- Research article
- Open Access
CD100 modulates cytotoxicity of CD8+ T cells in patients with acute myocardial infarction
BMC Immunology volume 22, Article number: 13 (2021)
CD100 is an immune semaphorin family member that highly expressed on T cells, which take part in the development of acute myocardial infarction (AMI). Matrix metalloproteinases (MMPs) are important mediators for membrane-bound CD100 (mCD100) shedding from T cells to generate soluble CD100 (sCD100), which has immunoregulatory effect on T cells. The aim of this study was to investigate modulatory role of CD100 on CD8+ T cell activity in AMI patients.
Peripheral sCD100 and MMP-2 level, as well as mCD100 level on T cells was assessed in patients with stable angina pectoris (SAP), unstable angina pectoris (UAP), and AMI. The regulatory function of MMP-2 on mCD100 shedding, sCD100 formation, and cytotoxicity of CD8+ T cells was analyzed in direct and indirect contact co-culture system.
AMI patients had higher peripheral sCD100 and lower mCD100 expression on CD8+ T cells in comparison with SAP, UAP, and controls. CD8+ T cells in AMI patients showed elevated direct cytotoxicity, enhanced cytokine production, and increased perforin/granzyme B secretion. Recombinant sCD100 stimulation promoted cytolytic function of CD8+ T cells in controls and AMI patients. Furthermore, AMI patients also had elevated circulating MMP-2 level. Recombinant MMP-2 stimulation induced mCD100 shedding from CD8+ T cells and sCD100 generation, resulting in enhancement of CD8+ T cell cytotoxicity in AMI patients.
Up-regulation of MMP-2 might contribute to elevation of mCD100 shedding and sCD100 formation, leading to increased cytotoxicity CD8+ T cells in AMI patients.
Atherosclerosis is a lipoprotein-driven disease, which results in formation of plaque at specific sites of arterial tree through intimal inflammation, necrosis, apoptosis, fibrosis, and calcification . Atherosclerosis mainly causes coronary artery diseases, including stable angina pectoris (SAP), unstable angina pectoris (UAP) and acute myocardial infarction (AMI) . Both innate and adaptive immune response could promote myocardial hypoxia [3, 4], resulting in the infiltration and recruitment of immune cells and adhesion of platelets. This process accelerates the progression of SAP, leading to the development of UAP and AMI [5, 6]. Activated T cell response was elevated in UAP and AMI patients compared with in SAP patients, indicating the potential involvement of T cell immunity in acute coronary syndrome . CD8+ T cells were also accumulated in the necrotic myocardium in AMI patients and contributed to myocardial injury . A recent report by Gang et al. demonstrated that peripheral CD8+ T cells are activated in AMI patients . However, the regulatory factors for CD8+ T cell activation are not completely understood in AMI patients.
CD100 is also called Sema4D, which is the first discovered immune semaphorin family member with modulatory activity in vascular and immune systems . CD100 could be produced by majority of hematopoietic cells, and functions as a ligand by binding to receptors depending on the cell types, including CD72 on lymphoid tissues and plexin B1/B2 on non-lymphoid tissues . Plaque marcophages and foam cells in human atheomas also express CD100 , which contributes to marcophages-mediated inflammation in atheroscleriosis . Two forms of CD100 could be found as a membrane-bound dimer (mCD100) or as a soluble molecule (sCD100) originated via proteolytic cleavage by certain factors, especially matrix metalloproteinases (MMPs) [14, 15]. Peripheral sCD100 was increased in patients with heart failure [16, 17] and atrial fibrillation . However, regulation of CD100 expression and the role of CD100 to cytotoxicity of CD8+ T cells were not fully elucidated in coronary artery diseases.
Previous studies have shown that MMP-2, MMP-9, and MMP-14 were important mediators for sCD100 formation and mCD100 shedding from CD8+ T cells [14, 15]. This process was closely related to enhancement of CD8+ T cell activity in patients with hepatitis B virus infection and non-small cell lung cancer (NSCLC) [14, 15]. Moreover, MMP-2 was an independent and powerful predictor of all-cause mortality of patients with acute coronary syndrome [19, 20]. Thus, we designed the following study to investigate mCD100/sCD100 imbalance and regulatory function of CD100 in SAP, UAP, and AMI patients. Firstly, mCD100 on T cells and sCD100 expression was examined. Secondly, functional characteristics of MMP-2 to mCD100 cleavage and sCD100 formation towards CD8+ T cells were assessed in vitro.
