Abstract

   Steroid receptor coactivator 3 (SRC-3) is a member of the p160 SRC
   family. This factor can interact with multiple nuclear hormone
   receptors and transcription factors to regulate the expression of their
   target genes. Although many physiological roles of SRC-3 have been
   revealed, its role in atherosclerosis is not clear. In this study, we
   found that SRC-3^-/-ApoE^-/- mice have reduced atherosclerotic lesions
   and necrotic areas in their aortas and aortic roots compared with
   SRC-3^+/+ApoE^-/- mice after Western diet (WD) feeding for 12 weeks.
   RNA-Seq and Western blot analyses of the aorta revealed that SRC-3 was
   required for maintaining the expression of ICAM-1, which was required
   for macrophage recruitment and atherosclerosis development.
   siRNA-mediated knockdown of SRC-3 in endothelial cells significantly
   reduced WD-induced atherosclerotic plaque formation. Additionally,
   treatment of ApoE^-/- mice with SRC-3 inhibitor bufalin prevented
   atherosclerotic plaque development. SRC-3 deficiency reduced aortic
   macrophage recruitment. Accordingly, ICAM-1 expression was markedly
   decreased in the aortas of SRC-3^-/-ApoE^-/- mice and ApoE^-/- mice
   with endothelial SRC-3 knockdown mediated by AAV9-shSRC-3 virus.
   Mechanistically, SRC-3 coactivated NF-κB p65 to increase ICAM-1
   transcription in endothelial cells. Collectively, these findings
   demonstrate that inhibiting SRC-3 ameliorates atherosclerosis
   development, at least in part through suppressing endothelial
   activation by decreasing endothelial ICAM-1 expression via reducing
   NF-κB signaling.

   Keywords: SRC-3, endothelial cell, ICAM-1, bufalin, NF-κB signaling

Introduction

   Atherosclerosis is a chronic inflammatory disease of the large arterial
   walls and is one of the main causes of death worldwide [47]^1. The
   pathology of atherosclerosis is characterized by the subendothelial
   accumulation of inflammation, vascular wall cells, extracellular
   matrix, and apolipoprotein B-containing lipoproteins [48]^2. The entry
   and retention of apolipoprotein B containing lipoproteins into the
   intima is a key initiating event in atherosclerosis [49]^3. The
   activation of endothelial cells can increase the expression of
   leukocyte adhesion molecules (VCAM-1 and ICAM-1) and chemoattractants
   (MCP-1), promoting the entry of bone marrow-derived monocytes into the
   intima, where these cells differentiate into macrophages [50]^4^,
   [51]^5. Macrophage internalizes oxLDL through CD36 and SR-1 to form
   foam cell, which leads the formation of atheromas and plays a critical
   role in plaque initiation and development [52]^6^, [53]^7. The typical
   pathology of vulnerable plaques includes large areas of necrotic cores
   and thinning of the fibrous cap. Plaque rupture of the fibrous cap
   leads to thrombus formation, which is the primary contributor to
   cardiovascular events, such as stroke, myocardial infarction, and
   sudden cardiac death [54]^8. Therefore, understanding the underlying
   molecular mechanisms can provide information for the development of
   effective preventive and therapeutic strategies.

   Steroid receptor coactivator 3 (SRC-3) belongs to the p160 coactivator
   family, which interacts with multiple nuclear receptors and other
   transcription factors to enhance their effects on target gene
   transcription [55]^9. Our previous studies showed that SRC-3 expression
   in macrophages could protect against LPS-induced endotoxic shock by
   regulating the proinflammatory cytokine balance [56]^10 and protect
   against Escherichia coli-induced septic peritonitis by enhancing the
   phagocytosis of bacteria and reducing macrophage apoptosis [57]^11. Our
   recent study demonstrated that SRC-3^-/- mice displayed delayed
   clearance of Citobacter rodentium and more severe tissue pathology
   after oral infection with C. rodentium due to decreased production of
   the chemokines CXCL2 and CXCL5 and decreased recruitment of
   neutrophils, indicating that SRC-3 plays a critical protective role in
   bacteria-induced colitis [58]^12. It has been reported that SRC-3 has
   an ER-dependent vasoprotective role in vascular trauma by suppressing
   vascular cell proliferation [59]^13, and deletion of SRC-1/3 causes
   noncompaction cardiomyopathy in the hearts of newborn and adult mice by
   inhibiting cardiomyocyte proliferation and differentiation [60]^14,
   suggesting that SRC-3 has a protective role in cardiovascular; however,
   the biological role of SRC-3 in atherosclerosis remains poorly defined.

   In this study, we used SRC-3^-/-ApoE^-/- mice to assess the role of
   SRC-3 in atherosclerosis. We found that SRC-3^-/-ApoE^-/- mice
   exhibited fewer atherosclerotic lesions and necrotic areas in the
   aortas and aortic roots than SRC-3^+/+ApoE^-/- mice after being fed a
   high-fat diet for 12 weeks. Furthermore, knockdown of SRC-3 in
   endothelial cells ameliorated atherosclerosis development. SRC-3
   accelerated atherosclerosis development, at least in part through
   increasing endothelial adhesion and the transmigration of leukocytes by
   promoting ICAM-1 expression in endothelial cells via enhancing NF-κB
   function.

Materials and methods

Mice and Diets

   SRC-3^-/- mice on a C57BL/6×129Sv background [61]^15 were bred with the
   ApoE^-/- mice on a C57BL/6J background (a gift from Jiahuai Han, Xiamen
   University) to generate SRC-3^+/-ApoE^-/- mice. Male SRC-3^+/+ApoE^-/-
   and SRC-3^-/-ApoE^-/- mice (8 weeks old) were fed a WD for 12 weeks.
   The WD was produced by Vital River Laboratories (Beijing, China; fed to
   SRC-3^-/-ApoE^-/- mice and mice that were injected with AAV-shSRC-3 or
   AAV-hICAM-1) or Ready Biotechnolgy (Shenzhen, China; fed to mice that
   were injected with AAV-shICAM-1) according to the protocol from Harlan
   (TD.88137). Animal experiments were approved by the Laboratory Animal
   Center of Xiamen University, Xiamen, Fujian, China.

Human samples

   Human lower limb aortic tissue specimens were obtained from 16 patients
   with arteriosclerosis obliterans who had undergone surgery at Gannan
   Medical University. Written informed consent was obtained from all
   individuals, and the study protocol was approved by the Institute
   Research Ethics Committee at the First Hospital of Xiamen University
   and Gannan Medical University.

Cell culture and transient transfection

   HUVECs (purchased from National Stem Cell Translational Resource
   Center, mycoplasma negative, DFSC-EC-01) were maintained in EGM2 media
   (Lonza) supplemented with 10% fetal bovine serum (Gibco) and the EGM-2
   bullet kit at 37 °C and 5% CO[2]. After reaching 60% confluence, the
   HUVECs were transfected with SRC-3 siRNA (Genepharma, Shanghai) or
   scrambled siRNA by using Lipofectamine 2000 (Invitrogen) according to
   the manufacturer's instructions. The cells were cultured for 48 h or 72
   h before further experiments.

