Embryonic ecdysone-induced gene expression and progression of organ morphogenesis
Sammanfattning
The formation of an epithelial organ requires a set of organ-specific gene programs that instruct parallel and successive developmental events. Still, it is unclear what are the core regulatory programs and how such programs are timely coordinated within the organ. We use mainly the Drosophila trachea (respiratory system) as a model to understand epithelial organ development. The trachea is a network of epithelial tubes, and its morphology is sensitive to mutations in genes whose products participate in consecutive steps of branching morphogenesis and tube size maturation. In paper I, we identified two gene functions required for tracheal tube elongation. We show that tracheal cells, at a specific time in development, acquire an ability to elongate that is mediated by a protein involved in actin organization. A luminal matrix holds back this elongation, and temporal expression of an anion channel appears required to modify the luminal matrix and thereby permit a controlled extent of elongation. In paper II, we show that a mucin-like protein is temporally expressed in the trachea and is required for tube elongation. The protein also drives diameter expansion of the hindgut, where it fills the growing lumen and appears to physically dilate the tube. The work demonstrates that regulated expression of a single protein can model epithelial tube diameter. In papers III and IV, we focused on the temporal regulation of tracheal gene expression, and uncovered an important function for the mid-embryonic ecdysone hormone pulse in progression of organ development. In paper III, we analysed the mechanism of embryonic ecdysone signalling and found that the hormone causes pan-embryonic activation of Ecdysone Receptor (EcR). EcR acts tissue-autonomously together with Ultraspiracle to promote concurrent progression of organ development. In paper IV, we show that ecdysone, via EcR and a downstream cascade of gene regulators is needed to advance parallel tracheal-specific gene programs. Together, the results reveal novel gene functions during epithelial tube formation, and show that correct temporal unfolding of the tracheal gene network relies on gene-regulatory input from an external cue in form of a hormone pulse.
Delarbeten
I) Tång E.*, Byri S.*, Chavoshi T.M., Norum M. and Uv A.
A gene program that regulates tube length in the Drosophila trachea
Manuscript II) Zulfaqhar A. S., Bougé A-L*, Chavoshi T.M.*, Byri S., Tång E., Bouhin H., Härd I., Uv A.
A luminal mucin-like protein promotes diameter expansion of the Drosophila hindgut.
Submitted manuscript. * Joint second authors III) Chavoshi T.M., Moussian B., Uv A.
Tissue-autonomous EcR functions are required for concurrent organ morphogenesis in the Drosophila embryo
Mechanisms of Development 127 (2010) 308-319
::PMID::20093179 IV) Chavoshi T.M. and Uv A.
Embryonic ecdysone is required for progression of tracheal gene programs in Drosophila
Manuscript
Examinationsnivå
Doctor of Philosophy (Medicine)
Universitet
University of Gothenburg. Sahlgrenska Academy
Institution
Institute of Biomedicine. Department of Medical Genetics
Disputation
klockan 13:00, Arvid Carlsson
Datum för disputation
2011-06-01
E-post
tina.chavoshi@gu.se
Datum
2011-05-26Författare
Chavoshi Alizadeh, Tina Mitra
Nyckelord
Drosophila
trachea
hindgut
tubulogenesis
luminal matrix
ecdysteroid
EcR:Usp
dorsal closure
Publikationstyp
Doctoral thesis
ISBN
978-91-628-8279-2
Språk
eng