Claudio Napoli

Fatty streak formation occurs in human fetal aortas and is greatly enhanced by maternal hypercholesterolemia. Intimal accumulation of low density lipoprotein and its oxidation precede monocyte recruitment into early atherosclerotic lesions.

To determine whether oxidized LDL enhances atherogenesis by promoting monocyte recruitment into the vascular intima, we investigated whether LDL accumulation and oxidation precede intimal accumulation of monocytes in human fetal aortas (from spontaneous abortions and premature newborns who died within 12 h; fetal age 6.2+/-1.3 mo). For this purpose, a systematic assessment of fatty streak formation was carried out in fetal aortas from normocholesterolemic mothers (n = 22), hypercholesterolemic mothers (n = 33), and mothers who were hypercholesterolemic only during pregnancy (n = 27). Fetal plasma cholesterol levels showed a strong inverse correlation with fetal age (R = -0.88, P < 0.0001). In fetuses younger than 6 mo, fetal plasma cholesterol levels correlated with maternal ones (R = 0.86, P = 0.001), whereas in older fetuses no such correlation existed. Fetal aortas from hypercholesterolemic mothers and mothers with temporary hypercholesterolemia contained significantly more and larger lesions (758,651+/-87,449 and 451,255+/-37,448 micron2 per section, respectively; mean+/-SD) than aortas from normocholesterolemic mothers (61,862+/-9,555 micron2; P < 0.00005). Serial sections of the arch, thoracic, and abdominal aortas were immunostained for recognized markers of atherosclerosis: macrophages, apo B, and two different oxidation-specific epitopes (malondialdehyde- and 4-hydroxynonenal-lysine). Of the atherogenic sites that showed positive immunostaining for at least one of these markers, 58.6% were established lesions containing both macrophage/foam cells and oxidized LDL (OxLDL). 17.3% of all sites contained only native LDL, and 13.3% contained only OxLDL without monocyte/ macrophages. In contrast, only 4.3% of sites contained isolated monocytes in the absence of native or oxidized LDL. In addition, 6.3% of sites contained LDL and macrophages but few oxidation-specific epitopes. These results demonstrate that LDL oxidation and formation of fatty streaks occurs already during fetal development, and that both phenomena are greatly enhanced by maternal hypercholesterolemia. The fact that in very early lesions LDL and OxLDL are frequently found in the absence of monocyte/macrophages, whereas the opposite is rare, suggests that intimal LDL accumulation and oxidation contributes to monocyte recruitment in vivo.

Nitric oxide as a signaling molecule in the vascular system: an overview.

In retrospect, basic research in the fields of nitric oxide (NO) and cyclic guanosine monophosphate (cGMP) during the past two decades appears to have followed a logical course, beginning with the findings that NO and cGMP are vascular smooth muscle relaxants, that nitroglycerin relaxes smooth muscle by metabolism to NO, progressing to the discovery that mammalian cells synthesize NO, and finally the revelation that NO is a neurotransmitter mediating vasodilation in specialized vascular beds. A great deal of basic and clinical research on the physiologic and pathophysiologic roles of NO in cardiovascular function has been conducted since the discovery that endothelium-derived relaxing factor (EDRF) is NO. The new knowledge on NO should enable investigators in this field to develop novel and more effective therapeutic strategies for the prevention, diagnosis, and treatment of numerous cardiovascular disorders. The goal of this review was to highlight the early research that led to our current understanding of the pathophysiologic role of NO in cardiovascular medicine. Furthermore, we discussed the possible mechanism of some drugs interfering with NO signaling cascade.

Adenovirus Serotype 5 Hexon Mediates Liver Gene Transfer

Adenoviruses are used extensively as gene transfer agents, both experimentally and clinically. However, targeting of liver cells by adenoviruses compromises their potential efficacy. In cell culture, the adenovirus serotype 5 fiber protein engages the coxsackievirus and adenovirus receptor (CAR) to bind cells. Paradoxically, following intravascular delivery, CAR is not used for liver transduction, implicating alternate pathways. Recently, we demonstrated that coagulation factor (F)X directly binds adenovirus leading to liver infection. Here, we show that FX binds to the Ad5 hexon, not fiber, via an interaction between the FX Gla domain and hypervariable regions of the hexon surface. Binding occurs in multiple human adenovirus serotypes. Liver infection by the FX-Ad5 complex is mediated through a heparin-binding exosite in the FX serine protease domain. This study reveals an unanticipated function for hexon in mediating liver gene transfer in vivo.