En face analysis of atherosclerosis and plaque histology

   For en face analysis of atherosclerotic lesions, the whole aorta was
   removed and stained with Oil Red O, and the lesion areas were
   quantified with Image-Pro Plus 6.0 (Image Metrology, Copenhagen,
   Denmark). Hearts were fixed in 4% paraformaldehyde and embedded in
   paraffin or O.C.T. for histological analysis. Five-micrometer sections
   of the atrioventricular valve region of the heart were cut and stained
   with hematoxylin and eosin (H&E) to analyze atherosclerosis lesions or
   Masson reagents to analyze collagen contents. Atherosclerotic lesions
   were analyzed in six consecutive sections from 4-6 different
   littermates in each group using Image-Pro Plus 6.0. The plaque
   stability score = (α-SMC area + collagen area) / (macrophage area +
   lipid area) [62]^16.

Immunohistochemistry

   Five-micrometer consecutive sections of aortic roots were cut,
   deparaffinized and rehydrated. Antigens were retrieved by soaking in
   citrate buffer (pH 6.0) with microwave heating for 20 min. The sections
   were blocked in 10% goat serum for 30 min and incubated with the
   following primary antibodies overnight: anti-F4/80 (Cell Signaling
   Technology, D4C8V, #30325) and anti-α-smooth muscle actin (Abcam, E184,
   ab32575). The sections were incubated with 3% H[2]O[2] for 10 min at
   the room temperature to eliminate endogenous peroxidase activity and
   then incubated with Elivision Plus kits (Maixin) at room temperature.
   DAB reagent was used to visualize the stained proteins. The positive
   areas were analyzed with Image Pro-Plus 6.0.

RNA-sequencing analysis

   Total RNA samples were isolated from the aortas of SRC-3^-/-ApoE^-/-
   and SRC-3^+/+ApoE^-/- mice using TRIZOL reagent (Invitrogen) and
   treated with RNase-free DNase I. The extracted RNA samples were sent to
   GENEWIZ for RNA-sequencing analysis. Each sample represented a pooled
   sample of three representative mice. P<0.05 and fold change>1.5 were
   defined as the thresholds for significantly differential gene
   expression. Pathway enrichment analysis and GO analysis were based on
   the KEGG pathway database and Gene Ontology Database, respectively.

Endothelial cell-enhanced AAV packaging

   The shuttle plasmids were cotransfected into HEK-293T cells with
   endothelial cell-enhanced RGDLRVS-AAV9-cap plasmids (a gift from O. J.
   Müller, Universitat Heidelberg, Germany) and pHelper [63]^17. The AAV
   viral particles were isolated and purified according to a previously
   reported protocol [64]^18. For AAV-mediated ICAM-1 overexpression and
   SRC-3 and ICAM-1 knockdown, 1 × 10^10 viral genomes were injected into
   male 8-week-old ApoE^-/- mice via the tail vein before the mice were
   fed a WD.

Oral administration of bufalin in ApoE^-/- mice

   For the preservation model, 8-week-old male ApoE^-/- mice were
   intraperitoneally injected with 1.0 mg/kg bufalin 6 times per week
   (once daily) [65]^19 for 13 weeks and were fed a WD. For the regression
   model, 8-week-old male ApoE^-/- mice were fed a WD for 10 weeks
   followed by 1.0 mg/kg bufalin administration 6 times per week (once
   daily) for another 13 weeks while being fed a WD. DMSO containing 0.9%
   NaCl was used as a vehicle. The mice were killed and dissected. Oil Red
   O staining was used to determine atherosclerotic plaque formation.

Quantitative real-time PCR

   Total RNA was extracted from tissues and cells using TRIzol reagent
   (Invitrogen). RNA integrity was assessed by absorbance spectroscopy,
   and samples with an OD260/OD280 of approximately 1.9 were used for
   experiments. One microgram of total RNA was reverse transcribed using a
   ReverTra Ace Qpcr RT Master Mix kit (TOYOBO). Real-time PCR was
   performed using FastStart Universal SYBR Green Master Mix (Rox)
   (Roche). The relative mRNA level was calculated by normalization to
   GAPDH. The primer sequences are available upon request.

Measurement of plasma lipids and glucose

   Total cholesterol and high-density lipoprotein levels were measured by
   kits (Nanjing Jiancheng) according to the manufacturer's instructions.
   Blood glucose levels were measured by a glucometer (Roche).

Immunoblot analysis

   HUVECs and the whole aorta were lysed in RAPA buffer (150 mM NaCl, 50
   mM Tris, 0.1% SDS, 1 mM EDTA, 1% Triton X-100, 1 mM PMSF and protease
   inhibitors). Proteins were quantified with a BCA assay. Equal amounts
   of proteins were loaded onto 8% sodium dodecyl sulfate-polyacrylamide
   gel electrophoresis gels and transferred onto polyvinylidene difluoride
   membranes (Millipore), followed by immunoblotting with anti-SRC-3 (Cell
   Signaling Technology, 5E11, #2116), anti-human ICAM-1 (Abcam, EPR4776,
   ab109361), anti-mouse ICAM-1 (Abcam, [66]EPR16608, ab179707), anti-p65
   (Cell Signaling Technology, D14E12, #8284), anti-p-p65 (Cell Signaling
   Technology, Ser536, #3031), anti-GAPDH (Cell Signaling Technology,
   D16H11, #5174) and anti-β-actin (Sigma, AC-15, #A5441). Western blots
   were analyzed using a Tonen Image System.

Construction of plasmids and the luciferase reporter assay

   Full-length human ICAM-1 cDNA was amplified by polymerase chain
   reaction (PCR) from HUVECs with the following primer sets: forward,
   ICAM-1 5'-CCGGAATTCATGGCTCCCAGCAGCCC-3'; reverse, ICAM-1
   5'-TGCTCTAGATCAGGGAGGCGTGGCTTGTG-3' and then inserted into the
   pCR3.1-HA vector at the EcoRI and XbaI sites to yield the human ICAM-1
   expression plasmid. The human ICAM-1 promoter 1007-bp fragment was
   amplified by PCR using mouse genomic DNA as a template with the
   following primer sets: forward, ICAM-1 (-1092)
   5'-CGGGGTACCCTTAAGAGTACCCAGCCTCGAC-3'; reverse, ICAM-1 (-88)
   5'-CGACGCGTCCCCTCCGGAACAAATGCT-3'. The fragment was ligated into the
   KpnI and MluI sites of the luciferase reporter vector PGL3-basic to
   produce the ICAM-1 promoter reporter plasmid. To generate site
   mutations in NF-κB, the transcription factor recognition site was
   abrogated by a one-step site-directed and site-saturation mutagenesis
   method [67]^20. The primers for site-directed mutation were yielded as
   follows: mNF-κB, forward, 5'-TaagAATTCCGGAGCTGAAGCGGCCAGCG-3', reverse,
   5'-TCAGCTCCGGAATTcttAAGCTAAAGCAAT-3'. Lowercase letters indicate
   mutated sites. DNA sequencing was used to verify the nucleotide
   sequences of these constructs. Luciferase activity was examined by a
   Dual Luciferase Reporter Assay System (Promega, Madison, WI). Renilla
   luciferase activity was used to normalize the transfection efficiency.

