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【摘要】
Objective— High-fat, cholesterol-containing diets contribute to hyperlipidemia. Both high-fat diets and hyperlipidemia are associated with chronic inflammatory diseases like atherosclerosis. Integrins, heterodimeric mediators of inflammatory cell recruitment, are not generally thought to be affected by diet. However, high-fat feeding promotes inflammation, atherosclerosis, and death in hyperlipidemic mice with β3 integrin deficiency, and treatment of humans from Western populations with oral β3 integrin inhibitors increases mortality. The mechanisms responsible for these β3 integrin-associated events are unknown.
Methods and Results— Here we show that diet-induced death in β3 integrin-deficient mice is a TNF -dependent process mediated by bone marrow–derived cells. In 2 different hyperlipidemic models, apoE-null and LDL receptor–null mice, β3-replete animals transplanted with β3-deficient marrow died with Western-type high-fat feeding whereas β3-deficient animals transplanted with β3-replete marrow were rescued from diet-induced death. Transplantation with β3-deficient marrow also increased atherosclerosis. TNF expression was increased in β3-deficient macrophages and normalized by either retroviral or adenoviral reconstitution of β3 integrin expression. Treatment with the anti-TNF antibody infliximab rescued β3 integrin–deficient mice from Western diet–induced death, directly implicating TNF in the pathophysiology triggered by diet-induced hyperlipidemia.
Conclusions— These findings suggest that macrophage β3 integrin, acting through TNF, suppresses inflammation caused by hyperlipidemia attributable to high-fat feeding.
The signals linking hyperlipidemia and the chronic inflammation characteristic of atherosclerosis are unknown. Here we demonstrate that the β3 integrin on macrophages suppresses diet-induced inflammation in hyperlipidemic mice by decreasing expression of TNF. Promoting anti-inflammatory signaling mediated by the β3 integrin could represent a novel treatment strategy for atherosclerosis.
【关键词】 integrins TNF diet bone marrow transplantation atherosclerosis infliximab
Introduction
Eating a high-fat diet, generally reflecting increased intake of both triglycerides and cholesterol, is increasingly common as Western culture is exported throughout the world. This practice contributes to atherosclerosis, obesity, and diabetes, disorders characterized by inflammation. 1 Nutrient excess prompts changes in a host of inflammatory proteins associated with metabolic disease including TNF, interleukin (IL)-6, NF- B, JNK, PKC, C-reactive protein, matrix metalloproteinases, and others, 2 but how diet is linked to specific inflammatory mediators is obscure.
Because the inflammatory response that occurs in atherosclerosis and obesity is characterized in part by macrophage infiltration, 3,4 the interaction between these inflammatory cells and the endothelium could be affected by diet. Monocytes initially form a loose attachment to the vasculature, then roll along the endothelial surface until they adhere firmly, migrate between endothelial cells into tissues, and become macrophages. This process is mediated by integrins (heterodimers on the surface of monocytes), cellular adhesion molecules (including P-selectin, E-selectin, intercellular adhesion molecule-1 [ICAM-1], vascular cell adhesion molecule -1, and PECAM-1), and chemokines such as MCP-1. Reports of the effects of high-fat diets on these proteins are inconsistent and their role in vascular disease is still poorly defined. In mice, the absence of several types of adhesion molecules decreases diet-induced atherosclerosis 5 but absence of CD11b, the chain for the β2 integrin Mac-1 (found extensively in vascular lesions), does not. 6 In humans, antibodies against ICAM-1, 7 the β2 integrins, 8,9 and P-selectin 10 have failed to improve vascular outcomes.
Unlike antagonism of β2 integrins, antagonism of β3 integrin (at least in the short-term) benefits patients with atherosclerotic disease. There are 2 integrins in the β3 family, IIbβ3 and vβ3, each defined by the subunit that partners with the regulatory β3 subunit. IIbβ3, or glycoprotein IIb/IIIa, is found on platelets where its inhibition blocks platelet aggregation to decrease thrombosis in patients undergoing vascular interventions. 11 vβ3, originally identified as the vitronectin receptor, is present in blood vessels as well as inflammatory cells including macrophages. 12 Short-term inhibition of IIbβ3 reproducibly improves outcomes, but long-term inhibition using small molecules curiously increases mortality in humans, 13 prompting speculation that defective β3 signaling could increase inflammatory mediators.