Plasma sCD100 and MMP-2 level was up-regulated in AMI patients
sCD100 level was increased in AMI group (119.7 ± 18.67 ng/ml) compared with control group (99.34 ± 13.25 ng/ml), SAP group (96.78 ± 8.59 ng/ml), and UAP group (102.4 ± 13.71 ng/ml) (P < 0.01, Fig. 1a). Similarly, plasma MMP-2 level was also up-regulated in AMI group (310.7 ± 44.32 ng/ml) in comparison with control group (230.9 ± 64.46 ng/ml), SAP group (264.2 ± 69.54 ng/ml), and UAP group (240.7 ± 57.96 ng/ml) (P < 0.05, Fig. 1b).
mCD100 on CD8+ T cells was down-regulated in AMI patients
Representative flow dots and histograms of mCD100 expression on CD4+ T cells and on CD8+ T cells were shown in Fig. 2a. There were no significant differences in either CD100+CD4+ percentage (Fig. 2b) or CD100 mean fluorescence intensity (MFI) in CD4+ T cells (Fig. 2c) among groups (P > 0.05). However, CD100+CD8+ percentage was reduced in AMI group (14.54 ± 2.64%) compared with control group (21.51 ± 4.42%), SAP group (21.31 ± 4.17%), and UAP group (19.41 ± 3.87%) (P < 0.0001, Fig. 2d). CD100 MFI in CD8+ T cells was also decreased in AMI group (72.23 ± 6.08) compared with control group (85.25 ± 9.99), SAP group (82.34 ± 8.30), and UAP group (84.21 ± 7.01) (P < 0.0001, Fig. 2e).
sCD100 promoted cytolytic activity of CD8+ T cells
CD8+ T cells, which were purified from controls (n = 10) and AMI patients (n = 10), were stimulated with recombinant human sCD100 for 24 h. The level of interferon-γ (IFN-γ) and tumor necrosis factor-α (TNF-α) was elevated in the supernatant in CD8+ T cells from AMI patients compared with controls (P < 0.01, Fig. 3a and b). The secretion of IFN-γ and TNF-α by CD8+ T cells was also elevated in response to CD100 stimulation in both AMI patients and controls (P < 0.05, Fig. 3a and b). Furthermore, the number of perforin- and granzyme B-producing CD8+ T cells was increased in AMI patients compared with controls (P < 0.0001, Fig. 3c and d). Perforin and granzyme B production by CD8+ T cells was increased in response to CD100 stimulation in both AMI patients and controls (P < 0.01, Fig. 3c and d).
CD8+ T cells from controls (n = 8) and AMI patients (n = 11), who were HLA-A02 restricted, were stimulated with sCD100 for 24 h. CD8+ T cells were then washed twice, and were co-cultured with human umbilical vein endothelial cells (HUVECs) in direct contact or in indirect contact manner. Supernatants were harvested 48 h post co-culture. In direct contact co-culture manner, HUVECs death was mediated by secreting cytokines by CD8+ T cells and perforin-granzyme pathway, which required direct cell-to-cell contact . The percentage of CD8+ T cell-induced HUVECs death was higher in AMI patients compared with controls (P = 0.0022, Fig. 4a). The percentage of HUVECs death was increased in response to sCD100 stimulation in both AMI patients and controls (P < 0.05, Fig. 4a), while the percentage of HUVECs death was still higher in AMI patients than in controls with sCD100 stimulation (P = 0.034, Fig. 4a). In indirect contact co-culture manner, HUVECs death was only mediated by CD8+ T cell-secreting cytokines and did not required direct cell-to-cell contact . The percentage of HUVECs death induced by CD8+ T cells was comparable between AMI patients and controls in indirect contact co-culture manner (P = 0.518, Fig. 4a). Importantly, there was no significant difference of cytokine-induced HUVECs death between AMI patients and controls in response to sCD100 stimulation in indirect contact co-culture manner (P > 0.05, Fig. 4a). The secretion of IFN-γ and TNF-α was elevated in the cultured supernatants in AMI patients compared with controls in both direct contact and indirect contact co-culture manner (P < 0.001, Fig. 4b and c). CD8+ T cell-secreting IFN-γ and TNF-α was also increased in response to sCD100 stimulation in both AMI patients and controls in both direct contact and indirect contact co-culture manner (P < 0.05, Fig. 4b and c).