Chromatin immunoprecipitation assay

   Wild-type HUVECs or transient SRC-3-knockdown HUVECs were used for
   chromatin immunoprecipitation (ChIP) assays, which were performed
   according to the method described by Abcam (Cambrige, MA). The
   following primers were used: ICAM-1 promoter NF-κB binding site,
   forward, 5'-GTCATCGCCCTGCCACC-3' and reverse,
   5'-ATTTCCGGACTGACAGGGTG-3'. Anti-SRC-3 antibodies (C-20, sc-7216) and
   anti-p65 (D14E12, #8284) antibodies were purchased from Santa Cruz
   Biotechnology and Cell Signaling Technology, respectively.

Monocyte-endothelial adhesion and transendothelial migration assays

   For the monocyte-endothelial adhesion assay, confluent HUVECs were
   transfected with scramble or SRC-3 siRNA for 48 h and then the scramble
   or SRC-3 siRNA-transfected HUVECs were stimulated with 10 ng/ml TNF-α
   or 2 ng/ml IL-1β for 3 h or 6 h. After 3 h or 6 h, Calcein
   (Yeasen)-labeled THP-1 monocytes were cocultured with the stimulated
   HUVECs for 30 min followed by two rounds of gentle washing to remove
   nonadherent THP-1 cells, and the cells were fixed and imaged with
   fluorescence microscopy at 488 nm. At least five random fields were
   imaged to quantify adherent THP-1 cells per condition.

   For the transendothelial migration assay, confluent HUVECs were
   transfected with scramble or SRC-3 siRNA for 24 h, and then the
   scramble or SRC-3 siRNA-transfected HUVECs were seeded onto 6.5 mm
   Transwell filters coated with 0.1% gelatin (Sigma-Aldrich) for another
   24 h. The HUVECs were stimulated with 10 ng/ml TNF-α or 2 ng/ml IL-1β
   for 6 h followed by the addition of calcein-labeled THP-1. After being
   incubated for 24 h, the transmigrated THP-1 cells were imaged and
   quantified.

Statistical analysis

   Data were collected from at least two independent experiments. All data
   are expressed as the mean ± SEM. Statistical significance was
   determined by unpaired two-tailed Student's t test. P<0.05 was
   considered statistically significant.

Results

SRC-3 deficiency prevents the development of atherosclerosis and enhances the
stability of atherosclerotic plaques

   To determine whether SRC-3 is involved in the development of
   atherosclerosis, we measured SRC-3 expression in human atherosclerotic
   plaques. We collected atherosclerotic plaques and plaque-adjacent
   vasculature in the lower limb aorta and assayed SRC-3 by Western
   blotting. As shown in Figure [68]1A, SRC-3 protein expression in the
   atherosclerotic plaques in lower limb aortas was significantly higher
   than that in the plaque-adjacent vasculature. To further determine
   whether SRC-3 was increased in mouse models of atherosclerosis, whole
   aortas were isolated from 12-week chow-fed and WD-fed male ApoE^-/-
   mice for Western blotting. The results showed that SRC-3 protein
   expression was significantly increased in the aortas of WD-fed ApoE^-/-
   mice compared with chow-fed ApoE^-/- mice (Figure [69]1B). These
   results suggest that SRC-3 may be involved in atherosclerosis
   development.

Figure 1.

   [70]Figure 1
   [71]Open in a new tab

   SRC-3^+/+ApoE^-/- mice exhibit more severe atherosclerosis. (A) SRC-3
   was highly expressed in human atherosclerotic plaques. N represents
   plaque-adjacent vasculature in the lower limb aorta. AS represents
   atherosclerotic plaques in the lower limb aorta. (B) SRC-3 expression
   was upregulated in the aortas of ApoE^-/- mice after the mice were fed
   a WD for 12 weeks. (C) SRC-3 was expressed in the endothelial cells and
   vascular smooth muscle cells of chow-fed SRC-3^-/-ApoE^-/- mice and was
   further increased after the mice were fed a WD for 12 weeks. Sections
   of frozen aortic roots from SRC-3^+/+ApoE^-/-and SRC-3^-/-ApoE^-/- mice
   were subjected to X-gal staining. Arrows indicate positively stained
   cells (blue). Scale bar, 100 µm. (D) SRC-3 promoted atherosclerotic
   plaque formation. Representative images of en face Oil Red O-stained
   aortas from SRC-3^+/+ApoE^-/- and SRC-3^-/-ApoE^-/- mice (left panel).
   Quantification of the plaque areas in aortas (right panel). (E-K)
   Cross-sections of the aortic roots from SRC-3^+/+ApoE^-/- and
   SRC-3^-/-ApoE^-/- mice were subjected to (E-F) H&E staining (scale bar,
   500 µm (E); scale bar, 200 µm (F)), (G) α-SMA staining (scale bar, 200
   µm), (H-I) Masson staining (scale bar, 200 µm (H); scale bar, 200 µm
   (I)), (J) Oil Red O staining (scale bar, 500 µm), and (K) F4/80
   staining (scale bar, 200 µm). Left panels, representative images. Right
   panels, quantification of stained area or a percentage of lesion area.
   “×” indicates necrotic area. (L) Plaque stability was significantly
   increased in SRC-3^-/-ApoE^-/- mice. The data represent the mean ± SEM.
   The results are representative of three independent experiments. P
   values were calculated by unpaired two-tailed Student's t-test. *,
   P<0.05; ** P<0.01.

   To assess whether SRC-3 deficiency affects the development of
   atherosclerosis, SRC-3^-/-ApoE^-/- mice were generated by crossing
   SRC-3^+/- mice with ApoE^-/- mice. Since a LacZ reporter was inserted
   into the 10th amino acid of SRC-3, which is controlled by the
   endogenous SRC-3 promoter in SRC-3^-/-ApoE^-/- mice [72]^15, we
   performed an X-gal staining assay to determine the pattern of SRC-3
   expression in the aortic roots of SRC-3^-/-ApoE^-/- mice. As shown in
   Figure [73]1C, SRC-3 expression (blue) was observed in endothelial
   cells (ECs) and vascular smooth muscle cells (VSMCs) in the aortic
   roots of chow-fed SRC-3^-/-ApoE^-/- mice, and the signals in the aortic
   roots of WD-fed SRC-3^-/-ApoE^-/- mice were stronger. After
   eight-week-old male SRC-3^-/-ApoE^-/- and SRC-3^+/+ApoE^-/- mice were
   fed a WD for 12 weeks, the Oil Red O-stained areas in the aortas of
   SRC-3^-/-ApoE^-/- mice were reduced by 60% compared with those in
   SRC-3^+/+ApoE^-/- mice (6.68% versus 2.43%; Figure [74]1D). Next, we
   analyzed the advanced atherosclerotic lesions in the aortic roots by
   H&E staining. Quantitative analysis of representative images showed
   that the lesion areas were much smaller in SRC-3^-/-ApoE^-/- mice than
   in SRC-3^+/+ApoE^-/- mice (Figure [75]1E). We also analyzed the
   necrotic cores of plaques, which are critical determinants of plaque
   vulnerability. Quantification of this index revealed a pronounced
   decrease in the total necrotic area in the lesions of SRC-3^-/-ApoE^-/-
   mice (Figure [76]1F). Since body weight, plasma lipid levels, and
   glucose levels are associated with atherosclerosis development, we
   measured body weight, plasma lipid levels, and glucose levels in
   SRC-3^-/-ApoE^-/- and SRC-3^+/+ApoE^-/- mice after the mice were fed a
   WD for 12 weeks. Decreased plasma lipid levels and glucose levels were
   observed in SRC-3^-/-ApoE^-/- mice after being fed a WD for 12 weeks
   ([77]Supplementary Figure 1A). Collectively, these results suggest that
   SRC-3 deficiency attenuates the development of atherosclerosis.

