CD28 controls the development of innate‐like CD8+ T cells by promoting the functional maturation of NKT cells

NK T cells(NKT cells) share functional characteristics and homing properties that are distinct from conventional T cells. In this study, we investigated the contribution of CD28 in the functional development of γδ NKT and αβ NKT cells in mice. We show that CD28 promotes the thymic maturation of promyelocytic leukemia zinc finger⁺ IL‐4⁺ NKT cells and upregulation of LFA‐1 expression on NKT cells. We demonstrate that the developmental defect of γδ NKT cells in CD28‐deficient mice is cell autonomous. Moreover, we show in both wild‐type C57BL/6 mice and in downstream of tyrosine kinase‐1 transgenic mice, a mouse model with increased numbers of γδ NKT cells, that CD28‐mediated regulation of thymic IL‐4⁺ NKT cells promotes the differentiation of eomesodermin⁺ CD44^high innate‐like CD8⁺ T cells. These findings reveal a previously unappreciated mechanism by which CD28 controls NKT‐cell homeostasis and the size of the innate‐like CD8⁺ T‐cell pool.     

Japanese encephalitis virus expands regulatory T cells by increasing the expression of PD‐L1 on dendritic cells

The mechanisms underlying Japanese encephalitis virus (JEV) pathogenesis need to be thoroughly explored to delineate therapeutic approaches. It is believed that JEV manipulates the innate and adaptive compartments of the host's immune system to evade immune response and cross the blood–brain barrier. The present study was thus designed to investigate the functional modulation of DCs after exposure to JEV and to assess the consequences on CD4⁺ T‐lymphocyte functions. Human monocyte‐derived DCs were either infected with 1 MOI of live virus, UV‐inactivated virus, or were mock‐infected. Replication‐competent JEV induced a significant increase in the expression of maturation markers 48 h postinfection, along with that of programmed cell death 1 ligand 1 (PD‐L1; also called B7‐H1 and CD274). JEV‐infected DCs expanded the Treg cells in allogenic mixed lymphocyte reactions. The expansion of Treg cells by JEV‐infected DCs was significantly reduced upon blocking PD‐L1 using an antagonist. In addition, JEV‐infected DCs significantly altered the proliferation and reduced the polarization of Th cells toward the Th1‐cell phenotype. The results, for the first time, suggest that JEV evades the host's immune system by modulating the crosstalk between DCs and T lymphocytes via the PD‐L1 axis.     

Innate and adaptive stimulation of murine diverse NKT cells result in distinct cellular responses

Natural killer T (NKT) cells recognize glycolipids presented on CD1d. They share features of adaptive T lymphocytes and innate NK cells, and mediate immunoregulatory functions via rapid production of cytokines. Invariant (iNKT) and diverse (dNKT) NKT cell subsets are defined by their TCR. The immunological role of dNKT cells, that do not express the invariant TCRα‐chain used by iNKT cells, is less well explored than that of iNKT cells. Here, we investigated signals driving Toll‐like receptor (TLR) ligand activation of TCR‐transgenic murine dNKT cells. IFN‐γ production by dNKT cells required dendritic cells (DC), cell‐to‐cell contact and presence of TLR ligands. TLR‐stimulated DC activated dNKT cells to secrete IFN‐γ in a CD1d‐, CD80/86‐ and type I IFN‐independent manner. In contrast, a requirement for IL‐12p40, and a TLR ligand‐selective dependence on IL‐18 or IL‐15 was observed. TLR ligand/DC stimulation provoked early secretion of pro‐inflammatory cytokines by both CD62L⁺ and CD62L^? dNKT cells. However, proliferation was limited. In contrast, TCR/co‐receptor‐mediated activation resulted in proliferation and delayed production of a broader cytokine spectrum preferentially in CD62L^? dNKT cells. Thus, innate (TLR ligand/DC) and adaptive (TCR/co‐receptor) stimulation of dNKT cells resulted in distinct cellular responses that may contribute differently to the formation of immune memory.     

