Discovery of a new class of integrin antibodies for fibrosis.

Lung fibrosis, or the scarring of the lung, is a devastating disease with huge unmet medical need. There are limited treatment options and its prognosis is worse than most types of cancer. We previously discovered that MK-0429 is an equipotent pan-inhibitor of αv integrins that reduces proteinuria and kidney fibrosis in a preclinical model. In the present study, we further demonstrated that MK-0429 significantly inhibits fibrosis progression in a bleomycin-induced lung injury model. In search of newer integrin inhibitors for fibrosis, we characterized monoclonal antibodies discovered using Adimab's yeast display platform. We identified several potent neutralizing integrin antibodies with unique human and mouse cross-reactivity. Among these, Ab-31 blocked the binding of multiple αv integrins to their ligands with IC50s comparable to those of MK-0429. Furthermore, both MK-0429 and Ab-31 suppressed integrin-mediated cell adhesion and latent TGFß activation. In IPF patient lung fibroblasts, TGFß treatment induced profound αSMA expression in phenotypic imaging assays and Ab-31 demonstrated potent in vitro activity at inhibiting αSMA expression, suggesting that the integrin antibody is able to modulate TGFß action though mechanisms beyond the inhibition of latent TGFß activation. Together, our results highlight the potential to develop newer integrin therapeutics for the treatment of fibrotic lung diseases.

Problematic Internet use and the risk of suicide ideation in Chinese adolescents: A cross-sectional analysis.

To evaluate the relationships between problematic Internet use (PIU) and suicidal ideation (SI) among adolescents, we encompassed 12,507 participants (16.6 ± 0.8 years). The occurrence of mood disorders, quality of life (QOL), personality traits and SI were compared in adolescents with and without PIU. Multilevel logistic regression models, trend analysis and interaction analysis were employed. A total of 2,809 (22.46%) adolescents reported SI. PIU was assessed using Internet Addiction Test score (IATs), and 3,442 (27.52%) participants met the criteria for PIU (IATs ≥ 40). PIU was significantly and independently associated with SI [AOR for suicidal ideation (vs. IATs < 40): 1.00 for 40-59 points; 1.3 (CI, 1.2-1.5): 60-79 points; 1.7 (CI, 1.4-2.1): 80-100 points; and 2.2 (CI, 1.2-3.9)]. Trend analysis demonstrated that PIU increased the risk of SI in each of the subgroups (p for trend ≤ 0.001 for each). Interaction analysis showed an association of PIU and SI that were dependent on mood disorders, QOL, impulsivity and aggression (p-value for interaction < 0.05). These findings highlight the need for a range of cross disciplinary health interventions to afflicted families, students, and clinicians, to increase the awareness of adverse PIU effects.

Smooth Muscle Hypoxia-Inducible Factor 1α Links Intravascular Pressure and Atherosclerosis--Brief Report.

OBJECTIVE: We hypothesized that the hypoxia-inducible factor (HIF) 1α in vascular smooth muscle contributes to the development of atherosclerosis, and links intravascular pressure to this process. APPROACH AND RESULTS: Transverse aortic constriction was used to create high-pressure vascular segments in control, apolipoprotein E (ApoE)(-/-), smooth muscle-HIF1α(-/-), and ApoE(-/-)×smooth muscle-HIF1α(-/-) double-knockout mice. Transverse aortic constriction selectively induced atherosclerosis in high-pressure vascular segments in young ApoE(-/-) mice on normal chow, including coronary plaques within 1 month. Concomitant deletion of HIF1α from smooth muscle significantly reduced vascular inflammation, and attenuated atherosclerosis. CONCLUSIONS: HIF1α in vascular smooth muscle plays an important role in the pathogenesis of atherosclerosis, and may provide a mechanistic link between blood pressure, vascular inflammation, and lipid deposition.

Normal glucose uptake in the brain and heart requires an endothelial cell-specific HIF-1α-dependent function.