Influence of maternal hypercholesterolaemia during pregnancy on progression of early atherosclerotic lesions in childhood: Fate of Early Lesions in Children (FELIC) study

BACKGROUND Children generally have low cholesterol and no clinical manifestations of atherosclerosis, but fatty-streak formation begins in fetuses and is greatly increased by maternal hypercholesterolaemia during pregnancy. In the FELIC study we assessed the evolution of such lesions during childhood. METHODS Computer-assisted imaging was used to measure the area of the largest individual lesion and the cumulative lesion area per section in serial cross-sections through the entire aortic arch and abdominal aorta of 156 normocholesterolaemic children aged 1-13 years, who died of trauma and other causes. Children were classified by whether their mother had been normocholesterolaemic (n=97) or hypercholesterolaemic (n=59) during pregnancy. Atherosclerosis was correlated with 13 established or potential risk factors. Findings The largest fatty streaks in the aortic arch of children younger than 3 years of hypercholesterolaemic mothers were 64% smaller than those previously found in corresponding fetuses (p<0.0001), which suggests that fetal fatty streaks may regress after birth. In the two groups, lesion size in the aortic arch and abdominal aorta increased linearly with age (r=0.87-0.98). However, lesions progressed strikingly faster in children of hypercholesterolaemic mothers than in those of normocholesterolaemic mothers (p<0.0001). Conventional risk factors for atherosclerosis in children or mothers correlated with lesion size, but did not account for the faster progression of atherogenesis in normocholesterolaemic children of hypercholesterolaemic mothers. INTERPRETATION Our results suggest that maternal hypercholesterolaemia during pregnancy induces changes in the fetal aorta that determine the long-term susceptibility of children to fatty-streak formation and subsequent atherosclerosis. If so, cholesterol-lowering interventions in hypercholesterolaemic mothers during pregnancy may decrease atherogenesis in children.

Akt induces enhanced myocardial contractility and cell size in vivo in transgenic mice

The serine-threonine kinase Akt seems to be central in mediating stimuli from different classes of receptors. In fact, both IGF-1 and IL6-like cytokines induce hypertrophic and antiapoptotic signals in cardiomyocytes through PI3K-dependent Akt activation. More recently, it was shown that Akt is involved also in the hypertrophic and antiapoptotic effects of β-adrenergic stimulation. Thus, to determine the effects of Akt on cardiac function in vivo, we generated a model of cardiac-specific Akt overexpression in mice. Transgenic mice were generated by using the E40K, constitutively active mutant of Akt linked to the rat α-myosin heavy chain promoter. The effects of cardiac-selective Akt overexpression were studied by echocardiography, cardiac catheterization, histological and biochemical techniques. We found that Akt overexpression produced cardiac hypertrophy at the molecular and histological levels, with a significant increase in cardiomyocyte cell size and concentric LV hypertrophy. Akt-transgenic mice also showed a remarkable increase in cardiac contractility compared with wild-type controls as demonstrated by the analysis of left ventricular (dP/dtmax) in an invasive hemodynamic study, although with graded dobutamine infusion, the maximum response was not different from that in controls. Diastolic function, evaluated by left ventricular dP/dtmin, was not affected at rest but was impaired during graded dobutamine infusion. Isoproterenol-induced cAMP levels, β-adrenergic receptor (β-AR) density, and β-AR affinity were not altered compared with control mice. Moreover, studies on signaling pathway activation from myocardial extracts demonstrated that glycogen synthase kinase3-β is phosphorylated, whereas p42/44 mitogen-activated protein kinases is not, indicating that Akt induces hypertrophy in vivo by activating the glycogen synthase kinase3-β/GATA 4 pathway. In summary, our results not only demonstrate that Akt regulates cardiomyocyte cell size in vivo, but, importantly, show that Akt modulates cardiac contractility in vivo without directly affecting β-AR signaling capacity.

Statin effects beyond lipid lowering—are they clinically relevant?