MMP-2 enhanced the cytolytic activity of CD8+ T cells in AMI patients via induction of CD100 shedding
CD8+ T cells from AMI patients (n = 10) were cultured with recombinant human MMP-2 for 24 h. sCD100 level in the cultured supernatants and mCD100 expression on CD8+ T cells was measured. MMP-2 stimulation enhanced sCD100 level in the supernatants (133.0 ± 39.89 ng/ml vs 73.70 ± 20.01 ng/ml, P = 0.0005, Fig. 5a), while the percentage of CD100+CD8+ cells (14.65 ± 2.15% vs 12.50 ± 0.76%, P = 0.0079, Fig. 5b) and CD100 MFI on CD8+ T cells (71.13 ± 7.16 vs 57.35 ± 13.71, P = 0.011, Fig. 5c) was down-regulated in response to MMP-2 stimulation.
CD8+ T cells from HLA-A02 restricted AMI patients (n = 9) were stimulated with MMP-2 in the presence or absence of anti-CD100 neutralization antibody, and were co-cultured with HUVEC in a direct contact manner. MMP-2 stimulation significantly elevated CD8+ T cell-induced HUVECs death (18.69 ± 3.15% vs 15.42 ± 2.24%, P = 0.022, Fig. 6), while anti-CD100 neutralization antibody remarkably reduced CD8+ T cell-induced HUVECs death (12.17 ± 1.69%, P = 0.0030, Fig. 6). Importantly, anti-CD100 neutralization antibody suppressed MMP-2-mediated cytotoxicity of CD8+ T cells in AMI patients, as HUVEC death was notably down-regulated in the presence of anti-CD100 neutralization antibody (14.69 ± 1.83%, P = 0.0046, Fig. 6).
In the present study, we found that there was imbalance between sCD100 level and mCD100 expression on CD8+ T cells in AMI patients. AMI patients showed up-regulation of peripheral sCD100 and down-regulation of mCD100 on CD8+ T cells, leading to the elevation of CD8+ T cell cytotoxicity. Importantly, sCD100 stimulation promoted cytolytic activity of CD8+ T cells from both controls and AMI patients, which presented as elevated direct cytotoxicity to target cells, enhanced cytokine secretion, and increased cytotoxic molecules expression. However, CD8+ T cells from AMI patients revealed stronger cytotoxicity compared with controls, even in response to sCD100 stimulation. Furthermore, circulating MMP-2 level was also elevated in AMI patients. Recombinant MMP-2 mediated mCD100 shedding from CD8+ T cells and sCD100 generation in AMI patients, resulting in enhancement of CD8+ T cell cytotoxicity. MMP-2-induced elevation of CD8+ T cell activity was dependent on sCD100 formation. The present data indicated that MMP-2-mediated elevation of sCD100 in AMI patients probably enhanced CD8+ T cell cytotoxicity, which is likely to play a role in the immunopathogenesis and AMI progression.
T cell infiltration and activation in myocardium is the hallmark of acute cardiac inflammatory response to heart injury . Infiltrating ovalbumin-specific CD8+ T cells in cardiomyocytes were activated and revealed strong cytotoxicity in transverse aortic constriction, although these cells do not accelerate progression of heart failure . CD8+ T cells were also accumulated in the necrotic myocardium of AMI, in turn infiltrating cytotoxic CD8+ T cells further mediated myocardial necrosis, leading to increased infarction size and aggravated ventricular function [23, 24]. However, a more recent study by IIatovskaya et al. suggested that CD8+ T cells might be both detrimental and beneficial to cardiac remodeling post-AMI . Although CD8+ T cells reduced cardiac physiology and over survival, functional CD8+ T cells might also contribute to removal of necrotic tissue, which was important for better scar formation and decreased incidence of cardiac rupture . Our present results indicated an increased cytotoxicity of circulating CD8+ T cells in AMI patients, which was in line with the previous report . This suggested that peripheral CD8+ T cells might be sufficient and necessary to determine the cardiac proinflammatory response in AMI. Importantly, CD8+ T cells-mediated cytotoxicity was dependent on cell-specific mechanisms . CD8+ T cells exhibited cytolytic activity not only through perforin-granzyme pathway which required direct cell-to-cell contact, but also via secretion of soluble proinflammatory cytokines . Interestingly, Silverio et al. revealed a possible antagonistic role of perforin- and IFN-γ-secreting CD8+ T cells in chronic chagasic cardiomyopathy . CD8+perforin+ cells might exert a detrimental role, whereas CD8+IFN-γ+ cells might play a beneficial role in Trypanosoma cruzi-elicited heart injury . We found that CD8+ T cells from AMI patients presented enhanced IFN-γ/TNF-α production and increased perforin/granzyme B secretion, leading to elevation in cytotoxicity of CD8+ T cells. However, in vivo experiments are still needed for further clarification of CD8+ T cells secreting IFN-γ and perforin in AMI.
