Up-regulating Sphingosine 1-Phosphate Receptor-2 Signaling Impairs Chemotactic, Wound-healing, and Morphogenetic Responses in Senescent Endothelial Cells*

Vascular endothelial cells (ECs) have a finite lifespan when cultured in vitro and eventually enter an irreversible growth arrest state called “cellular senescence.” It has been shown that sphingolipids may be involved in senescence; however, the molecular links involved are poorly understood. In this study, we investigated the signaling and functions of sphingosine 1-phosphate (S1P), a serum-borne bioactive sphingolipid, in ECs of different in vitro ages. We observed that S1P-regulated responses are significantly inhibited and the S1P1-3 receptor subtypes are markedly increased in senescent ECs. Increased expression of S1P1 and S1P2 was also observed in the lesion regions of atherosclerotic endothelium, where senescent ECs have been identified in vivo. S1P-induced Akt and ERK1/2 activation were comparable between ECs of different in vitro ages; however, PTEN (phosphatase and tensin homolog deleted on chromosome 10) activity was significantly elevated and Rac activation was inhibited in senescent ECs. Rac activation and senescent-associated impairments were restored in senescent ECs by the expression of dominant-negative PTEN and by knocking down S1P2 receptors. Furthermore, the senescent-associated impairments were induced in young ECs by the expression of S1P2 to a level similar to that of in vitro senescence. These results indicate that the impairment of function in senescent ECs in culture is mediated by an increase in S1P signaling through S1P2-mediated activation of the lipid phosphatase PTEN.

The S1P receptor subtypes were expressed in distinct combinations in different cell types to produce an appropriate biological effect. For example, S1P 1 and S1P 3 are expressed in endothelial cells (ECs) (12). The signaling pathways regulated by the S1P 1 and S1P 3 receptors are required for the chemotaxis of endothelial cells, adherens junction assembly, endothelial morphogenesis, and angiogenic response in vitro and in vivo (7,(12)(13). However, the functional outcomes resulting from the concerted effects of the signaling pathways mediated by the distinct S1P receptor subtypes are currently unknown in a physiological environment.
In contrast to S1P 1 -stimulating chemotaxis, S1P 2 -mediated signaling was shown to inhibit cell migration (14 -16). For example, embryonic fibroblasts isolated from S1P 2 null mice exhibited an enhanced chemotaxis toward S1P, serum, and platelet-derived growth factor; this enhancement was reversed by the reintroduction of S1P 2 receptors (14). Recently, the mechanisms of S1P 2 -regulated inhibition of chemotaxis have started to become identified in several laboratories. For example, it was shown that the inhibition of migration by the S1P 2 receptor was mediated by G ␣12/13 -dependent Rac inactivation (15). In addition, Rho-dependent PTEN activation was demonstrated to account for the S1P 2 -mediated inhibitory effect (16). Together, these data indicate that S1P is able to control two completely opposite biological activities via the activation of distinct S1P receptor signaling pathways, i.e. S1P 1 stimulates chemotaxis and S1P 2 inhibits it. Thus, the physiological responses of S1P may be an orchestrated manifestation between the signaling cascades activated by the S1P receptor subtypes.
Most primary human cultures have a finite lifespan in vitro. By serial subculture, cells will cease proliferation and enter an irreversible state of terminal differentiation, which is termed replicative senescence. Cellular senescence is thought to be an important tumor-suppressive mechanism in vivo (17). For example, it was shown that senescence prevents the replication of neoplastic cells and thus inhibits tumor formation in the young animal. In contrast, the accumulation of senescent cells during the aging process may have detrimental effects. The number of senescent cells increases in the elderly can alter the tissue homeostasis (18). Also, it has been suggested that senescent ECs may be responsible for impaired wound healing and angiogenesis in the elderly (19). Moreover, altered gene expression by senescent ECs can negatively impact the surrounding microenvironment. For example, nitric oxide (NO) is a multifunctional mediator involved in vasodilatation and angiogenesis (20). NO production was shown to be inhibited in senescent ECs (21), suggesting that accumulation of senescent ECs in vivo may affect vascular tone and homeostasis. Furthermore, senescent ECs were shown to be present in human atherosclerotic lesions but not in non-atherosclerotic lesions (22,23). These results together suggest that senescent ECs in vivo may contribute to the pathogenesis of human vascular diseases.
Sphingolipids have been shown to play critical roles in mediating cellular senescence and regulating senescent-associated dysfunctions (24 -28). In this study, we utilized cultured ECs as an in vitro model to investigate the underlying mechanisms of senescent-associated endothelial impairments. We demonstrate that the senescent-associated endothelial dysfunctions can be attributed to the up-regulation of S1P 2 signaling. This study is significant because it shows for the first time the functional balance between S1P 1 and S1P 2 signaling in regulating physiological events such as senescent-dependent impairments of wound-healing and morphogenetic capabilities in vascular ECs.

EXPERIMENTAL PROCEDURES
Reagents-S1P purchased from Biomol was dissolved in 4 mg/ml fatty acid-free BSA (Sigma). Mouse monoclonal S1P 1 antibody E1-49 (IgG 2b) (29) was generated by conventional hybridoma technology using bacteria-expressed S1P 1 as immunogen. Phospho-specific anti-Akt1 was from Calbiochem, monoclonal mouse anti-Rac was from Upstate, and polyclonal rabbit anti-Akt and polyclonal rabbit phospho-specific anti-ERK1/2 were purchased from Cell Signaling. Polyclonal rabbit anti-ERK2 and anti-actin (H-300) were purchased from Santa Cruz Biotechnology (Santa Cruz, CA). Protein G-ultralink and A-Trisacryl beads were from Pierce. Peroxidase-conjugated sheep anti-rabbit IgG and peroxidase-conjugated goat anti-mouse IgG was from MP Biomedicals and Pierce Biotechnology, respectively. Matrigel was from BD Biosciences. For immunohistochemical staining, polyclonal rabbit anti-S1P 1 and anti-S1P 2 were provided by Dr. Suzanne Mandala (Merck Research Laboratories). Alexa-conjugated secondary antibodies and an ABC kit were from Molecular Probes and Vector laboratories, respectively. Other reagents, unless specified, were purchased from Sigma.
