Person:

D'Amore, Patricia

Cultured endothelial cells constitutively synthesize significant levels of thrombospondin, an extracellular matrix-associated protein with reported anti-anti-angiogenic properties. However, two murine endothelial cell lines, bEND.3 and Py-4-1, which have been immortalized with polyoma T oncogenes and which generate vascular malformations in vivo, produce little or no thrombospondin though bEND.3 (but not Py-4-1) growth is inhibited by the addition of exogenous thrombospondin. In addition, Py-4-1 cells are not growth-inhibited by transforming growth factor-beta, a potent endothelial inhibitor. These results indicate that these two cell lines may be useful tools in understanding the role and mechanism of action of thrombospondin and transforming growth factor-beta in endothelial cell biology. A role for thrombospondin in vascular development is further suggested by the observation of significant differences in the levels of thrombospondin mRNA and protein between capillary and aortic endothelial cells. Transforming growth factor-beta-1 treatment of normal endothelial cells increases steady-state levels of thrombospondin mRNA and protein and results in extensive deposition of thrombospondin into the extracellular matrix. In contrast, transforming growth factor-beta-1 has little effect on thrombospondin levels in the tumorigenic endothelial cell lines. In view of our earlier finding that contact between endothelial cells and mural cells generates activated transforming growth factor-beta-1, and the fact that thrombospondin is present in a fibrillar network around vascular structures in vitro, we speculate that modulation of thrombospondin production and distribution by transforming growth factor-beta may be a physiological process to enjoin stabilization of vessels and cessation of vessel growth.

PURPOSE: To develop oxygen-induced retinopathy in the mouse with reproducible and quantifiable proliferative retinal neovascularization suitable for examining pathogenesis and therapeutic intervention for retinal neovascularization in retinopathy of prematurity (ROP) and other vasculopathologies. METHODS: One-week-old C57BL/6J mice were exposed to 75% oxygen for 5 days and then to room air. A novel fluorescein-dextran perfusion method has been developed to assess the vascular pattern. The proliferative neovascular response was quantified by counting the nuclei of new vessels extending from the retina into the vitreous in 6 microns sagittal cross-sections. Cross-sections were also stained for glial fibrillary acidic protein (GFAP). RESULTS: Fluorescein-dextran angiography delineated the entire vascular pattern, including neovascular tufts in flat-mounted retinas. Hyperoxia-induced neovascularization occurred at the junction between the vascularized and avascular retina in the mid-periphery. Retinal neovascularization occurred in all the pups between postnatal day 17 and postnatal day 21. There was a mean of 89 neovascular nuclei per cross-section of 9 eyes in hyperoxia compared to less than 1 nucleus per cross-section of 8 eyes in the normoxia control (P < 0.0001). Proliferative vessels were not associated with GFAP-positive astrocyte processes. CONCLUSIONS: The authors have described a reproducible and quantifiable mouse model of oxygen-induced retinal neovascularization that should prove useful for the study of pathogenesis of retinal neovascularization as well as for the study of medical intervention for ROP and other retinal angiopathies.

The rabbit corneal pocket assay is one of the most frequently used systems for the study of angiogenesis. This model particularly is useful to identify stimulators of new blood vessel formation. More recently, however, interest in inhibitors of angiogenesis has grown, and several antiangiogenic agents have been identified. Investigations of angiogenesis inhibitors require a reliable model for the stimulation of neovascularization. One method was modified to produce corneal neovascularization by implanting into the rabbit cornea a sustained-release polymer containing endotoxin (Escherichia coli lipopolysaccharide). The implant was prepared by mixing weighed quantities of endotoxin with ethylene vinyl acetate copolymer (Elvax) and forming 1-mm3 pellets containing 1%, 7.5%, 15%, 20%, 30%, and 40% (w/w) of endotoxin. Pure Elvax pellets were implanted as controls. Intrastromal corneal pockets were created in 92 eyes of male, albino New Zealand rabbits (n = 80), and sterilized endotoxin-copolymer implants were introduced. The growth rate of new vessels was measured by slit-lamp biomicroscopy. Endotoxin loads of 15% (n = 40) produced a strong neovascularization response with minimal stromal edema, with a mean growth rate of 0.21 +/- 0.12 mm/day. Loads of 1%, 7.5%, and 20% yielded 0.1 +/- 0.03 mm/day, 0.27 +/- 0.05 mm/day, 0.30 +/- 0.06 mm/day, respectively (n = 8, each group). Higher loads (30% and 40%; n = 8, each group) produced intense neovascularization, accompanied by severe corneal edema that obscured accurate measurement of the vessels. Corneal pockets that did not contain polymer implants were avascular. When endotoxin-Elvax pellets were removed, the new vessels regressed within 2 weeks.