Role of dendritic cells infected with human herpesvirus 6 in virus transmission to CD4 T cells

Human herpesvirus 6 (HHV-6) is a ubiquitous betaherpesvirus that predominantly infects and replicates in CD4⁺ T lymphocytes. However, the mechanism of HHV-6 transmission to T cells from the peripheral mucosa is unknown. Here we found that dendritic cells (DCs) can transmit HHV-6 to T cells, resulting in productive infection. In immature monocyte-derived DCs (MDDCs) infected with HHV-6, viral early and late antigens were expressed, and nucleocapsids containing a DNA core were observed, although few virions were detected in the cytoplasm by electron microscopy, indicating that the maturation of HHV-6 virions may be incomplete in MDDCs. However, HHV-6 transmission from MDDCs to stimulated CD4⁺ T cells occurred efficiently in coculture of these cells, but not from MDDCs culture supernatants. This transmission was partially inhibited by treating the DCs with a viral DNA synthesis blocker, indicating that viral replication in MDDCs is required for this transmission. Furthermore, myeloid DCs and plasmacytoid DCs infected with HHV-6 could also transmit the virus to stimulated T cells. Thus, DCs may be the first cell population targeted by HHV-6 and could play an important role in the virus' transmission to T cells for their further propagation.     

Differential recruitment and activation of natural killer cell sub‐populations by Mycobacterium bovis‐infected dendritic cells

Through complex interplay with APCs, subsets of NK cells play an important role in shaping adaptive immune responses. Bovine tuberculosis, caused by Mycobacterium bovis, is increasing in incidence and detailed knowledge of host–pathogen interactions in the natural host is essential to facilitate disease control. We investigated the interactions of NK‐cell sub‐populations and M. bovis‐infected DCs to determine early innate mechanisms in the response to infection. A sub‐population of NK cells (NKp46⁺CD2^?) selectively expressing lymphoid homing and inflammatory chemokine receptors were induced to migrate towards M. bovis‐infected DCs. This migration was associated with increased expression of chemokines CCL3, 4, 5, 20 and CXCL8 by M. bovis‐infected DCs. Activation of NKp46⁺CD2^? NK cells and secretion of IFN‐γ was observed, a response reliant on localised IL‐12 release and direct cellular interaction. In a reciprocal manner, NKp46⁺CD2^? cells induced an increase in the intensity of cell surface MHC class II expression on DCs. In contrast, NKp46⁺CD2⁺ NK cells were unable to secrete IFN‐γ and did not reciprocally affect DCs. This study provides novel evidence to demonstrate distinct effector responses between bovine NK‐cell subsets during mycobacterial infection.     

DC therapy induces long‐term NK reactivity to tumors via host DC

We vaccinated mice with DC loaded with or without invariant NKT‐cell ligand α‐galactosylceramide and evaluated long‐term resistance against tumor challenge. When mice had been given either DC or DC/galactosylceramide and were challenged with tumor cells even 6–12 months later, both NK and NKT cells were quickly activated to express CD69 and produce IFN‐γ. The NK cells could resist a challenge with several different tumors in vivo. The activated NK and NKT cells could be depleted with anti‐NK1.1 treatment. In spite of this, the activated cells recovered, indicating that tumor‐responsive NK and NKT cells were being generated continuously as a result of vaccination with DC and were not true memory cells. The NK and NKT antitumor response in DC‐vaccinated mice depended on CD4⁺ T cells, but neither CD8⁺T cells nor CD4⁺CD25⁺ regulatory T cells. However, both vaccine DC and host DC were required for the development of long‐term, tumor reactive innate immunity. These results indicate that DC therapy in mice induces long‐lasting innate NK‐ and NKT‐cell activation through a pathway that requires host DC and CD4⁺ T cells and that the continued generation of active NK cells resists the establishment of metastases in vivo.     

Immunophenotype of peripheral blood natural killer cells and IL‐10 serum levels in relation to Helicobacter pylori status

Recent findings suggest that NK (Natural Killer) cells may directly modulate the antimicrobial immune responses. In this study, we performed immunophenotypic analysis of peripheral blood NK cells with regard to CD56, CD16, Nkp46, and CD25 markers, as well as IL‐10 levels quantification in the sera samples of asymptomatic, H. pylori (Hp)‐infected or uninfected individuals, and combined these results with our previous findings on lymphocyte cytotoxic activity. Twenty healthy volunteers [10 Hp(?);10 Hp(+)] were included in the study. The percentages of classic lymphocytes (CD3⁺) and NK cells (CD3^?CD56⁺, CD3^?Nkp46⁺, CD3^?CD16⁺) with or without CD25 receptor were evaluated by fluorochrome‐conjugated monoclonal antibody staining and flow cytometry analysis. IL‐10 quantification was performed by enzyme‐linked immunosorbent assay‐ELISA. Our study showed elevated levels of IL‐10 and higher NK cell numbers of both CD3^?CD56⁺CD25⁺ and CD3^?Nkp46⁺CD25⁺ phenotypes, as well as CD3⁺CD25⁺ classic lymphocytes in Hp(+) compared with Hp(?) individuals. No differences between Hp(?) and Hp(+) individuals were found either in total number of classic lymphocytes or NK cell subtypes. Our data suggest that in Hp(+) donors, there is a domination of lymphocytes and NK cells co‐expressing CD25 marker, which might be influenced by the regulatory IL‐10. This phenomenon may be a result of H. pylori adaptation to a changing environment in vivo leading to a chronic infection and lack of severe gastric pathologies.     

