Dean Y. Li

Elastin is an essential determinant of arterial morphogenesis

Elastin, the main component of the extracellular matrix of arteries, was thought to have a purely structural role. Disruption of elastin was believed to lead to dissection of arteries,, but we showed that mutations in one allele encoding elastin cause a human disease in which arteries are blocked, namely, supravalvular aortic stenosis,. Here we define the role of elastin in arterial development and disease by generating mice that lack elastin. These mice die of an obstructive arterial disease, which results from subendothelial cell proliferation and reorganization of smooth muscle. These cellular changes are similar to those seen in atherosclerosis. However, lack of elastin is not associated with endothelial damage, thrombosis or inflammation, which occur in models of atherosclerosis. Haemodynamic stress is not associated with arterial obstruction in these mice either, as the disease still occurred in arteries that were isolated in organ culture and therefore not subject to haemodynamic stress. Disruption of elastin is enough to induce subendothelial proliferation of smooth muscle and may contribute to obstructive arterial disease. Thus, elastin has an unanticipated regulatory function during arterial development, controlling proliferation of smooth muscle and stabilizing arterial structure.

Arteriovenous malformations in mice lacking activin receptor-like kinase-1.

The mature circulatory system is comprised of two parallel, yet distinct, vascular networks that carry blood to and from the heart. Studies have suggested that endothelial tubes are specified as arteries and veins at the earliest stages of angiogenesis, before the onset of circulation. To understand the molecular basis for arterial-venous identity, we have focused our studies on a human vascular dysplasia, hereditary haemorrhagic telangiectasia (HHT), wherein arterial and venous beds fail to remain distinct. Genetic studies have demonstrated that HHT can be caused by loss-of-function mutations in the gene encoding activin receptor-like kinase-1 (ACVRL1; ref. 5). ACVRL1 encodes a type I receptor for the TGF-β superfamily of growth factors. At the earliest stage of vascular development, mice lacking Acvrl1 develop large shunts between arteries and veins, downregulate arterial Efnb2 and fail to confine intravascular haematopoiesis to arteries. These mice die by mid-gestation with severe arteriovenous malformations resulting from fusion of major arteries and veins. The early loss of anatomical, molecular and functional distinctions between arteries and veins indicates that Acvrl1 is required for developing distinct arterial and venous vascular beds.

A critical role for elastin signaling in vascular morphogenesis and disease

Vascular proliferative diseases such as atherosclerosis and coronary restenosis are leading causes of morbidity and mortality in developed nations. Common features associated with these heterogeneous disorders involve phenotypic modulation and subsequent abnormal proliferation and migration of vascular smooth muscle cells into the arterial lumen, leading to neointimal formation and vascular stenosis. This fibrocellular response has largely been attributed to the release of multiple cytokines and growth factors by inflammatory cells. Previously, we demonstrated that the disruption of the elastin matrix leads to defective arterial morphogenesis. Here, we propose that elastin is a potent autocrine regulator of vascular smooth muscle cell activity and that this regulation is important for preventing fibrocellular pathology. Using vascular smooth muscle cells from mice lacking elastin (Eln-/-), we show that elastin induces actin stress fiber organization, inhibits proliferation, regulates migration and signals via a non-integrin, heterotrimeric G-protein-coupled pathway. In a porcine coronary model of restenosis, the therapeutic delivery of exogenous elastin to injured vessels in vivo significantly reduces neointimal formation. These findings indicate that elastin stabilizes the arterial structure by inducing a quiescent contractile state in vascular smooth muscle cells. Together, this work demonstrates that signaling pathways crucial for arterial morphogenesis can play an important role in the pathogenesis and treatment of vascular disease.

Novel arterial pathology in mice and humans hemizygous for elastin.

Obstructive vascular disease is an important health problem in the industrialized world. Through a series of molecular genetic studies, we demonstrated that loss-of-function mutations in one elastin allele cause an inherited obstructive arterial disease, supravalvular aortic stenosis (SVAS). To define the mechanism of elastins effect, we generated mice hemizygous for the elastin gene (ELN +/-). Although ELN mRNA and protein were reduced by 50% in ELN +/- mice, arterial compliance at physiologic pressures was nearly normal. This discrepancy was explained by a paradoxical increase of 35% in the number of elastic lamellae and smooth muscle in ELN +/- arteries. Examination of humans with ELN hemizygosity revealed a 2. 5-fold increase in elastic lamellae and smooth muscle. Thus, ELN hemizygosity in mice and humans induces a compensatory increase in the number of rings of elastic lamellae and smooth muscle during arterial development. Humans are exquisitely sensitive to reduced ELN expression, developing profound arterial thickening and markedly increased risk of obstructive vascular disease.