   To further examine the effect of SRC-3 deficiency on the stability of
   atherosclerotic plaques, we investigated the properties that affect
   plaque stability, including α-SMA content, collagen content, fibrous
   cap thickness, lipid accumulation, and macrophage numbers. The α-SMA
   content of aortic root lesions in SRC-3^-/-ApoE^-/- mice was decreased
   compared with that in SRC-3^+/+ApoE^-/- mice (Figure [78]1G). However,
   the collagen content of aortic root lesions was significantly increased
   in SRC-3^-/-ApoE^-/- mice compared with SRC-3^+/+ApoE^-/- mice (Figure
   [79]1H). Fibrous caps in the aortic root lesions of SRC-3^-/-ApoE^-/-
   mice were thicker than those of SRC-3^+/+ApoE^-/- mice (Figure [80]1I).
   Lipid staining with Oil Red O revealed a robust 36% decrease in lipid
   accumulation in the aortic root lesions of SRC-3^-/-ApoE^-/- mice
   compared with SRC-3^+/+ApoE^-/- mice (Figure [81]1J).
   Immunohistological staining of macrophages (F4/80-positive), which can
   form foam cells that are critical for atherogenesis, was performed, and
   there was greatly reduced staining of F4/80-positive cells in the
   aortic root lesions of SRC-3^-/-ApoE^-/- mice compared with
   SRC-3^+/+ApoE^-/- mice (Figure [82]1K). In summary, aortic plaque
   stability was significantly increased in SRC-3^-/-ApoE^-/- mice
   compared with SRC-3^+/+ApoE^-/- mice (Figure [83]1L). These results
   suggest that SRC-3 reduces the stability of atherosclerotic plaques in
   the aortic root.

SRC-3 in endothelial cells promotes the development of atherosclerosis

   Our results demonstrated that SRC-3 was highly expressed in endothelial
   cells (Figure [84]1B). Therefore, we hypothesized that endothelial
   SRC-3 may play an important role in promoting the development of
   atherosclerosis. It has been reported that the transduction efficiency
   of the RGDLRVS-AAV9-cap plasmid in endothelial cells is significantly
   higher than both wild-type AAV2 and AAV9 in vitro [85]^17, and the
   RGDLRVS-AAV9-cap plasmid has been used for endothelial-specific gene
   expression or knockdown in mouse models [86]^18^, [87]^21. To
   downregulate SRC-3 expression in endothelial cells in vivo, we infected
   ApoE^-/- mice with endothelial-specific RGDKRVS-AAV9-mediated SRC-3
   short hairpin RNA (shSRC-3) and negative control short hairpin RNA
   (shCtrl) by tail vein injection before feeding the mice a WD. The
   aortas of ApoE^-/- mice injected with AAV9-mediated shSRC-3 exhibited
   significantly reduced SRC-3 protein expression after the mice were fed
   a WD (Figure [88]2A). There were comparable plasma cholesterol levels
   and glucose levels between the AAV-shSRC-3 group and the AAV-shCtrl
   group after WD feeding ([89]Supplementary Figure 1B). En face analysis
   of Oil Red O-stained atherosclerotic lesion area showed an approximate
   2-fold decrease in the AAV-shSRC-3 group compared with the AAV-shCtrl
   group after WD feeding (Figure [90]2B). Staining of smooth muscle
   actin, collagen, lipids, and the macrophage marker F4/80 in the aortic
   roots in the AAV-shSRC-3 group and AAV-shCtrl group was performed to
   assess plaque composition. Consistent with the en face results,
   enhanced staining for collagen but reduced staining for lipids and the
   macrophage marker F4/80 were observed in AAV-shSRC-3 aortic roots
   (Figure [91]2C-F). These results demonstrate that SRC-3 in endothelial
   cells plays an important role in promoting the development of
   atherosclerosis.

Figure 2.

   [92]Figure 2
   [93]Open in a new tab

   SRC-3 in endothelial cells contributes to the development of
   atherosclerosis. (A) Western blot showing that AAV-mediated SRC-3 shRNA
   decreased SRC-3 expression levels in the aortas of ApoE^-/- mice. (B)
   SRC-3 knockdown reduced WD-induced atherosclerotic plaque formation in
   ApoE^-/- mice. Representative images of en face Oil Red O-stained
   aortas from ApoE^-/- mice injected with AAV-mediated SRC-3 shRNA and
   scramble shRNA (left panel). Quantification of the plaque areas of
   aortas (right panel). The data represent the mean ± SEM. (C-F)
   Cross-sections of the aortic roots of ApoE^-/- mice injected with
   AAV-mediated SRC-3 shRNA and scramble shRNA were subjected to (C) H&E
   staining (scale bar, 100 µm), (D) Masson staining (scale bar, 500 µm),
   (E) Oil Red O staining (scale bar, 100 µm), (F) F4/80 staining (scale
   bar, 100 µm). Left panels, representative images. Right panels,
   quantification of stained area or a percentage of lesion area. The data
   represent the mean ± SEM. The results are representative of three
   independent experiments. P values were calculated by unpaired
   two-tailed Student's t-test. *, P<0.05; **, P<0.01; ***, P<0.001.

SRC-3 increases ICAM-1 expression during atherosclerosis development

   To examine the mechanism of SRC-3-mediated promotion of
   atherosclerosis, we performed messenger RNA (mRNA) sequencing in the
   aortas of WD-fed SRC-3^-/-ApoE^-/- and SRC-3^+/+ApoE^-/- mice. KEGG
   enrichment pathway analysis revealed eight enriched pathways (Figure
   [94]3A and E), including the NF-kappa B signaling pathway, cell
   adhesion molecules (CAMs), and ECM-receptor interaction. Gene Ontology
   (GO) analysis of enriched biological processes indicated that SRC-3 was
   associated with cell adhesion and the inflammatory response (Figure
   [95]3B). Because the aortas of WD-fed SRC-3^-/-ApoE^-/- mice had
   reduced macrophage recruitment (Figure [96]1K), we focused on the
   expression of cell adhesion molecules, CC and CXC chemokines and their
   receptors, which are responsible for leukocyte recruitment (Figure
   [97]3C). The RNA-Seq results revealed decreased expression of CCL3,
   CD68, ICAM-1, and VCAM-1 in the aortas of WD-fed SRC-3^-/-ApoE^-/- mice
   (Figure [98]3C); however, real-time quantitative PCR showed that only
   ICAM-1 expression was significantly reduced in the aortas of WD-fed
   SRC-3^-/-ApoE^-/- mice (Figure [99]3D). ICAM-1 is involved in the
   progression of atherosclerosis in ApoE^-/- mice [100]^22^, [101]^23^,
   [102]^24^, [103]^25^, [104]^26. Therefore, ICAM-1 was selected for
   further investigation. Western blot analysis showed that the protein
   levels of ICAM-1 were significantly decreased in the aortas of WD-fed
   SRC-3^-/-ApoE^-/- mice compared with SRC-3^+/+ApoE^-/- mice (Figure
   [105]3E), suggesting that SRC-3 upregulates ICAM-1 expression.
   Consistently, the protein levels of SRC-3 were positively correlated
   with the protein levels of ICAM-1 in human atherosclerotic lesions
   (Figure [106]3E and F). Taken together, these results suggest that
   SRC-3 promotes ICAM-1 expression during atherosclerosis development.