Cell Culture and Adenoviral Transduction-ECs with different in vitro ages were established essentially as described (30). Briefly, human umbilical vein endothelial cells (HUVECs) were plated at 4 ϫ 10 5 cells in a 100-mm culture dish and split every 3 days. The number of population doublings (PDs) that occurred during each passage was calculated as PD ϭ log 2 (number of cells proliferated/number of cells seeded). The cumulative population doubling level (CPDL), used to represent the age of the ECs in vitro, is the sum of PDs of each passage. According to this protocol, HUVECs became senescence at CPDL ϭ 60. Senescence was verified by the expression of senescent-associated (SA) ␤-galactosidase, a specific biomarker for senescent cells (31), and the lack of BrdUrd nuclear labeling (Zymed Laboratories Inc.), an indicator of cell proliferation. HUVECs of three stages were used throughout this study: young, intermediate, and senescent ECs with CPDLs of 15, 35, and 60, respectively. The transduction of endothelial cells with adenoviral particles was essentially as described before (13,29).
Electric Cell-substrate Impedance Sensing (ECIS) Assay-The ECIS TM Model 1600R (Applied BioPhysics) was used to measure the endothelial wound-healing responses essentially as described (29,32). Briefly, 200 l of cell suspension (5 ϫ 10 5 cells per ml) was seeded to each well of either an 8W1E or 8W10E ECIS array (Applied BioPhysics), which was pre-equilibrated with 200 l of medium at 37°C for 30 min. Two days later, endothelial cells were washed and replaced with plain M199 medium supplemented with 0.5% fetal bovine serum. For assessing wound-healing responses, the cell-covered electrode was connected to an AC source. By applying 5 V for 30 s, a relatively high current is delivered to the cell-covered electrode, which results in cell killing (29,32). After stimulating without or with S1P, endothelial wound-healing responses were determined in real-time by measuring the recovery of electrical impedance, an indicator of endothelial migration and proliferation into the wounded area (29,32).
Endothelial Morphogenesis and Rac Activation-The in vitro endothelial morphogenesis assay was performed in three-dimensional Matrigel (BD Biosciences) as described (12,13,33). Rac activity was measured as described (13). Briefly, HUVECs of different CPDLs were treated without or with S1P for various times. Cells were collected and solubilized with magnesiumcontaining lysis buffer (25 mM HEPES, pH 7.6, 150 mM NaCl, 1% Nonidet P-40, 10% glycerol, 25 mM NaF, 10 mM MgCl 2 , and 1 mM EDTA) containing protease inhibitors (Calbiochem). 400 g of cell extracts was incubated with glutathione S-transferase-p21-activated kinase (Rac binding domain of p21-activated kinase) beads at 4°C for 1 h to isolate the GTP-bound form of activated Rac. After washing, bound Rac polypeptides were resolved on a 12% SDS-PAGE and detected by Western blot analysis with monoclonal Rac antibody.
Immunoprecipitation and Western Blot Analysis-HUVECs treated without and with S1P were collected with cell scrapers in ice-cold phosphate-buffered saline followed by centrifugation (250 ϫ g, 5 min). Cell extracts were prepared in TBST/OG buffer (10 mM Tris-HCl, pH 8.0, 0.15 M NaCl, 1% Triton X-100, inhibitors (Calbiochem) with constant agitation at 4°C for 30 min, followed by centrifugation at 15,000 ϫ g for 20 min. Cell extracts were incubated overnight at 4°C with the indicated antibodies, and the immunocomplexes were precipitated by adding the mixtures of protein-A and protein-G beads at 4°C for 1 h. After washing, precipitated polypeptides were released by boiling in double-strength Laemmli buffer at 95°C for 5 min, resolved on a 10% SDS-PAGE, and transferred to nitrocellulose membranes. Subsequently, the membranes were blocked in 5% nonfat dry milk (Lab Scientific) in TBST (20 mM Tris-HCl, pH 7.4, 500 mM NaCl and 0.1% Tween 20). The blots were washed and incubated with the indicated primary antibodies on a rotary shaker at 4°C for overnight. The blots were then incubated with horseradish peroxidase-conjugated second antibody for 1 h at room temperature, incubated with enhanced chemilumenescence reagent (ECL) (Amersham Biosciences) for 1 min, and visualized by exposure to Kodak X-Omat films.
PTEN Phosphatase Assay-PTEN phosphatase activity was measured with the PTEN Malachite Green Assay Kit (Upstate) according to the manufacturer's instructions. Endothelial cells with different in vitro lifespans were solubilized in a lysis buffer containing 20 mM Tris, 300 mM NaCl, 2 mM EDTA, 0.2% SDS, 2% Triton X-100, and protease inhibitors (Calbiochem). After centrifuging at 15,000 ϫ g for 20 min, cellular PTEN polypeptides were immunoprecipitated by incubating extracts (500 g) with anti-PTEN (Cell Signaling) at 4°C overnight, followed by adding protein-A beads for 1 h at 4°C. The precipitated PTEN was then assessed for phosphatase activity by using D-myophosphatidylinositol 3,4,5-triphosphate (Echelon Biosciences, Salt Lake City) containing phospholipids vesicles. The released phosphate was quantitated after the addition of the malachite green reagent (Upstate) by measuring the absorbance at 630 nm.
Migration Assay-Endothelial chemotaxis was measured using the Transwell migration assay (8-m pore size, Costar) as described (13,29). Briefly, polycarbonate membranes were coated with human fibronectin (1 g/ml) overnight at 4°C. Following serum starvation, HUVECs were trypsinized, counted, and resuspended in M199 media with 0.5% fatty-acid free BSA (Sigma). Cells (7.5 ϫ 10 4 cells in 100 l) were placed in the upper chamber, and medium (600 l) containing S1P was added to the lower chamber. ECs were allowed to migrate for 4 h at 37°C in a humidified chamber with 5% CO 2 . Subsequently, the non-migrated cells on the upper side of the filter were removed with a cotton swab. The filters were fixed with 4% formaldehyde and stained with 0.1% crystal violet solution. Following eluting the stained dye with 10% acetic acid, cell chemotaxis was quantitated with the BMG FluoStar Galaxy microplate reader (BMG Labtechnologies) with absorbance at 590 nm.
