Matthew R. Ritter

Myeloid progenitors differentiate into microglia and promote vascular repair in a model of ischemic retinopathy

Vision loss associated with ischemic diseases such as retinopathy of prematurity and diabetic retinopathy are often due to retinal neovascularization. While significant progress has been made in the development of compounds useful for the treatment of abnormal vascular permeability and proliferation, such therapies do not address the underlying hypoxia that stimulates the observed vascular growth. Using a model of oxygen-induced retinopathy, we demonstrate that a population of adult BM-derived myeloid progenitor cells migrated to avascular regions of the retina, differentiated into microglia, and facilitated normalization of the vasculature. Myeloid-specific hypoxia-inducible factor 1alpha (HIF-1alpha) expression was required for this function, and we also demonstrate that endogenous microglia participated in retinal vascularization. These findings suggest what we believe to be a novel therapeutic approach for the treatment of ischemic retinopathies that promotes vascular repair rather than destruction.

Functional Adult Myocardium in the Absence of Na+-Ca2+ Exchange. Cardiac-Specific Knockout of NCX1

The excitation–contraction coupling cycle in cardiac muscle is initiated by an influx of Ca2+ through voltage-dependent Ca2+ channels. Ca2+ influx induces a release of Ca2+ from the sarcoplasmic reticulum and myocyte contraction. To maintain Ca2+ homeostasis, Ca2+ entry is balanced by efflux mediated by the sarcolemmal Na+-Ca2+ exchanger. In the absence of Na+-Ca2+ exchange, it would be expected that cardiac myocytes would overload with Ca2+. Using Cre/loxP technology, we generated mice with a cardiac-specific knockout of the Na+-Ca2+ exchanger, NCX1. The exchanger is completely ablated in 80% to 90% of the cardiomyocytes as determined by immunoblot, immunofluorescence, and exchange function. Surprisingly, the NCX1 knockout mice live to adulthood with only modestly reduced cardiac function as assessed by echocardiography. At 7.5 weeks of age, measures of contractility are decreased by 20% to 30%. We detect no adaptation of the myocardium to the absence of the Na+-Ca2+ exchanger as measured by both immunoblots and microarray analysis. Ca2+ transients of isolated myocytes from knockout mice display normal magnitudes and relaxation kinetics and normal responses to isoproterenol. Under voltage clamp conditions, the current through L-type Ca2+ channels is reduced by 50%, although the number of channels is unchanged. An abbreviated action potential may further reduce Ca2+ influx. Rather than upregulate other Ca2+ efflux mechanisms, the myocardium appears to functionally adapt to the absence of the Na+-Ca2+ exchanger by limiting Ca2+ influx. The magnitude of Ca2+ transients appears to be maintained by an increased gain of sarcoplasmic reticular Ca2+ release. The myocardium of the NCX1 knockout mice undergoes a remarkable adaptation to maintain near normal cardiac function.

Insulin-like growth factor 2 and potential regulators of hemangioma growth and involution identified by large-scale expression analysis

Hemangiomas are benign tumors of the vascular endothelium and are the most common tumors of infancy. These tumors are characterized by an initial phase of rapid proliferation, which is followed, in most cases, by spontaneous involution. Although most lesions resolve without complication, there are some cases in which hemangiomas can be life threatening when occurring near a vital structure. Treatment for these aggressive tumors represents an unmet clinical need. In addition, this characteristic progression of hemangiomas through distinct phases provides a unique opportunity for studying endothelial cell biology and angiogenesis. Using DNA microarrays representing approximately 10,000 human genes, we identified insulin-like growth factor 2 (IGF-2) as a potentially important regulator of hemangioma growth. IGF-2 was highly expressed during the proliferative phase and substantially decreased during involution. This finding was confirmed at the message level by quantitative reverse transcription–PCR and at the protein level by immunohistochemistry. IGF-2 protein was localized primarily to tumor vessels or vascular channels. Using a human hemangioma explant model, we show that IGF-2 promotes sprouting from intact hemangioma tissue. In addition, several angiogenesis-related factors, including integrins αvβ3 and α5β1, are present in proliferating hemangiomas. During the involuting phase, an increase in several IFN-induced genes was observed. These studies identify potential regulators of hemangioma growth and involution and provide a foundation on which to build further mechanistic investigations into angiogenesis, using hemangiomas as a model.

Pathogenesis of infantile haemangioma: new molecular and cellular insights.