Figure 3.

   [107]Figure 3
   [108]Open in a new tab

   SRC-3 increases ICAM-1 expression during atherosclerosis development.
   (A) KEGG enrichment pathway analysis and (B) Gene Ontology (GO)
   biological process analysis of mRNA profiles in the aortas of
   SRC-3^+/+ApoE^-/- and SRC-3^-/-ApoE^-/- mice after WD feeding for 12
   weeks. (C) Selected genes involved in leukocyte recruitment and
   proinflammatory markers are shown as a heat map. (D) The mRNA level of
   ICAM-1 in the aortas of SRC-3^-/-ApoE^-/- mice was significantly
   decreased after WD feeding for 12 weeks. (E) The protein level of
   ICAM-1 in the aortas of SRC-3^+/+ApoE^-/- and SRC-3^-/-ApoE^-/- mice
   after WD feeding for 12 weeks. Each lane represents a pooled sample of
   three representative mice. (F) Western blot analysis of SRC-3 and
   ICAM-1 in 16 atherosclerotic plaques and plaque-adjacent vasculature in
   the lower limb aorta of accident patients. N represents plaque-adjacent
   vasculature in the lower limb aorta; AS represents atherosclerotic
   plaques in the lower limb aorta. (G) Correlation between SRC-3 and
   ICAM-1 protein levels in 16 atherosclerotic plaques and plaque-adjacent
   vasculature in the lower limb aorta. The data represent the mean ± SEM.
   The results are representative of three independent experiments. P
   values were calculated by unpaired two-tailed Student's t-test. *,
   P<0.05.

SRC-3 promotes ICAM-1 expression by enhancing NF-κB signaling

   Since both the mRNA and protein levels of ICAM-1 were significantly
   decreased in the aortas of WD-fed SRC-3^-/-ApoE^-/- mice compared with
   SRC-3^+/+ApoE^-/- mice, SRC-3 may regulate ICAM-1 expression at the
   transcriptional level. To determine whether SRC-3 can regulate ICAM-1
   expression in endothelial cells, we transfected SRC-3-specific small
   interfering RNA (siSRC-3) into human umbilical vein endothelial cells
   (HUVECs) to knock down SRC-3 and examined ICAM-1 expression. As shown
   in Figure [109]4A and B, the protein and mRNA levels of ICAM-1 in
   siSRC-3-transfected HUVECs were significantly reduced compared with
   scrambled siRNA (siCtrl)-transfected HUVECs before and after TNFα or
   IL-1β treatment. Restoration of SRC-3 expression in SRC-3-knockdown
   HUVECs could rescue ICAM-1 expression after TNFα or IL-1β treatment
   ([110]Supplementary Figure 2A and B). Furthermore, we examined whether
   SRC-3 could promote ICAM-1 transcription by transfecting the ICAM-1
   promoter-reporter plasmid into wild-type and SRC-3-knockdown HUVECs. As
   shown in Figure [111]4C, TNFα or IL-1β treatment markedly induced
   ICAM-1 promoter activity in scramble HUVECs, whereas SRC-3 knockdown
   significantly reduced the induction of ICAM-1 promoter activity. These
   results suggest that SRC-3 promotes ICAM-1 expression at the
   transcriptional level.

Figure 4.

   [112]Figure 4
   [113]Open in a new tab

   SRC-3 regulates ICAM-1 expression via enhancing NF-κB signaling. (A)
   The protein levels of SRC-3 and ICAM-1 in SRC-3 siRNA-transfected
   HUVECs were significantly reduced compared with those in scrambled
   siRNA-transfected HUVECs after TNFα or IL-1β treatment. (B) The mRNA
   level of ICAM-1 in the SRC-3 siRNA-transfected HUVECs was markedly
   decreased after TNFα or IL-1β treatment. (C) ICAM-1 promoter activity
   was reduced in SRC-3 siRNA-transfected HUVECs after TNFα or IL-1β
   treatment. (D) SRC-3 cooperated with p65 to enhance the activity of the
   NF-κB reporter (upper panel) and ICAM-1 promoter (lower panel). (E)
   NF-κB binding site mutation abolished NF-κB-mediated ICAM-1 promoter
   activity. (F) The recruitment of SRC-3 and p65 was significantly
   reduced in SRC-3 siRNA-transfected HUVECs after TNFα or IL-1β treatment
   (right panel). Position of the subfragments detected by ChIP assays
   (left panel). (G) The SRC-3 siRNA-transfected HUVECs monolayer
   exhibited a significantly decreased number of adhered (upper panel) and
   transmigrated (lower panel) THP-1 cells after TNFα or IL-1β treatment.
   (H) Western blot showing ICAM-1 overexpression in SRC-3
   siRNA-transfected HUVECs. (I) ICAM-1 overexpression in SRC-3
   siRNA-transfected HUVECs rescued monocyte attachment to HUVECs and
   monocyte transendothelial migration after TNFα or IL-1β treatment. The
   data represent the mean ± SEM of three independent experiments. P
   values were calculated by unpaired two-tailed Student's t-test. *,
   P<0.05; **, P<0.01;***, P<0.001.

   It has been reported that ICAM-1 expression can be induced by NF-κB
   [114]^27. Because TNFα or IL-1β treatment can induce NF-κB activation
   (Figure [115]4A) and SRC-3 can interact with p65 to enhance
   p65-mediated NF-κB reporter activation (Figure [116]4D, upper panel),
   we hypothesized that SRC-3 may enhance NF-κB-mediated ICAM-1
   expression. We tested this hypothesis by transfecting HUVECs with an
   ICAM-1 promoter-reporter plasmid with SRC-3, p65, or both SRC-3 plus
   p65 expression plasmids. Transfection of p65 or SRC-3 alone induced a
   10-fold or 1.3-fold increase in ICAM-1 promoter activity (Figure
   [117]4D, lower panel), respectively, whereas cotransfection of p65 and
   SRC-3 induced a 13-fold increase in ICAM-1 promoter activity (Figure
   [118]4D, lower panel). These results suggest that SRC-3 can enhance
   NF-κB-mediated ICAM-1 expression. To further confirm the role of p65 in
   NF-κB-mediated activation of the ICAM-1 promoter, we mutated the NF-κB
   binding site on the ICAM-1 promoter. As shown in Figure [119]4E,
   cotransfection of p65 and SRC-3 induced the activity of the wild-type
   ICAM-1 promoter by approximately 15-fold, while mutating the NF-κB
   binding site dramatically abolished NF-κB-mediated ICAM-1 promoter
   activity, suggesting that the NF-κB binding site is essential for
   NF-κB-mediated activation of the ICAM-1 promoter. We next determined
   whether SRC-3 and p65 could be recruited to the NF-κB binding site on
   the promoter after TNFα or IL-1β treatment. As shown in Figure 4F,
   SRC-3 and p65 bound to the NF-κB binding site on the ICAM-1 promoter
   after TNFα or IL-1β treatment, whereas SRC-3 knockdown in HUVECs
   markedly reduced the recruitment of p65 and SRC-3 to the ICAM-1
   promoter, suggesting that SRC-3 and p65 are recruited to the NF-κB
   binding site to enhance NF-κB-mediated activation of the ICAM-1
   promoter after TNFα or IL-1β treatment.