Immunohistochemical Analysis-Paraffin sections were prepared from aorta of atherosclerotic mice as previously described (34). Subsequently, aortic specimens were blocked with 5% BSA in phosphate-buffered saline and incubated with indicated antibodies (1:100 dilution in 1% BSA) overnight at 4°C. After washing with phosphate-buffered saline (3 ϫ 5 min), specimens were incubated with biotin-conjugated secondary antibody (1:200 dilution in 1% BSA, Vectastain-Elite-ABC-Kit) for 30 min at room temperature, followed by incubation with avidin-biotinylated horseradish peroxidase solution (Vectastain-Elite-ABC-Kit) for 30 min at room temperature. Immu-S1P Signaling in Senescent Endothelial Cells OCTOBER 31, 2008 • VOLUME 283 • NUMBER 44 nostaining was then developed by diaminobenzidine tetrachloride solution according to manufacturer's instructions (Vector Laboratories). Specimens were counterstained with hematoxylin solution (Sigma). Because horseradish peroxidase enzymes specifically bound to antigen-antibody complexes were visualized by the addition of diaminobenzidine tetrachloride chromogen, the intensity of brown staining indicates the relative abundance of antigen. For quantitative purposes, the immunoreactivity (i.e. the intensity of brown staining) was analyzed by MetaMorph image acquisition and analysis software (Meta-Morph Version 6.1, Molecular Devices) (35). In addition, specimens were counterstained with hematoxylin solution, which produces a contrasting purple color for negative cells. The staining of SA-␤-galactosidase was performed essentially as described (22,23,31).
Next, we utilized the potent chemoattractant S1P (13,29) to examine the chemotactic capability of young, intermediate, and senescent ECs. As shown in Fig. 1B, S1P-mediated chemotactic response is inversely related to the in vitro ages of ECs. Moreover, S1P is unable to induce detectable chemotaxis in senescent ECs. S1P greatly accelerates the woundhealing and injury repair process in ECs (29). Therefore, we utilized the electrical cell-substrate impedance sensing (ECIS) technique (29,32) to measure the S1P-mediated woundhealing response in ECs with different in vitro ages. Young, intermediate, and senescent ECs were plated in the ECIS arrays. Subsequently, ECs attached to the microelectrodes (100 m in diameter) of arrays were killed by applying a high voltage electrical current (5 V for 30 s; arrow, Fig. 1C). The efficacy of the elevated electrical current to completely kill ECs attached to the microelectrodes was verified by cell viability staining with ethidium homodimer/calcein acetoxymethyl ester (29,32) and was shown by the complete drop of transendothelial electrical resistance (TEER) to the basal level (arrow, Fig. 1C). In contrast, the elevated electrical current had no effect on cells surrounding the microelectrodes (29,32). These viable cells surrounding the microelectrodes then migrate into electrically wounded areas, proliferate, re-establish the cell-cell interactions, and , and senescent (S, CPDL ϭ 60) ECs. Cells were labeled with BrdUrd reagent for 24 h. Subsequently, cells were immunostained with anti-BrdUrd following the manufacturer's instructions (BrdUrd staining kit, Zymed Laboratories Inc.). Mean Ϯ S.E. represents percentage of BrdUrd incorporated nuclei from 3-5 microscopic fields of duplicate experiments. B, chemotactic responses were measured by a Transwell migration assay as described under "Experimental Procedures." Note that S1P (100 nM)-induced chemotactic responses were inversely related to in vitro ages of cultured ECs. C, young, intermediate, and senescent ECs were plated into each well of 8W1E arrays and incubated at 37°C to allow the transendothelial electrical resistance (TEER) to reach equilibrium. 24 h later, the cells attached to the microelectrodes were killed by applying 5 V of electrical current for 30 s (arrow), which resulted in an abrupt impedance drop. Subsequently, endothelial wound-healing responses in the presence or absence of 100 nM S1P were determined in real-time by measuring the recovery of TEER, an indicator of endothelial migration into the wounded area (29). D, morphogenesis of young and senescent ECs on matrigel (upper panel) and quantitative analysis of tubular length (lower panel) in the presence or absence of S1P (200 nM) were performed as described (12,13). Scale bar, 318 m.
thus repair the injuries. The sequential events of the woundhealing process can be monitored in real-time by the increasing TEER. As shown in Fig. 1C, S1P significantly accelerated this wound-healing response in the electrically injured endothelial monolayer (t test, p Ͻ 0.005). It required ϳ2 h for young ECs to repair the wounds in the presence of S1P (thick blue line, Fig.  1C); whereas it required ϳ5 h for young ECs to repair in the absence of S1P (thin blue line, Fig. 1C). Moreover, the woundhealing capability is inversely related to the in vitro ages of ECs. For example, it required ϳ4 h for intermediate ECs to maximally repair the wounded area in the presence of S1P (thick green line, Fig. 1C). In contrast, ϳ10 h were required for wound repair with senescent ECs treated with S1P (thick red line, Fig. 1C).
We next employed a Matrigel morphogenesis assay, a widely used model system to assess in vitro angiogenic responses (33), to determine the S1P-mediated endothelial morphogenetic responses in young and senescent ECs. ECs were plated on Matrigel and treated without or with S1P. As shown in Fig. 1D, young ECs formed an organized network of tubule-like structures after S1P treatment, whereas the ability of S1P to stimu-late morphogenesis was completely diminished in senescent ECs. These data together indicate that senescent ECs are severely impaired in proliferative, chemotactic, woundhealing, and angiogenic responses.
Expression of S1P Family of GPCRs in Senescent ECs-We next determined the expression profiles of the S1P family of GPCRs during the in vitro aging process in cultured ECs. By analysis with the semiquantitative RT-PCR ( Fig. 2A) and real-time PCR (Fig. 2B) techniques, S1P 1 expression is shown to be significantly increased in an in vitro age-dependent manner in cultured ECs. The increased expression of S1P 1 receptor during in vitro aging process was further confirmed at the protein level by directly immunoblotting ECs extracts (top panel, Fig. 2C), or by immunoprecipitating endothelial extracts followed by immunoblotting (middle panel, Fig. 2C) with a monoclonal S1P 1 antibody. The expression of the S1P 3 receptor was also increased in senescent ECs (Fig.  2, A and B). It was shown that S1P 2 receptors are barely detected in the early passage of ECs (12). Interestingly, we observed that S1P 2 expression was dramatically induced in in vitro aged ECs (Fig. 2,  A and B). In contrast, the expression of the S1P 4 receptor was slightly decreased in senescent ECs (Fig. 2, A and B), and S1P 5 was not detected in young and senescent ECs (data not shown). Furthermore, the in vitro aged-dependent induction of S1P 1 and S1P 2 receptors was observed in human pulmonary artery endothelial cells (HPAECs, Fig. 2D). The in vitro lifespan of HPAECs (ATCC, CRL-2598) is approximately CPDL ϭ 45. The expression of S1P 1 in young (CPDL ϭ 22), intermediate (CPDL ϭ 30), and senescent (CPDL ϭ 45) HPAECs also increased in an in vitro aged-dependent manner (top panel, Fig. 2D). Moreover, similar to S1P 2 expression in HUVECs, S1P 2 receptors were undetectable in young HPAECs, whereas S1P 2 expression is markedly increased in the intermediate and senescent HPAECs (middle panel, Fig. 2D).
