Apoe-KO(2)

品系全名

C57BL/6JSmo-Apoeem5Smoc

目录号

NM-KO-190565

品系状态

活体

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基因信息

基因名
Apoe

基因曾用名

Apo-E; AI255918

染色体位置

7

NCBI ID

11816

MGI ID

88057

Ensembl ID

ENSMUSG00000002985

Pubmed

Apoe

人类同源基因

APOE

品系描述

通过敲除Apoe基因exon 2-4,建立Apoe-KO(2)小鼠模型。原Apoe-KO(NM-KO-00033)小鼠模型因技术原因已下架。
应用领域:动脉粥样硬化、高脂血症、血胆脂醇过多、心脏功能损伤、脑梗塞、老年痴呆症及慢性乙型肝炎等

疾病预测

腹部肥胖代谢综合症
Abdominal Obesity-Metabolic Syndrome

近似模型的表型

MGI:5428435
注:该品系需与Cyp19A1-KO(NM-KO-2102244)交配才可能获得预期表型

参考文献

Scott NJ, Cameron VA, Raudsepp S, Lewis LK, Simpson ER, Richards AM, Ellmers LJ, Generation and characterization of a mouse model of the metabolic syndrome: apolipoprotein E and aromatase double knockout mice. Am J Physiol Endocrinol Metab. 2012 Mar;302(5):E576-84

冠状动脉疾病
Coronary Artery Disease

近似模型的表型

MGI:5558016
注:该品系需与Scarb1-KO(NM-KO-201876)交配才可能获得预期表型

参考文献

Tsukamoto K, Mani DR, Shi J, Zhang S, Haagensen DE, Otsuka F, Guan J, Smith JD, Weng W, Liao R, Kolodgie FD, Virmani R, Krieger M, Identification of apolipoprotein D as a cardioprotective gene using a mouse model of lethal atherosclerotic coronary artery disease. Proc Natl Acad Sci U S A. 2013 Oct 15;110(42):17023-8

家族性合并高脂血症
Familial Combined Hyperlipidemia

近似模型的表型

MGI:4354296
注:该品系需与Lpl-KO(NM-KO-201300)交配才可能获得预期表型

参考文献

Xian X, Ding Y, Zhang L, Wang Y, McNutt MA, Ross C, Hayden MR, Deng X, Liu G, Enhanced atherothrombotic formation after oxidative injury by FeCl3 to the common carotid artery in severe combined hyperlipidemic mice. Biochem Biophys Res Commun. 2009 Aug 7;385(4):563-9

验证数据

image.png

Fig.1 Detection of mouse APOE expression in Apoe-KO(2) mice by WB. Various tissues lysates were collected from male 10-week-old wild-type C57BL/6 mice (WT) and homozygous Apoe-KO(2) mice (HO), and then analyzed by western blot with anti-APOE antibody (Abcam, ab183596). 20 μg of total proteins were loaded for western blotting analysis. 

image.png

Fig.2 Lipid profile biochemical markers of male Apoe-KO mice and  WT mice CD conditions. Under CD conditions, male Apoe-KO mice exhibit elevated levels of total cholesterol (T-CHO), and low-density lipoprotein cholesterol (LDL-C) compared to WT mice, while high-density lipoprotein cholesterol (HDL-C) levels are decreased. (n=5-10)

Abbr. WT, wild type; CD, chow diet.

image.png

Fig.3 Oil Red O staining of aortic valve in male Apoe-KO mice and WT mice under CD conditions. The results indicate that no lipid accumulation was observed in the aortic valves of WT mice at 7 months of age. In contrast, all Apoe-KO mice (6/6) exhibited significant lipid accumulation in the aortic valves as early as 5 months of age, with the severity of this phenotype progressively worsening with age. (n=4-6)

Abbr. WT, wild type; CD, chow diet.

image.png

Fig.4 Oil Red O staining of aorta in male Apoe-KO mice and WT mice under CD conditions. The results indicate that at 5 months of age, WT mice exhibit no significant lesions in the aorta, while some Apoe-KO mice (4/6) show fat accumulation near the aortic arch. By 6 to 7 months of age, all Apoe-KO mice (4/4) exhibit fat accumulation, with the severity of this phenotype progressively increasing. (n=4-6)

Abbr. WT, wild type; CD, chow diet.

image.png

Fig.5 Masson staining of aortic valve in Apoe-KO mice and WT mice under CD conditions. Muscle fibers appear red, while collagen fibers are stained blue. Apoe-KO mice exhibit increased collagen content within plaques, suggesting enhanced plaque stability. (n=3)

Abbr. WT, wild type; CD, chow diet.

image.png

Fig.6 Representative pictures of aortic valve. In WT mice, no significant plaque formation, necrosis, or inflammatory cell infiltration is seen. However, in Apoe-KO mice, extensive plaque formation is observed in the aortic valve, protruding into the lumen. Numerous interwoven collagen fibers are present, along with abundant infiltration of foam cells (red arrows). A small amount of cholesterol crystals (black arrows), appearing as needle-shaped voids, are visible, accompanied by minor deposits of brown pigment (green arrows). A small number of infiltrating lymphocytes (yellow arrows) are also noted. Myocardial cells display loose and irregular arrangement. The black box indicates the location of the magnified view.

image.png

Fig.7 The body weight curve of male Apoe-KO mice and WT mice under WD conditions (Sysebio, D12108C). (n=10~15)

Abbr. WT, wild type; WD, western diet.