Decreased level of sCD100 and increased mCD100 on T cells was found in chronic hepatitis B patients  and chronic human immunodeficiency virus-1-infected patients even following effective antiviral therapy [28, 29]. In contrast, acute infection always induced elevation of sCD100 and reduced expression of mCD100 on CD8+ T cells [14, 30, 31], indicating that sCD100 might mainly result from mCD100 shedding from activated immune cells. Our present results also revealed the imbalance between two active forms of CD100, with increased sCD100 and decreased mCD100 on peripheral CD8+ T cells, in AMI patients. Importantly, AMI patients also had up-regulated sCD100 and down-regulated mCD100 than in SAP and UAP patients. This was partly consistent with previous report on coronary heart disease . However, there was no statistical difference of mCD100 on CD4+ T cells between healthy individuals and patients with coronary heart disease, which was in line with the findings in NSLCL patients , suggesting that the change of CD100 on T cells might be CD8 specific. Thus, CD100 might be a specific immunoregulator for CD8+ T cells in AMI patients. However, few reports focused on sCD100/mCD100 regulation to T cell function in AMI patients. The extracellular domain of CD100 retained biological activity after shedding from immune cell surface upon activation, resulting in the alteration of macrophage differentiation and phenotype in atherosclerosis  and facilitation of CD8+ T cells activity in chronic hepatitis [14, 33]. Thus, sCD100 that is shed from CD8+ T cells in turn promoted CD8+ T cell cytotoxicity, further demonstrating the consequences of CD8+ T cells activation in AMI patients. Previous studies have showed CD72, but not plexin B1/B2 expression, on CD8+ T cells . Anti-CD72 neutralization antibody blocked CD100 activity to CD8+ T cells in NSCLC and hepatitis C virus-infected patients [15, 33]. Thus, sCD100 might directly stimulate CD8+ T cells via CD72 signaling pathway, which contributed to the regulation of CD8+ T cell cytotoxicity in AMI patients.
Various MMPs, including a disintegrin and metalloproteinase domain 17 , a disintegrin and metalloproteinase with thrombospondin motif 4 , MMP-2 , MMP-9 , and MMP-14 [15, 36], have been observed to be able to cleave mCD100, giving rise to a biologically active sCD100 . Moreover, spontaneous shedding of mCD100 from immortalized human T cell line has also been reported in vitro . Our current data indicated the elevation of MMP-2 in AMI patients, which was consistent with previous reports [39, 40]. MMP-2 was also a proteolytoc enzyme for CD100 cleavage on CD8+ T cells in AMI patients, because recombinant MMP-2 stimulation to CD8+ T cells reduced mCD100 expression on CD8+ T cells in AMI patients, whereas enhanced sCD100 level in culture supernatants. This was similar to the role of MMP-9 in chronic hepatitis B patients  and in oral keratinocytes , as well as MMP-14 in NSCLC patients . Importantly, MMP-2 could also induce the cytolytic activity of CD8+ T cells in AMI patients. This process required CD100 shedding from CD8+ T cells, because neutralization of CD100 significantly suppressed MMP-2-mediated elevation of CD8+ T cell cytotoxicity in AMI patients. Anti-CD100 neutralization antibody treatment also reduced CD8+ T cell activity, indicating the spontaneous shedding of CD100 from cultured CD8+ T cells might also be functional. Thus, increased plasma MMP-2 level was efficient for CD100 shedding from CD8+ T cells to form sCD100, leading to the activation of peripheral CD8+ T cells in AMI patients.
Elevated circulating MMP-2 level in AMI patients might effectively mediate mCD100 shedding from CD8+ T cells, giving rise to the formation of biologically active sCD100. MMP-2-induced CD100 cleavage has a pivotal immunomodulatory role in peripheral CD8+ T cells, which might serve as potential therapeutic target for AMI.