We generated data in support of this idea when we found that hyperlipidemic β3-deficient mice developed accelerated atherosclerosis and lethal pulmonary inflammation when fed a high-fat diet, 14 a striking phenotype lacking a molecular mechanism. We pursued the mechanism by testing the hypothesis that the β3 integrin on bone marrow–derived cells affects the inflammatory response induced by high-fat cholesterol-containing diets. We found that transplanting β3 integrin–deficient marrow into β3 integrin–replete animals reproduces the diet-induced phenotype, that transplanting β3 integrin–replete marrow into β3 integrin–deficient animals rescues them from the diet-induced phenotype, that the β3 integrin on macrophages mediates expression of proinflammatory mediators including TNF, and that antagonism of TNF with the antibody infliximab rescues β3 integrin–deficient mice from the diet-induced phenotype. These results unexpectedly implicate the β3 integrin on macrophages in the suppression of an inflammatory cascade initiated by TNF and linked to one of the most common conditions in developed countries, diet-induced hyperlipidemia.
Methods
Bone Marrow Transplantation
Experimental protocols were approved by the Washington University Animal Studies Committee. Animals were weaned at 3 weeks to mouse chow providing 6% calories as fat as described. 14 Congenic animals were generated by backcrossing male β3 +/– apoE –/– and male β3 +/– LDLR –/– mice to female apoE-null mice or female LDLR-null mice each in the C57BL/6 background using a marker assisted selection protocol. 15 β3 –/– apoE –/– and β3 +/+ apoE –/– littermates as well as β3 –/– LDLR –/– and β3 +/+ LDLR –/– littermates were generated for experiments. Bone marrow was transplanted into lethally irradiated donors, and degree of engraftment was estimated as described 16 using C57BL/6-TgN(ACTbEGFP)-GFP-mice (Jackson Laboratory, Bar Harbor, ME, USA) crossed onto an apoE null or LDLR-null background to obtain β3 –/– apoE –/– and β3 –/– LDLR –/– mice and their β3 +/+ littermates transgenic for GFP.
Inflammatory Stimuli
To stimulate inflammation, littermates were injected with lipopolysaccharide (LPS) (10 mg/kg, serotype 0111:B4, Sigma), then plasma was collected and flash-frozen. For the in vivo treatment with anti-TNF antibody, β3 –/– apoE –/– littermates were injected with a loading dose of either infliximab (10 mg/kg, Centocor) or an IgG kappa isotype control antibody at the same dose. The mice were then started on a Western-type diet containing 0.15% cholesterol and providing 42% calories as fat (TD 88137, Harlan). Injections with 10 mg/kg body weight of infliximab or isotype control were given twice weekly.
Analytical Procedures
Serum lipids were measured after a 4-hour fast and aortic sinus atherosclerosis was assayed in serial sections of Oil Red O–stained tissue, each as described. 17 TNF and IL-6 were measured in serum by ELISA (BD Biosciences). For NF- B, p65 activation in nuclear extracts was quantified as arbitrary units using an oligonucleotide-based ELISA (Active Motif). Controls included incubations with free wild-type and mutated NF- B oligos. Quantitative RT-polymerase chain reaction (PCR)-based gene expression was performed (normalized to L32 or GAPDH) as described 16 with the following primers: TNF forward 5'-CATCTTCTCAAAATTCGAGTGACAA-3', reverse 5'-TGGGAGTAGACAAGGTACAACCC-3', probe 5'-FAM-CACGTCGTAGCAAACCACCAAGTGGA-TAMRA-3'; β3 forward 5'-CGCATCCCATTTGCTAGTGTT-3', reverse 5'-AATGCCTGCCAGTCTTCCAT-3', probe 5'-FAM- CGGATGCCAAGACCCATATTGCCC-BHQ-3'.
Macrophage Culture
Macrophages were elicited from the peritoneum using thioglycollate as described 16 or isolated from bone marrow. For the latter, marrow from the femora and tibia of adult mice was collected, red cells were lysed with 0.747% NH 4 Cl/0.017% Tris-Cl, and remaining cells were suspended in MEM with 10% FBS supplemented with 1:10 (v:v) CMG 14–12 culture supernatant (equivalent to 130 ng/mL of recombinant M-colony stimulating factor ) and cultured for 4 days with media/M-CSF replacement every other day. Cells were then washed and seeded at 2 x 10 6 cells per well in 6-well cluster dishes for experiments. For assessment of β3 expression, cells were incubated with LPS (1 µg/mL), TNF (50 ng/mL), palmitate (500 µmol/L complexed 4:1 to BSA as detailed by Shi et al 18 ), or appropriate vehicles.
