High-Resolution Imaging of Intravascular Atherogenic Inflammation in Live Mice

Chèvre, Raphaël; González-Granado, José-María; Megens, Remco T. A.; Sreeramkumar, Vinatha; Silvestre-Roig, Carlos; Molina-Sánchez, Pedro; Weber, Christian; Soehnlein, Oliver; Hidalgo, Andrés; Andrés, Vicente

doi:10.1161/circresaha.114.302590

Cited by 78 publications

(86 citation statements)

References 42 publications

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“…LysM is expressed in all myeloid cells including macrophages, monocytes, and granulocytes but also in AMCs, which possess similarities to the myeloid linage. 40,41 Tissue-resident myeloid cells as well as progenitor cells are present in healthy vessels and in part are LysM positive. [42][43][44][45] The deletion experiments in the present study indicate that potentially tissue-resident, adventitial-localized, clodronate-sensitive macrophages are the source of SDF1 in response to injury and 1,25-VitD3.…”

Section: Discussionmentioning

confidence: 99%

Vitamin D Promotes Vascular Regeneration

et al. 2014

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V itamin D is a misnomer. The body produces this hormone through precursors with final hydroxylation to the most active metabolite 1, 1,. Vitamin D is ingested with food or synthesized from the precursor 7-dehydrocholesterol, which is then photochemically converted in the sunlight-exposed skin into cholecalciferol (vitamin D 3 ). Active 1,25-VitD3 is generated by 2 hydroxylation steps: 25β-hydroxylation in the liver followed by 1α-hydroxylation in the kidney. The latter reaction is particularly rate limiting, and thus the effective concentration of 1,25-VitD3 is much lower than that of vitamin D 3 or 25-hydroxy-vitamin D 3 . By a positive feedback loop, 1,25-VitD3 induces 24-hydroxylase expression. Because 1,24, is water soluble and cleared by the kidney, this pathway limits the effects of the hormone, and 24-hydroxylase expression can be used as a marker for the biological activity of 1,25-VitD3. Unless vitamin D is supplemented, intake with food is usually insufficient, and thus endogenous production contributes significantly to plasma levels. This leads to vitamin D deficiencies in up to 70% in some population groups in which sunlight exposure is low because of modern lifestyle, clothing, and few sunshine hours during winter. 1,2 Clinical Perspective on p 986Background-Vitamin D deficiency in humans is frequent and has been associated with inflammation. The role of the active hormone 1, 1, in the cardiovascular system is controversial. High doses induce vascular calcification; vitamin D 3 deficiency, however, has been linked to cardiovascular disease because the hormone has anti-inflammatory properties. We therefore hypothesized that 1,25-VitD3 promotes regeneration after vascular injury. Methods and Results-In healthy volunteers, supplementation of vitamin D 3 (4000 IU cholecalciferol per day) increased the number of circulating CD45-CD117+Sca1+Flk1+ angiogenic myeloid cells, which are thought to promote vascular regeneration. Similarly, in mice, 1,25-VitD3 (100 ng/kg per day) increased the number of angiogenic myeloid cells and promoted reendothelialization in the carotid artery injury model. In streptozotocin-induced diabetic mice, 1,25-VitD3 also promoted reendothelialization and restored the impaired angiogenesis in the femoral artery ligation model. Angiogenic myeloid cells home through the stromal cell-derived factor 1 (SDF1) receptor CXCR4. Inhibition of CXCR4 blocked 1,25-VitD3-stimulated healing, pointing to a role of SDF1. The combination of injury and 1,25-VitD3 increased SDF1 in vessels. Conditioned medium from injured, 1,25-VitD3-treated arteries elicited a chemotactic effect on angiogenic myeloid cells, which was blocked by SDF1-neutralizing antibodies. Conditional knockout of the vitamin D receptor in myeloid cells but not the endothelium or smooth muscle cells blocked the effects of 1,25-VitD3 on healing and prevented SDF1 formation. Mechanistically, 1,25-VitD3 increased hypoxia-inducible factor 1-α through binding to its promoter. Increased hypoxia-inducible factor signaling subsequently...