Currently, five different statins (simvastatin,pravastatin, lovastatin, fluvastatin, and atorvastatin) are approved for treatment of hypercholesterolemia in humans and two new compounds (rosuvastatin and NK-104) are under investigation.1,2 Despite differences in their pharmacokinetic profiles, all statins have at least onecharacteristic in common: they block the conversion of HMG-CoA to mevalonic acid with consecutive attenuation of the biosynthesis of cholesterol (Fig. 1), which is associated with a reduction in serum total and low-density lipoprotein (LDL) cholesterol of as much as 20–31 and 28–42% during chronic treatment.3 Because of these properties, statins have become the most widely prescribed lipid-lowering drugs in patients with elevatedserum cholesterol levels. Several large trialsdemonstrated that statins are not only safe and well tolerated but also significantly decrease cardiovascular morbidity and mortality in hypercholesterolemic patients in both primary and secondary prevention.4–8 However, the striking benefit achieved with statin treatment in patients with a wide range of cholesterol levels, which cannot be attributed to their cholesterol lowering effect alone, has raised the question about the possible presence of additional effects of statins beyond their impact on serum cholesterol levels. Indeed, in recent years a substantial quantity of data has accumulated showing that statins exert variouseffects on multiple targets, which are independent of their plasma cholesterol lowering properties. Fig. 1 The effect of statins on the mevalonate pathway. Statins inhibit conversion of HMG-CoA to mevalonate by competitive inhibition of the rate limiting enzyme HMG-CoA reductase. Herewith, statins not only inhibit the cellular production of cholesterol but also the biosynthesis of several intermediates of the mevalonate pathway (e.g. farnesylpyrophosphate and geranylgeranylpyrophosphate). These so-called isoprenoids are essential for the posttranslational modification of several proteins involved in important intracellular signaling pathways (e.g. the small GTP-binding proteins Ras and Rho). Many of these so-called pleiotropic effects have been shown to be secondary to the …

Deletion of the p66Shc longevity gene reduces systemic and tissue oxidative stress, vascular cell apoptosis, and early atherogenesis in mice fed a high-fat diet

Several experimental and clinical studies have shown that oxidized low-density lipoprotein and oxidation-sensitive mechanisms are central in the pathogenesis of vascular dysfunction and atherogenesis. Here, we have used p66Shc−/− and WT mice to investigate the effects of high-fat diet on both systemic and tissue oxidative stress and the development of early vascular lesions. To date, the p66Shc−/− mouse is the unique genetic model of increased resistance to oxidative stress and prolonged life span in mammals. Computer-assisted image analysis revealed that chronic 21% high-fat treatment increased the aortic cumulative early lesion area by ≈21% in WT mice and only by 3% in p66Shc−/− mice. Early lesions from p66Shc−/− mice had less content of macrophage-derived foam cells and apoptotic vascular cells, in comparison to the WT. Furthermore, in p66Shc−/− mice, but not WT mice, we found a significant reduction of systemic and tissue oxidative stress (assessed by isoprostanes, plasma low-density lipoprotein oxidizability, and the formation of arterial oxidation-specific epitopes). These results support the concept that p66Shc−/− may play a pivotal role in controlling systemic oxidative stress and vascular diseases. Therefore, p66Shc might represent a molecular target for therapies against vascular diseases.

Increased Oxidative Stress in Experimental Renovascular Hypertension

The pathophysiological mechanisms responsible for maintenance of chronic renovascular hypertension remain undefined. Excess angiotensin II generation may lead to release of reactive oxygen species and increased vasoconstrictor activity. To examine the potential involvement of oxidation-sensitive mechanisms in the pathophysiology of renovascular hypertension, blood samples were collected and renal blood flow measured with electron-beam computed tomography in pigs 5 and 10 weeks after induction of unilateral renal artery stenosis (n=7) or sham operation (n=7). Five weeks after procedure, plasma renin activity and mean arterial pressure were elevated in hypertensive pigs. Levels of prostaglandin F2&agr; (PGF2&agr;)–isoprostanes, vasoconstrictors and markers of oxidative stress, also were significantly increased (157±21 versus 99±16 pg/mL;P <0.05) and correlated with both plasma renin activity (r =0.83) and arterial pressure (r =0.82). By 10 weeks, plasma renin activity returned to baseline but arterial pressure remained elevated (144±10 versus 115±5 mm Hg;P <0.05). Isoprostane levels remained high and still correlated directly with the increase in arterial pressure (r =0.7) but not with plasma renin activity. Stenotic kidney blood flow was decreased at both studies. In shock-frozen cortical tissue, ex vivo endogenous intracellular radical scavengers were significantly decreased in both kidneys. The present study demonstrates, for the first time, that in early renovascular hypertension, an increase in plasma renin activity and arterial pressure is associated with increased systemic oxidative stress. When plasma renin activity later declines, PGF2&agr;-isoprostanes remain elevated, possibly due to local activation or slow responses to angiotensin II, and may participate in sustenance of arterial pressure. Moreover, oxidation-sensitive mechanisms may influence ischemic and hypertensive parenchymal renal injury.