Viruses
Human β3 integrin in the U3 retroviral vector and a LacZ control vector were packaged 14 and added to macrophages in medium containing polybrene (4 µg/mL; Sigma). After 24 hours, cells were treated with medium containing M-CSF as noted above and incubated for an additional 48 hours before harvest.
The full-length human β3 integrin cDNA was cloned into a recombinant adenoviral plasmid containing a green fluorescent protein gene and packaged in 293 cells by standard techniques. 19 An empty adenoviral plasmid containing the gene for the GFP alone served as control. Viruses were purified by ultracentrifugation and delivered to bone marrow macrophages as described, 20 except that cells were exposed to virus for 24 hours in M-CSF–containing medium before subsequent treatment with LPS (1µ g/mL) in 0.5% BSA-containing medium.
Statistical Analyses
Parametric data were compared by unpaired t test or ANOVA and nonparametric data by the Mann–Whitney test. Survival is represented in Kaplan–Meier plots that were analyzed by the log-rank method and confirmed by Cox regression. The assumption that the proportional hazard does not change was validated by showing that the logarithm of the estimated cumulative hazard function was constant over time.
Results
Replication of the Systemic Null Phenotype With β3-Deficient Bone Marrow and Rescue of the Null Phenotype With β3 Wild-Type Marrow
Apolipoprotein E–deficient (apoE –/– ) and low-density lipoprotein receptor–deficient (LDLR –/– ) mice develop severe hyperlipidemia and atherosclerosis when fed a diet mimicking the average macronutrient composition consumed by Western populations. In each mouse model, the absence of the gene for the β3 integrin in all tissues has no effect on the lipid phenotype, but most animals die because of pulmonary inflammation and the surviving mice have accelerated atherosclerosis. 14 To identify a mechanism underlying these observations, bone marrow transplantation was performed after mice were bred into a uniform C57BL/6 background over several generations using a marker assisted selection protocol. Evidence of appropriate engraftment after transplantation was obtained through a combination of bone marrow histology (supplemental Figure IA, available online at http://atvb.ahajournals.org), genotyping (supplemental Figure IB) and characterization of GFP-positive leukocytes in both ApoE –/– and LDLR –/– mice as described in Methods. Mean GFP positive leukocytes in several experiments 4 weeks after transplantation was 84.5% (range 66.3 to 94.3%).
With Western diet feeding, only 3 of 18 apoE-deficient (β3 wild-type) mice transplanted with β3-deficient marrow survived compared with 19 of 19 mice receiving β3 wild-type marrow ( Figure 1 A, P <0.0001). LDLR-deficient (β3 wild-type) mice transplanted with β3-deficient marrow also had increased mortality with Western diet feeding compared with animals receiving β3 wild-type marrow ( Figure 1 B, P =0.002). In the converse experiments, apoE-deficient mice also deficient for β3 integrin were rescued from Western diet-induced death by transplantation with β3 wild-type (apoE –/– ) marrow ( Figure 1 C, P <0.0001), and LDLR-deficient mice also deficient for β3 integrin were rescued from Western diet-induced death by transplantation with β3 wild-type (LDLR –/– ) marrow ( Figure 1 D, P <0.0001). The phenotype appeared to be more pronounced in apoE-deficient macrophages, suggesting that macrophage apoE affects the interaction between integrin levels and diet-induced inflammation, a notion consistent with known effects of apoE on macrophage function. 21 There was no effect on mortality in transplanted animals fed low fat chow instead of the Western diet (supplemental Figure II).
Figure 1. Diet-induced death in mice transplanted with β3 integrin–deficient bone marrow and rescue by transplantation with β3 integrin–replete bone marrow. Mice were started on a Western diet at day 0, which was 4 weeks after transplantation. A, Survival for β3 +/+ apoE –/– mice transplanted with bone marrow from β3 +/+ apoE –/– (circles) or β3 –/– apoE –/– (triangles) mice. B, β3 +/+ LDLR –/– mice transplanted with marrow from β3 +/+ LDLR –/– (circles) or β3 –/– LDLR –/– (triangles) mice. C, β3 –/– apoE –/– mice transplanted with marrow from β3 +/+ apoE –/– (circles) or β3 –/– apoE –/– (triangles) mice. D, β3 –/– LDLR –/– mice transplanted with marrow from either β3 +/+ LDLR –/– (circles) or β3 –/– LDLR –/– (triangles) mice. Curves show cumulative survival. Probability values were obtained by log-rank testing.
