Abstract
Heterozygous Bmp4 mutations in humans and mice cause severe ocular anterior segment dysgenesis (ASD). Abnormalities include pupil displacement, corneal opacity, iridocorneal adhesions, and variable intraocular pressure, as well as some retinal and vascular defects. It is presently not known what source of BMP4 is responsible for these defects, as BMP4 is expressed in several developing ocular and surrounding tissues. In particular, BMP4 is expressed in the ciliary margins of the optic cup which give rise to anterior segment structures such as the ciliary body and iris, making it a good candidate for the required source of BMP4 for anterior segment development. Here, we test whether ciliary margin-derived BMP4 is required for ocular development using two different conditional knockout approaches. In addition, we compared the conditional deletion phenotypes with Bmp4 heterozygous null mice. Morphological, molecular, and functional assays were performed on adult mutant mice, including histology, immunohistochemistry, in vivo imaging, and intraocular pressure measurements. Surprisingly, in contrast to Bmp4 heterozygous mutants, our analyses revealed that the anterior and posterior segments of Bmp4 conditional knockouts developed normally. These results indicate that ciliary margin-derived BMP4 does not have a major role in ocular development, although subtle alterations could not be ruled out. Furthermore, we demonstrated that the anterior and posterior phenotypes observed in Bmp4 heterozygous animals showed a strong propensity to co-occur, suggesting a common, non-cell autonomous source for these defects.
Highlights
In order to examine the role of BMP4 on anterior segment formation, without affecting lens induction [9,15,33], Bmp4 was deleted from the ciliary margin of the optic cup using a Cre recombinase driven by the peripheral retina-specific regulatory element “α” of the murine Pax6 gene
The present study has demonstrated that from the optic cup stage on, retinal neuroepitheliumderived BMP4 does not play a critical role in the development of the mouse eye
We found evidence suggesting Bone Morphogenic Protein (BMP) signaling was involved in ciliary body formation
Summary
Ocular development requires precise interactions between the neuroepithelium, surface ectoderm, mesoderm and neural crest. These cell types work in concert throughout embryonic and early postnatal development to form the multiple, specialized tissues of the eye [1,2]. Abnormalities in ocular tissue morphogenesis can lead to congenital diseases of both the anterior and posterior eye [3]. Anterior segment dysgenesis (ASD) is defined by ocular defects affecting the lens, cornea, iris, trabecular meshwork, ciliary body, and/or Schlemm’s canal [4].
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