Nerve growth factor (NGF), acidic fibroblast growth factor (aFGF), and basic fibroblast growth factor (bFGF) promote the survival and differentiation of a variety of peripheral and central neurons. The signal transduction mechanisms that mediate the actions of these factors in neuronal cells are not well understood. We examined the effect of a deficiency in protein kinase C (PKC) and/or cAMP second messenger systems on the actions of NGF, aFGF, and bFGF in the pheochromocytoma (PC12) cell line. Activation of PKC was not required for NGF, aFGF, and bFGF to maximally induce ornithine decarboxylase (ODC), transcription of the early response genes, d2 and d5, or neurite outgrowth. In a PC12 cell mutant that is deficient in cAMP responsiveness (A126-1B2), all three growth factors maximally induced the transcription of d5 and neurite outgrowth, but aFGF and bFGF did not induce significant increases in ODC. NGF and aFGF maximally induced the transcription of d2 in A126-1B2 cells, but bFGF-induced d2 transcription was attenuated. NGF, aFGF, and bFGF maximally induced neurite outgrowth and d5 transcription in A126 cells that were made deficient in PKC. The d2 transcriptional response was substantially reduced in cells deficient in both PKC and cAMP responsiveness. These observations lead us to conclude that (a) cAMP- and PKC-dependent events are, at least in part, causally linked to NGF, aFGF, and bFGF induction of both ODC and transcription of d2 and may control functionally redundant pathways; (b) NGF, aFGF, and bFGF can elicit neurite outgrowth and increase transcription of d2 and d5 in PC12 cells via mechanisms that are independent of both PKC and cAMP; (c) NGF, aFGF, and bFGF can induce ODC in the absence of PKC; and (d) aFGF and bFGF require cAMP responsiveness to induce ODC in PC12 cells.

Basic fibroblast growth factor (bFGF) is thought to be a trophic factor for several classes of neurons. Its distribution changes in response to cortical neural injury. We have determined the effect of injury to the optic nerve on localization of bFGF in the rodent retina and visual pathways. Our observations were confirmed by using different antisera and monoclonal antibodies. While photoreceptors normally contain virtually no bFGF, crushing the optic nerve causes a striking increase, over a period of several weeks, in the amount of bFGF in retinal photoreceptors. Since photoreceptors do not synapse directly upon the injured ganglion cells, intermediary cells must participate in the cascade of events that results in the elevated bFGF. In light of the observation that exogenous bFGF protects photoreceptors from photodamage (Faktorovich et al., 1992), this increase in bFGF in photoreceptors may explain, in part, why crushing the optic nerve protects photorecptors against photodamage (Bush and Williams, 1991). Whereas bFGF is constitutively found in glia in the optic nerve, little bFGF is found in glia in the optic tract. However, damage to the optic nerve increases bFGF in astrocytes in the optic tract. This change occurs within days, suggesting that a relatively direct signal may intervene between the injured axon and the adjacent glial cells. Thus, despite the fact that the optic nerve and optic tract are contiguous structures through which axons of retinal ganglion cells project, the glial elements in these structures express distinct properties, because of differences in either glial subclasses or microenvironment.

We aimed to determine if and how endothelial cells (EC) recruit precursors of smooth muscle cells and pericytes and induce their differentiation during vessel formation. Multipotent embryonic 10T1/2 cells were used as presumptive mural cell precursors. In an under-agarose coculture, EC induced migration of 10T1/2 cells via platelet-derived growth factor BB. 10T1/2 cells in coculture with EC changed from polygonal to spindle-shaped, reminiscent of smooth muscle cells in culture. Immunohistochemical and Western blot analyses were used to examine the expression of smooth muscle (SM)-specific markers in 10T1/2 cells cultured in the absence and presence of EC. SM-myosin, SM22alpha, and calponin proteins were undetectable in 10T1/2 cells cultured alone; however, expression of all three SM-specific proteins was significantly induced in 10T1/2 cells cocultured with EC. Treatment of 10T1/2 cells with TGF-beta induced phenotypic changes and changes in SM markers similar to those seen in the cocultures. Neutralization of TGF-beta in the cocultures blocked expression of the SM markers and the shape change. To assess the ability of 10T1/2 cells to contribute to the developing vessel wall in vivo, prelabeled 10T1/2 cells were grown in a collagen matrix and implanted subcutaneously into mice. The fluorescently marked cells became incorporated into the medial layer of developing vessels where they expressed SM markers. These in vitro and in vivo observations shed light on the cell-cell interactions that occur during vessel development, as well as in pathologies in which developmental processes are recapitulated.

Wnts are highly conserved developmental regulators that mediate inductive signaling between neighboring cells and participate in the determination of embryonic axes. Frizzled proteins constitute a large family of putative transmembrane receptors for Wnt signals. FrzA is a novel protein that shares sequence similarity with the extracellular domain of Frizzled. The Xenopus homologue of FrzA is dynamically regulated during early development. At the neurula stages, XfrzA mRNA is abundant in the somitic mesoderm, but later becomes strongly expressed in developing heart, neural crest derivatives, endoderm, otic vesicle and other sites of organogenesis. To evaluate possible biological functions of FrzA, we analyzed its effect on early Xenopus development. Microinjection of bovine or Xenopus FrzA mRNA into dorsal blastomeres resulted in a shortened body axis, suggesting a block of convergent extension movements. Consistent with this possibility, FrzA blocked elongation of ectodermal explants in response to activin, a potent mesoderm-inducing factor. FrzA inhibited induction of secondary axes by Xwnt8 and human Wnt2, but not by Xdsh, supporting the idea that FrzA interferes with Wnt signaling. Furthermore, FrzA suppressed Wnt-dependent activation of the early response genes in ectodermal explants and in the marginal zone. Finally, immunoprecipitation experiments demonstrate that FrzA binds to the soluble Wingless protein in cell culture supernatants in vitro. Our results indicate that FrzA is a naturally occurring secreted antagonist of Wnt signaling.