Multiple role of reactive oxygen species in the arterial wall

Increased oxidative stress plays an important role in vascular dysfunction and atherogenesis. Both systemic factors, such as hypercholesterolemia and hyperglycemia, and local factors, such as activation of macrophages and T cells, may contribute to oxidative stress. Oxidation of lipids in lipoproteins and cell membranes leads to functionally important modifications of proteins that affect their recognition by cell surface receptors and protein–protein interactions within the cell, including DNA binding. Oxidized LDL and extracellular oxidation modulate oxidation‐sensitive signaling pathways, but it is not clear to what extent this results from receptor‐mediated activation or from direct effects on the intracellular redox‐balance. Extensive evidence indicates that reactive oxygen species (ROS) regulate gene expression by modulating a large number of transcription factors, including the nuclear transcription factor kappa B (NFκB), the peroxisome proliferator activated receptorγ (PPARγ), and pathways linked to apoptosis. It is also increasingly recognized that cell differentiation and proliferation, cytokine expression, and programmed cell death are determined by the interactions between oxidation‐sensitive regulatory pathways previously thought to lead to distinct outcomes. Because hypercholesterolemia exerts pro‐oxidant effects both intra‐ and extracellularly and because increased ROS formation affects vascular reactivity and atherogenesis by modulating multiple signaling pathways and transcriptional events, future investigations of its atherogenic mechanisms should place greater emphasis on the net effect of such modulation on the expression of a large spectrum of genes. One way of doing this will be by defining clusters of genes responding to hypercholesterolemic stimuli—or interventions with structurally unrelated antioxidants—in analogous ways, irrespective of what regulatory pathway they are controlled by. Microarray technologies that allow simultaneous assessment of large numbers of genes may provide a tool for this approach. J. Cell. Biochem. 82: 674–682, 2001.

The fetal origins of atherosclerosis: maternal hypercholesterolemia, and cholesterol-lowering or antioxidant treatment during pregnancy influence in utero programming and postnatal susceptibility to atherogenesis

It has long been postulated that pathogenic events during fetal development influence atherosclerosis‐related diseases later in life, but the mechanisms involved are unknown. This review focuses on the evidence indicating that maternal hypercholesterolemia during pregnancy is responsible for one cascade of pathogenic events. Maternal hypercholesterolemia is associated with greatly increased fatty streak formation in human fetal arteries and accelerated progression of atherosclerosis during childhood. Recent experiments in genetically more homogeneous rabbits established that temporary diet‐induced maternal hypercholesterolemia is sufficient to enhance fetal lesion formation. More important, maternal hypercholesterolemia or ensuing pathogenic events in the fetus increase postnatal atherogenesis in response to hypercholesterolemia. Maternal treatment with cholesterol‐lowering agents or antioxidants greatly reduces fetal and postnatal atherogenesis, indicating a pathogenic role of lipid peroxidation and a potential involvement of oxidation‐sensitive signaling pathways. Experiments in a murine model showed that differences in arterial gene expression between offspring of normo‐and hypercholesterolemic mothers persist long after birth, supporting the assumption that fetal lesion formation is associated with genetic programming, which may in turn affect postnatal atherogenesis. A better understanding of pathogenic programming events in utero may lead to the identification of genes determining the susceptibility to atherosclerosis and define novel preventive approaches.—Palinski, W., Napoli, C. The fetal origins of atherosclerosis: maternal hypercholesterolemia, and cholesterol‐lowering or antioxidant treatment during pregnancy influence in utero programming and postnatal susceptibility to atherogenesis. FASEB J. 16, 1348–1360 (2002)