Although intimately positioned between metabolic substrates in the bloodstream and the tissue parenchymal cells that require these substrates, a major role of the vascular endothelium in the regulation of tissue metabolism has not been widely appreciated. We hypothesized that via control of transendothelial glucose transport and contributing paracrine mechanisms the endothelium plays a major role in regulating organ and tissue glucose metabolism. We further hypothesized that the hypoxia-inducible factor -1α (HIF-1α) plays an important role in coordinating these endothelial functions. To test these hypotheses, we generated mice with endothelial cell-specific deletion of HIF-1α. Loss of HIF in the endothelium resulted in significantly increased fasting blood glucose levels, a blunted insulin response with delayed glucose clearance from the blood after i.v. loading, and significantly decreased glucose uptake into the brain and heart. Endothelial HIF-1α knockout mice also exhibited a reduced cerebrospinal fluid/blood glucose ratio, a finding consistent with reduced transendothelial glucose transport and a diagnostic criterion for the Glut1 deficiency genetic syndrome. Endothelial cells from these mice demonstrated decreased Glut1 levels and reduced glucose uptake that was reversed by forced expression of Glut1. These data strongly support an important role of the vascular endothelium in determining whole-organ glucose metabolism and indicate that HIF-1α is a critical mediator of this function.

Renalase deficiency aggravates ischemic myocardial damage.

Chronic kidney disease (CKD) leads to an 18-fold increase in cardiovascular complications not fully explained by traditional risk factors. Levels of renalase, a recently discovered oxidase that metabolizes catecholamines, are decreased in CKD. Here we show that renalase deficiency in a mouse knockout model causes increased plasma catecholamine levels and hypertension. Plasma blood urea nitrogen, creatinine, and aldosterone were unaffected. However, knockout mice had normal systolic function and mild ventricular hypertrophy but tolerated cardiac ischemia poorly and developed myocardial necrosis threefold more severe than that found in wild-type mice. Treatment with recombinant renalase completely rescued the cardiac phenotype. To gain insight into the mechanisms mediating this cardioprotective effect, we tested if gene deletion affected nitrate and glutathione metabolism, but found no differences between hearts of knockout and wild-type mice. The ratio of oxidized (NAD) to reduced (NADH) nicotinamide adenine dinucleotide in cardiac tissue, however, was significantly decreased in the hearts of renalase knockout mice, as was plasma NADH oxidase activity. In vitro studies confirmed that renalase metabolizes NADH and catecholamines. Thus, renalase plays an important role in cardiovascular pathology and its replacement may reduce cardiac complications in renalase-deficient states such as CKD.

Hypoxia-inducible factor-dependent degeneration, failure, and malignant transformation of the heart in the absence of the von Hippel-Lindau protein.

Hypoxia-inducible transcription factor 1 (HIF-1) and HIF-2alpha regulate the expression of an expansive array of genes associated with cellular responses to hypoxia. Although HIF-regulated genes mediate crucial beneficial short-term biological adaptations, we hypothesized that chronic activation of the HIF pathway in cardiac muscle, as occurs in advanced ischemic heart disease, is detrimental. We generated mice with cardiac myocyte-specific deletion of the von Hippel-Lindau protein (VHL), an essential component of an E3 ubiquitin ligase responsible for suppressing HIF levels during normoxia. These mice were born at expected frequency and thrived until after 3 months postbirth, when they developed severe progressive heart failure and premature death. VHL-null hearts developed lipid accumulation, myofibril rarefaction, altered nuclear morphology, myocyte loss, and fibrosis, features seen for various forms of human heart failure. Further, nearly 50% of VHL(-/-) hearts developed malignant cardiac tumors with features of rhabdomyosarcoma and the capacity to metastasize. As compelling evidence for the mechanistic contribution of HIF-1alpha, the concomitant deletion of VHL and HIF-1alpha in the heart prevented this phenotype and restored normal longevity. These findings strongly suggest that chronic activation of the HIF pathway in ischemic hearts is maladaptive and contributes to cardiac degeneration and progression to heart failure.

Endothelial expression of beta1 integrin is required for embryonic vascular patterning and postnatal vascular remodeling.