Autopsies revealed an extensive mononuclear infiltrate in the lungs of β3 +/+ apoE –/– mice transplanted with β3 –/– apoE –/– marrow and β3 +/+ LDLR –/– mice transplanted with β3 –/– LDLR –/– marrow found dead with Western diet feeding (supplemental Figure IIIC and IIID). Stains and cultures of this infiltrate were negative for pathogens but infiltrates in both apoE –/– and LDLR –/– mice stained positive for macrophages (supplemental Figure IIIE and IIIF). Lungs were histologically normal in β3 +/+ apoE –/– mice and β3 +/+ LDLR –/– mice transplanted with β3 +/+ apoE –/– or β3 +/+ LDLR –/– marrow, respectively, and euthanized after six weeks of high fat feeding (supplemental Figure IIIA and IIIB).
Accelerated Vascular Disease in Mice Transplanted With β3-Deficient Marrow
Atherosclerosis, a macrophage-driven inflammatory process, was more extensive in β3 +/+ LDLR –/– mice transplanted with β3 –– /LDLR –/– marrow as compared with β3 +/+ LDLR –/– marrow ( Figure 2A and 2 C), the experiment in which sufficient animals survived to allow vascular analysis ( Figure 1 B). Accelerated vascular disease occurred despite the absence of a macrophage β3 genotype effect on serum cholesterol ( Figure 2 B). For each of the experimental groups, genotype had no effect on body weight (supplemental Table I) or serum chemistries (supplemental Figure IV).
Figure 2. Increased atherosclerosis in β3 +/+ LDLR –/– mice transplanted with β3 –/– LDLR –/– bone marrow. A, Aortic sinus atherosclerosis in β3 +/+ LDLR –/– recipient mice reconstituted with β3 +/+ LDLR –/– (n=14, solid bar) or β3 –/– LDLR –/– (n=7, open bar) marrow and surviving 10 weeks of Western diet feeding. B, Fasting cholesterol levels in the mice studied in Panel A at baseline on a chow diet and over time on the Western diet. C, Representative atherosclerotic lesions for the mice studied in Panel A. Results are presented as mean±SEM. * P <0.05.
Inflammatory Stressors Increase Macrophage β3 Expression
Increased inflammation in the absence of the β3 gene in macrophages raises the possibility that β3 in this cell type suppresses inflammation. If this were physiologically relevant, β3 expression might be induced by inflammatory stressors. Consistent with this notion, β3 mRNA was increased ( Figure 3 A) when bone marrow macrophages from β3 +/+ apoE –/– mice were treated for 1 hour with either of 2 classic initiators of inflammatory cascades, TNF (50 ng/mL) or LPS (1µg/mL). Palmitate, a proinflammatory fatty acid, increased β3 mRNA ( Figure 3 B) as well as β3 protein (not shown), in these cells. To determine whether in vivo exposure to cholesterol-containing lipoproteins associated with diet-induced hyperlipidemia affects β3 expression, peritoneal macrophages elicited from mice fed chow were compared with elicited macrophages from mice fed the Western diet ( Figure 3 C). β3 expression was increased in cells obtained from Western diet–fed mice ( Figure 3 C).
Figure 3. Induction of β3 integrin mRNA in macrophages (A-C) and increased TNF in β3-deficient macrophages (D–H). A, β3 expression in bone marrow–derived macrophages treated with TNF (50 ng/mL), LPS (1 µg/mL), or vehicle for 1 hour (n=3 for each condition). * P <0.01. B, β3 expression in bone marrow–derived macrophages after treatment with 500 µmol/L palmitate with BSA (open bars) or BSA alone (solid bars) (n=3 dishes per condition). * P <0.01, # P <0.05. C, β3 expression in thioglycollate-elicited peritoneal macrophages from apoE –/– mice fed a chow diet (solid bar) or Western diet (open bar) for 4 weeks (n=3 animals per condition). * P <0.05. D, TNF expression in unstimulated bone marrow–derived macrophages from β3 +/+ apoE –/– mice (solid bar) and β3 –/– apoE –/– mice (open bar). * P <0.05. E, TNF expression in cells from mice with the same genotypes after transduction with a control retrovirus. * P <0.01. F, Expression in cells transducted with a human β3 integrin retrovirus (Rvβ3). G, TNF message and supernatant protein levels (inset) of LPS-stimulated bone marrow–derived macrophages from β3 +/+ apoE –/– mice (solid bar) and β3 –/– apoE –/– mice (open bar) after transduction with a control adenovirus (n=3). * P <0.01 for mRNA and * P <0.05 for protein. H, The same parameters in LPS-stimulated bone marrow–derived macrophages from β3 +/+ apoE –/– mice (solid bar) and β3 –/– apoE –/– mice (open bar) after reconstitution of β3 expression using an adenovirus (Adβ3). Results are presented as mean±SEM.