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Section: Discussionmentioning

confidence: 99%

Vitamin D Promotes Vascular Regeneration

et al. 2014

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“…This implies a transluminal route for the accession of these cells to early sites of atherosclerosis where they promote monocyte recruitment and lesion development. 20,25 At a similar stage of disease, neutrophil extracellular traps were found at the bifurcation sites of carotid arteries in vivo but not in healthy mice. 26 The potential contribution of dendritic cells has been established in CC chemokine ligand 17 (CCL17) E/+ Apoe −/− mice where CCL17-expressing dendritic cells were shown to accumulate in the lesion and to interact with T-cells, thereby promoting atherogenesis.…”

Section: Tplsm In Atherosclerotic Researchmentioning

confidence: 99%

“…Image acquisition triggered on respiratory/ heart cycles, mechanical stabilization, and strong fluorescent markers enabled recording of good quality time-lapse movies of the arterial wall and leukocyte interactions with the vessel wall, 17 even in 3D ( Figure 1B). 20 Using a comparable layout, Li et al 21 managed to track single leukocytes recruited to damaged cardiac tissue in living mice after coronary ischemia reperfusion, both in transplanted and in native hearts, ≤120-μm depth. More recently, an intravital live cell-triggered imaging system has been developed by Ley et al 22 to reveal monocyte patrolling and macrophage migration in atherosclerotic arteries, implementing cardiac triggered acquisition, as well as frame selection and image registration algorithms, to produce stable movies of myeloid cell movement in atherosclerotic arteries in live mice.…”

Section: Tplsm In Atherosclerotic Researchmentioning

confidence: 99%

Optical Imaging Innovations for Atherosclerosis Research

Megens

Bianchini

Schmitt

et al. 2015

ATVB

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Abstract-Cardiovascular disease is the leading cause of death and morbidity worldwide. Improving vascular prevention and therapy based on a refined mechanistic pervasion of atherosclerosis as the underlying pathology could limit the effect of vascular disease in aging societies. During the past decades, microscopy has contributed greatly to a better understanding of vascular physiology and pathology by allowing imaging of living specimen with subcellular resolution and high specificity. An important advance has been accomplished through the application of multiphoton microscopy in the vascular domain, a technological development that enabled multidimensional and dynamic imaging deep into the cellular architecture of intact tissue under physiological conditions. To identify and validate new targets for treating atherosclerosis, novel imaging strategies with nanoscale resolution will be essential to visualize molecular processes in intracellular and extracellular compartments. This review will discuss the current use of 2-photon microscopy and will provide an overview and outlook on options for introducing nanoscopic optical imaging modalities in atherosclerosis research. as histology. 5 A method that enables TPLSM in ex vivo intact murine carotid arteries mounted and pressurized in perfusion chambers and where both intraluminal and extraluminal physiological conditions are maintained for prolonged time 6 has been used for studying of structural components of the intima, such as endothelial cell orientation and activation, 7 endothelial junction distribution, 8,9 and glycocalyx thickness. 10 TPLSM can also be used for studying the extracellular matrix proteins collagen and elastin, 2 key mechanical components present in these layers. Collagen can be visualized by second harmonic generation, 11 a nonlinear energy-conservative process based on the recombination of 2 near-infrared scattered photons into one with exactly half the wavelength. This phenomenon only occurs in dense noncentrosymmetric samples, such as fibered collagens and striated muscle myosin, and produces mainly forward scattered light in ≤200-μm thick specimens, whereas backward scattered photons are the major signal components at deeper locations in tissues. 12 This strategy has been used to characterize the collagen fiber network in the tunica adventitia and intima of mounted healthy and diseased arteries 7,13 and to evaluate plaque burden 14 and the thickness of the fibrous cap of atherosclerotic stable and unstable plaques in the human aorta. 15 Elastin is the most abundant extracellular matrix protein in the tunica media where it forms elastic laminae interspersed among smooth muscle cells. When illuminated with near-infrared light, it emits autofluorescent signals in a broad range of the visible spectrum, providing further useful insights into arterial structure and function. 15Nonstandard Abbreviations and Acronyms 3D3-dimensional STED stimulated emission depletion TPLSM 2-photon laser scanning microscopy Figure 1. A, Single photon vs. 2-photon...

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“…Several studies have shown that platelets and myeloid leukocytes display reciprocal cooperation for recruitment into the inflamed vasculature; for example, neutrophils recruited to TNF-α-stimulated venules efficiently capture circulating platelets, 14 and this has been recently demonstrated to also occur in nascent atherosclerotic lesions. 15 In turn, activated platelets can secrete and deposit chemokines on the surface of leukocytes and endothelial cells, thereby enhancing adhesion of the leukocytes on atherosclerotic surfaces. 7 In agreement with these previous studies, Karshovska et al show that JAM A-deficient platelets release more CXCL4 and CCL5-2 potent inflammatory chemokines-into the plasma, thereby creating a proatherogenic milieu that facilitates their own deposition and further recruitment of monocytes and neutrophils onto atherosclerotic regions of arteries.…”

Section: Circulation Research February 13 2015mentioning

confidence: 99%