Up-regulation of S1P 2 in Aorta of Atherosclerotic Mice-Senescent ECs have been identified in the vascular endothelium in atherosclerosis (22,23), an aged-associated vascular disorder. We previously developed a mouse model to elucidate the role of leukotriene B4 in atherosclerosis (34). Aorta containing atherosclerotic lesion and non-lesion regions were therefore used to examine the expression of the S1P receptor subtypes in situ (Fig. 3). The endothelial layers were identified by immuno- and realtime qPCR (B) as described under "Experimental Procedures." S1P 1 expression was age-dependently increased in cultured HUVECs, and S1P 2 expression was barely detected in young ECs, whereas it was markedly increased in intermediate and senescent ECs. Similarly, S1P 3 was barely detected in young ECs and significantly up-regulated in senescent ECs. A low level of S1P 4 receptor was detected in young and intermediate ECs and is absent in senescent ECs. S1P 5 was not detected in ECs with different in vitro ages. The data are from a representative experiment, which was repeated six times with identical results. *, p Ͻ 0.01 (t test). C, endothelial extracts were immunoblotted (upper panel), or immunoprecipitated followed by Western-blotting with anti-S1P 1 (middle panel). Immunoblotting with anti-␤-actin was used as an internal control for loading (lower panel). The result is representative of triplicate experiments. Ϫ, assays were performed without endothelial extracts; *, immunoglobulin heavy chain used for immunoprecipitation assays. D, S1P 1 and S1P 2 expression in HPAECs with different in vitro ages. S1P 1 expression was age-dependently increased in HPAECs. Also, S1P 2 expression was significantly induced in senescent HPAECs and was undetected in young HPAECs. OCTOBER 31, 2008 • VOLUME 283 • NUMBER 44 staining with antibodies to Von Willebrand factor (indicated by arrows, top panel, Fig. 3A) and PECAM (arrows, bottom row, Fig. 3B). The smooth muscle layers were characterized by immunostaining with ␣-actin antibodies (arrows, bottom panel, Fig. 3A). In agreement with previous reports (22,23), SA-␤-galactosidase-positive ECs (i.e. senescent ECs) were clearly identified in the endothelial layer of the atherosclerotic lesion (dark blue layer indicated by arrows, top right panel, Fig.  3B). In contrast, no senescent ECs were identified in the nonlesion region of the aortic endothelium (light blue cell layer indicated by arrows, top left panel, Fig. 3B).

S1P Signaling in Senescent Endothelial Cells
We next examined the expression of S1P 1 and S1P 2 receptors in the lesion and non-lesion regions of atherosclerotic aorta by immunohistochemical staining followed by quantitation with MetaMorph image acquisition and analysis software. The immunohistochemical staining was developed by the diaminobenzidine tetrachloride reagent and counterstained with hematoxylin. Therefore, the intensity of brown staining quantitatively indicates the expression of S1P 1 or S1P 2 receptors, and the negative cells that were counterstained with hematoxylin show purple staining. As shown in Fig.  3B, the immunoreactivity of the S1P 1 antibody was increased in the endothelial layer of the atherosclerotic lesion (light brown versus dark brown in non-lesion versus lesion, arrows, second row, Fig.  3B). Indeed, quantitative analysis shows that there is a 2.4 Ϯ 0.1-fold increase (n ϭ 6, p Ͻ 0.05, t test) of S1P 1 receptors in the lesion region of atherosclerotic aorta (Fig. 3C). Importantly, S1P 2 was barely detectable in the non-lesion endothelium (light brown, arrows, left panel, third row, Fig. 3B). In sharp contrast, S1P 2 expression was dramatically increased in the endothelium of the atherosclerotic lesion (dark brown, arrows, right panel, third row, Fig. 3B). Quantitative analysis shows that there is a 3.5 Ϯ 0.2-fold increase (n ϭ 6, p Ͻ 0.05, t test) of S1P 2 receptors in the lesion region of atherosclerotic aorta (Fig. 3C). Together, these data indicate that the up-regulation of the S1P 1 and S1P 2 receptors in senescent ECs is physiologically significant.
Elevated PTEN Activity and Diminished Rac Activation in Senescent ECs-Next, we investigated the underlying mechanisms of the functional impairments in senescent ECs. It was previously shown that S1P signaling via S1P 1 /S1P 3 receptors activates Akt and ERK1/2 (12,13). Thus, young, intermediate, and senescent ECs were serum-starved, and S1Pinduced Akt and ERK1/2 activation was measured by immunoblotting with phospho-specific antibodies. As shown in Fig. 4A, S1P effectively activated Akt in young, intermediate, and senescent ECs with approximately similar kinetics. A robust Akt activation was observed 5 min after S1P stimulation, and S1P-induced Akt activation was sustained for up to 1 h in ECs with different in vitro ages. Similarly, S1P also activated ERK1/2 in senescent ECs with comparable kinetics as observed in young and intermediate ECs (Fig. 4B). Furthermore, there was no significant difference in the quantity of endogenous Akt and ERK1/2 protein between young, intermediate, and senescent ECs (Fig. 4, A and B). These data show that S1P-mediated ERK1/2 and Akt signaling cascades remain fully functional in senescent ECs. . S1P 2 receptors are up-regulated in the endothelium at the atherosclerotic lesion. The aorta segments were prepared from atherosclerotic mice (ϳ25 weeks old) as described previously (34). The atherosclerotic lesion and non-lesion regions (arrowheads, top, panel A) of the aorta were identified as reported previously (34). The endothelium was identified by staining with anti-Von Willebrand factor (vWF, arrows, top, panel A) and anti-PECAM (arrows, bottom row, panel B). The smooth muscle layers were identified by anti-␣actin staining (arrows, bottom, panel A). B, the non-lesion and lesion regions of atherosclerotic aorta were examined for expression of SA-␤-galactosidase activity (top row), S1P 1 (second row), and S1P 2 (third row). SA-␤galactosidase activity was observed in the endothelium of lesion regions (blue color indicated by arrows) and absent in the non-lesion regions. A small increase of S1P 1 expression was observed in lesion regions compared with the non-lesion regions (brown color indicated by arrows, second row). The expression of S1P 2 receptors was not detected in the endothelium of the non-lesion regions of the aorta (light brown indicated by arrows, left panel, third row). In contrast, S1P 2 receptors were markedly up-regulated in the endothelium of atherosclerotic lesions (dark brown indicated by arrows, right panel, third row). C, quantitation of S1P 1 and S1P 2 expression. The expression of S1P 1 and S1P 2 receptors in lesion and non-lesion regions of the atherosclerotic endothelium was quantitated by MetaMorph software (MetaMorph Version 6.1, Molecular Devices) (35). Data represent mean Ϯ S.E. of six microscopic fields. Both S1P 1 and S1P 2 receptors are significantly up-regulated in the lesion regions of atherosclerotic endothelium (*, p Ͻ 0.05, t test). NL, non-lesion; L, lesion regions.