Patients and controls
Sixty-five patients were enrolled in the present study, and were divided into three groups as previously described by Gang et al. . (a) SAP (n = 22). Inclusion criteria: Typical exertional chest pain which is relieved by rest or nitroglycerin-based medication, and downsloping or horizontal ST-segment depression > 1 mm in an exercise test . (b) UAP (n = 20). Inclusion criteria: Chest pain at rest or provoked by minimal exertion, and accompanied by ST-segment or T-wave alterations . (c) AMI (n = 23). Inclusion criteria: more than three folds elevation of upper limit of normal of troponin I and creatine kinease MB. Patients who were afflictied with thromboembolism, valvular heart disease, collagen disease, dissemninated intravascular coagulation, advanced liver disease, renal failure, sepsis, cancers, or autoimmune diseases were excluded from the study. Furthermore, twenty healthy individuals who obtained general physical examination in Zhengzhou Central Hospital Affiliated to Zhengzhou University were also enrolled as control. The study protocol was approved by Ethical Committee of Zhengzhou Central Hospital Affiliated to Zhengzhou University, and was conformed to the ethical guidelines of the 1975 Declaration of Helsinki (6th revision, 2008). Informed consents were obtained from all enrolled subjects or legal guardians. The clinical characteristics of patients and controls were shown in Table 1.
Isolation of peripheral blood mononuclear cells (PBMCs)
Blood samples were obtained immediately upon admission by collection into ethylene diamine tetraacetic acid anti-coagulated vacationers. Plasma was havested by centrifugation, and was stored at − 80 °C until use. PBMCs were isolated by density gradient centrifugation using Ficoll Plus 1.077 (Solarbio, Beijing, China).
Purification of CD8+ T cells
CD8+ T cells were purified from PBMCs using Human CD8+ T Cell Isolation Kit (Miltenyi Biotech GmbH, Bergisch Gladbach, Germany). The purify of CD8+ T cells was more than 95% based on flow cytometry determination.
Cell culture and stimulation
(a) 104 of CD8+ T cells were stimulated with recombinant human CD100 (200 ng/ml; Abcam, Cambridge, MA, USA) for 24 h. (b) 104 of CD8+ T cells were stimulated with recombinant human MMP-2 (500 ng/ml; Abcam) for 24 h. (c) CD8+ T cells from HLA-A02 restricted subjects were stimulated recombinant human CD100 (200 ng/ml) for 24 h. Cells were then washed twice, and 104 of stimulated CD8+ T cells were co-cultured with 5 × 104 of HUVECs in direct contact or in direct contact manners for 48 h. HUVECs were also HLA-A02 restricted as previously reported , and could be recognized by CD8+ T cells from HLA-A02 restricted donors. (d) CD8+ T cells from HLA-A02 restricted subjects were stimulated with recombinant human MMP-2 (500 ng/ml; Abcam) in absence or presence of anti-CD100 neutralization antibody (Clone 133-1C6; 2 μg/ml; Abcam), and were co-cultured with 5 × 104 of HUVECs in a direct contact manner for 48 h.
Flow cytometry analysis
PBMCs were transferred into FACS tubes, and were stained with anti-CD3-FITC (Clone SK-7; eBioscience, ThermoFisher, San Diego, CA, USA), anti-CD4-PerCP Cy5.5 (Clone RPA-T4; eBioscience, ThermoFisher), anti-CD8-APC (Clone MEM-31; eBioscience, ThermoFisher), and anti-CD100-PE (Clone #758726; R&D System, Minneapolis, MN, USA) for 30 min at 4 °C in the dark. Stained cells were acquired using FACS Calibure (BD Bioscience, San Jose, CA, USA). Results were analyzed using FlowJo V11 (TreeStar, Ashland, OR, USA).
Enzyme linked immunosorbent assay (ELISA)
CD100 level in the plasma and supernatants was measured by human sCD100 ELISA kit (CUSABIO, Wuhan, China). MMP-2 level in the plasma was measured by MMP-2 Human ELISA kit (Invitrogen, ThermoFisher, Carlsbad, CA, USA). IFN-γ and TNF-α level in the supernatants was measured by IFN gamma Human ELISA kit (Invitrogen, ThermoFisher) and TNF alpha Human ELISA kit (Invitrogen, ThermoFisher), respectively.
Enzyme linked immunospot assay (ELISPOT)
Perforin and granzyme B secretion by CD8+ T cells were assessed using Human Perforin ELISPOT Kit (Abcam) and Human Granzyme B ELISPOT Kit (Abcam), respectively. The results were shown as numbers of spot-forming cells (SFC).