Natural killer T-cell characterization through gene expression profiling: an account of versatility bridging T helper type 1 (Th1), Th2 and Th17 immune responses

Natural killer T (NKT) cells constitute a distinct lymphocyte lineage at the interface between innate and adaptive immunity, yet their role in the immune response remains elusive. Whilst NKT cells share features with other conventional T lymphocytes, they are unique in their rapid, concomitant production of T helper type 1 (Th1) and Th2 cytokines upon T-cell receptor (TCR) ligation. In order to characterize the gene expression of NKT cells, we performed comparative microarray analyses of murine resting NKT cells, natural killer (NK) cells and naïve conventional CD4⁺ T helper (Th) and regulatory T cells (Treg). We then compared the gene expression profiles of resting and alpha-galactosylceramide (αGalCer)-activated NKT cells to elucidate the gene expression signature upon activation. We describe here profound differences in gene expression among the various cell types and the identification of a unique NKT cell gene expression profile. In addition to known NKT cell-specific markers, many genes were expressed in NKT cells that had not been attributed to this population before. NKT cells share features not only with Th1 and Th2 cells but also with Th17 cells. Our data provide new insights into the functional competence of NKT cells which will facilitate a better understanding of their versatile role during immune responses.     

Gal‐3 regulates the capacity of dendritic cells to promote NKT‐cell‐induced liver injury

Galectin‐3 (Gal‐3), an endogenous lectin, exhibits pro‐ and anti‐inflammatory effects in various disease conditions. In order to explore the role of Gal‐3 in NKT‐cell‐dependent pathology, we induced hepatitis in C57BL/6 WT and Gal‐3‐deficient mice by using specific ligand for NKT cells: α‐galactosylceramide, glycolipid Ag presented by CD1d. The injection of α‐galactosylceramide significantly enhanced expression of Gal‐3 in liver NKT and dendritic cells (DCs). Genetic deletion or selective inhibition of Gal‐3 (induced by Gal‐3‐inhibitor TD139) abrogated the susceptibility to NKT‐cell‐dependent hepatitis. Blood levels of pro‐inflammatory cytokines (TNF‐α, IFN‐γ, IL‐12) and their production by liver DCs and NKT cells were also downregulated. Genetic deletion or selective inhibition of Gal‐3 alleviated influx of inflammatory CD11c⁺CD11b⁺ DCs in the liver and favored tolerogenic phenotype and IL‐10 production of liver NKT and DCs. Deletion of Gal‐3 attenuated the capacity of DCs to support liver damage in the passive transfer experiments and to produce pro‐inflammatory cytokines in vitro. Gal‐3‐deficient DCs failed to optimally stimulate production of pro‐inflammatory cytokines in NKT cells, in vitro and in vivo. In conclusion, Gal‐3 regulates the capacity of DCs to support NKT‐cell‐mediated liver injury, playing an important pro‐inflammatory role in acute liver injury.     

Decrease in intrahepatic CD56+ lymphocytes in gastric and colorectal cancer patients with liver metastases

