Adoptive immunotherapy of a newly induced sarcoma: immunologic characteristics of effector cells

A newly induced syngeneic transplantable sarcoma, MCA 105, was used for studies of the biologic characteristics of fresh noncultured and secondarily in vitro sensitized (IVS) cells with antitumor reactivity. Fresh spleen cells harvested from mice immunized to the MCA 105 tumor by a mixture of viable tumor cells and Corynebacterium parvum exhibited no detectable cytotoxic activity to MCA 105 tumor targets in a 4-hr chromium-release assay, and adoptive transfer of these cells mediated the specific regression of established MCA 105 tumors. Phenotypic analysis of fresh, noncultured immune cells revealed that the therapeutically effective cells expressed both the Lyt-1 and the Lyt-2 T cell differentiation antigens. The therapeutic efficacy of fresh noncultured immune cells was not augmented by the concomitant administration of exogeneous interleukin 2 (IL 2). Secondary IVS of fresh immune cells with irradiated MCA 105 tumor stimulator cells resulted in the generation of tumor-specific cytotoxic effector cells. The generation of cytotoxic effector cells required Lyt-1+, 2+ cytotoxic precursor cells. Effective adoptive immunotherapy with these IVS immune cells, unlike fresh noncultured immune cells, depended on the concomitant administration of IL 2. Furthermore, the generation of therapeutically effective cells did not require the specific stimulation by MCA 105 tumor cells, because cultures of MCA 105 immune spleen cells with FBL-3 lymphoma cells in vitro also contained in vivo functional immune effector cells. These cells, however, possessed no detectable MCA 105 cytotoxic activity in vitro. Although this observation suggests that a noncytotoxic cell population is sufficient to initiate tumor regression in vivo, it does not exclude the possibility that cytolytic cells are generated in vivo after adoptive transfer of these cells. As a whole, our results indicate that secondary IVS functional immune effector cells are characteristically distinct from freshly harvested immune cells.     

Restoration of in vitro responsiveness of xid B cells to TNP-Ficoll by 8-mercaptoguanosine

8-Mercaptoguanosine (8sGuo) has been reported to enhance responses of normal mice to the type 2 antigen trinitrophenol (TNP)-Ficoll. In this report, we demonstrate that this immune adjuvant restores the immune responsiveness of B cells from mice with the x-linked immune defect (xid), which are nonresponsive to the type 2 antigen TNP-Ficoll. The data demonstrate that TNP-Ficoll, which by itself cannot stimulate anti-TNP responses in CBA/N mice, is able to initiate the initial steps of cell activation in xid B cells and render them sensitive to the subsequent differentiative effects of 8sGuo. We propose that the unresponsiveness of xid B cells to type 2 antigens reflects not the inability of these antigens to stimulate xid B cells from G0 to G1, but rather the inability of these antigen-activated cells to respond to a second signal to which these immune defective B cells are poorly responsive and can be substituted for by 8sGuo.     

Adaptive features of natural killer cells,lymphocytes of innate immunity

Natural killer cells (NK cells) are traditionally attributed to the innate immune system. It is considered that previously received stimuli have little effect on the functioning of these immune cells. Indeed, NK cells even without prior sensitization provide a rapid effector response against tumor, virus-infected, or otherwise damaged cells. They have a limited repertoire of receptors, the expression of which does not require somatic recombination. However, recent data indicate that NK cells may acquire the properties specific to adaptive immune cells. In particular, NK cells have been shown to possess the features of immunological memory, namely, the ability to more quickly and effectively respond to a repeated stimulus. The mechanisms of memory acquisition in NK cells differ from those implemented in T and B lymphocytes and are still rather vague. Presumably, some of these mechanisms underlie the significant phenotypic and functional NK cell diversity emerging during their differentiation. The recent data accumulated in this area considerably change the existing immunology paradigm, which postulates a clear delineation of the adaptive and innate immune cells. The published data on phenotypic and functional characteristics of NK cells and particular changes in these characteristics during NK cell differentiation and generation of memory-like NK cells are reviewed.     