β3 Suppresses TNF
Message levels for TNF, a central mediator of inflammatory responses under many conditions, were increased in unstimulated bone marrow macrophages from β3 –/– apoE –/– as compared with β3 +/+ apoE –/– mice ( Figure 3 D). Restoration of β3 expression in these cells using a human β3 retrovirus decreased TNF expression ( Figure 3 F) but control virus treatment did not ( Figure 3 E). Normalization of TNF was also demonstrated in LPS-stimulated bone marrow macrophages. Both TNF message and protein were increased in LPS-stimulated cells from β3 –/– apoE –/– as compared with β3 +/+ apoE –/– mice treated with a control adenovirus ( Figure 3 G with protein shown in inset). After reconstitution of β3 expression using a human β3 adenovirus, TNF mRNA (main figure) and TNF protein (inset) were normalized ( Figure 3 H).
Increased Cytokines in the Absence of β3 Integrin
The increased TNF phenotype in unstimulated and stimulated β3-deficient macrophages was also present systemically in mice with β3 deficiency. Administration of LPS (10 mg/kg) resulted in higher circulating levels of TNF protein at 1 hour in β3 –/– apoE –/– as compared with β3 +/+ apoE –/– mice, an effect also seen 4 and 6 hours after treatment ( Figure 4 A). Consistent with the known stimulation of IL-6 by TNF, IL-6 protein levels peaked at 4 hours after LPS in the circulation of these same mice and were also elevated in β3 –/– apoE –/– as compared with β3 +/+ apoE –/– mice at each time point ( Figure 4 B). TNF -initiated systemic inflammation is orchestrated by NF- B, and consistent with the inflammatory phenotype in the absence of the β3 gene, NF- B activation after LPS stimulation was greater in bone marrow macrophages from β3-deficient as compared with β3 wild-type mice ( Figure 4 C).
Figure 4. Increased inflammatory signaling in β3-deficient mice and prevention of diet-induced death by infliximab. A, β3 +/+ apoE –/– mice (solid bars) and β3 –/– apoE –/– mice (open bars) were injected with LPS, and TNF was measured in serum at various times after treatment (n 6 for each genotype). * P <0.05. B, Measurement of IL-6 concentration in the mice of Panel A. * P <0.05. C, Bone marrow–derived macrophages from β3 +/+ LDLR –/– (solid bars) or β3 –/– LDLR –/– mice (open bars) were stimulated with LPS then p65 activation was quantified in nuclear extracts at various times after treatment. * P <0.01, ** P <0.05. Results are presented as mean±SEM. D, β3 –/– apoE –/– mice were started on a Western diet and treated with infliximab, an anti-TNF antibody (solid symbols), or an isotype-specific control antibody (open symbols). The significant difference in survival rate was assessed by log-rank comparison.
Blocking the Effect of TNF Rescues Mice From Western Diet–Induced Death
The anti-TNF antibody infliximab is used clinically to decrease inflammation in well-defined clinical settings including rheumatoid arthritis, Crohn disease, uveitis, and psoriasis. Because TNF was increased in isolated macrophages ( Figure 3 ) and in the circulation ( Figure 4 A) of β3-deficient mice, we sought to determine whether TNF antagonism alters the phenotype of these animals. Treatment with infliximab rescued β3 –/– apoE –/– mice from death induced by eating a Western diet ( Figure 4 D, solid symbols), whereas injections with an isotype-specific control antibody did not ( Figure 4 D, open symbols).
Discussion
These current data suggest that the β3 integrin on macrophages is an antiinflammatory molecule that suppresses TNF. Inflammatory stressors such as LPS, Western diet, and TNF itself induce β3 expression ( Figure 3 ), perhaps to dampen downstream signaling. The absence of β3 is associated with increased TNF, reconstitution of β3 normalizes TNF ( Figure 3 ), Western diet feeding to mice transplanted with β3-deficient marrow provokes inflammation manifested as pulmonary infiltration leading to death ( Figure 1; supplemental Figure III) and accelerated atherosclerosis ( Figure 2 ), and TNF antagonism in β3-deficient animals prevents death induced by this diet ( Figure 4 D).