The cytotoxicity of CD8+ T cells was shown as the percentage of HUVECs death by measurement of lactate dehydrogenase (LDH) release in the supernatants as previously described [9, 15]. LDH expression in the supernantants was measured using LDH Cytotoxicity Assay Kit (Beyotime, Wuhan, Hubei Province, China). Low-level control was defined as LDH expression in the supernatant from HUVECs, while high-level control was defined as LDH expression in the supernatant from Triton X-100-treated HUVECs. The percentage of HUVECs death was calculated using following equation: (experimental level – low-level control)/(high-level control – low-level control) × 100% [9, 15].
Data were analyzed using SPSS Version 21.0 for Windows (Chicago, IL, USA). All data were analyzed by Shapiro-Wilk test for normal distribution, and data sets were following normal distributions. Variables were presented as mean ± standard deviation, and statistical significance was determined using Student’s t test, one-way ANOVA and SNK-q test. All tests were two-tailed, and P values less than 0.05 were considered as statistically significant.
Availability of data and materials
All data used and analyzed during the present study will be available from the corresponding author on reasonable request.
Acute myocardial infarction
Enzyme linked immunosorbent assay
Enzyme linked immunospot assay
Human umbilical vein endothelial cell
Mean fluorescence intensity
Non-small cell lung cancer
Peripheral blood mononuclear cell
Stable angina pectoris
Tumor necrosis factor-α
Unstable angina pectoris
Bentzon JF, Otsuka F, Virmani R, Falk E. Mechanisms of plaque formation and rupture. Circ Res. 2014;114(12):1852–66.
Wang C, Hu S, Wu J, Yu H, Pan W, Qin Y, He L, Li L, Hou J, Zhang S, et al. Characteristics and significance of healed plaques in patients with acute coronary syndrome and stable angina: an in vivo OCT and IVUS study. EuroIntervention. 2019;15(9):e771–8.
Libby P, Pasterkamp G, Crea F, Jang IK. Reassessing the mechanisms of acute coronary syndromes. Circ Res. 2019;124(1):150–60.
Wolf D, Ley K. Immunity and inflammation in atherosclerosis. Circ Res. 2019;124(2):315–27.
Matusik P, Guzik B, Weber C, Guzik TJ. Do we know enough about the immune pathogenesis of acute coronary syndromes to improve clinical practice? Thromb Haemost. 2012;108(3):443–56.
Elabbassi W, Al-Nooryani A. Acute coronary syndrome. An acute inflammatory syndrome. Saudi Med J. 2006;27(12):1799–803.
Flego D, Liuzzo G, Weyand CM, Crea F. Adaptive immunity Dysregulation in acute coronary syndromes: from cellular and molecular basis to clinical implications. J Am Coll Cardiol. 2016;68(19):2107–17.
Yan X, Anzai A, Katsumata Y, Matsuhashi T, Ito K, Endo J, Yamamoto T, Takeshima A, Shinmura K, Shen W, et al. Temporal dynamics of cardiac immune cell accumulation following acute myocardial infarction. J Mol Cell Cardiol. 2013;62:24–35.
Gang H, Peng D, Hu Y, Tang S, Li S, Huang Q. Interleukin-9-secreting CD4(+) T cells regulates CD8(+) T cells cytotoxicity in patients with acute coronary syndromes. APMIS. 2021;129(2):91–102.
Elhabazi A, Marie-Cardine A, Chabbert-de Ponnat I, Bensussan A, Boumsell L. Structure and function of the immune semaphorin CD100/SEMA4D. Crit Rev Immunol. 2003;23(1–2):65–81.
Kuklina EM. Receptor functions of Semaphorin 4D. Biochemistry (Mosc). 2019;84(9):1021–7.
Luque MC, Gutierrez PS, Debbas V, Martins WK, Puech-Leao P, Porto G, Coelho V, Boumsell L, Kalil J, Stolf B. Phage display identification of CD100 in human atherosclerotic plaque macrophages and foam cells. PLoS One. 2013;8(9):e75772.
Luque MCA, Galuppo MK, Capelli-Peixoto J, Stolf BS. CD100 effects in macrophages and its roles in atherosclerosis. Front Cardiovasc Med. 2018;5:136.