   In response to endothelial cell activation, various leukocytes are
   recruited, which is a basic event in vascular inflammation. The
   processes that participate in inflammatory cell recruitment include
   leukocyte-endothelial adhesion and transmigration. To determine the
   role of endothelial SRC-3 in vascular inflammation, we performed
   proinflammatory cytokine-mediated monocyte-endothelial cell adhesion
   and transmigration assays. As shown in Figure [120]4G, the
   siSRC-3-transfected HUVEC monolayer exhibited a marked decrease in the
   number of adhered and transmigrated THP-1 cells compared with the
   siCtrl-transfected HUVEC monolayer after TNFα or IL-1β treatment. We
   next determined whether the restoration of ICAM-1 expression in
   SRC-3-knockdown HUVECs could rescue the number of adhered and
   transmigrated THP-1 cells after TNFα or IL-1β treatment. As shown in
   Figure [121]4H and I, ectopic expression of ICAM-1 in SRC-3-knockdown
   HUVECs rescued the number of adhered and transmigrated THP-1 cells
   after TNFα or IL-1β treatment. These results suggest that SRC-3
   promotes the adhesion and transmigration of THP-1 cells at least in
   part by increasing ICAM-1 expression.

ICAM-1 expressed in endothelial cells is required for atherosclerosis
development

   To verify that ICAM-1 in endothelial cells promotes atherosclerotic
   plaque formation in mice, we infected ApoE^-/- mice with
   endothelial-specific RGDKRVS-AAV9-ICAM-1 or scramble virus by tail vein
   injection before feeding the mice a WD. Mice that were injected with
   endothelial-specific AAV9-ICAM-1 virus showed significantly higher
   ICAM-1 expression (Figure [122]5A) and markedly increased plaque
   formation (Figure [123]5B) and lesion area (Figure [124]5C) than mice
   that were injected with the scramble control virus. Furthermore,
   staining for lipids and the macrophage marker F4/80 in the aortic roots
   in the AAV9-scramble control group and AAV9-ICAM-1 expression group was
   performed to assess plaque composition. Consistent with the en face
   results, increased staining for lipids and the macrophage marker F4/80
   was observed in AAV9-hICAM-1-infected aortic roots (Figure [125]5C and
   E). There was no difference in plasma lipid content levels and plasma
   glucose levels between the AAV9-scramble and AAV9-hICAM-1 groups
   ([126]Supplementary Figure 3A). Conversely, we knocked down mouse
   ICAM-1 by using an endothelial-specific AAV9-shICAM-1 virus. Plasma
   lipid levels and plasma glucose levels were comparable between the
   AAV-scramble control and AAV-shICAM-1 virus-infected groups
   ([127]Supplementary Figure 3B). Mice that were injected with the
   endothelial-specific AAV9-shICAM-1 virus exhibited significantly
   decreased atherosclerotic plaque formation and lesion areas
   ([128]Supplementary Figure 4A and B). Consistent with the en face
   results, reduced staining for lipids and the macrophage marker F4/80
   was observed in AAV9-shICAM-1 virus-infected aortic roots
   ([129]Supplementary Figure 4C-E). These results demonstrate that ICAM-1
   in endothelial cells is required for the development of
   atherosclerosis.

Figure 5.

   [130]Figure 5
   [131]Open in a new tab

   ICAM-1 in endothelial cells is required for atherosclerosis
   development. (A) Western blot analysis showing increased hICAM-1
   expression in the aortas of mice injected with AAV expressing hICAM-1.
   (B) hICAM-1 overexpression accelerated WD-induced atherosclerotic
   plaque formation in ApoE^-/- mice. Representative images of en face Oil
   Red O-stained aortas from ApoE^-/- mice injected with AAV expressing
   hICAM-1 and vector (left panel). Quantification of the plaque areas of
   aortas (right panel). The data represent the mean ± SEM. (C-E)
   Cross-sections of the aortic roots from ApoE^-/- mice injected with
   AAV-hICAM-1 and vector were subjected to (C) H&E staining (scale bar,
   100 µm), (D) Oil Red O staining (scale bar, 100 µm), and (E) F4/80
   staining (scale bar, 100 µm). Left panels, representative images. Right
   panels, quantification of stained area or a percentage of lesion area.
   The data represent the mean ± SEM. The results are representative of
   three independent experiments. P values were calculated by unpaired
   two-tailed Student's t-test. *, P<0.05; **, P<0.01;***, P<0.001.

Pharmacological inhibition of SRC-3 reduces atherosclerosis

   Since SRC-3 deficiency prevents atherosclerosis development, we
   assessed the protective effect of bufalin, a small-molecule inhibitor
   of SRC-3 that has been used in tumor therapy [132]^28^, [133]^29, in
   the development of atherosclerosis. We first performed proinflammatory
   cytokine-mediated monocyte-endothelial cell adhesion and transmigration
   assays to determine whether bufalin alleviates macrophage recruitment
   in vitro. As shown in Figure [134]6A, the expression of SRC-3 and
   ICAM-1 in HUVECs was significantly reduced by bufalin treatment.
   Additionally, bufalin treatment significantly decreased the expression
   of p-p65 (Figure [135]6A). Consequently, a significant reduction in
   adhered and transmigrated THP cells was observed in the presence of
   bufalin-treated HUVECs in response to TNFα or IL-1β treatment (Figure
   [136]6B).

Figure 6.