Our data show that Western diet-feeding in the absence of the β3 integrin in bone marrow–derived cells affects 2 phenotypes, pulmonary infiltration and atherosclerosis. Evolving evidence in both mice and men supports the notion that these processes are related. Although generally not appreciated, apoE-null mice, animals that develop extensive vascular disease when fed an atherogenic diet, also manifest lung infiltration with lipid-laden macrophages in response to the same diet. 22 Dietary cholesterol exacerbates and statin treatment diminishes disease in a mouse model of pulmonary inflammation. 23 High fat/high cholesterol feeding to apoE null and LDLR null mice transplanted with ABCG1 null marrow results in pulmonary inflammation with relative protection from atherosclerosis. 24
In humans, chronic pulmonary disease is a common comorbidity that tracks with decreased survival in patients with coronary artery disease. 25 Consumption of a Western diet increases the risk for chronic obstructive pulmonary disease in people. 26 The use of statin drugs, which lower lipids and decrease cardiovascular event rates in people with coronary heart disease, decreases the risk of pneumonia and sepsis. 27,28 Collectively, these published data suggest that pulmonary inflammation and vascular disease may share a similar inflammatory diathesis related to high fat/high cholesterol diets.
Based on the data in the current work, β3 integrin appears to be a candidate molecule for mediating clinically relevant systemic inflammation caused by Western-type diets. Both TNF and IL-6 29,30 predict vascular disease, a common consequence of inflammation, and both are increased with β3 deficiency in mice ( Figure 4 ). Chronic inhibition of β3 in vascular disease patients from populations eating Western diets increases the risk of death. 13 Antagonism of TNF decreases inflammation in patients with the metabolic syndrome, a disorder driven by Western diet feeding and obesity. 31 TNF antagonism is also associated with decreased cardiovascular disease in rheumatoid arthritis, 32 a chronic inflammatory state that can also be complicated by substantial pulmonary inflammation. Because lipids increase β3 expression in macrophages ( Figure 3 ), variations in the β3 gene impairing its response to a high fat diet could promote atherosclerosis and other chronic inflammatory diseases.
There is a conceptual framework for pursuing the signals linking β3 and inflammation. Cholesterol, shown to affect TNF production by macrophages, 33 or palmitate, which acts in part through TLR4, 18 could be the specific dietary trigger for the β3 response because both are presented to macrophages as components of lipoproteins. vβ3, a promiscuous receptor that is unlikely to exist in the unliganded state in vivo, 34 is one of several cell surface receptors mediating uptake of apoptotic cells that may propagate tissue inflammation. 35 vβ3 signaling is known to stimulate phosphorylation of IRS-1, 36 an adaptor protein that increases PI3 kinase/AKT signaling. Wortmannin, a PI3 kinase inhibitor, blocks late phase platelet aggregation mediated by β3, 37 evidence that outside-in β3 signals involve PI3 kinase. Inhibition of the PI3 kinase/AKT pathway in mice promotes LPS-induced cytokine release, 38 consistent with dampening of inflammation by β3-PI3 kinase signals.
There are apparently conflicting data in mouse tumor models 39 and cell monolayer systems 40 suggesting that β3 integrins actually promote the transendothelial migration of macrophages. These results, derived from experimental models strikingly different from mice fed high fat/high cholesterol diets, indicate that β3 signaling may be context-specific. The circumstance of Western diet feeding and its attendant generation of proinflammatory lipoproteins (that are presented in discrete ways to macrophages) could represent a stimulus to the β3 integrin to dampen inflammation.
Because the spread of Western habits is unlikely to abate, diseases exacerbated by high fat/high cholesterol diets will become more prevalent. Promoting antiinflammatory signaling driven by expression of the β3 integrin gene in macrophages represents a novel approach to treating these diseases.
Acknowledgments
Sources of Funding
This work was supported by NIH grants P50 HL083762, HL58427, Clinical Nutrition Research Unit DK56341, and Diabetes Research and Training Center DK20579.
Disclosures
C.F.S. has received lecture fees from Merck and Bristol-Myers Squibb.
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作者单位:Department of Medicine, Division of Endocrinology, Metabolism & Lipid Research (J.G.S, Y.Z., T.C., C.F.S.), and the Department of Cell Biology & Physiology (C.F.S.), Washington University School of Medicine, St. Louis, MO.