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Query: UMLS:C0004153 (
atherosclerosis
)
77,401
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Vascular calcification is highly correlated with
atherosclerosis
and cardiovascular disease and is a significant predictor of cardiovascular morbidity and mortality. Studies in mice indicate a genetic contribution to this dystrophic extra osseous calcification. We sought to elaborate a method to induce dystrophic arterial calcification in mice and further examine the pathogenetical mechanisms involved in the phenotype. We established a method of freeze-thaw injury of the infrarenal aorta producing a limited tissue necrosis and histologically investigated the occurrence of dystrophic calcification within the aortic wall 1, 3 and 7 days after injury in C57BL/6 (a mouse strain shown to be resistant to dystrophic cardiac calcification after injury) and C3H/He (susceptible to dystrophic cardiac calcification). C57BL/6 mice exhibited no dystrophic calcification at all within the vessel wall upon injury of the infrarenal aorta (0/5 mice 1 day after injury and 0/10 animals 7 days after injury). By contrast C3H/He mice displayed a remarkable extent of calcification mainly present within the media of the infrarenal aorta which was evident as early as 24 h (three out of five animals 1 day after injury) and reached its maximum extent 7 days after injury (10 out of 10 animals at the seventh postoperative day, p<0.001 compared to C57BL/6 mice). Upon immuno-histological analysis calcification was accompanied by the occurrence of certain bone-matrix associated proteins. Osteopontin and Bone Morphogenetic
Protein 2
/4 expression was detected co-localized with the calcified lesions. Our results demonstrate that freeze-thaw injury of the infrarenal aorta is a sufficient method to induce dystrophic arterial calcification in mice. We present evidence that the occurrence of arterial calcification in C3H/He mice seems to be actively regulated by certain bone-matrix associated proteins.
...
PMID:Arterial calcification in mice after freeze-thaw injury. 1671 Nov 62
Chronic low-grade inflammation orchestrated by macrophages plays a critical role in metabolic chronic diseases, like obesity and
atherosclerosis
. However, the underlying mechanism remains to be elucidated. Here, the E3 ubiquitin ligase F-box/WD Repeat-Containing
Protein 2
(FBXW2), the substrate-binding subunit of E3 ubiquitin ligase SCF (a complex of FBXW2, SKP1, and cullin-1), as an inflammatory mediator in macrophages, is identified. Myeloid-specific FBXW2 gene deficiency improves both obesity-associated with insulin resistance and
atherosclerosis
in murine models. The beneficial effects by FBXW2 knockout are accompanied by decreased proinflammatory responses and macrophage infiltration in the microenvironment. Mechanistically, it is identified that KH-type splicing regulatory protein (KSRP) is a new bona fide ubiquitin substrate of SCF
FBXW2
. Inhibition of KSRP prevents FBXW2-deficient macrophages from exerting a protective effect on inflammatory reactions, insulin resistance and plaque formation. Furthermore, it is demonstrated that the C-terminus (P3) of FBXW2 competitively ablates the function of FBXW2 in KSRP degradation and serves as an effective inhibitor of obesity and atherogenesis progression. Thus, the data strongly suggest that SCF
FBXW2
is an important mediator in the context of metabolic diseases. The development of FBXW2 (P3)-mimicking inhibitors and small-molecular drugs specifically abrogating KSRP ubiquitination-dependent inflammatory responses are viable approaches for obesity and
atherosclerosis
treatment.
...
PMID:E3 Ligase FBXW2 Is a New Therapeutic Target in Obesity and Atherosclerosis. 3310 72
