Published in Volume
111, Issue 12
(June 15, 2003)J Clin Invest.
Copyright © 2003, American Society for Clinical Investigation
An eye on insulin
1Department of Cellular and Molecular Physiology, and 2
Department of Ophthalmology, Penn State College of Medicine, Hershey, Pennsylvania, USA
Address correspondence to: Thomas W. Gardner, Department of Cellular and Molecular Physiology, and Department of Ophthalmology, Penn State College of Medicine, 500 University Drive, Hershey, Pennsylvania 17033, USA. Phone: (717) 531-6711; Fax: (717) 531-7667; E-mail: firstname.lastname@example.org.
Published June 15, 2003
Diabetic retinopathy, the most frequent complication of diabetes and leading cause of vision loss, involves vascular and neural damage in the retina. Insulin and IGF-1 signaling are now shown to contribute to retinal neovascularization, in part, by modulating the expression of various vascular mediators.
Physiologic and pathologic blood vessel growth patterns are stimulated by local and systemic influences. The hope of angiogenesis research is to understand these complex interactions in order to provide better means to control pathologic vessel formation, or perhaps stimulate appropriate vessel growth, to reduce maladaptive consequences. In the retina, normal vessel growth occurs in the plane of the retina from the optic nerve toward the periphery in a radial pattern and is guided by cues from astrocytes in the inner retina (1). This growth is mediated by VEGF and other ligands (2), while angioblasts from the circulation can provide endothelial progenitors (3).
The problem of retinal neovascularization
Pathologic neovascularization of the retina is a common and serious complication of retinopathy of prematurity (ROP) and diabetic retinopathy (DR). The treatment of DR, ablation of the diseased retina with laser photocoagulation or cryotherapy to cause involution of the new vessels, has remained fundamentally unchanged for almost 50 years. The nature of the growth promoting stimuli is not well understood, but in ROP the stimulus is assumed to be in part due to perinatal retinal hyperoxia followed by hypoxia. The classic response to hypoxia includes hypoxia-inducing factor-1 (HIF-1) translocation to the nucleus and subsequent downstream events such as the upregulation of VEGF, eNOS, and endothelin-1 (ET-1). The fact that VEGF is increased in the vitreous of diabetic patients makes it tempting to speculate that diabetes induces a hypoxic, or HIF-1–driven response that is similar to that observed in ROP. Current animal models of diabetes do not develop proliferative retinopathy and the only model that simulates the neovascularization seen clinically is that induced by relative hypoxia in developing retinas. Postnatal mice are placed in hyperoxic conditions for several days, at a time when their vessels have not yet reached the peripheral retina, which causes vasoconstriction; when they are returned to room air, the vasoconstriction is relieved and neovascularization develops when the retina perceives relative hypoxia (4). This model provides a rodent model of neovascularization in the absence of systemic metabolic defects due to insulin depletion or resistance. Smith et al. (5) previously showed that an IGF-1 inhibitor blocked neovascularization in this model but no studies have examined the effect of the insulin receptor.
A role for insulin and IGF-1 in retinal neovascularization
In this issue of the JCI, Kondo and colleagues (6) have utilized a clever genetic system in mice to probe the role of insulin and IGF signaling in this experimental model of relative hypoxia. They use two different genetically altered lines of mice, one of which contains an insulin receptor (IR) gene that can be deleted in the presence of Cre recombinase (7), resulting in an absence of the IR in all cells that have expressed the recombinase, and a similar line that contains an IGF-1 receptor (IGF-1R) gene that can be deleted in the presence of the recombinase (8). Experimental animals are bred to be homozygous for either of the modified receptor genes and to carry a transgene that expresses Cre recombinase under the control of the Tie-2 promoter/enhancer (9). The endothelium in these animals is systemically devoid of the IR or IGF-IR, and referred to as vascular endothelial insulin receptor knockout (VENIRKO) and vascular endothelial insulin-like growth factor receptor knockout (VENIFARKO), respectively. While neither Kondo et al. (6) nor Vicent et al. (10) confirm the loss of IR or IGF-1R proteins, it is presumed that the loss is nearly complete given the severe reduction in message detected by quantitative PCR amplification of endothelial cell RNA from these mice and the careful description of the Tie2-Cre transgenic line (9). The results are quite interesting.
First, Kondo (6) and Vicent (10) found no developmental or physiological consequences of IR or IGF-1R loss in endothelium; i.e., no gross or histological changes in the vasculature, and no metabolic changes such as those seen in subsets of the tissue-specific knockouts for each of these receptors (reviewed in ref. 11). However, when young mice are put through the relative hypoxia protocol there are distinct differences between control mice and those with an absence of the IR or IGF-1R in the endothelium. They find reduced neovascularization, and concomitantly less immunoreactivity for markers of neovascularization including, VEGF, eNOS, and ET-1 in VENIRKO and to a lesser extent in VENIFARKO mice, compared to wild-type mice. One cannot exclude the possibility that the reduction of VEGF, eNOS, and ET-1 is simply because there are fewer endothelial cells to express these proteins. Nonetheless, this result is interesting because deficiencies in the IR and the IGF-1R signaling pathways are critically linked to metabolic defects in Type I and Type II diabetes and insulin resistance — disease states where neovascularization is a frequent complication.
New findings beget new questions
The question is, what are the normal functions of the IR and IGF-1R in the retina? They probably do not regulate acute glucose utilization as they do in skeletal muscle, liver, and fat because their activity is constant under physiological conditions (12). In the CNS, the insulin and IGF signaling pathways stimulate embryonic growth, and loss of function mutations cause developmental eye defects in Drosophila (13). In retinal endothelial cells, insulin stimulates mitogenesis and insulin transport (14, 15). Hence, it is possible that the IR and IGF-1R in the retina function largely to provide trophic stimuli for maintenance of cell numbers. Therefore, signaling via factors upregulated by HIFs may intersect or augment the IR and IGF-1R pathways to promote neovascularization. The articles by Kondo et al. (6) and Vicent et al. (10) demonstrate that, from a developmental standpoint, endothelial cell insulin and IGF signaling are unnecessary, and consequences due to loss of signaling through these receptors may only be observed in response to some perturbation or injury. The neovascularization described by Kondo et al. presumably requires increased proliferation and/or survival of endothelial cell progenitors, so it is not surprising that disruption of the insulin and IGF signaling pathways results in less neovascularization. It would be helpful to know if the reduced vascularization in the knockout mice resulted from less proliferation or more apoptosis. The deciphering of downstream signals such as the activity of PI3K in the endothelium in response to relative hypoxia might also shed some light on this provocative result.
Looking forward therapeutically
The observations that loss of the IR and IGF-1R signaling pathways appear to counter the response to relative hypoxia and do not alter vasculogenesis in the absence of relative hypoxia suggest that it is not insulin and IGF-1 signaling in endothelial cells alone that promotes neovascularization in diabetes. It also prompts us to look to other cell types in the retina for a response to diminished insulin action. The experiments of Kondo et al. (6) do not address the role of retinal glia or neurons in vascular regulation. Answers to these questions will directly impact therapeutic choices for diabetic patients. Kondo et al. suggest that, in diabetes, inhibition of retinal insulin or IGF-1 signaling in the eye might be beneficial, however, in the context of what is understood to be systemically reduced insulin signaling in these disease states, therapeutic blocking of insulin signaling appears counterintuitive. Identification of specific molecules at the intersection of the HIF-1 and insulin and IGF-1 signals, as well as a thorough understanding of how the varied cell types in the retina respond to the diabetic state, will necessarily precede therapeutic trials to prevent loss of vision.
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