Subsequently, we assayed Rac activity in normally growing young, intermediate, and senescent ECs. As shown in Fig. 5A, ECs with different in vitro ages expressed similar amounts of Rac polypeptides. However, Rac activity was significantly diminished in intermediate ECs, and barely detectable in senescent ECs (top panel, Fig. 5A). Moreover, S1P-stimulated Rac activation was inversely related to the in vitro ages of ECs (lower panel, Fig. 5A). Recently, it was shown that PTEN (phosphatase and tensin homolog deleted on chromosome 10) negatively regulates Rac activation and cell migration (16). Indeed, PTEN activity was markedly elevated in senescent ECs (Fig. 5B). The assay for PTEN activity is specific because the transduction of adenoviral particles carrying the dominant-negative PTEN construct (PTEN-C/S, the catalytic Cys-124 is mutated to Ser) (36) significantly abrogated PTEN activity; whereas transduction of adenoviral particles carrying wild-type PTEN construct had no effect (Fig. 5B). Furthermore, when serum-starved young and senescent ECs were stimulated with S1P, PTEN was significant activated in senescent ECs (Fig. 5C). These data suggest that the elevated PTEN activity and reduced Rac activation may be the major factor contributing to the impaired functions in senescent ECs.

Impaired Functions in Senescent ECs
Are Revoked by the Inhibition of S1P 2 /PTEN Signaling-We next examined whether the elevated S1P 2 signaling results in impairment of S1P-mediated responses in senescent ECs. As shown in Fig. 6A, transduction with lentiviral particles carrying si-S1P 2 specifically knocked down Ͼ95% of S1P 2 expression in senescent ECs, whereas transduction with lentiviral particles carrying control siRNA of an irrelevant gene (Luciferase) had no effect. The lentiviral-mediated S1P 2 knockdown is specific, because both S1P 1 and actin remain intact in si-S1P 2 -transduced ECs (two lower panels, Fig. 6A). Moreover, S1P 2 knockdown resulted in a significant increase in Rac activity in S1P-stimulated senescent ECs (-fold increase, 5.6 Ϯ 0.4 versus 1.9 Ϯ 0.6 in si-S1P 2 versus si-Luc transduced cells, respectively, n ϭ 3) (Fig. 6B). In addition, S1P 2 knockdown markedly reinstated S1P-induced chemotactic responses in senescent ECs, comparable to that in young ECs (Fig. 6C). It should be noted that there is a small but marked increase of Rac activity (Fig. 6B, -fold increase, 2.1 Ϯ 0.3 versus 1.1 Ϯ 0.5 in si-S1P 2 versus si-Luc transduced ECs, without S1P addition, n ϭ 3) and chemotactic response (Fig. 6C, A 595 nm , 0.149 Ϯ 0.009 versus 0.068 Ϯ 0.013 in si-S1P 2 versus si-Luc transduced ECs, without S1P addition, n ϭ 3) in si-S1P 2 knockdown ECs without S1P stimulation. This small increase in Rac activation and migratory response in S1P 2 knockdown ECs may be due to the relief of senescent ECs from the constraint of S1P 2 inhibitory signaling. Finally, S1P-stimulated wound-healing capability was markedly restored in senescent ECs transduced with si-S1P 2 , whereas there was no detectable restoration in senescent ECs transduced si-Luc (Fig. 6D).
Subsequently, we determined whether S1P-mediated endothelial responses could be restored in senescent ECs by inhibiting PTEN activity. Senescent ECs were transduced with adenoviral particles carrying wild-type or dominant negative PTEN mutant vector, and the Rac activity was measured after stimulating without or with S1P. S1P treatment resulted in a dramatic increase of Rac activation in senescent ECs transduced with adenoviral particles carrying the DN-PTEN vector (Fig. 7A). In contrast, senescent ECs transduced with adenoviral particles carrying wild-type PTEN were unable to further augment the S1P-induced Rac activation. Moreover, the inhibition of endogenous PTEN by the expression of the DN-PTEN mutant restored S1P-mediated chemotactic (Fig. 7B) and wound-healing responses (Fig. 7C) in a dose-dependent manner. In control experiments, adenoviral particles carrying control vectors (␤-galactosidase and WT-PTEN) did not restore the impaired functions to senescent ECs. Furthermore, the impairment of S1P-mediated morphogenesis in senescent ECs was reinstated in a dose-dependent manner by the expression of dominant-negative PTEN polypeptides (Fig. 7D).