Gulubova M, Manolova I, Kyurkchiev D, Julianov A, Altunkova I. Decrease in intrahepatic CD56⁺ lymphocytes in gastric and colorectal cancer patients with liver metastases. APMIS 2009; 117: 870–9. The aim of the study was to examine the main intrahepatic lymphocyte subpopulations, namely CD3⁺ lymphocytes, natural killer (NK)‐like T lymphocytes (NKT) expressing the CD3⁺ CD56⁺ phenotype, CD56⁺ NK cells, CD4⁺, and CD8⁺ T cells in livers of patients with gastric and colorectal cancer with and without hepatic metastases. The proportion of each lymphocyte subset was determined in 34 patients with gastric or colorectal cancer (18 with and 16 without liver metastasis) by two‐color flow cytometry after extraction of hepatic mononuclear cell fraction. The distribution of lymphocyte subpopulations in selected areas of liver metastases and adjacent liver tissue was evaluated using immunohistochemistry for CD4, CD8, and CD56. Flow cytometry analysis revealed a significant decrease in the proportion of CD3⁺ CD56⁺ cells in metastatic livers, but not in nonmetastatic livers (11.9 ± 10.3 vs 24.2 ± 13.6%, p = 0.02). The percentage of intrahepatic CD3^?CD56⁺ cells was also decreased in patients with metastases compared to those without (10.1 ± 11.6 vs 16.6 ± 8.9%, p = 0.039). Immunohistochemically, three types of lymphocytes (CD4⁺, CD8⁺, and CD56⁺) were present in the metastatic tissue, although the number of CD56⁺ cells was almost twice lower. We found a low prevalence of tumor‐infiltrating CD4⁺, CD8⁺, and CD56⁺ cells in livers with multiple metastases, whereas in cases with solitary metastasis a higher degree of lymphocyte infiltration was observed. The number of CD3^?CD56⁺ and CD3⁺ CD56⁺ cells was decreased in metastatic livers compared to those unaffected by metastases. Therefore the prevalence of tumor‐infiltrating lymphocytes seems to be related to the progression of metastatic liver disease. Depletion of hepatic innate lymphocytes may reveal susceptibility to metastatic liver disease and could be a reason for the escape of metastatic cells from the mechanisms of liver immune control.     

Increased frequency of CD56Bright NK‐cells,CD3−CD16+CD56− NK‐cells and activated CD4+T‐cells or B‐cells in parallel with CD4+CDC25High T‐cells control potentially viremia in blood donors with HCV

A detailed phenotypic analysis of major and minor circulating lymphocyte subsets is described in potential blood donors with markers of hepatitis C virus (HCV), including non‐viremic and viremic groups. Although there were no changes in the hematological profile of either group, increased the levels of pre‐NK cells (CD3^?CD16⁺CD56^?) and a lower frequency of mature NK cells (CD3^?CD16⁺CD56⁺) characterized innate immunity in the non‐viremic group. Both non‐viremic and viremic groups displayed significantly increased levels of CD56^Bright NK cells. Furthermore, this subset was significantly elevated in the viremic subgroup with a low viral load. In addition, an increase in the NKT2 subset was observed only in this subgroup. An enhanced frequency of activated CD4⁺ T‐cells (CD4⁺HLA‐DR⁺) was a characteristic feature of the non‐viremic group, whereas elevated CD19⁺ B‐cells and CD19⁺CD86⁺ cell populations were the major phenotypic features of the viremic group, particularly in individuals with a low viral load. Although CD4⁺CD25^High T‐cells were significantly elevated in both the viremic and non‐viremic groups, it was particularly evident in the viremic low viral load subgroup. A parallel increase in CD4⁺CD25^High T‐cells, pre‐NK, and activated CD4⁺ T‐cells was observed in the non‐viremic group, whereas a parallel increase in CD4⁺CD25^High T‐cells and CD19⁺ B‐cells was characteristic of the low viral load subgroup. These findings suggest that CD56^Bright NK cells, together with pre‐NK cells and activated CD4⁺ T‐cells in combination with CD4⁺CD25^High T‐cells, might play an important role in controlling viremia. Elevated CD56^Bright NK cells, B‐cell responses and a T‐regulated immunological profile appeared to be associated with a low viral load. J. Med. Virol. 81:49–59, 2009. © 2008 Wiley‐Liss, Inc.     

NK cells are primed by ANRS MVAHIV‐infected DCs,via a mechanism involving NKG2D and membrane‐bound IL‐15, to control HIV‐1 infection in CD4+ T cells

Natural killer (NK) cells are the major antiviral effector cell population of the innate immune system. It has been demonstrated that NK‐cell activity can be modulated by the interaction with dendritic cells (DCs). The HIV‐1 vaccine candidate Modified Vaccinia Ankara encoding an HIV polypeptide (MVA_HIV), developed by the French National Agency for Research on AIDS (ANRS), has the ability to prime NK cells to control HIV‐1 infection in DCs. However, whether or not MVA_HIV‐primed NK cells are able to better control HIV‐1 infection in CD4⁺ T cells, and the mechanism underlying the specific priming, remain undetermined. In this study, we show that MVA_HIV‐primed NK cells display a greater capacity to control HIV‐1 infection in autologous CD4⁺ T cells. We also highlight the importance of NKG2D engagement on NK cells and DC‐produced IL‐15 to achieve the anti‐HIV‐1 specific priming, as blockade of either NKG2D or IL‐15 during MVA_HIV‐priming lead to a subsequent decreased control of HIV‐1 infection in autologous CD4⁺ T cells. Furthermore, we show that the decreased control of HIV‐1 infection in CD4⁺ T cells might be due, at least in part, to the decreased expression of membrane‐bound IL‐15 (mbIL‐15) on DCs when NKG2D is blocked during MVA_HIV‐priming of NK cells.     