Yang S, Wang L, Pan W, Bayer W, Thoens C, Heim K, Dittmer U, Timm J, Wang Q, Yu Q, et al. MMP2/MMP9-mediated CD100 shedding is crucial for inducing intrahepatic anti-HBV CD8 T cell responses and HBV clearance. J Hepatol. 2019;71(4):685–98.
Wang HM, Zhang XH, Ye LQ, Zhang K, Yang NN, Geng S, Chen J, Zhao SX, Yang KL, Fan FF. Insufficient CD100 shedding contributes to suppression of CD8(+) T-cell activity in non-small cell lung cancer. Immunology. 2020;160(2):209–19.
Lu Q, Dong N, Wang Q, Yi W, Wang Y, Zhang S, Gu H, Zhao X, Tang X, Jin B, et al. Increased levels of plasma soluble Sema4D in patients with heart failure. PLoS One. 2013;8(5):e64265.
Willner N, Goldberg Y, Schiff E, Vadasz Z. Semaphorin 4D levels in heart failure patients: a potential novel biomarker of acute heart failure? ESC Heart Fail. 2018;5(4):603–9.
Xiang L, You T, Chen J, Xu W, Jiao Y. Serum soluble Semaphorin 4D is associated with left atrial diameter in patients with atrial fibrillation. Med Sci Monit. 2015;21:2912–7.
Dhillon OS, Khan SQ, Narayan HK, Ng KH, Mohammed N, Quinn PA, Squire IB, Davies JE, Ng LL. Matrix metalloproteinase-2 predicts mortality in patients with acute coronary syndrome. Clin Sci (Lond). 2009;118(4):249–57.
Sun H, Zhang J, Zheng Y, Shang S. Expressions and clinical significance of factors related to acute coronary syndrome. J Biol Regul Homeost Agents. 2018;32(2):299–305.
Ma F, Feng J, Zhang C, Li Y, Qi G, Li H, Wu Y, Fu Y, Zhao Y, Chen H, et al. The requirement of CD8+ T cells to initiate and augment acute cardiac inflammatory response to high blood pressure. J Immunol. 2014;192(7):3365–73.
Groschel C, Sasse A, Monecke S, Rohrborn C, Elsner L, Didie M, Reupke V, Bunt G, Lichtman AH, Toischer K, et al. CD8(+)-T cells with specificity for a model antigen in Cardiomyocytes can become activated after transverse aortic constriction but do not accelerate progression to heart failure. Front Immunol. 2018;9:2665.
Zhang L, Wang Z, Wang D, Zhu J, Wang Y. CD8(+)CD28(+) T cells might mediate injury of cardiomyocytes in acute myocardial infarction. Mol Immunol. 2018;101:74–9.
Tae Yu H, Youn JC, Lee J, Park S, Chi HS, Lee J, Choi C, Park S, Choi D, Ha JW, Shin EC. Characterization of CD8(+)CD57(+) T cells in patients with acute myocardial infarction. Cell Mol Immunol. 2015;12(4):466–73.
Ilatovskaya DV, Pitts C, Clayton J, Domondon M, Troncoso M, Pippin S, DeLeon-Pennell KY. CD8(+) T-cells negatively regulate inflammation post-myocardial infarction. Am J Physiol Heart Circ Physiol. 2019;317(3):H581–96.
Maini MK. CD8(+) T cells cure without killing. Nat Rev Immunol. 2019;19(4):201.
Silverio JC, Pereira IR, Cipitelli Mda C, Vinagre NF, Rodrigues MM, Gazzinelli RT, Lannes-Vieira J. CD8+ T-cells expressing interferon gamma or perforin play antagonistic roles in heart injury in experimental Trypanosoma cruzi-elicited cardiomyopathy. PLoS Pathog. 2012;8(4):e1002645.
Vadasz Z, Elbirt D, Radian S, Bezalel-Rosenberg S, Mahlab-Guri K, Toubi E, Asher I, Sthoeger Z. Low levels of the immunoregulator Semaphorin 4D (CD100) in sera of HIV patients. Clin Immunol. 2018;191:88–93.
Correa-Rocha R, Lopez-Abente J, Gutierrez C, Perez-Fernandez VA, Prieto-Sanchez A, Moreno-Guillen S, Munoz-Fernandez MA, Pion M. CD72/CD100 and PD-1/PD-L1 markers are increased on T and B cells in HIV-1+ viremic individuals, and CD72/CD100 axis is correlated with T-cell exhaustion. PLoS One. 2018;13(8):e0203419.