   [137]Figure 6
   [138]Open in a new tab

   Pharmacological inhibition of SRC-3 reduces atherosclerosis. (A) The
   protein levels of SRC-3, ICAM-1 and p-p65 in bufalin-treated HUVECs
   were significantly reduced compared with those in vehicle-treated
   HUVECs after TNFα or IL-1β treatment. The bufalin-treated HUVECs
   monolayer resulted in a dramatically decreased number of adhered (upper
   panel) and transmigrated (lower panel) THP-1 cells after TNFα or IL-1β
   treatment. (B-C) ApoE^-/- mice were administered vehicle or bufalin
   (1.0 mg/kg, six times a week) by intraperitoneal injection for 13 weeks
   concomitant with WD feeding. (B) Dosing regimen (ApoE^-/- prevention
   model). (C) Representative images of en face Oil Red O-stained aortas
   from ApoE^-/- mice treated with vehicle or bufalin (left panel).
   Quantification of the plaque areas of aortas (right panel). The data
   represent the mean ± SEM. (D) The protein levels of SRC-3 and ICAM-1 in
   the aortas of ApoE^-/- mice treated with bufalin were significantly
   reduced in the ApoE^-/- prevention model. (E-F) ApoE^-/- mice were fed
   a WD for 10 weeks and then treated with vehicle or bufalin (1.0 mg/kg,
   six times a week) by intraperitoneal injection for 13 weeks concomitant
   with WD feeding. (E) Dosing regimen (ApoE^-/- regression model). (F)
   Representative images of en face Oil Red O-stained aortas from ApoE^-/-
   mice treated with vehicle or bufalin (left panel). Quantification of
   the plaque areas of aortas (right panel). The data represent the mean ±
   SEM. (G) The protein levels of SRC-3 and ICAM-1 in the aortas of
   ApoE^-/- mice treated with bufalin were significantly reduced in the
   ApoE^-/- regression model. The data represent the mean ± SEM. The
   results are representative of three independent experiments. P values
   were calculated by unpaired two-tailed Student's t-test. *, P<0.05; **,
   P<0.01;***, P<0.001.

   We then determined the protective effect of bufalin on atherosclerosis
   by using ApoE^-/- prevention model. Bufalin was administered to
   ApoE^-/- mice (1.0 mg/kg, six times a week) by intraperitoneal
   injection for 13 weeks during WD feeding (Figure [139]6C).
   Bufalin-treated mice exhibited decreased atherosclerotic plaque
   formation compared with those treated with vehicle only (Figure
   [140]6D). Furthermore, the protein levels of SRC-3 and ICAM-1 in the
   aortas from ApoE^-/- mice treated with bufalin were also significantly
   reduced after the mice were fed a WD for 13 weeks (Figure [141]6E).
   Reduced p-p65 was observed in the aortas of mice treated with bufalin
   after WD feeding for 13 weeks (Figure [142]6F). Bufalin treatment did
   not significantly affect plasma lipid or glucose levels
   ([143]Supplementary Figure 5A).

   It is well known that atherosclerosis is an advanced disease, and so we
   performed a regression model by treating ApoE^-/- mice that were fed WD
   alone for 10 weeks with bufalin for 13 weeks during WD feeding (Figure
   [144]6F). Bufalin treatment further diminished plaque development
   (Figure [145]6G). The levels of SRC-3, ICAM-1, and p-p65 in the aortas
   of bufalin-treated mice were also reduced compared with those of
   vehicle-treated mice (Figure [146]6H). Bufalin treatment significantly
   increased TC and HDL-C, but decreased glucose levels
   ([147]Supplementary Figure 5B). These results demonstrate that the
   pharmacological SRC-3 inhibitor bufalin can ameliorate the development
   of atherosclerosis.

Discussion

   Lipid-mediated inflammation of the vessel wall is a key initiating
   event in atherosclerosis that activates endothelial cells to recruit
   macrophages in a leukocyte adhesion molecule-dependent manner [148]^30.
   In this study, we found that global SRC-3 deficiency or endothelial
   SRC-3 knockdown on an ApoE^-/- background ameliorated the development
   of atherosclerosis, suggesting that SRC-3 could promote atherosclerosis
   development. Mechanistically, SRC-3 promoted atherosclerosis
   development by increasing ICAM-1 expression at the transcriptional
   level by enhancement of NF-κB function in endothelial cells to promote
   macrophage recruitment (Figure [149]7). SRC-3 depletion or
   pharmacological inhibition of SRC-3 by bufalin ameliorated
   atherosclerosis development, at least in part by decreasing endothelial
   ICAM-1 expression via reduction of NF-κB function (Figure [150]7).

Figure 7.

   [151]Figure 7
   [152]Open in a new tab

   Schematic model of the mechanism by which SRC-3 accelerates
   atherosclerosis development. SRC-3 promotes atherosclerosis development
   by increasing ICAM-1 transcription by enhancing the function of NF-κB
   in endothelial cells to promote macrophage recruitment. SRC-3 depletion
   or pharmacological inhibition of SRC-3 by bufalin ameliorates
   atherosclerosis development through decreasing endothelial ICAM-1
   expression and macrophage recruitment via reduction of NF-κB function.

   In this study, we showed that the genetic ablation of SRC-3 prevented
   the development of atherosclerosis in ApoE^-/- mice, indicating that
   SRC-3 injures the vasculature during atherosclerosis. A previous study
   showed that SRC-3 was required for estrogen-induced inhibition of
   neointima formation during vascular trauma, which may be caused by
   suppressing of vascular cell proliferation [153]^13. Recently, it has
   been reported that SRC-1/3 deficiency can cause noncompaction
   cardiomyopathy-like abnormalities in the hearts of newborn and adult
   mice, which are caused by the inhibition of cardiomyocyte proliferation
   and differentiation [154]^14, suggesting that SRC-3 has a
   vasoprotective role. These studies demonstrate that SRC-3 has injures
   or protects the vasculature in different cardiovascular diseases
   through diverse mechanisms.

   Advanced atherosclerotic lesions, which are essentially a nonresolving
   inflammatory condition, can cause the formation of the vulnerable
   plaques, increasing the risk of plaque rupture. Vulnerable plaques are
   characterized by the formation of necrotic cores and thinning of the
   fibrous cap. The necrotic core is the result of increased macrophage
   death and impaired efferocytosis [155]^8. H&E staining of the aortic
   roots showed that the total necrotic areas in the aortic root lesions
   of SRC^-/-ApoE^-/- mice were smaller than those in SRC-3^+/+ApoE^-/-
   mice, and fibrous caps in the aortic root lesions of SRC-3^-/-ApoE^-/-
   mice were thicker than those of SRC-3^+/+ApoE^-/- mice. In human
   atherosclerotic-associated cardiovascular events, plaque morphology is
   a more critical predictor of plaque rupture than plaque size, and the
   size of the necrotic core plays a primary role in plaque vulnerability
   [156]^16. Other features, such as high levels of inflammatory cytokines
   and significant accumulation of lipids also contribute to the
   vulnerability of atherosclerotic plaques [157]^31. In this study,
   analysis of atherosclerotic plaques revealed that SRC-3^-/-ApoE^-/-
   mice exhibited notably decreased infiltration of macrophages, decreases
   in α-SMA levels and lipid accumulation and an increase in collagen
   content. Advanced necrotic cores and other deteriorated features of
   vulnerable plaques are responsible for the majority of clinical events.

   Our results showed that global SRC-3 deficiency on the ApoE^-/-
   background ameliorated the development of atherosclerosis. Previous
   studies have shown that RGDLRVS-AAV9-cap plasmid-based virus
   preferentially mediates genes expression in endothelial cells in vitro
   and in vivo [158]^17^, [159]^18^, [160]^21. Therefore, ApoE^-/- mice
   were infected with endothelial-specific RGDKRVS-AAV9-shSRC-3 or control
   shRNA virus by tail vein injection before being fed a WD, and a model
   of atherosclerosis was constructed. We found that mice on the ApoE^-/-
   background that were infected with endothelial-specific AAV9-shSRC-3
   also exhibited significant reductions in atherosclerotic plaques,
   similar to the effects of global SRC-3 deficiency on the ApoE^-/-
   background, suggesting that endothelial SRC-3 contributes to
   atherosclerosis development. Additionally, SRC-3^-/-ApoE^-/- mice
   exhibited markedly decreased levels of plasma lipids and glucose
   compared with SRC-3^+/+ApoE^-/- mice after being fed a WD for 12 weeks.
   However, mice on the ApoE^-/- background that were infected with
   endothelial-specific AAV9-shSRC-3 virus did not exhibit significantly
   altered levels of plasma lipids or glucose. Therefore, the decrease in
   plasma lipid and glucose levels due to global SRC-3 deficiency on the
   ApoE^-/- background could contribute to the reduction in
   atherosclerotic plaque formation in a manner that is independent of the
   endothelial cells.

