Forkhead Genes in Mammalian Development
Abstract
This thesis concerns aspects of Forkhead gene biology and it’s relation to mammalian
development. Genes from three subclasses are discussed, Foxj3, Foxf1 and f2, and Foxe3.
We have identified and characterized a novel forkhead gene, FoxJ3, that is expressed in
neuroectoderm, neural crest and mytome, suggesting possible function in the nervous system
and muscle. The myotome, which will develop into muscle, along with the mesenchyme lining
the intestinal gut, originates from embryonic mesoderm.
Forkhead factors, Foxf1 and Foxf2, are expressed in intestinal mesenchyme derived from
splanchnic mesoderm. Foxf function is important for patterning of the gut tube. Removal of
Foxf results in a range of intestinal phenotypes, such as agangliosis and megacolon. Both Foxf1
and Foxf2 are regulated by hedgehog signaling, Foxf mutants display mesenchymal increase in
Wnt5a expression, and reduction in Bmp4 expression. The extracellular matrix is depleted of
collagens, and together with altered paracrine factors, this leads to a phenotype where
epithelial cells lose polarization and become resistant to apoptosis.
The ocular lens develops from the head ectoderm and a critical factor in its formation is
Foxe3. Foxe3 is, after secondary fiber differentiation starts, expressed exclusively in the lens
epithelium. These cells provide the precursors for lens fibers. Fiber cells are elongated,
terminally differentiated cells that provide the specialized optical properties of the lens. Ectopic
expression of Foxe3 in the fiber compartment interferes with several aspects of fiber
differentiation. The cytoskeletal remodeling and organelle degradation is blocked in transgenic
lenses, whereas fiber cell specific expression of crystallins seems to be undisturbed.
Foxe3 is also involved in patterning of the anterior segment of eye. Heterozygous Foxe3
mutants show defects in differentiation of the cornea, iris and filtration angle. The anterior
segment similarities in Foxe3 and Pax6 heterozygous mutants provide, along with Foxe3
expression being dependent on Pax6 gene dosage, an indication that Foxe3 is a major
contributor to the phenotype of Pax6 mutants.Foxe3 can interact with many signaling pathways active in the eye. Foxe3 expression can be altered by changes in growth factor ligands. Furthermore, components of different growth factor pathways can be controlled by Foxe3. Taken together, Foxe3 biology is regulated on many cellular levels in the ocular lens.
Parts of work
I.
Landgren H, Carlsson P
FoxJ3, a novel mammalian forkhead gene expressed in neuroectoderm, neural crest and myotome.
Dev Dyn. 2004 Oct;231(2):396-401::DOI::10.1002/dvdy.20131 II
Ormestad M, Astorga J, Landgren H, Wang T, Johansson BR, Miura N, Carlsson P
Murine Foxf1 and Foxf2 control murine gut development by limiting mesenchymal Wnt signaling and promoting extra cellular matrix production.
Development. 2006 Mar;133(5):833-43::DOI::10.1242/dev.02252 III
Blixt Å, Landgren H, Johansson BR, Carlsson P
Foxe3 is required for morphogenesis and differentiation of the anterior segment of the eye and is sensitive to Pax6 gene dosage.
Dev Biol. 2007 Feb 1;302(1):218-29::DOI::10.1016/j.ydbio.2006.09.021 IV
Landgren H, Blixt Å, Carlsson P
Persistent FoxE3 expression block cytoskeletal remodeling and organelle degradation during lens fiber differentiation.
Invest Ophthalmol Vis Sci. 2008 Oct;49(10):4269-77::DOI::10.1167/iovs.08-2243 V
Landgren H, Carlsson P
Foxe3 expression and protein degradation is regulated by growth factor signaling.
Manuscript
Degree
Doctor of Philosophy
University
Göteborgs universitet. Naturvetenskapliga fakulteten
Institution
Department of Cell and Molecular Biology ; Institutionen för cell- och molekylärbiologi
Disputation
Torsdagen den 27 november, kl 10.00, hörsal Ivan Ivarsson, Medicinaregatan 3.
Date of defence
2008-11-27
henrik.landgren@cmb.gu.se
Date
2008-11-12Author
Landgren, Henrik
Keywords
Development
Forkhead
Publication type
Doctoral thesis
ISBN
978-91-628-7100-0
Language
eng