Jennifer Streeter

Opportunity Nox: The Future of NADPH Oxidases as Therapeutic Targets in Cardiovascular Disease

Over 40 years ago, NADPH (nicotinamide adenine dinucleotide phosphate) oxidase 2 (Nox2) was discovered in phagocytes and found to be essential in innate immunity. More than 20 years passed before additional Nox isoforms were discovered; and since then, studies have revealed that several of these isoforms (Nox1, Nox2, Nox4, and Nox5) are found in human cardiac and vascular cells and contribute to the pathogenesis of cardiovascular diseases (CVDs). Recently, major efforts have focused on identifying inhibitors capable of ameliorating Nox-mediated CVD. In this review, we briefly discuss the role of each Nox isoform in CVD, identify steps in Nox signaling that will serve as potential targets for the design of therapeutics, and highlight innovative strategies likely to yield effective Nox inhibitors within the next decade.

Inhibition of NADPH Oxidase by Apocynin Attenuates Progression of Atherosclerosis

Of the multiple sources of reactive oxygen species (ROS) in the blood vessel, NADPH oxidases are the primary source. Whereas several studies have implicated NADPH oxidases in the initiation of atherosclerosis, their roles in disease progression are incompletely understood. Our objective was to determine the potential clinical relevance of inhibiting NADPH oxidase in established atherosclerosis. Using a hypercholesteremic murine model of atherosclerosis (ApoE−/−/LDLR−/− (AS) mice on normal chow diet), we first established a time-dependent relationship between superoxide levels and lesion size in AS mice. Next, we identified NADPH oxidase as the primary source of ROS in atherosclerotic lesions. Treatment of aortic segments from AS mice with apocynin, which interferes with NADPH oxidase activation in part by preventing translocation of the subunit p47phox, significantly reduced superoxide levels. Moreover, addition of apocynin to the drinking water of AS mice produced a decrease in lesion size as compared to untreated AS mice, with the effect most pronounced in the thoracoabdominal aorta but absent from the aortic arch. Granulocyte function in AS+apocynin mice was suppressed, confirming efficacy of apocynin treatment. We conclude that apocynin attenuates the progression of atherosclerosis in hypercholesterolemic mice, potentially by its ability to inhibit generation of superoxide by NADPH oxidase.

Phosphorylation of Nox1 Regulates Association With NoxA1 Activation Domain

Rationale: Activation of Nox1 initiates redox-dependent signaling events crucial in the pathogenesis of vascular disease. Selective targeting of Nox1 is an attractive potential therapy, but requires a better understanding of the molecular modifications controlling its activation. Objective: To determine whether posttranslational modifications of Nox1 regulate its activity in vascular cells. Methods and Results: We first found evidence that Nox1 is phosphorylated in multiple models of vascular disease. Next, studies using mass spectroscopy and a pharmacological inhibitor demonstrated that protein kinase C-beta1 mediates phosphorylation of Nox1 in response to tumor necrosis factor-&agr;. siRNA-mediated silencing of protein kinase C-beta1 abolished tumor necrosis factor-&agr;–mediated reactive oxygen species production and vascular smooth muscle cell migration. Site-directed mutagenesis and isothermal titration calorimetry indicated that protein kinase C-beta1 phosphorylates Nox1 at threonine 429. Moreover, Nox1 threonine 429 phosphorylation facilitated the association of Nox1 with the NoxA1 activation domain and was necessary for NADPH oxidase complex assembly, reactive oxygen species production, and vascular smooth muscle cell migration. Conclusions: We conclude that protein kinase C-beta1 phosphorylation of threonine 429 regulates activation of Nox1 NADPH oxidase.

Nox1 NADPH oxidase is necessary for late but not early myocardial ischaemic preconditioning

AIMS Ischaemic preconditioning (IPC) is an adaptive mechanism that renders the myocardium resistant to injury from subsequent hypoxia. Although reactive oxygen species (ROS) contribute to both the early and late phases of IPC, their enzymatic source and associated signalling events have not yet been understood completely. Our objective was to investigate the role of the Nox1 NADPH oxidase in cardioprotection provided by IPC. METHODS AND RESULTS Wild-type (WT) and Nox1-deficient mice were treated with three cycles of brief coronary occlusion and reperfusion, followed by prolonged occlusion either immediately (early IPC) or after 24 h (late IPC). Nox1 deficiency had no impact on the cardioprotection afforded by early IPC. In contrast, deficiency of Nox1 during late IPC resulted in a larger infarct size, cardiac remodelling, and increased myocardial apoptosis compared with WT hearts. Furthermore, expression of Nox1 in WT hearts increased in response to late IPC. Deficiency of Nox1 abrogated late IPC-mediated activation of cardiac nuclear factor-κB (NF-κB) and induction of tumour necrosis factor-α (TNF-α) in the heart and circulation. Finally, knockdown of Nox1 in cultured cardiomyocytes prevented TNF-α induction of NF-κB and the protective effect of IPC on hypoxia-induced apoptosis. CONCLUSIONS Our data identify a critical role for Nox1 in late IPC and define a previously unrecognized link between TNF-α and NF-κB in mediating tolerance to myocardial injury. These findings have clinical significance considering the emergence of Nox1 inhibitors for the treatment of cardiovascular disease.