Infantile haemangioma is the most common tumour of infancy, yet the origin of these lesions remains controversial and the predictable life cycle is poorly understood. Much new information on infantile haemangiomas has emerged over the past decade, but experts continue to debate fundamental features, including cell of origin, nonrandom distribution, and mechanisms regulating the sometimes explosive growth and slow involution. The development of useful laboratory models has been difficult, in turn restricting the development of treatment options available to the clinician. Despite this, new research and creative thinking has spawned several hypotheses on the origin of these tumours and their interesting clinical behaviour, including suggestions of an intrinsic defect in local endothelial cells, a contribution of circulating endothelial progenitors or haemangioblasts, embolisation of shed placental cells and developmental field defects. While no single hypothesis seems to describe all features of infantile haemangioma, continued research seeks to integrate these ideas, create a better understanding of these important tumours and bring new treatments to the clinic.

Progenitor cells and retinal angiogenesis.

Nothing more dramatically captures the imagination of the visually impaired patient or the ophthalmologist treating them than the possibility of rebuilding a damaged retina or vasculature with “stem cells.” Stem cells (SC) have been isolated from adult tissues and represent a pool of cells that may serve to facilitate rescue/repair of damaged tissue following injury or stress. We propose a new paradigm to “mature” otherwise immature neovasculature or, better yet, stabilize existing vasculature to hypoxic damage. This may be possible through the use of autologous bone marrow (BM) or cord blood derived hematopoietic SC that selectively target sites of neovascularization and gliosis where they provide vasculo- and neurotrophic effects. We have demonstrated that adult BM contains a population of endothelial and myeloid progenitor cells that can target activated astrocytes, a hallmark of many ocular diseases, and participate in normal developmental, or injury-induced, angiogenesis in the adult. Intravitreal injection of these cells from mice and humans can prevent retinal vascular degeneration ordinarily observed in mouse models of retinal degeneration; this vascular rescue correlates with functional neuronal rescue as well. The use of autologous adult BM derived SC grafts for the treatment of retinal vascular and degenerative diseases represents a novel conceptual approach that may make it possible to “mature” otherwise immature neovasculature, stabilize existing vasculature to hypoxic damage and/or rescue and protect retinal neurons from undergoing apoptosis. Such a therapeutic approach would obviate the need to employ destructive treatment modalities and would facilitate vascularization of ischemic and otherwise damaged retinal tissue.

Identifying potential regulators of infantile hemangioma progression through large-scale expression analysis: a possible role for the immune system and indoleamine 2,3 dioxygenase (IDO) during involution.

Hemangiomas are benign endothelial tumors. Often referred to as hemangiomas of infancy (HOI), these tumors are the most common tumor of infancy. Most of these lesions proliferate rapidly in the first months of life, and subsequently slowly involute during early childhood without significant complications. However, they often develop on the head or neck, and may pose a significant cosmetic concern for families. In addition, a fraction of these tumors can grow explosively and ulcerate, bleed, or obstruct vision or airway structures. Current treatments for these tumors are associated with significant side effects, and our knowledge of the biology of hemangiomas is limited. The natural evolution of these lesions creates a unique opportunity to study the changes in gene expression that occur as the endothelium of these tumors proliferates and then subsequently regresses. Such information may also increase our understanding of the basic principals of angiogenesis in normal and abnormal tissue. We have performed large-scale genomic analysis of hemangioma gene expression using DNA microarrays. We recently identified insulin-like growth factor 2 as a potentially important regulator of hemangioma growth using this approach. However, little is known about the mechanisms involved in hemangioma involution. Here we explore the idea that hemangioma involution might be an immune-mediated process and present data to support this concept. We also demonstrate that proliferating hemangiomas express indoleamine 2,3 dioxygenase (IDO) and discuss a possible mechanism that accounts for the often slow regression of these lesions.

Chapter 6. Ocular models of angiogenesis.

During normal retinal vascular development, vascular endothelial cells proliferate and migrate through the extracellular matrix in response to a variety of cytokines, leading to the formation of new blood vessels in a highly ordered fashion. However, abnormal angiogenesis contributes to the vast majority of diseases that cause catastrophic loss of vision. During abnormal neovascularization of the iris, retina, or choroid, angiogenesis is unregulated and usually results in the formation of dysfunctional blood vessels. Multiple models of ocular angiogenesis exist which recapitulate particular aspects of both normal and pathological neovascularization. These experimental methods are useful for studying the mechanisms of normal developmental angiogenesis, as well as studying various aspects of pathological angiogenesis including ischemic retinopathies, vascular leak, and choroidal neovascularization. This chapter will outline several protocols used to study ocular angiogenesis, put the protocols into brief historical context, and describe some of the questions for which these protocols are commonly used.