Robo4 stabilizes the vascular network by inhibiting pathologic angiogenesis and endothelial hyperpermeability

The angiogenic sprout has been compared to the growing axon, and indeed, many proteins direct pathfinding by both structures. The Roundabout (Robo) proteins are guidance receptors with well-established functions in the nervous system; however, their role in the mammalian vasculature remains ill defined. Here we show that an endothelial-specific Robo, Robo4, maintains vascular integrity. Activation of Robo4 by Slit2 inhibits vascular endothelial growth factor (VEGF)-165-induced migration, tube formation and permeability in vitro and VEGF-165-stimulated vascular leak in vivo by blocking Src family kinase activation. In mouse models of retinal and choroidal vascular disease, Slit2 inhibited angiogenesis and vascular leak, whereas deletion of Robo4 enhanced these pathologic processes. Our results define a previously unknown function for Robo receptors in stabilizing the vasculature and suggest that activating Robo4 may have broad therapeutic application in diseases characterized by excessive angiogenesis and/or vascular leak.

Robo4 is a vascular-specific receptor that inhibits endothelial migration

Guidance and patterning of axons are orchestrated by cell-surface receptors and ligands that provide directional cues. Interactions between the Robo receptor and Slit ligand families of proteins initiate signaling cascades that repel axonal outgrowth. Although the vascular and nervous systems grow as parallel networks, the mechanisms by which the vascular endothelial cells are guided to their appropriate positions remain obscure. We have identified a putative Robo homologue, Robo4, based on its differential expression in mutant mice with defects in vascular sprouting. In contrast to known neuronal Robo family members, the arrangement of the extracellular domains of Robo4 diverges significantly from that of all other Robo family members. Moreover, Robo4 is specifically expressed in the vascular endothelium during murine embryonic development. We show that Robo4 binds Slit and inhibits cellular migration in a heterologous expression system, analogous to the role of known Robo receptors in the nervous system. Immunoprecipitation studies indicate that Robo4 binds to Mena, a known effector of Robo-Slit signaling. Finally, we show that Robo4 is the only Robo family member expressed in primary endothelial cells and that application of Slit inhibits their migration. These data demonstrate that Robo4 is a bona fide member of the Robo family and may provide a repulsive cue to migrating endothelial cells during vascular development.

Risk factors predictive of right ventricular failure after left ventricular assist device implantation.

Right ventricular failure (RVF) after left ventricular assist device (LVAD) implantation appears to be associated with increased mortality. However, the determination of which patients are at greater risk of developing postoperative RVF remains controversial and relatively unknown. We sought to determine the preoperative risk factors for the development of RVF after LVAD implantation. The data were obtained for 175 consecutive patients who had received an LVAD. RVF was defined by the need for inhaled nitric oxide for >/=48 hours or intravenous inotropes for >14 days and/or right ventricular assist device implantation. An RVF risk score was developed from the beta coefficients of the independent variables from a multivariate logistic regression model predicting RVF. Destination therapy (DT) was identified as the indication for LVAD implantation in 42% of our patients. RVF after LVAD occurred in 44% of patients (n = 77). The mortality rates for patients with RVF were significantly greater at 30, 180, and 365 days after implantation compared to patients with no RVF. By multivariate logistic regression analysis, 3 preoperative factors were significantly associated with RVF after LVAD implantation: (1) a preoperative need for intra-aortic balloon counterpulsation, (2) increased pulmonary vascular resistance, and (3) DT. The developed RVF risk score effectively stratified the risk of RV failure and death after LVAD implantation. In conclusion, given the progressively growing need for DT, the developed RVF risk score, derived from a population with a large percentage of DT patients, might lead to improved patient selection and help stratify patients who could potentially benefit from early right ventricular assist device implantation.

The cerebral cavernous malformation signaling pathway promotes vascular integrity via Rho GTPases

Cerebral cavernous malformation (CCM) is a common vascular dysplasia that affects both systemic and central nervous system blood vessels. Loss of function mutations in the CCM2 gene cause CCM. Here we show that targeted disruption of Ccm2 in mice results in failed lumen formation and early embryonic death through an endothelial cell autonomous mechanism. We show that CCM2 regulates endothelial cytoskeletal architecture, cell-to-cell interactions and lumen formation. Heterozygosity at Ccm2, a genotype equivalent to that in human CCM, results in impaired endothelial barrier function. On the basis of our biochemical studies indicating that loss of CCM2 results in activation of RHOA GTPase, we rescued the cellular phenotype and barrier function in heterozygous mice with simvastatin, a drug known to inhibit Rho GTPases. These data offer the prospect for pharmacological treatment of a human vascular dysplasia with a widely available and safe drug.