Helper roles of NK and CD8+ T cells in the induction of tumor immunity

The work in our laboratory addresses two interrelated areas of dendritic cell (DC) biology: (1) the role of DCs as mediators of feedback interactions between NK cells, CD8⁺ and CD4⁺ T cells; and (2) the possibility to use such feedback and the paradigms derived from anti-viral responses, to promote the induction of therapeutic immunity against cancer. We observed that CD8⁺ T cells and NK cells, the classical “effector” cells, also play “helper” roles, regulating ability of DCs to induce type-1 immune immunity, critical for fighting tumors and intracellular pathogens. Our work aims to delineate which pathways of NK and CD8⁺ T cell activation result in their helper activity, and to identify the molecular mechanisms allowing them to induce type-1 polarized DCs (DC1s) with selectively enhanced ability to promote type-1 responses and anti-cancer immunity. The results of these studies allowed us and our colleagues to design phase I/II clinical trials incorporating the paradigms of DC polarization and helper activity of effector cells in cancer immunotherapy.     

Tolerogen-induced interferon-producing killer dendritic cells (IKDCs) protect against EAE

Natural killer (NK) cells and dendritic cells (DCs) have been shown to link the innate and adaptive immune systems. Likewise, a new innate cell subset, interferon-producing killer DCs (IKDCs), shares phenotypic and functional characteristics with both DCs and NK cells. Here, we show IKDCs play an essential role in the resolution of experimental autoimmune encephalomyelitis (EAE) upon treatment with the tolerizing agent, myelin oligodendrocyte glycoprotein (MOG), genetically fused to reovirus protein σ1 (termed MOG-pσ1). Activated IKDCs were recruited subsequent MOG-pσ1 treatment of EAE, and disease resolution was abated upon NK1.1 cell depletion. These IKDCs were able to kill activated CD4⁺ T cells and mature dendritic DCs, thus, contributing to EAE remission. In addition, IKDCs were responsible for MOG-pσ1-mediated MOG-specific regulatory T cell recruitment to the CNS. The IKDCs induced by MOG-pσ1 expressed elevated levels of HVEM for interactions with cognate ligand-positive cells: LIGHT⁺ NK and T_eff cells and BTLA⁺ B cells. Further characterization revealed these activated IKDCs being MHC class II^high, and upon their adoptive transfer (CD11c⁺NK1.1⁺MHC class II^high), IKDCs, but not CD11c⁺NK1.1⁺MHC class II^{intermediate/low} (unactivated) cells, conferred protection against EAE. These activated IKDCs showed enhanced CD107a, PD-L1, and granzyme B expression and could present OVA, unlike unactivated IKDCs. Thus, these results demonstrate the interventional potency induced HVEM⁺ IKDCs to resolve autoimmune disease.     

Natural killer and dendritic cells collaborate in the immune response induced by the vaccine against uterine cervical cancer

Virus‐like particles (VLPs) of human papillomavirus (HPV) are used as a vaccine against HPV‐induced cancer, and recently we have shown that these VLPs are able to activate natural killer (NK) cells. Since NK cells collaborate with dendritic cells (DCs) to induce an immune response against viral infections and tumors, we studied the impact of this crosstalk in the context of HPV vaccination. NK cells in the presence of HPV‐VLPs enhanced DC‐maturation as shown by an upregulation of CD86 and HLA‐DR and an increased production of IL‐12p70, but not of the immunosuppressive cytokine IL‐10. This activation was bidirectional. Indeed, in the presence of HPV‐VLPs, DCs further activated NK cells by inducing the upregulation of cell surface activation markers (CD69 and HLA‐DR). The function of NK cells was also improved as shown by an increase in IFN‐γ secretion and cytotoxic activity against an HPV⁺ cell line. This crosstalk between NK cells and DCs needed CD40 interaction and IL‐12p70 secretion, whereas NKG2D was not implicated. Our results provide insight into how VLPs interact with innate immune cells and how NK cells and DCs play a role in the immune response induced by this vaccine agent.     