The largest subgroup of integrins is that containing the beta1 subunit. beta1 integrins have been implicated in a wide array of biological processes ranging from adhesion to cell growth, organogenesis, and mechanotransduction. Global deletion of beta1 integrin expression results in embryonic death at ca. embryonic day 5 (E5), a developmental time point too early to determine the effects of this integrin on vascular development. To elucidate the specific role of beta1 integrin in the vasculature, we conditionally deleted the beta1 gene in the endothelium. Homozygous deletion of beta1 integrins in the endothelium resulted in failure of normal vascular patterning, severe fetal growth retardation, and embryonic death at E9.5 to 10, although there were no overt effects on vasculogenesis. Heterozygous endothelial beta1 gene deletion did not diminish fetal or postnatal survival, but it reduced beta1 subunit expression in endothelial cells from adult mice by approximately 40%. These mice demonstrated abnormal vascular remodeling in response to experimentally altered in vivo blood flow and diminished vascularization in healing wounds. These data demonstrate that endothelial expression of beta1 integrin is required for developmental vascular patterning and that endothelial beta1 gene dosing has significant functional effects on vascular remodeling in the adult. Understanding how beta1 integrin expression is modulated may have significant clinical importance.

An engineered VEGF-activating zinc finger protein transcription factor improves blood flow and limb salvage in advanced-age mice.

Advances in understanding the relationship between protein structure and DNA binding specificity have made it possible to engineer zinc finger protein (ZFP) transcription factors to specifically activate or repress virtually any gene. To evaluate the potential clinical utility of this approach for peripheral vascular disease, we investigated the ability of an engineered vascular endothelial growth factor (VEGFa)-activating ZFP (MVZ+426b) to induce angiogenesis and rescue hindlimb ischemia in a murine model. Hindlimb ischemia was surgically induced in advanced-age C57/BL6 mice. Adenovirus (Ad) encoding either MVZ+426b or the fluorescent marker dsRed was delivered to the adducter muscle of the ischemic hindlimb, and the effects on blood flow, limb salvage, and vascularization were assessed. Ad-MVZ+426b induced expression of VEGFa at the mRNA and protein levels and stimulated a significant increase in vessel counts in the ischemic limb. This was accompanied by significantly increased blood flow and limb salvage as measured serially for 4 wk. These data demonstrate that activation of the endogenous VEGFa gene by an engineered ZFP can induce angiogenesis in a clinically relevant model and further document the feasibility of designing ZFPs to therapeutically regulate gene expression in vivo.

Cardiac myocyte-specific HIF-1alpha deletion alters vascularization, energy availability, calcium flux, and contractility in the normoxic heart.

At a resting pulse rate the heart consumes almost twice-as much oxygen per gram tissue as the brain and more than 43 times more than resting skeletal muscle (1). Unlike skeletal muscle, cardiac muscle cannot sustain anaerobic metabolism. Balancing oxygen demand with availability is crucial to cardiac function and survival, and regulated gene expression is a critical element of maintaining this balance. We investigated the role of the hypoxia-inducible transcription factor HIF-1alpha in maintaining this balance under normoxic conditions. Cardiac myocyte-specific HIF-1alpha gene deletion in the hearts of genetically engineered mice caused reductions in contractility, vascularization, high-energy phosphate content, and lactate production. This was accompanied by altered calcium flux and altered expression of genes involved in calcium handling, angiogenesis, and glucose metabolism. These findings support a central role for HIF-1alpha in coordinating energy availability and utilization in the heart and have implications for disease states in which cardiac oxygen delivery is impaired. Heart muscle requires a constant supply of oxygen. When oxygen supply does not match myocardial demand cardiac contractile dysfunction occurs, and prolongation of this mismatch leads to apoptosis and necrosis. Coordination of oxygen supply and myocardial demand involves immediate adaptations, such as coronary vasodilatation, and longer-term adaptations that include altered patterns of gene expression (2-4). How the expression of multiple genes is coordinated with oxygen availability in the heart and the impact of oxygen-dependent gene expression on cardiac function are insufficiently understood. Further elucidating these relationships may help clarify the molecular pathology of various cardiovascular disease states, including ischemic cardiomyopathy and myocardial hibernation (5, 6).