   ICAM-1 belongs to the Ig superfamily and is composed of a transmembrane
   domain and a short cytoplasmic domain [161]^32. This factor is
   expressed by endothelial cells, epithelial cells, all leukocyte subsets
   [162]^33, platelets [163]^34, and vascular smooth muscle cells
   [164]^35. ICAM-1 can mediate leukocyte rolling and firm adhesion to the
   vessel wall and leukocyte transmigration across the endothelial layer
   [165]^36, promoting vascular inflammation. It has been reported that
   ICAM-1 deficiency or inhibition protects against the development of
   atherosclerosis in ApoE^-/- mice [166]^22^, [167]^23^, [168]^24^,
   [169]^25^, [170]^26. In this study, we found that ICAM-1 overexpression
   in the vascular endothelial cells of mice infected with AAV9-hICAM-1
   accelerated atherosclerotic plaque formation after the mice were fed a
   WD for 12 weeks, whereas ICAM-1 knockdown in the vascular endothelial
   cells of mice infected with AAV9-shICAM-1 virus alleviated
   atherosclerotic plaque formation after being fed WD for 12 weeks.
   Furthermore, ectopic ICAM-1 expression in SRC-3-knockdown HUVECs
   increased the number of adhered and transmigrated THP-1 cells compared
   with that in SRC-3-knockdown HUVECs. These results suggest that
   endothelial ICAM-1 plays an import role in promoting the development of
   atherosclerosis, at least in part through increasing leukocyte adhesion
   and transmigration and is sufficient to promote atherosclerosis
   development.

   Bufalin is a major bioactive monomer of the traditional Chinese
   medicine Chan Su, which is acquired from the skin and parotid venom
   glands of the Chinese toad [171]^37^, [172]^38. It has been reported
   that bufalin is a small-molecule inhibitor of SRC-3 that can directly
   bind to the receptor interacting domain of the SRC-3 protein to promote
   its degradation [173]^28. In this study, bufalin treatment of ApoE^-/-
   mice ameliorated atherosclerotic plaque formation in an ApoE^-/-
   prevention model and regression model, suggesting that bufalin plays an
   important protective role against atherosclerosis. Furthermore, the
   protein levels of SRC-3 and ICAM-1 were reduced in the aortas of
   bufalin-treated ApoE^-/- mice after the mice were fed a WD for 13
   weeks. We found that bufalin suppressed the protein expression of p-p65
   and p65 in the aortas of bufalin-treated ApoE^-/- mice after the mice
   were fed a WD for 13 weeks. Additionally, bufalin-treated HUVECs
   exhibited significant reductions in adhered and transmigrated monocytes
   in response to TNFα or IL-1β, and bufalin treatment reduced the protein
   levels of SRC-3, ICAM-1, and p-p65 in HUVECs, similar to the effect on
   bufalin-treated ApoE^-/- mice, suggesting that endothelial cells are
   targets of bufalin. These results demonstrate that SRC-3 pathway
   inhibited by bufalin was involved in atherosclerosis development, at
   least in part through reducing ICAM-1 expression via reducing NF-κB
   signaling. Recent studies have shown that bufalin exerts anticancer
   activity on various cancers [174]^29. Furthermore, Chan Su has been
   widely used in the clinical treatment of malignancies in China and
   exhibits good therapeutic efficacy [175]^39^, [176]^40. Thus, the SRC-3
   inhibitor bufalin may not only represent a new drug for the prevention
   and treatment of atherosclerosis, but may also be safe for
   SRC-3-targeted cancer therapies at the experimental and clinical
   levels.

   NF-κB can regulate endothelial ICAM-1 expression at the transcriptional
   level [177]^41^, [178]^42. Furthermore, endothelial NF-κB deficiency
   decreased the expression of leukocyte adhesion molecules, attenuated
   macrophage recruitment to atherosclerotic plaques and decreased the
   expression of proinflammatory cytokines in the aorta [179]^43^,
   [180]^44, suggesting that endothelial NF-κB is required for promoting
   atherosclerotic plaque formation. The present study showed that NF-κB
   signaling was inhibited in aortas of SRC-3^-/-ApoE^-/- mice after WD
   feeding for 12 weeks or SRC-3-knockdown HUVECs after TNFα and IL-1β
   treatment, suggesting that SRC-3 can activate NF-κB. Additionally, it
   has been reported that SRC-3 can serve as a coactivator for p65 to
   enhance its transcriptional activity [181]^12^, [182]^45^, [183]^46.
   Our results showed that SRC-3 could be recruited to the p65 binding
   site on the ICAM-1 reporter/promoter and that SRC-3 could cooperate
   with p65 to enhance ICAM-1 transcription, suggesting that SRC-3
   coactivates NF-κB to upregulate ICAM-1 transcription. Although we found
   a consistent transcription factor AP-1 binding site (TGACTCGCA) at the
   ICAM-1 promoter, our results showed that SRC-3 could not cooperate with
   AP-1 to induce ICAM-1 promoter activity ([184]Supplementary Figure 6).
   Certainly, we could not exclude that SRC-3 could coactivate other key
   transcription factors in the endothelial cells to affect ICAM-1
   expression.

   Given that macrophage foam cell formation is critical for the
   atherosclerosis development, we investigated the effect of SRC-3 on
   macrophage foam cell formation demonstrated by affecting oxLDL uptake.
   As shown in [185]Supplementary Figure 7B and C, oxLDL uptake was
   significantly reduced in two SRC-3-knockdown stable RAW264.7 cell lines
   compared with control RAW264.7 cell line (shCtrl), suggesting that
   SRC-3 knockdown reduces macrophage foam cell formation. To determine
   whether bufalin treatment affects SRC-3 function in macrophages, we
   first assessed the effect of bufalin treatment on SRC-3 expression in
   macrophages. As shown in [186]Supplementary Figure 7D, bufalin
   treatment didn't decreased SRC-3 expression in macrophages, whereas
   bufalin treatment could significantly reduced SRC-3 expression in
   HUVECs. It suggests that the effect of bufalin on SRC-3 expression may
   be cell context-dependent.

   In summary, our study shows that endothelial SRC-3 deficiency or
   pharmacological inhibition prevents atherosclerosis development by
   decreasing endothelial ICAM-1 expression, resulting in the inhibition
   of macrophage recruitment. Thus, SRC-3 is a potential target for
   atherosclerosis prevention and therapy.

Supplementary Material

   Supplementary figures and table.
   [187]Click here for additional data file.^ (5.2MB, pdf)

Acknowledgments