Smooth Muscle Cell–targeted RNA Aptamer Inhibits Neointimal Formation

Inhibition of vascular smooth muscle cell (VSMC) proliferation by drug eluting stents has markedly reduced intimal hyperplasia and subsequent in-stent restenosis. However, the effects of antiproliferative drugs on endothelial cells (EC) contribute to delayed re-endothelialization and late stent thrombosis. Cell-targeted therapies to inhibit VSMC remodeling while maintaining EC health are necessary to allow vascular healing while preventing restenosis. We describe an RNA aptamer (Apt 14) that functions as a smart drug by preferentially targeting VSMCs as compared to ECs and other myocytes. Furthermore, Apt 14 inhibits phosphatidylinositol 3-kinase/protein kinase-B (PI3K/Akt) and VSMC migration in response to multiple agonists by a mechanism that involves inhibition of platelet-derived growth factor receptor (PDGFR)-β phosphorylation. In a murine model of carotid injury, treatment of vessels with Apt 14 reduces neointimal formation to levels similar to those observed with paclitaxel. Importantly, we confirm that Apt 14 cross-reacts with rodent and human VSMCs, exhibits a half-life of ~300 hours in human serum, and does not elicit immune activation of human peripheral blood mononuclear cells. We describe a VSMC-targeted RNA aptamer that blocks cell migration and inhibits intimal formation. These findings provide the foundation for the translation of cell-targeted RNA therapeutics to vascular disease.Inhibition of vascular smooth muscle cell (VSMC) proliferation by drug eluting stents has markedly reduced intimal hyperplasia and subsequent in-stent restenosis. However, the effects of antiproliferative drugs on endothelial cells (EC) contribute to delayed re-endothelialization and late stent thrombosis. Cell-targeted therapies to inhibit VSMC remodeling while maintaining EC health are necessary to allow vascular healing while preventing restenosis. We describe an RNA aptamer (Apt 14) that functions as a smart drug by preferentially targeting VSMCs as compared to ECs and other myocytes. Furthermore, Apt 14 inhibits phosphatidylinositol 3-kinase/protein kinase-B (PI3K/Akt) and VSMC migration in response to multiple agonists by a mechanism that involves inhibition of platelet-derived growth factor receptor (PDGFR)-β phosphorylation. In a murine model of carotid injury, treatment of vessels with Apt 14 reduces neointimal formation to levels similar to those observed with paclitaxel. Importantly, we confirm that Apt 14 cross-reacts with rodent and human VSMCs, exhibits a half-life of ~300 hours in human serum, and does not elicit immune activation of human peripheral blood mononuclear cells. We describe a VSMC-targeted RNA aptamer that blocks cell migration and inhibits intimal formation. These findings provide the foundation for the translation of cell-targeted RNA therapeutics to vascular disease.

61. Vascular Smooth Muscle Cell RNA Aptamers for the Treatment of Cardiovascular Disease

Cardiovascular disease (CVD) is the leading cause of mortality in many countries. Many vascular disorders, including in-stent restenosis, arteriosclerosis, vein graft disease, and cardiac allograft arteriopathy are caused by pathological vascular smooth muscle cell (VSMC) remodeling following injury. An ideal therapeutic intervention would target the VSMCs without impairing the injured vessel re-endothelialization. However, current therapies do not selectively prevent pathological VSMC remodeling leading to impaired re-endothelization, late stent thrombosis and death. Thus, there is a clear need for cell-targeted treatment and prevention options of pathological VSMC remodeling.Our group has described the development of VSMC-specific, aptamers for (1) modulating signaling pathways associated with pathological VSMC remodeling and (2) delivering therapeutic molecules to these cells in vivo. Here we demonstrate that one of these aptamers, Vapt14, inhibits protein kinase B (PKB)/Akt activation and VSMC migration in response to multiple agonists by a mechanism that involves inhibition of platelet-derived growth factor receptor (PDGFR)-beta phosphorylation. In a murine model of carotid injury, treatment of vessels with Vapt14 reduces intimal:medial thickness to levels comparable to that of paclitaxel. Importantly, we confirm that Vapt14 cross-reacts with rodent and human VSMCs, exhibits a half-life of ~300 hours in human serum, and does not elicit immune activation of human peripheral blood mononuclear cells (PBMCs) in vitro. In addition, we confirm delivery of Vapt14 to VSMC in vitro and in vivo with fluorescence microscopy. Studies are being expanded to evaluate aptamer-mediated delivery of therapeutic biomolecules (e.g. small molecules, RNAi modulators) to areas of vascular injury. In summary this work provides an essential foundation for the translation of cell-targeted RNA therapeutics to multiple hyperplastic vascular diseases.

Any questions? A concise guide to navigating the Q&A session after a presentation.

The ability to give an effective and engaging presentation is a crucial skill that every scientist must master early in his or her career. It is not only a useful skill for conferences, meetings and seminars; a successful and convincing presentation can also open the door to fruitful collaborations, successful grant applications or a new job. Many researchers therefore spend a considerable amount of time and effort preparing and practising for an upcoming talk. In fact, they often rehearse their presentation to the point they can recite the entire talk on cue. However, few scientists practice taking and answering questions from an audience. Mastering this skill is important because even the most well‐rehearsed talk can be easily ruined by a poor Q&A session. After all, nearly anyone can memorize a talk, but it is the way a presenter handles questions that best demonstrates his or her knowledge and understanding of the subject. Moreover, in scientific talks, it is often the last impression—that is, the Q&A session—that counts. Therefore, preparing for the Q&A is as important, if not more important, than preparing for the talk itself. > … preparing for the Q&A is as important, if not more important, than preparing for the talk itself The focus of this article is therefore on preparing for and answering questions effectively and the steps that can be taken to improve this skill. Many readers might recognize the situations outlined in this article; although some of these might seem daunting, there is a solution to every one. The first step in conducting an effective QA not welcoming questions …