Organ-specific lymphangiectasia, arrested lymphatic sprouting, and maturation defects resulting from gene-targeting of the PI3K regulatory isoforms p85alpha, p55alpha, and p50alpha.

The phosphoinositide 3-kinase (PI3K) family has multiple vascular functions, but the specific regulatory isoform supporting lymphangiogenesis remains unidentified. Here, we report that deletion of the Pik3r1 gene, encoding the regulatory subunits p85alpha, p55alpha, and p50alpha impairs lymphatic sprouting and maturation, and causes abnormal lymphatic morphology, without major impact on blood vessels. Pik3r1 deletion had the most severe consequences among gut and diaphragm lymphatics, which share the retroperitoneal anlage, initially suggesting that the Pik3r1 role in this vasculature is anlage-dependent. However, whereas lymphatic sprouting toward the diaphragm was arrested, lymphatics invaded the gut, where remodeling and valve formation were impaired. Thus, cell-origin fails to explain the phenotype. Only the gut showed lymphangiectasia, lymphatic up-regulation of the transforming growth factor-beta co-receptor endoglin, and reduced levels of mature vascular endothelial growth factor-C protein. Our data suggest that Pik3r1 isoforms are required for distinct steps of embryonic lymphangiogenesis in different organ microenvironments, whereas they are largely dispensable for hemangiogenesis.

Cardiovascular and hematopoietic defects associated with Notch1 activation in embryonic Tie2-expressing populations.

Notch signaling is critical for the development and maintenance of the cardiovasculature, with loss-of-function studies defining roles of Notch1 in the endothelial/hematopoietic lineages. No in vivo studies have addressed complementary gain-of-function strategies within these tissues to define consequences of Notch activation. We developed a transgenic model of Cre recombinase-mediated activation of a constitutively active mouse Notch1 allele (N1ICD(+)) and studied transgene activation in Tie2-expressing lineages. The in vivo phenotype was compared to effects of Notch1 activation on endothelial tubulogenesis, paracrine regulation of smooth muscle cell proliferation, and hematopoiesis. N1ICD(+) embryos showed midgestation lethality with defects in angiogenic remodeling of embryonic and yolk sac vasculature, cardiac development, smooth muscle cell investment of vessels, and hematopoietic differentiation. Angiogenic defects corresponded with impaired endothelial tubulogenesis in vitro following Notch1 activation and paracrine inhibition of smooth muscle cells when grown with Notch1-activated endothelial cells. Flow cytometric analysis of hematopoietic and endothelial precursor populations demonstrated a significant loss of CD71(+)/Ter119(+) populations with an active N1ICD(+) allele and a corresponding increase in c-Kit(+)/CD71 and Flk1(+) populations, suggesting a developmental block during the transition between c-Kit- and Ter119-expressing erythroblasts. Cardiovascular lineages are sensitive to an imbalance in Notch signaling, with aberrant activation reflecting a vascular phenotype comparable to a loss-of-function Notch1 mutation.

Widespread delta-like-1 expression in normal adult mouse tissue and injured endothelium is reflected by expression of the Dll1LacZ locus.

BACKGROUND: Our study characterizes Delta-like 1 (Dll1) in the adult mouse, particularly in normal versus injured vasculature, with the aid of the transgenic Dll1(LacZ) line. METHODS: Normal mouse adult tissues or those from the Dll1(LacZ) reporter line were analyzed for Dll1 expression and promoter activity. Vascular tissue was analyzed before and after carotid artery ligation. RESULTS: In wild-type mice, Dll1 transcript expression was widespread. Similarly, the Dll1(LacZ) reporter had beta-galactosidase activity detectable in the cerebellum, cerebrum, spinal cord, liver, lung and cornea, although the normal adult vasculature had no reporter expression. Following arterial ligation, there was acute induction of Dll1(LacZ) reporter expression, both in the ligated left carotid artery, and the uninjured right contralateral artery. Expression returned to low/undetectable levels 4-10 days after arterial ligation. CONCLUSION: The expression of Dll1 in the adult mouse is more widespread than previously realized, although not in resting large arteries in the adult mouse. Following arterial injury, Dll1 promoter activity is induced selectively in the endothelial cells of both the injured artery and the contralateral uninjured artery. Our results show that while overall expression in the adult mouse is widespread, Dll1 may be selectively expressed in the endothelium of injured vasculature, similar to the endothelial-restricted expression of Dll4.

Genetically increasing Myoc expression supports a necessary pathologic role of abnormal proteins in glaucoma.

Despite the importance of MYOC for glaucoma, the protein's normal function(s) and the pathogenic mechanism(s) of MYOC mutations are not clear. Elevated intraocular pressure (IOP) and glaucoma are sometimes induced by corticosteroids, and corticosteroid use can result in substantially increased MYOC expression. It has been suggested, therefore, that steroid-induced MYOC protein levels cause steroid-induced glaucoma and that protein level-increasing mutations in MYOC contribute to glaucoma not associated with steroid use. A causative role of elevated MYOC levels in steroid-induced glaucoma is controversial, however, and it is not clear if elevated MYOC levels can result in IOP elevation. To directly test if increased levels of MYOC can cause IOP elevation and glaucoma, we generated bacterial artificial chromosome transgenic mice that overexpress Myoc at a level similar to that induced by corticosteroid use. These mice do not develop elevated IOP or glaucoma. Our present findings, along with the absence of glaucoma in mice completely lacking MYOC, show that changing the level of MYOC is not pathogenic (from absent to approximately 15 times normal). These findings suggest that noncoding sequence variants are unlikely to influence glaucoma and that disease pathogenesis in primary open-angle glaucoma patients is dependent upon the expression of abnormal mutant proteins. This work does not support a causative role for increased MYOC levels or the MYOC gene in steroid-induced glaucoma.