades,
particularly against pediatric brain tumors. "This study is a great
example of the way whole-genome sequencing of cancer patients allows us to dig
deep into the biology of certain tumors and catch a glimpse of their Achilles
heel," said co-author Richard K. Wilson, Ph.D., director of The Genome
Institute at Washington University School of Medicine in St. Louis. "These
results help us better understand the disease and, as a result, we will be able
to more effectively diagnose and treat these kids." This study involved
sequencing the complete normal and cancer genomes of 37 young patients with
medulloblastoma, making it the largest such effort to date involving the
cancer. Researchers then checked tumors from an additional 56 patients for the
same alterations. The genome is the complete set of instructions needed for
human life. It is carried in the DNA found in nearly every cell. The findings
are part of the Pediatric Cancer Genome Project, which launched in 2010 as a
three-year effort to decipher the complete normal and tumor genomes of 600
young cancer patients with some of the most challenging tumors. The endeavor
has already yielded important clues into the origin, spread and treatment
response in childhood cancers of the blood, brain, eye and nervous system. Medulloblastoma
is diagnosed in about 400 U.S.
children and adolescents annually. Their outcome varies widely based on the
subtype they have. While nearly all patients with the wingless (WNT) subtype
survive, just 60 percent of those with subtype 3 medulloblastoma are alive
three years after diagnosis. WNT medulloblastoma is named for the pathway
disrupted in the tumor subtype. This study found a high percentage of patients
with WNT-subtype medulloblastoma had mutations in the DDX3X gene. The
investigators found evidence that mutated DDX3X is required to sustain the
brain cells where WNT subtype tumors develop. The research also found evidence
linking alterations in other genes, including CDH1 and PIK3CA, to the
development and spread of the WNT subtype. "It is particularly exciting
that these genes, or the pathways in which they work, are already the focus of
drug development efforts. This opens up the possibility of using these drugs to
treat medulloblastoma in new ways," said Giles Robinson, M.D., St. Jude
Department of Oncology research associate and one of the study's first authors.
Investigators demonstrated that subtype three and four medulloblastoma often
had alterations in genes that impact cell maturation. The genes carry
instructions for proteins that add or remove the chemical group methyl to the
H3K27 protein. H3K27 is part of the chromatin structure that packages DNA to
fit inside cells. That packaging helps determine if genes are switched on or off.
The addition of methyl to H3K27 permits less specialized cells to keep dividing
and blocks activity of genes that would prompt cells to stop dividing,
differentiate and take on more specialized roles. Some subgroup 3 and 4 tumors
were characterized by a gain in EZH2, which adds methyl to H3K27. EZH2 is also
associated with adult cancers and the focus of ongoing drug development. St.
Jude has begun screening those and other compounds for evidence of
effectiveness against medulloblastoma. In other subtype 3 and 4 tumors a
different gene, KDM6A , was
inactivated by mutations. KDM6A
works to remove methyl groups from H3K27, thus eliminating this gene's function
could keep cells in an immature dividing state. The results suggest the genes
possibly work together to promote medulloblastoma development. The EZH2 and KDM6A alterations were found only in the
subgroup three and four tumors, which also had higher levels of H3K27
methylation than other medulloblastoma subtypes. "With this research we
have 'lifted the lid' on the most aggressive and challenging form of
medulloblastoma, subtype 3, which was really a black box in terms of our
understanding, and revealed a major driver of the disease," Gilbertson
said. The findings add to mounting evidence from the Pediatric Cancer Genome
Project that epigenetic changes play a pivotal role in fueling childhood
cancer. Epigenetic mechanisms can serve as on-off switches, altering gene
activity without changing the makeup of the gene. Such changes can lead to the
unlimited cell growth of cancer. Journal reference: Nature
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