We recently showed that S1P signaling via the S1P 1 receptor induces the ligation of integrin ␣ v and ␤ 3 subunits and the association of focal adhesion kinase (FAK) and ␣-actinin with integrin ␣ v ␤ 3 . This ultimately results in the activation of integrin ␣ v ␤ 3 in young ECs (37). However, S1P was unable to induce the activation of integrin ␣ v ␤ 3 in senescent ECs (Fig. 8 and supplemental Fig. S1). Thus, we examined whether senescent-elevated PTEN signaling antagonizes S1P 1 -mediated integrin ␣ v ␤ 3 activation in senescent ECs. Confocal microscopic analy-sis showed that transduction of dominant-negative PTEN adenoviral particles induced association of FAK and integrin ␣ v ␤ 3 at focal adhesion sites in S1P-treated senescent ECs (supplemental Fig. S1). In contrast, transduction of adenoviral par- Western blots of the cellular extracts (50 g) with anti-Rac shows that the quantities of endogenous Rac polypeptides were not changed in ECs with different in vitro ages (lower blot). Lower panel, young, intermediate, and senescent ECs were plated for 3 days followed by serum starvation in plain M199. After stimulating with S1P (100 nM) for the indicated times, Rac activation was measured as described above. The immunoblot intensity was quantitated with a Typhoon densitometer equipped with ImageQuant software. The histogram shows S1P-stimulated Rac activation represented as the ratio of activated Rac/total cellular Rac (mean Ϯ S. E., n ϭ 3). B, cellular extracts of normal growing young and senescent ECs were immunoprecipitated with anti-PTEN. The phosphatase activity of precipitated PTEN was then measured as described under "Experimental Procedures." Alternatively, senescent ECs were transduced with adenoviral particles carrying dominant-negative or wild-type PTEN (200 m.o.i.) for 16 h. The PTEN activity was then measured. Inset, Western blot shows the endogenous or transduced PTEN polypeptides. The data are the mean Ϯ S.E. of triplicate determinants. C, young and senescent ECs were plated for 3 days followed by serum starvation in plain M199. After stimulating with S1P (100 nM, 15 min), PTEN activity was measured as described above. The data represents the mean Ϯ S.E. of triplicate determinants (*, t test; p Ͻ 0.01). FIGURE 6. S1P 2 knockdown restores the impaired activities of senescent ECs. A, senescent ECs were transduced with lentiviral particles carrying siRNA oligonucleotides for Luciferase or S1P 2 receptor. RT-PCR measurement shows the efficacy of S1P 2 knockdown. Note that the expression of S1P 2 in senescent ECs transduced with a si-S1P 2 construct was completely inhibited, whereas an irrelevant siRNA (si-Luc) had no effect on S1P 2 knockdown. Also note that transduction of si-S1P 2 has no nonspecific off-target effects on the expression of S1P 1 and actin. B, senescent ECs were transduced with lentiviral particles carrying si-S1P 2 or si-Luc. Cells were grown for 3 days and serum-starved in plain M199 for 2 h. Subsequently, cells were stimulated with 200 nM S1P for 1 min, and Rac activity was measured as described above. Fold increase, mean Ϯ S.E. of three determinants. C, endothelial migration was measured in young, si-S1P 2transduced, or si-Luc-transduced senescent ECs in the presence or absence of S1P (100 nM) stimulation. The data are mean Ϯ S.E. of three determinants. D, si-S1P 2 -or si-Luc-transduced senescent ECs were plated in the ECIS array. S1P-mediated wound-healing response was measured as described above. Arrow, S1P (200 nM) was added immediately after the endothelial monolayers were injured by elevated electrical voltage. Data are the mean Ϯ S.E. of triplicate determinants of a representative experiment, which was repeated three times with identical results. ticles carrying control vector or wild-type PTEN was unable to induce association of FAK with integrin ␣ v ␤ 3 at focal adhesion sites in S1P-stimulated senescent ECs (supplemental Fig. S1). Inhibition of PTEN and the resulting integrin ␣ v ␤ 3 activation after S1P treatment in senescent ECs were further confirmed by Western blot analysis (Fig. 8). Senescent ECs were transduced with adenoviral particles carrying control, wild-type, or dominant-negative PTEN vectors followed by stimulation without or with S1P. Cellular extracts were immunoprecipitated with LM609, an antibody that immunoreacts with activated integrin ␣ v ␤ 3 heterodimers, followed by immunoblotting. As shown in Fig. 8, transduction with dominant-negative PTEN markedly induces association of FAK with integrin ␣ v ␤ 3 and ligation of ␣ v and ␤ 3 subunits. In agreement with our confocal analysis, transduction of adenoviral particles carrying control and wild-type PTEN vectors had no effect on integrin ␣ v ␤ 3 activation (Fig. 8). These data indicate that inhibition of integrin ␣ v ␤ 3 activation is a downstream effect of PTEN signaling in senescent ECs.

Expression of S1P 2 Receptor Inhibits Migration, Wound Healing, and Morphogenesis in Young ECs-
To further verify that up-regulation of S1P 2 signaling contributes to the SA impairment of endothelial function, we examined whether the expression of S1P 2 in young ECs was able to replicate the impairment that occurred in senescent ECs. Young ECs were transduced with various concentrations of adenoviral particles carrying S1P 2 receptor. As shown in Fig. 9A, young ECs transduced with 100 m.o.i. of adenoviral particles carrying the S1P 2 vector ectopically express S1P 2 receptors to a level similar to that attained by in vitro senescent ECs. Subsequently, young ECs were transduced with adenoviral particles carrying ␤-galactosidase, S1P 1 , or S1P 2 vectors, and activation of integrin ␣ v ␤ 3 at cell migratory edges after S1P stimulation was examined by confocal microscopy. Integrin ␣ v ␤ 3 heterodimers were markedly activated in young ECs transduced with adenoviral particles carrying control ␤-galactosidase or S1P 1 receptors (arrows, top two panels, Fig. 9B). There were 92 Ϯ 6% and 87 Ϯ 11% of cells positive for integrin ␣ v ␤ 3 activation in young ECs transduced with ␤-galactosidase and S1P 1 adenoviral particles, respectively. In contrast, S1P treatment was unable to activate integrin ␣ v ␤ 3 in 72 Ϯ 12% of S1P 2 transduced young ECs (Fig. 9B). Furthermore, young ECs were cotransduced with adenoviral particles carrying S1P 2 and wildtype, or dominant-negative PTEN vectors followed by stimulation without or with S1P. As shown in Fig. 9C, co-transduction with dominant-negative PTEN markedly induces the association of ␣-actinin with integrin ␣ v ␤ 3 and the activation of integrin ␣ v ␤ 3 in S1P 2 -transduced young ECs (arrows, bottom row, Fig. 9C). Co-transduction of adenoviral particles carrying wild-type PTEN vectors had no effect on the activation of integrin ␣ v ␤ 3 in S1P 2 -transduced young EC (Fig. 9C). Quantitative analysis showed that S1P stimulation resulted in 67 Ϯ 12% (n ϭ 6) of S1P 2 and dominant-negative PTEN co-transduced cells exhibiting integrin ␣ v ␤ 3 activation and ␣-actinin-␣ v ␤ 3 association. In contrast, 23 Ϯ 9% (n ϭ 6) of S1P 2 and wild-type PTEN co-transduced cells showed integrin ␣ v ␤ 3 activation and ␣-actinin-␣ v ␤ 3 association after S1P treatment.
