Carl S. Thummel
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Molecular Mechanisms of Hormone
Action in Drosophila
Summary: Carl Thummel's laboratory uses
the fruit fly, Drosophila, as a model system
to study the molecular mechanisms of
hormone signaling.
Small lipophilic hormones, including steroids, retinoids,
and thyroid hormone, play a central role in the
development and physiology of higher organisms. These
signals are transduced by members of the nuclear receptor
superfamily that act as hormone-dependent transcription
factors, reprogramming gene expression within a target
cell. Extensive studies in vertebrate systems have defined
the molecular mechanisms by which nuclear receptors
control promoter activity. In contrast, much less is known
about the events that occur downstream from the
receptor. It remains unclear how hormone-regulated target
genes propagate the hormonal signal to direct appropriate
biological responses during development.
Our laboratory is studying the mechanisms of hormone
action in a simple model system--the fruit fly Drosophila
melanogaster. Pulses of the steroid hormone ecdysone act
as a critical temporal signal for the insect, triggering the
major developmental transitions in the life cycle. These
transitions include molting of the larval cuticle as the
insect grows in size, and metamorphosis--the dramatic
transformation of a crawling larva into a highly mobile and
reproductively active adult fly. Metamorphosis is achieved
by the ecdysone activation of two divergent genetic
programs: the destruction of obsolete larval tissues and
their replacement by developing adult tissues. We are
studying the molecular basis of these two hormone-
regulated pathways.
Quicktime Movie: Drosophila
metamorphosis...
The entire adult fly is carried within the larva in the form of
small clusters of diploid adult progenitor cells. These cells
are dispensable for larval growth and viability but are
called into action at the onset of metamorphosis when
sequential pulses of ecdysone trigger their morphogenesis
and differentiation to form an adult animal. We have
conducted several genetic screens for genes involved in
formation of the adult leg as a model system for
understanding how the hormone directs terminal
differentiation. To date, 17 regions on the autosomes as
HHMI INVESTIGATOR
Carl S.
Thummel
AT HHMI
Genetic Switch for
Maturation Discovered
Hormonal Henchman
Triggers Death
ON THE WEB
The Thummel Lab
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Carl S. Thummel
well as mutations in 16 specific loci have been identified
that are required for this response, defining a central role
for the Rho1 small GTPase in controlling cell shape
changes through effects on the actin cytoskeleton. A long-
term goal in these studies is to identify the link between
the ecdysone signal and Rho1 activation, providing insights
into the molecular mechanisms by which a hormonal signal
can drive tissue morphogenesis.
Unexpectedly, we have discovered that a parallel
morphogenetic program occurs in response to ecdysone at
an earlier stage in development--during embryogenesis.
Ecdysone signaling at this stage is required for coordinated
changes in cell shape that drive major morphogenetic
movements, establishing the body plan of the first instar
larva. Some of the mutations recovered in our genetic
screens for adult leg development also affect these
embryonic morphogenetic events, suggesting that the
hormone acts through a common pathway to drive
morphogenesis at different stages in the life cycle.
As the adult tissues grow and develop during
metamorphosis, they replace larval tissues that are rapidly
destroyed. We have shown that the destruction of the
larval midgut and salivary glands occurs as a steroid-
triggered programmed cell death response. Ecdysone
coordinately induces two death-activator genes, reaper
and hid, immediately before the onset of larval tissue cell
death. Our functional studies indicate that these genes act
together, in a partially redundant manner, to direct the
death of larval tissues, and that premature activation of
this pathway is prevented by the DIAP1 death inhibitor. In
addition, we have shown that the ecdysone-receptor
complex directly induces reaper transcription, providing a
link between the steroid hormone and a programmed cell
death response. We have also identified several key
ecdysone-inducible transcription factors that direct
appropriate reaper and hid expression in doomed salivary
glands, defining a genetic cascade that leads to the
destruction of this tissue. These studies provide insight
into how the larval tissues are destroyed during
metamorphosis, as well as a framework for understanding
how steroid hormones control programmed cell death in
other organisms.
Past studies of metamorphosis have required dissection or
sectioning of animals to follow events that occur
underneath the opaque pupal cuticle. We have
circumvented this problem by expressing green fluorescent
protein (GFP) in specific tissues and following, in time-
lapse movies, the development of these tissues in living
animals. This method has provided a foundation for open-
ended genetic screens to dissect the molecular
mechanisms of steroid-triggered programmed cell death.
We are screening for mutants that show normal responses
to ecdysone during development but retain persistent
salivary glands that express GFP. A pilot screen identified
eight genes in this pathway, including several transcription
factors and signaling molecules. We are characterizing
several of these loci in more detail, as well as conducting
an open-ended EMS screen to saturate the third
chromosome for genes in this pathway. This approach uses
the animal for perhaps its greatest strength, as a genetic
tool to unravel complex biological pathways that are likely
to be conserved in other organisms--in this case, providing
a foundation for understanding the molecular basis of
steroid-triggered programmed cell death.
The Drosophila genome encodes 18 canonical members of
the nuclear receptor superfamily, of which only one (EcR)
has a known ligand that binds to its ligand-binding domain
(LBD) and activates target gene transcription. This
observation raises the question of whether the remaining
orphan receptors have ligands and, if so, how these novel
http://www.hhmi.org/research/investigators/thummel.html (2 z 3) [6.10.2005 14:30:01]