Regulation of HLA-DR and co-stimulatory molecule expression on natural killer T cells by granulocyte-macrophage colony-stimulating factor

A subset of mononuclear cells present in most tissues coexpresses receptors of both natural killer (NK) and T cells. Although linked to antiviral immunity, the function of these putative NKT cells is uncertain. We present evidence that human CD56⁺ DR^? NKT cells exhibit hybrid adaptive and innate immune functions. These cells spontaneously lysed tumour cell targets and upon engagement of T‐cell antigen receptors secreted the cytokines interferon‐γ and granulocyte–macrophage colony‐stimulating factor (GM‐CSF). Conversely, GM‐CSF treatment transformed the NKT cells into dendritic cells, inducing rapid expression of HLA‐DR and the co‐stimulatory molecules CD80 and CD86. The ability to stimulate tetanus toxoid‐specific responses from naïve T cells was acquired within 3 days of activating CD56⁺ NKT cells with GM‐CSF. These results suggest a potential role for NKT cells in the initiation and control of primary immunity during the acute phase of infection.     

Early Changes in Frequency of Peripheral Blood Lymphocyte Subpopulations in Severe Traumatic Brain‐Injured Patients

Infections are leading causes of increased morbidity and mortality of severe traumatic brain‐injured (STBI) patients. The mechanism underlying the susceptibility to the infections is still unexplained. The purpose of the study was to investigate changes in frequency of leucocytes subpopulations in peripheral blood of patients with STBI during the course of intensive care treatment. Twenty patients with STBI were included in the study. Healthy age‐ and sex‐ volunteers served as control. Peripheral blood samples were taken from these patients at day 1, 4 and 7, and peripheral blood mononuclear cells (PBMC) were isolated. The percentage of T, B lymphocyte, NK and NKT cells as well as monocytes was analysed by simultaneous detection of surface antigens using fluorochrome‐conjugated monoclonal antibodies. The two major subsets of T lymphocytes (CD3⁺CD56^?CD4⁺ and CD3⁺CD56^?CD8⁺) and NK cells (CD3^?CD56^+dim and CD3^?CD56^+bright) were also analysed by flow cytometry. Extracranial infections were presented in 55% patients with STBI. At day 4, the percentage of T lymphocytes with cytotoxic phenotype significantly diminished and their numbers restored at day 7. The frequency of NKT cells showed the identical time‐dependent pattern, whereas the percentage of NK cells diminished on day 4 but did not restore after 7 days. The frequency of B lymphocytes did not change significantly during the time investigated, whereas the percentage of monocytes increased immediately after the injury and gradually diminished. The decrease in cells with cytotoxic phenotype might explain high incidence of susceptibility to infection of patients with STBI.     

Granulysin Expression in Lymphocytes that Populate the Peripheral Blood and the Myocardium after an Acute Coronary Event

We aimed to analyse granulysin (GNLY)‐mediated cytotoxicity in the peripheral blood of patients with non‐ST‐segment elevation myocardial infarction (NSTEMI) treated with anti‐ischaemic drug therapy. Thirty‐nine NSTEMI patients with a median age of 70 years and 28 age‐matched healthy subjects were enrolled in this study. On day 7 after MI, the number of GNLY⁺ lymphocytes in the peripheral blood increased approximately six‐fold of that in the healthy subjects, measured by flow cytometry. On day 14, the number of GNLY⁺ cells significantly decreased in T, NKT, and both CD56^+dim and CD56^+bright NK subsets. GNLY⁺ CD3⁺ and GNLY⁺ CD56⁺ cells infiltrated central zone of myocardial infarction (MI). In persons who died in the first week after MI, GNLY⁺ cells were found within accumulation of apoptotic leucocytes and reached the apoptotic cardiomyocytes in border MI zones probably due to the influence of interleukin‐15 in peri‐necrotic cardiomyocytes, as it is was shown by immunohistology. By day 28, the percentage of GNLY⁺ lymphocytes in peripheral blood returned to the levels similar to that of the healthy subjects. Anti‐GNLY mAb decreased apoptosis of K562 targets using peripheral blood NK cells from days 7 and 28 after MI, while in assays using cells from days 1 and 21, both anti‐GNLY and anti‐perforin mAbs were required to significantly decrease apoptosis. Using NK cells from day 14, K562 apoptosis was nearly absent. In conclusion, it seems that GNLY⁺ lymphocytes, probably attracted by IL‐15, not only participate partially in myocardial cell apoptosis, but also hasten resolution of cardiac leucocyte infiltration in patients with NSTEMI.