Functional Effect of Contortrostatin, a Snake Venom Disintegrin, on Human Glioma Cell Invasion In Vitro

The metastatic spread of cancer is a complex process that involves the combination of different cellular actions including cell adhesion to the extracellular matrix (ECM), breakdown of the ECM by specific matrix-degrading proteinases, and active cell locomotion. Contortrostatin (CN), a homodimeric snake venom disintegrin, has previously been demonstrated to be effective in blocking vitronectin/fibronectin-dependent adhesion and invasion of T98G human glioblastoma cells through Matrigel using in vitro studies. However, it is not known at what step of the invasion process CN exerts its inhibitory effect. In the present report, CN is shown to decrease invasion of various glioma cell lines through Matrigel affecting neither cell adhesion, nor cell viability. While CN had no effect on cell binding to laminin and type IV collagen, it blocked adhesion of f v g 3-positive, but not f v g 3-negative cells, to vitronectin and fibronectin. Furthermore, members of the matrix metalloproteinase (MMP) family and their physiological inhibitors, and of the plasminogen activator (PA)/plasmin system were demonstrated not to be involved in CN-induced loss of glioma cell invasiveness. Instead, CN inhibited active locomotion of cells on Matrigel. These data suggest that CN-mediated inhibition of glioma cell invasion through Matrigel is a direct result of impaired cell motility. Moreover, use of several glioma cell lines and integrin antibodies strongly indicates the versatility of CN in inhibiting the invasion process based on the ability of CN to interact with different integrins, including f v g 3, f v g 5, and f 5 g 1.

Contortrostatin, a homodimeric disintegrin, actively disrupts focal adhesion and cytoskeletal structure and inhibits cell motility through a novel mechanism.

Irttegrins play a major role in the regulation of cell motility. They physically link the extracellular environment to the cytoskeleton and participate in large protein complexes known as focal adhesions. In this report, it is demonstrated that treatment of tumor cells with the homodimeric disintegrin contortrostatin induces integrin-mediatcd tyrosine phosphorylation events and causes severe disruptions in the actin cytoskeleton and disassembly of focal adhesion structures without affecting cellular adhesion to a reconstituted basement membrane. Included in this disruption is the tyrosine phosphorylation and altered subcellular localization of FAK. Through use of transfected 293 cells with specific integrin expression profiles and anti-αvβ3 mAbs, we demonstrate that these events are mediated exclusively by the αvβ3 integrin and are likely the result of contortrostatin-mediated crosslinking of this receptor at the cell surface, since monovalent disintegrins, flavoridin or echistatin do not induce such effects. Further, it is shown that contortrostatin potently inhibits motility in cells expressing the αvβ3 integrin. The results of this study describe a novel integrin-mediated mechanism by which cell motility can be inhibited and suggest an alternative approach to therapeutic intervention for cancer invasion and metastasis.

Integrins in Ocular Angiogenesis

The integrin family of membrane proteins are ubiquitously expressed cell surface receptors that not only mediate cell anchorage to the surrounding extracellular matrix, but are also critically important in transducing environmental cues to subcellular signaling pathways. Integrins play important roles in cell differentiation and survival and have generated interest in diverse fields ranging from structural biology and immunology to tumor biology and ophthalmology. Much of the interest has centered on the roles of integrins during cell-cell adhesion, such as that which occurs between endothelial cells and leukocytes during arrest and extravasation from blood vessels during inflammation. Another major area of interest has been the function of integrins and their interaction with the extracellular matrix (ECM). Integrins specifically bind components of the ECM such as fibronectin and vitronectin, but also non-ECM molecules such as von Willebrand factor and thrombospondin. The specificity of interaction with various ligands is a result of the noncovalently linked α/β chains that form the functional integrin heterodimer. The α-subunit is comprised of approx 1000 amino acids and contains calcium-binding motifs that are critical to integrin function (1). Integrin β-subunits are made up of approx 750 amino acids and introduce additional variability through alternative splicing of the cytoplasmic regions. Different pairings of α- and β-subunits produce at least 20 different integrin heterodimers with distinct but overlapping binding specificities (2). In turn, each ECM component may be recognized by several integrins. In general, integrins recognize amino acid sequences that contain a key acidic residue that is critical for binding (3). A common example of an integrin ligand sequence is the RGD (Arg-Gly-Asp) sequence, which is found in a number of integrin-binding proteins (4). Integrin-binding sequences that are unrelated to the RGD motif show structural and topological similarities to the RGD sequence, suggesting that specific spatial elements are required for recognition (5). Some integrins are known to require activation in order to bind their corresponding ligands, a mechanism referred to as “inside-out” signaling. For example, the αIIbβ3 integrin is a constitutively expressed receptor on platelets but is able to bind its primary ligand, fibrinogen, only after a conformational change induced by platelet activation (6).