Targeting Robo4-dependent Slit signaling to survive the cytokine storm in sepsis and influenza

Blunting increased vascular permeability caused by an infection-induced cytokine storm with a Slit ligand increased survival in rodent models of sepsis and viral infection. Batten Down the Vascular Hatches Against the Storm An organism under stress from a massive infection or burn reacts strongly to protect itself. Body-wide inflammation is triggered, but this response can have negative effects of its own. These can include a fast heart rate, abnormally high temperature, and a marked discharge of cytokines from the immune system, called a cytokine storm. Death often occurs in these patients, a result of the failure of multiple organs. In mice, London et al. now inhibit one of the consequences of a cytokine storm—leakage from the vasculature into the intercellular space—and can thereby prevent the lethal effects of bacterial and viral infection. Cytokines released during a cytokine storm, including tumor necrosis factor and interleukin-1β, act on the cells of the vascular lining, weakening their junctions and allowing cells and fluid to leak in. Because the resulting edema is one cause of organ failure, London et al. have targeted this process. They show that an abbreviated version of a soluble ligand, called Slit, when added to cultured vascular endothelial cells, can strengthen the cell-cell contacts. Acting by increasing the amount of a cell adhesion protein, vascular endothelial cadherin, on the cell surface, Slit reduced the permeability of the endothelial cell layer. This was also true in whole animals; the authors injected mice with an immunogenic bacterial protein to simulate infection and then measured vascular leakage. They then tested whether Slit could help mice survive a severe infection. Whether infected with gut bacteria or H5N1 flu, treatment of the mice with the abbreviated Slit molecule improved their odds of surviving. Further, the ability of Slit to reduce vascular permeability in the face of a severe infection depended on another signaling molecule, the Robo4 receptor. Sepsis and other illnesses in which a cytokine storm is triggered are difficult to treat effectively. The standard of care is rapid antibiotic administration and supportive treatment of patients, but this is too often ineffective. The approach described here by London et al. may yield another tool to fight the cytokine storm, a way to strengthen the ability of the body to withstand its own assault. The innate immune system provides a first line of defense against invading pathogens by releasing multiple inflammatory cytokines, such as interleukin-1β and tumor necrosis factor–α, which directly combat the infectious agent and recruit additional immune responses. This exuberant cytokine release paradoxically injures the host by triggering leakage from capillaries, tissue edema, organ failure, and shock. Current medical therapies target individual pathogens with antimicrobial agents or directly either blunt or boost the host’s immune system. We explored a third approach: activating with the soluble ligand Slit an endothelium-specific, Robo4-dependent signaling pathway that strengthens the vascular barrier, diminishing deleterious aspects of the host’s response to the pathogen-induced cytokine storm. This approach reduced vascular permeability in the lung and other organs and increased survival in animal models of bacterial endotoxin exposure, polymicrobial sepsis, and H5N1 influenza. Thus, enhancing the resilience of the host vascular system to the host’s innate immune response may provide a therapeutic strategy for treating multiple infectious agents.

Developmental adaptation of the mouse cardiovascular system to elastin haploinsufficiency

Supravalvular aortic stenosis is an autosomal-dominant disease of elastin (Eln) insufficiency caused by loss-of-function mutations or gene deletion. Recently, we have modeled this disease in mice (Eln+/-) and found that Eln haploinsufficiency results in unexpected changes in cardiovascular hemodynamics and arterial wall structure. Eln+/- animals were found to be stably hypertensive from birth, with a mean arterial pressure 25-30 mmHg higher than their wild-type counterparts. The animals have only moderate cardiac hypertrophy and live a normal life span with no overt signs of degenerative vascular disease. Examination of arterial mechanical properties showed that the inner diameters of Eln+/- arteries were generally smaller than wild-type arteries at any given intravascular pressure. Because the Eln+/- mouse is hypertensive, however, the effective arterial working diameter is comparable to that of the normotensive wild-type animal. Physiological studies indicate a role for the renin-angiotensin system in maintaining the hypertensive state. The association of hypertension with elastin haploinsufficiency in humans and mice strongly suggests that elastin and other proteins of the elastic fiber should be considered as causal genes for essential hypertension.