Liu B, Ma Y, Yi J, Xu Z, Zhang YS, Zhang C, Zhuang R, Yu H, Wang J, Yang A, et al. Elevated plasma soluble Sema4D/CD100 levels are associated with disease severity in patients of hemorrhagic fever with renal syndrome. PLoS One. 2013;8(9):e73958.
Liu B, Ma Y, Zhang Y, Zhang C, Yi J, Zhuang R, Yu H, Yang A, Zhang Y, Jin B. CD8low CD100- T cells identify a novel CD8 T cell subset associated with viral control during human Hantaan virus infection. J Virol. 2015;89(23):11834–44.
Gong H, Lyu X, Li S, Chen R, Hu M, Zhang X. sSema4D levels are increased in coronary heart disease and associated with the extent of coronary artery stenosis. Life Sci. 2019;219:329–35.
Li BJ, He Y, Zhang Y, Guo YH, Zhou Y, Zhang PX, Wang W, Zhao JR, Li JG, Zuo WZ, et al. Interferon-alpha-induced CD100 on naive CD8(+) T cells enhances antiviral responses to hepatitis C infection through CD72 signal transduction. J Int Med Res. 2017;45(1):89–100.
Zhu L, Bergmeier W, Wu J, Jiang H, Stalker TJ, Cieslak M, Fan R, Boumsell L, Kumanogoh A, Kikutani H, et al. Regulated surface expression and shedding support a dual role for semaphorin 4D in platelet responses to vascular injury. Proc Natl Acad Sci U S A. 2007;104(5):1621–6.
Yoshida Y, Ogata A, Kang S, Ebina K, Shi K, Nojima S, Kimura T, Ito D, Morimoto K, Nishide M, et al. Semaphorin 4D contributes to rheumatoid arthritis by inducing inflammatory cytokine production: pathogenic and therapeutic implications. Arthritis Rheum. 2015;67(6):1481–90.
Basile JR, Holmbeck K, Bugge TH, Gutkind JS. MT1-MMP controls tumor-induced angiogenesis through the release of semaphorin 4D. J Biol Chem. 2007;282(9):6899–905.
Maleki KT, Cornillet M, Bjorkstrom NK. Soluble SEMA4D/CD100: a novel immunoregulator in infectious and inflammatory diseases. Clin Immunol. 2016;163:52–9.
Elhabazi A, Delaire S, Bensussan A, Boumsell L, Bismuth G. Biological activity of soluble CD100. I. the extracellular region of CD100 is released from the surface of T lymphocytes by regulated proteolysis. J Immunol. 2001;166(7):4341–7.
Zhou L, Kou DQ. Correlation between acute myocardial infarction complicated with cerebral infarction and expression levels of MMP-2 and MMP-9. Eur Rev Med Pharmacol Sci. 2019;23(1):297–302.
Nakaya R, Uzui H, Shimizu H, Nakano A, Mitsuke Y, Yamazaki T, Ueda T, Lee JD. Pravastatin suppresses the increase in matrix metalloproteinase-2 levels after acute myocardial infarction. Int J Cardiol. 2005;105(1):67–73.
Ke Y, Dang E, Shen S, Zhang T, Qiao H, Chang Y, Liu Q, Wang G. Semaphorin4D drives CD8(+) T-cell Lesional trafficking in Oral lichen Planus via CXCL9/CXCL10 Upregulations in Oral keratinocytes. J Invest Dermatol. 2017;137(11):2396–406.
Boegel S, Lower M, Bukur T, Sahin U, Castle JC. A catalog of HLA type, HLA expression, and neo-epitope candidates in human cancer cell lines. Oncoimmunology. 2014;3(8):e954893.
We thank the volunteers for their participation in this study.
Ethics approval and consent to participate
The study protocol was approved by Ethical Committee of Zhengzhou Central Hospital Affiliated to Zhengzhou University, and was conformed to the ethical guidelines of the 1975 Declaration of Helsinki (6th revision, 2008). Informed consents were obtained from all enrolled subjects or legal guardians.
Consent for publication
The authors declare that they have no competing interests.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Li, Y., Qin, L., Bai, Q. et al. CD100 modulates cytotoxicity of CD8+ T cells in patients with acute myocardial infarction. BMC Immunol 22, 13 (2021). https://doi.org/10.1186/s12865-021-00406-y
- Acute myocardial infarction
- T lymphocytes