New mouse model grants insight into the genetic and molecular mechanisms
underpinning acute myeloid leukaemia
Press
Release 8 April 2008 [PDF]
Leukaemia – cancer of blood or
bone marrow – is caused by mutations that allow defective
blood cells to accumulate and displace healthy blood. To
devise effective therapies it is crucial to know which mutations
cause leukaemia and which cell type gives rise to leukaemic
cells. Researchers from the European Molecular Biology
Laboratory [EMBL] in Italy, the EMBL-European
Bioinformatics Institute, UK, and the Universities of Harvard,
USA, and Lund, Sweden, have now used genetic engineering
to introduce a mutation found in human leukaemia patients
into mice. In the current issue of Cancer Cell they report that
the mutation causes leukaemia by triggering innate genetic
programmes that allow white blood cells to proliferate uncontrollably.
The findings have implications for the way
leukaemia should be treated.
Blood is generated from a small number of multipotent stem
cells that divide, differentiate and give rise to the many different
cell types that make up the blood. At the same time they
also maintain the pool of stem cells through a process called
self-renewal. While differentiating, cells acquire specific properties
and functions, but lose the capacity to self-renew in the
way stem cells do. Mutations interfering with this process and
promoting uncontrolled proliferation of certain blood cells
can lead to leukaemia. Researchers of the group of Claus
Nerlov at EMBL's Mouse Biology Unit now prove that a mutation
in a protein called C/EBPα causes acute myeloid
leukaemia [AML], a type of leukaemia affecting one lineage of
white blood cells, in mice.
"10 percent of all patients suffering from AML have this mutation,
but we could never be sure if it causes the disease. By precisely
reproducing the human mutation in the mouse we now
proved a causative relation," says Peggy Kirstetter, who carried
out the research in Nerlov's lab.
Instead of promoting uncontrolled proliferation of malignant
blood stem cells, often assumed as the cause of leukaemia,
the mutation acts on already partially differentiated cells. It
reprogrammes these cells to self-renew and to produce countless
dysfunctional daughter cells, which displace the healthy
blood cells, eventually leading to the inability to transport oxygen
around in the body.
"This is the first time that non-stem cell myeloid leukaemia
has been generated within a healthy blood system. The findings
will have profound implications for our understanding of
the development and treatment of leukaemias," says Nerlov.
Scientists always thought that the mutation was the crucial
step leading to leukaemia that should be targeted by drugs.
Nerlov and colleagues identified a genetic programme activated
in self-renewing leukemic cells, which is shared with similar
leukaemias caused by other types of mutations. The findings
suggest that the cellular changes that lead to self-renewal are
mutation-independent. To develop drugs with a more general
efficacy it may therefore be more efficient to target the molecules
and pathways shared between different cancer stem cells.
Source Article
P. Kirstetter, M.B. Schuster, O. Bereshchenko. S. Moore, H. Dvinge, E. Kurz, K. Theilgaard-Mönch, R. Månsson, T.Å. Pedersen, T.
Pabst, E. Schrock, B.T. Porse, S.E.W. Jacobsen, P. Bertone, D.G. Tenen & C. Nerlov. Modeling of C/EBPa mutant acute myeloid
leukemia reveals a common expression signature of committed myeloid leukemia initiating cells. Cancer Cell, 8 April 2008
Press Contact
Anna-Lynn Wegener
Press Officer
EMBL Heidelberg
Tel: +49 6221 387-8452
Email: wegener@embl.de
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