Moreover, S1P-mediated endothelial migration (Fig. 10A) and wound-healing responses (Fig. 10B) were inhibited in a dose-dependent manner by the expression of S1P 2 receptors in  OCTOBER 31, 2008 • VOLUME 283 • NUMBER 44 young ECs. In contrast, transduction with adenoviral particles carrying the control ␤-galactosidase vector had no effect on S1P-induced migration (Fig. 10A) or wound-healing responses (Fig. 10B). Furthermore, the S1P-stimulated formation of a tubular-like network in Matrigel was diminished by the expression of S1P 2 receptors in a dose-dependent manner (Fig. 10C). Trypan blue exclusion showed that Ͼ95% of S1P 2 -transduced cells were viable, indicating that the inhibition of endothelial functions by S1P 2 expression did not result from nonspecific cytotoxic effects (data not shown). These results support the notion that S1P 2 signaling negatively regulates chemotactic, wound-healing, and morphogenetic responses in senescent ECs.

DISCUSSION
Research carried out over the past decades has shown that cellular senescence occurs in animals and in other organ systems (19, 22, 23, 38 -42). Also, senescent ECs have been identified in vasculature in vivo (19,22,23). Moreover, the senescent ECs were observed to be present only in lesions of atherosclerotic aorta and not in the normal regions (Fig. 3) (22,23). This observation implies that endothelial senescence in vivo may contribute to the pathogenesis of human atherosclerosis. In the present study, we utilized in vitro replicatively senescent ECs to investigate the mechanisms of functional impairments, which might have physiological implications in vascular disorders. An accumulating body of evidence suggests that sphingolipids may play an important role in regulation of cellular senescence (43)(44)(45)(46)(47). For example, the intracellular concentration of ceramide was significantly elevated in senescent fibroblasts compared with their young counterparts (43). Also, ceramide was shown to inhibit Cdk2 kinase, increase Kip1 and Kip2 Cdk inhibitors (44), induce dephosphorylation of retinoblastoma tumor suppressor protein (43), inhibit cell growth (45), and induce cellular senescence (43,46). Moreover, ceramide has been implicated in the inhibition of telomerase activity in human cell lines by inhibiting transcription of the human telomerase gene hTERT (47). All of these studies strongly suggest that sphingolipids, particular ceramide, play an important role in regulating pathways related to cellular senescence. S1P, a serum-borne bioactive sphingolipid, regulates various biological activities both in vitro and in vivo. For example, it has been shown that S1P is an important modulator of endothelial functions, including proliferation, survival, cytoskeletal architecture, chemotaxis, wound-healing, morphogenetic, and angiogenic responses (1-4, 13, 29). However, the role of S1P and its signaling pathways in regulating vascular EC senescence has not been elucidated. Therefore, in the present study, we examined the Subsequently, cells were stimulated with or without S1P (500 nM) for 10 min. Cellular extracts (500 g) were precipitated with LM609 antibody followed by immunoblotting with FAK, ␣ v , and ␤ 3 antibodies. The migratory positions of endogenous polypeptides are indicated by arrows. Extracts (10 g) were immunoblotted with ␤-actin antibody in a parallel assay to show that an equal quantity of extracts was used for the immunoprecipitation assay. Left lane, TBST/OG buffer was incubated with LM609 antibody. Note that S1P treatment was unable to induce the association of FAK with integrin ␣ v ␤ 3 as well as the ligation of ␣ v and ␤ 3 subunits in the control vector and wild-type PTEN-transduced senescent ECs. In contrast, S1P stimulated the association of FAK with integrin ␣ v ␤ 3 as well as the ligation of ␣ v and ␤ 3 subunits in dominant-negative PTEN-transduced senescent ECs. The data shown are from a representative experiment, which was repeated two times with similar results. FIGURE 9. Ectopical expression of S1P 2 inhibits integrin ␣ v ␤ 3 activation in young ECs. A, young ECs were transduced with increased concentrations of adenoviral particles carrying S1P 2 receptors. The expression of S1P 2 receptors in senescent (S) or young (Y) ECs was determined by RT-PCR. Note that the expression of S1P 2 receptors in senescent ECs was attained in young ECs by transduction with ϳ100 m.o.i. of adenoviral particles. B, young ECs were transduced with adenoviral particles (100 m.o.i.) carrying the ␤-galactosidase (top panel), S1P 1 (middle panel), or S1P 2 vectors (bottom panel). Cells were serum-starved, stimulated with S1P (200 nM, 37°C for 10 min), and immunostained with mouse monoclonal LM609 (Chemicon). Note that S1P induced the activation of integrin ␣ v ␤ 3 at the focal contact sites of the migratory fronts in young ECs transduced with ␤-galactosidase and S1P 1 (arrows, top two panels). In contrast, S1P was unable to activate integrin ␣ v ␤ 3 in young ECs transduced with adenoviral particles carrying S1P 2 receptor. C, young ECs were co-transduced with adenoviral particles (100 m.o.i. each) carrying S1P 2 and wild-type (first and second rows), or S1P 2 and dominant-negative PTEN (third and forth rows) for 16 h. After stimulation with (second and fourth rows) or without (first and third rows) S1P (200 nM, 37°C for 10 min), cells were immunostained with mouse monoclonal anti-LM609 (left panels) and rabbit polyclonal anti-␣-actinin (middle panels). The merged images are shown in the right panels. Note that transduction of dominant-negative PTEN induced the co-localization of ␣-actinin and integrin ␣ v ␤ 3 in young ECs expressing S1P 2 receptors (arrows, bottom row). In contrast, S1P treatment was unable to induce integrin ␣ v ␤ 3 activation and ␣-actinin-␣ v ␤ 3 association in young ECs co-transduced with adenoviral particles carrying S1P 2 and wild-type PTEN vectors. response of cultured ECs of different in vitro ages to S1P stimulation. We observed that S1P-mediated chemotactic, woundhealing, and morphogenetic responses were inversely related to the in vitro age of cultured ECs (Fig. 1). Cultured ECs at early passage abundantly express S1P 1 receptors and few S1P 3 receptors (12). The SA functional impairments were not due to the inhibition of S1P 1 /S1P 3 expression or S1P 1 /S1P 3 -mediated signaling, because the S1P 1 /S1P 3 