Emerging role of immune cell network in autoimmune skin disorders: An update on pemphigus,vitiligo and psoriasis

Autoimmune skin diseases are a group of disorders that arise due to a deregulated immune system resulting in skin tissue destruction. In the majority of these conditions, either autoreactive immune cells or the autoantibodies are generated against self-antigens of the skin. Although the etiology of these diseases remains elusive, biochemical, genetic, and environmental factors such as infectious agents, toxins damage the skin tissue leading to self-antigen generation, autoantibody attack and finally results in autoimmunity of skin. Immune dysregulation, which involves predominantly T helper 1/17 (Th1/Th17) polarization and the inability of regulatory T cells to regress immune response, is implicated in autoimmune skin diseases.The emerging roles of immune cells, cytokines, and chemokines in the pathogenesis of common autoimmune skin diseases like pemphigus, vitiligo, and psoriasis are discussed in this review. The main focus is on the interplay between immune cell network including the innate and adaptive immune system, regulatory cells, immune checkpoints and recently identified tissue-resident memory cells (TRMs) in disease pathogenesis and relapse. We also attempt to highlight on the immune mechanisms common to these diseases which can be targeted for designing novel therapeutics.     

Cytoskeletal control of the secretory immune synapse

The immune synapse is a very important but often transient site for secretion between immune cells. How secretion is controlled in a coordinated fashion at the synapse is a subject of much investigation. Two key mechanisms are the polarisation of the centrosome and rapid actin dynamics across the immune synapses that form between interacting immune cells. In recent years it has become clear that different immune cells utilise a diversity of immune synapses that modify these mechanisms in order to optimise specialised modes of secretion. Here we describe some of the latest research, focusing on regulation by centrosomal and actin dynamics in a variety of immune cells.     

Immunoproteomics: Mass spectrometry-based methods to study the targets of the immune response

The mammalian immune system has evolved to display fragments of protein antigens derived from microbial pathogens to immune effector cells. These fragments are typically peptides liberated from the intact antigens through distinct proteolytic mechanisms that are subsequently transported to the cell surface bound to chaperone-like receptors known as major histocompatibility complex (MHC) molecules. These complexes are then scrutinized by effector T cells that express clonally distributed T cell receptors with specificity for specific MHC-peptide complexes. In normal uninfected cells, this process of antigen processing and presentation occurs continuously, with the resultant array of self-antigen-derived peptides displayed on the surface of these cells. Changes in this peptide landscape of cells act to alert immune effector cells to changes in the intracellular environment that may be associated with infection, malignant transformation, or other abnormal cellular processes, resulting in a cascade of events that result in their elimination. Because peptides play such a crucial role in informing the immune system of infection with viral or microbial pathogens and the transformation of cells in malignancy, the tools of proteomics, in particular mass spectrometry, are ideally suited to study these immune responses at a molecular level. Here we review recent advances in the studies of immune responses that have utilized mass spectrometry and associated technologies, with specific examples from collaboration between our laboratories.     

Use of proteomics to define targets of T-cell immunity

The mammalian immune system has evolved to display peptides derived from microbial antigens to immune effector cells. Liberated from the intact antigens through distinct proteolytic mechanisms, these peptides are subsequently transported to the cell surface while bound to chaperone-like receptors known as major histocompatibility complex molecules. These complexes are then scrutinized by T-cells that express receptors with specificity for specific major histocompatibility complex–peptide complexes. In normal uninfected cells, this process of antigen processing and presentation occurs continuously, with the resultant array of self-antigen-derived peptides displayed on the surface of these cells. Changes in this cellular peptide array alert the immune system to changes in the intracellular environment that may be associated with infection, oncogenesis or other abnormal cellular processes, resulting in a cascade of events that result in the elimination of the abnormal cell. Since peptides play such an essential role in informing the immune system of infection with viral or microbial pathogens and the transformation of cells in malignancy, the tools of proteomics, in particular mass spectrometry, are ideally suited to study these immune responses at a molecular level. Recent advances in studies of immune responses that have utilized mass spectrometry and associated technologies are reviewed. The authors gaze into the future and look at current challenges and where proteomics will impact in immunology over the next 5 years.     

