Epithelia of the vertebrate intestinal tract characteristically maintain an inflammatory hyporesponsiveness toward the lumenal prokaryotic microflora. We report the identification of enteric organisms (nonvirulent Salmonella strains) whose direct interaction with model human epithelia attenuate synthesis of inflammatory effector molecules elicited by diverse proinflammatory stimuli. This immunosuppressive effect involves inhibition of the inhibitor kappaB/nuclear factor kappaB (IkappaB/NF-kappaB) pathway by blockade of IkappaB-alpha degradation, which prevents subsequent nuclear translocation of active NF-kappaB dimer. Although phosphorylation of IkappaB-alpha occurs, subsequent polyubiquitination necessary for regulated IkappaB-alpha degradation is completely abrogated. These data suggest that prokaryotic determinants could be responsible for the unique tolerance of the gastrointestinal mucosa to proinflammatory stimuli.
Objectives To examine selective macrophage differentiation occurring in areas of intraplaque hemorrhage in human atherosclerosis. Background Macrophage subsets are recognized in atherosclerosis but the stimulus for and importance of differentiation programs remains unknown. Methods We used freshly isolated human monocytes, a rabbit model, and human atherosclerotic plaques to analyze macrophage differentiation in response to hemorrhage. Results Macrophages characterized by high expression of both mannose and CD163 receptors preferentially exist in atherosclerotic lesions at sites of intraplaque hemorrhage. These hemoglobin (Hb)-stimulated macrophages, M(Hb), are devoid of neutral lipids typical of foam cells. In vivo modeling of hemorrhage in the rabbit model demonstrated that sponges exposed to red cells showed an increase in mannose receptor positive macrophages only when these cells contained hemoglobin (Hb). Cultured human monocytes exposed to hemoglobin:haptoglobin complexes (Hb:Hp), but not IL-4, expressed the M(Hb) phenotype and were characterized by their resistance to cholesterol loading and upregulation of ABC transporters. M(Hb) demonstrated increased ferroportin (FPN) expression, reduced intracellular iron, and reactive oxygen species (ROS). Degradation of FPN using hepcidin increased ROS, inhibited ABCA1 expression, and cholesterol efflux to ApoAI, suggesting reduced ROS triggers these effects. Knockdown of liver x receptor alpha (LXRα) inhibited ABC transporter expression in M(Hb) and macrophages differentiated in the anti-oxidant superoxide dismutase. Lastly, liver X receptor α (LXR) luciferase reporter activity was increased in M(Hb) and significantly reduced by overnight treatment with hepcidin. Collectively, these data suggest reduced ROS triggers LXRα activation and macrophage reverse cholesterol transport (RCT). Conclusions Hb is a stimulus for macrophage differentiation in human atherosclerotic plaques. A reduction of macrophage intracellular iron plays an important role in this non- foam cell phenotype by reducing ROS, which drives transcription of ABC transporters through activation of LXRα. Reduction of macrophage intracellular iron may be a promising avenue to increase macrophage RCT.
Intake of hemoglobin by the hemoglobin-haptoglobin receptor CD163 leads to a distinct alternative non-foam cell antiinflammatory macrophage phenotype that was previously considered atheroprotective. Here, we reveal an unexpected but important pathogenic role for these macrophages in atherosclerosis. Using human atherosclerotic samples, cultured cells, and a mouse model of advanced atherosclerosis, we investigated the role of intraplaque hemorrhage on macrophage function with respect to angiogenesis, vascular permeability, inflammation, and plaque progression. In human atherosclerotic lesions, CD163+ macrophages were associated with plaque progression, microvascularity, and a high level of HIF1α and VEGF-A expression. We observed irregular vascular endothelial cadherin in intraplaque microvessels surrounded by CD163+ macrophages. Within these cells, activation of HIF1α via inhibition of prolyl hydroxylases promoted VEGF-mediated increases in intraplaque angiogenesis, vascular permeability, and inflammatory cell recruitment. CD163+ macrophages increased intraplaque endothelial VCAM expression and plaque inflammation. Subjects with homozygous minor alleles of the SNP rs7136716 had elevated microvessel density, increased expression of CD163 in ruptured coronary plaques, and a higher risk of myocardial infarction and coronary heart disease in population cohorts. Thus, our findings highlight a nonlipid-driven mechanism by which alternative macrophages promote plaque angiogenesis, leakiness, inflammation, and progression via the CD163/HIF1α/VEGF-A pathway.
Objectives We recently reported that lowering of macrophage free intracellular iron increases expression of cholesterol efflux transporters ABCA1 and ABCG1 by reducing generation of reactive oxygen species. In this study, we explore whether reducing macrophage intracellular iron levels via pharmacologic suppression of hepcidin can increase macrophage-specific expression of cholesterol efflux transporters and reduce atherosclerosis. Methods and Results To suppress hepcidin, increase expression of the iron exporter ferroportin (FPN), and reduce macrophage intracellular iron, we used a small molecule inhibitor of BMP signaling, LDN 193189 (LDN). LDN (10 mg/kg i.p. bid) was administered to mice and its effects on atherosclerosis, intracellular iron, oxidative stress, lipid efflux, and foam cell formation were measured in plaques and peritoneal macrophages. Long-term LDN administration to Apo E (-/-) mice increased ABCA1 immunoreactivity within intraplaque macrophages by 3.7-fold (n=8; p=0.03), reduced oil-red-o positive lipid area by 50% (n=8; p=0.02) and decreased total plaque area by 43% (n=8; p=0.001). LDN suppressed liver hepcidin transcription and increased macrophage FPN, lowering intracellular iron and hydrogen peroxide production. LDN treatment increased macrophage ABCA1 and ABCG1 expression, significantly raised cholesterol efflux to ApoA-1 and decreased foam cell formation. All preceding LDN-induced effects on cholesterol efflux were reversed by exogenous hepcidin administration, suggesting that modulation of intracellular iron levels within macrophages as the mechanism by which LDN triggers these effects. Conclusion These data suggest that pharmacologic manipulation of iron homeostasis may be a promising target to increase macrophage reverse cholesterol transport and limit atherosclerosis.
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