receptors were up-regulated (Fig. 2) and the S1P 1 /S1P 3 -mediated Akt and ERK1/2 pathways were fully functional in senescent ECs (Fig. 4). Strikingly, S1P 2 receptors, which are undetected in ECs at early passages (12), were markedly induced in cultured senescent ECs (Fig. 2). The up-regulation of S1P 2 receptor was also observed in cultured senescent pulmonary arterial ECs (Fig. 2) as well as the lesion regions of atherosclerotic endothelium (Fig. 3), where senescent ECs were identified in vivo (22,23). Importantly, ectopic expression of S1P 2 receptors can induce the senescent-association functional impairments in young ECs (Figs. 9 and 10). Furthermore, knockdown of S1P 2 receptors restores the S1Pmediated Rac activation, wound-healing, and chemotactic responses in senescent ECs (Fig. 6). Collectively, these data support the hypothesis that S1P 2 signaling negatively regulates chemotactic, wound-healing, and morphogenetic responses in senescent ECs. Moreover, these in vitro and in vivo lines of evidence suggest that up-regulation of S1P 2 receptors may be one of major risk factors involved in SA vascular dysfunctions. S1P 2 signaling was shown to inhibit cell migration in the Chinese hamster ovary cells ectopically expressing S1P 2 receptors (15). The S1P 2 -mediated inhibitory effect was subsequently observed in several cell lines such as mouse embryonic fibroblasts, mast cells, glioblastoma, and vascular smooth muscle cells (14, 16, 48 -51). However, the S1P 2 -mediated pathways regulating this inhibitory signaling remain to be elucidated. In this study, we show that the S1P-stimulated Rac activation is impaired in an age-dependent manner in cultured ECs (Fig. 5). ECs with different in vitro ages express similar amounts of Rac polypeptides (Fig. 5A); this suggests that the diminished Rac activity in senescent ECs is mediated by an inhibitory signal rather than a decreased expression of endogenous Rac polypeptides. Subsequently, we demonstrated that PTEN activity was markedly elevated in senescent ECs (Fig.  5B). Moreover, transduction with DN-PTEN restored S1P-induced Rac activation in senescent ECs (Fig. 7). These results suggest that PTEN is an essential signaling molecule in transducing S1P 2 signaling to mediate functional impairment in senescent ECs. In agreement, it was shown that PTEN negatively regulates Rac activation and cell migration (16). Therefore, these data together suggest that the elevated PTEN activity and reduced Rac activation may be the major factors contributing to the impaired functions in senescent ECs.
Integrin ␣ v ␤ 3 plays a critical role in regulating proliferation, adhesion, migration, and angiogenic responses in ECs. We recently showed that the S1P 1 /G i /Rho GTPase/integrin ␣ v ␤ 3 signaling pathway regulates the S1P-stimulated chemotactic response in young ECs (37). Although S1P 1 receptor-mediated signaling is fully functional in senescent ECs (Figs. 2 and 4), S1P treatment was unable to stimulate integrin ␣ v ␤ 3 activation in senescent ECs (Fig. 8 and supplemental Fig. S1). Also, expression of S1P 2 receptors in young ECs markedly inhibited S1P- FIGURE 10. S1P 2 expression impairs migratory, wound-healing, and morphogenetic responses in young ECs. A, young ECs (CPDL ϭ 15) were transduced with adenoviral particles carrying ␤-galactosidase or S1P 2 vectors for 16 h. Subsequently, chemotactic responses were measured by a Transwell migration assay in the presence or absence of S1P (200 nM). Inset, Western blot of cellular extracts shows the expression of transduced S1P 2 polypeptides. B, young ECs weregrowntoconfluenceintheECISarray.Subsequently,cellsweretransducedwith adenoviral particles carrying ␤-galactosidase or S1P 2 vectors for 16 h. After creating the wound by elevating voltage (arrow), S1P-mediated wound-healing responses were monitored in real-time by the increase of TEER. C, young ECs were infected with adenoviral particles carrying ␤-galactosidase or S1P 2 vectors. Cells were plated onto growth factor-reduced Matrigel for 24 h in the presence of S1P (200 nM). The tubular lengths were quantitated as described (12,13). Magnification, ϫ5. The data in A, B, and C are mean Ϯ S.E. of three determinants of a representative experiment, which was repeated at least three times with similar results. OCTOBER 31, 2008 • VOLUME 283 • NUMBER 44 mediated integrin ␣ v ␤ 3 activation (Fig. 9B). These results suggest that integrin ␣ v ␤ 3 is one of the downstream targets of the S1P 2 /PTEN signaling cascade. Indeed, transduction with dominant-negative PTEN in S1P 2 -expressing young ECs markedly induced activation of integrin ␣ v ␤ 3 (Fig. 9C). Moreover, inhibition of elevated PTEN activity reinstated the S1P-induced integrin ␣ v ␤ 3 activation in senescent ECs. To our knowledge, this is the first demonstration of S1P 2 /PTEN signaling negatively regulating integrin activation in vascular ECs. These data suggest that the balance between S1P 1 and S1P 2 signaling pathways may determine the functional responsiveness (such as integrin ␣ v ␤ 3 activation) in vascular ECs.

S1P Signaling in Senescent Endothelial Cells
A "genetic programming" or "error accumulating" mechanism is thought to account for senescence-associated dysfunctions and diseases (30, 31, 38 -42). Data presented in this study argue that up-regulation of S1P 2 receptors (i.e. genetic programming) negatively regulate wound-healing and morphogenetic responses of senescent ECs. Mechanistically, we demonstrated that S1P 2 -mediated PTEN phosphatase activation results in Rac inhibition, which ultimately abrogates integrin ␣ v ␤ 3 activation, chemotactic, wound-healing, and morphogenetic responses in senescent ECs (Fig. 11). Indeed, knockdown of the up-regulated S1P 2 (Fig. 6) or inhibition of the activated PTEN (Fig. 7) restored Rac activation and functional impairments in senescent ECs. Furthermore, expression of S1P 2 in young ECs was replicated the SA dysfunctions that occur in senescent ECs, including impairment of integrin ␣ v ␤ 3 activation, chemotactic, wound-healing, and morphogenetic responses (Figs. 9 and 10). Collectively, these data suggest that S1P 2 -mediated signaling functions as a novel switch to control the senescent-related impairments of vasculature. The knowledge obtained from this study may help develop therapeutic strategies for treating vascular dysfunctions in the future.