September 18, 2003
Zebrafish Studies Provide Insight into Blood-Cell Formation
Researchers tracking down the cause of anemia in mutant zebrafish embryos have discovered a protein that guides the creation of new blood cells.
The researchers, led by Howard Hughes Medical Institute (HHMI) investigator
Leonard I. Zon
and HHMI associate Alan J. Davidson at Children's Hospital, Boston, published their findings in the September 18, 2003, issue of the journal
Nature
. Zon and Davidson collaborated with researchers at Dana-Farber Cancer Institute, the Whitehead Institute for Biomedical Research at MIT, the Max Planck Institute for Developmental Biology in Germany and the University of Rochester.
“So it seems as if there are specific
hox
genes that actually regulate blood cells, and others that arent so important.”
Leonard I. Zon
In the initial discovery that sparked the study, researchers observed that a zebrafish embryo with a mutation called
kugelig
(
kgg
) developed a lethal anemia in addition to having a malformed tail.
“After evaluating the
kgg
mutant for blood-forming stem cells, we realized that its mutation seemed to affect the genetic program for creating blood cells,” said Zon. “The program for making blood vessels looked perfectly normal, but there seemed to be some specificity there that made us want to explore this mutant further.” Stem cells are immature progenitor cells that give rise to more specialized cells that form tissues and organs.
The researchers traced the genetic defect in the
kgg
mutant zebrafish to a gene called
cdx4
. This gene is a member of a family of “
caudal
” genes that other researchers had shown were regulators of a key suite of genes called
hox
genes that control development.
Hox
genes are known to govern the pattern of body formation in animals, but “nobody had thought about this combination of
caudal
genes and
hox
genes as regulating stem cells, and in particular blood stem cells,” said Zon.
When the researchers eliminated
cdx4
from normal zebrafish, they observed the same defects that they saw in the
kgg
mutants. Conversely, injecting the normal
cdx4
gene into
kgg
mutants “rescued” them from the defect.
To see whether the
cdx4
gene actually controlled
hox
genes, the researchers overexpressed various members of the
hox
gene family into the mutant zebrafish. The researchers found that some
hox
genes, but not others, restored blood formation in the
kgg
zebrafish.
“So it seems as if there are specific
hox
genes that actually regulate blood cells, and others that aren't so important,” said Zon. “By doing those sets of experiments, we were able to say definitively that
cdx4
controlled some
hox
genes, and that it regulated blood development.”
In further tests to define the regulatory role of
cdx4
, the researchers overexpressed
cdx4
in normal zebrafish. “We found that the middle part of the embryo, or mesoderm, which does not normally consist of blood cells, converted to blood cells,” said Zon. “So, we demonstrated that overexpressing
cdx4
changed
hox
gene expression, and also altered the fate of this mesoderm to actually become blood-forming,” he said.
“That was a real surprise, because for years we had been looking for some regulatory factor that would actually change the middle part of the embryo into blood, altering its fate, but we hadn't been able to find such a component,” he said.
To extend their findings to mammals, the researchers studied the
Cdx4/Hox
machinery in mouse embryonic blood-forming stem cells. They found that overexpressing
Cdx4
in the mouse embryonic stem cells both altered the expression of mouse
Hox
genes and caused a pronounced expansion in the numbers of hematopoietic progenitor cells.
According to Zon, the group's findings not only increase understanding of the embryonic blood-forming machinery, but they could also help reveal how it can go awry in human leukemias.
“We know that a human cousin of
cdx4
, called
CDX2
, produces leukemia when it fuses to a gene called
TEL
,” said Zon. He and his colleagues believe that this fusion disrupts the normal
HOX
-regulating function of the cell and transforms it into a leukemic cell. Similarly, he said, the gene
MLL
, whose involvement in abnormal fusion proteins has been implicated in leukemia, might also be related to the
cdx4/hox
signaling machinery.
“So, we believe there is a subset of leukemias that are caused by
MLL
fusions,
CDX
fusions, and even
HOX
fusions,” said Zon. “Now, with this zebrafish system, we can really begin to understand the role that the specific
hox
and
cdx
genes play during normal hematopoietic development. We can introduce the genes one by one into the
kgg
mutant and test whether and how they participate in such development.”
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