Note. WD started at 6 weeks of age.

image.png

Fig.8 Lipid profile biochemical markers of male Apoe-KO mice and WT mice under WD conditions. Under WD conditions, male Apoe-KO mice exhibit elevated levels of triglycerides (TG), total cholesterol (T-CHO), and low-density lipoprotein cholesterol (LDL-C) compared to WT mice, while high-density lipoprotein cholesterol (HDL-C) levels are decreased. (n=7~15)

Abbr. WT, wild type; WD, western diet.

Note. WD started at 6 weeks of age.

image.png

Fig.9 Oil Red O staining of aortic valve in male Apoe-KO mice and WT mice under WD conditions. The results indicate that no lipid accumulation was observed in the aortic valves of WT mice at 17 weeks of WD. In contrast, all Apoe-KO mice (3/3) exhibited significant lipid accumulation in the aortic valves as early as 7 weeks of WD, with the severity of this phenotype progressively worsened with age. (n=3~5)

Abbr. WT, wild type; WD, western diet.

Note. WD started at 6 weeks of age.

image.png

Fig.10 Oil Red O staining of aorta in male Apoe-KO mice and WT mice under WD conditions. The results indicate that after 17 weeks of WD, WT mice exhibit no significant lesions in the aorta, while all Apoe-KO mice (3/3) show fat accumulation near the aortic arch after 7 weeks of WD. By 17 weeks of WD, the severity of this phenotype progressively increasing. (n=3~5)

Abbr. WT, wild type; WD, western diet.

Note. WD started at 6 weeks of age.

image.png

Fig.11 Masson staining of aortic valve in Apoe-KO mice and WT mice under WD conditions. Muscle fibers appear red, while collagen fibers are stained blue. Apoe-KO mice exhibit increased collagen content, suggesting enhanced plaque stability. (n=3)

Abbr. WT, wild type; WD, western diet.

Note. WD started at 6 weeks of age.

image.png

Fig.12 Representative pictures of aortic valve. In WT mice after 17 weeks of WD feeding, the vascular intima of cardiac tissue appears smooth with no plaque formation. Myocardial cells are loosely arranged, and occasional perivascular lymphocyte infiltration is noted (red arrows). In contrast, ApoE-KO mice after 7 week of WD feeding display extensive plaques (yellow arrows) within the vessels, protruding into the lumen, with fibrous connective tissue (brown arrows) and minimal foam cell accumulation (blue arrows) on the surface. Needle-like clefts (orange arrows), likely cholesterol crystals, and necrotic debris (black arrows) are seen within the plaques. Lymphocyte infiltration (red arrows) and fibrous tissue proliferation (purple arrows) are present in the interstitial space. The black box indicates the magnified region.

Abbr. WT, wild type; WD, western diet.

Note. WD started at 6 weeks of age.

发表文献 10篇

1. Cross-Species scRNA-seq Finds Ideal Mouse Models for Aortic Dissection Mechanisms
发表年份:2026 来源杂志:iScience

2. Enhanced Vascular Smooth Muscle Cell and Extracellular Matrix Repair Using a Metal-Organic Framework-Based Co-Delivery System for Abdominal Aortic Aneurysm Therapy
发表年份:2024 来源杂志:Advanced Healthcare Materials

3. GSDME-mediated pyroptosis promotes the progression and associated inflammation of atherosclerosis
发表年份:2023 来源杂志:Nature Communications

4. Brown adipose tissue-derived Nrg4 alleviates endothelial inflammation and atherosclerosis in male mice
发表年份:2022 来源杂志:Nature Metabolism

5. Endothelial METRNL determines circulating METRNL level and maintains endothelial function against atherosclerosis
发表年份:2022 来源杂志:Acta Pharmaceutica Sinica B

6. LARP7 ameliorates cellular senescence and aging by allosterically enhancing SIRT1 deacetylase activity
发表年份:2021 来源杂志:Cell Reports

7. The proatherosclerotic function of indoleamine 2, 3-dioxygenase 1 in the developmental stage of atherosclerosis
发表年份:2019 来源杂志:Signal Transduction and Targeted Therapy

8. Acetaldehyde dehydrogenase 2 interactions with LDLR and AMPK regulate foam cell formation
发表年份:2018 来源杂志:JOURNAL OF CLINICAL INVESTIGATION

9. The Essential Role of Pin1 via NF-κB Signaling in Vascular Inflammation and Atherosclerosis in ApoE−/− Mice
发表年份:2017 来源杂志:INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES

10. Periostin enhances adipose-derived stem cell adhesion, migration, and therapeutic efficiency in Apo E deficient mice with hind limb ischemia
发表年份:2015 来源杂志:Stem Cell Research & Therapy

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参考文献

LARP7 ameliorates cellular senescence and aging by allosterically enhancing SIRT1 deacetylase activity
来源杂志:Cell Reports

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