Use of proteomics to define targets of T-cell immunity

The mammalian immune system has evolved to display peptides derived from microbial antigens to immune effector cells. Liberated from the intact antigens through distinct proteolytic mechanisms, these peptides are subsequently transported to the cell surface while bound to chaperone-like receptors known as major histocompatibility complex molecules. These complexes are then scrutinized by T-cells that express receptors with specificity for specific major histocompatibility complex-peptide complexes. In normal uninfected cells, this process of antigen processing and presentation occurs continuously, with the resultant array of self-antigen-derived peptides displayed on the surface of these cells. Changes in this cellular peptide array alert the immune system to changes in the intracellular environment that may be associated with infection, oncogenesis or other abnormal cellular processes, resulting in a cascade of events that result in the elimination of the abnormal cell. Since peptides play such an essential role in informing the immune system of infection with viral or microbial pathogens and the transformation of cells in malignancy, the tools of proteomics, in particular mass spectrometry, are ideally suited to study these immune responses at a molecular level. Recent advances in studies of immune responses that have utilized mass spectrometry and associated technologies are reviewed. The authors gaze into the future and look at current challenges and where proteomics will impact in immunology over the next 5 years.     

Approaches to improve tumor accumulation and interactions between monoclonal antibodies and immune cells

Monoclonal antibodies (mAb) have become a mainstay in tumor therapy. Clinical responses to mAb therapy, however, are far from optimal, with many patients presenting native or acquired resistance or suboptimal responses to a mAb therapy. MAbs exert antitumor activity through different mechanisms of action and we propose here a classification of these mechanisms. In many cases mAbs need to interact with immune cells to exert antitumor activity. We summarize evidence showing that interactions between mAbs and immune cells may be inadequate for optimal antitumor activity. This may be due to insufficient tumor accumulation of mAbs or immune cells, or to low-affinity interactions between these components. The possibilities to improve tumor accumulation of mAbs and immune cells, and to improve the affinity of the interactions between these components are reviewed. We also discuss future directions of research that might further improve the therapeutic efficacy of antitumor mAbs.     

Adhesive interactions in the immune system

The immune system is composed of bone-marrow-derived, nucleated cells, many of which circulate through the mammalian host in search of sites of pathogen invasion and other environmental dangers. The key to successful host defence is the ability of these leukocytes to mobilize rapidly to such sites of perturbation of homeostasis. Regulated adhesive interactions of these cells with the endothelium, extracellular matrix, cells of the solid organs and each other are a central feature of the immune response. This review considers the molecules involved in adhesion by cells of the immune system - with particular emphasis on the aspects of adhesion that are unique to leukocytes, namely transendothelial migration, regulation of adhesiveness, and leukocyte activation.     

Endothelial cells in the eyes of an immunologist

Endothelial cell activation in the process of tumor angiogenesis and in various aspects of vascular biology has been extensively studied. However, endothelial cells also function in other capacities, including in immune regulation. Compared to the more traditional immune regulatory populations (Th1, Th2, Treg, etc.), endothelial cells have received far less credit as being immune regulators. Their regulatory capacity is multifaceted. They are critical in both limiting and facilitating the trafficking of various immune cell populations, including T cells and dendritic cells, out of the vasculature and into tissue. They also can be induced to stimulate immune reactivity or to be immune inhibitory. In each of these parameters (trafficking, immune stimulation and immune inhibition), their role can be physiological, whereby they have an active role in maintaining health. Alternatively, their role can be pathological, whereby they contribute to disease. In theory, endothelial cells are in an ideal location to recruit cells that can mediate immune reactivity to tumor tissue. Furthermore, they can activate the immune cells as they transmigrate across the endothelium into the tumor. However, what is seen is the absence of these protective effects of endothelial cells and, instead, the endothelial cells succumb to the defense mechanisms of the tumor, resulting in their acquisition of a tumor-protective role. To understand the immune regulatory potential of endothelial cells in protecting the host versus the tumor, it is useful to better understand the other circumstances in which endothelial cells modulate immune reactivities. Which of the multitude of immune regulatory roles that endothelial cells can take on seems to rely on the type of stimulus that they are encountering. It also depends on the extent to which they can be manipulated by potential dangers to succumb and contribute toward attack on the host. This review will explore the physiological and pathological roles of endothelial cells as they regulate immune trafficking, immune stimulation and immune inhibition in a variety of conditions and will then apply this information to their role in the tumor environment. Strategies to harness the immune regulatory potential of endothelial cells are starting to emerge in the non-tumor setting. Results from such efforts are expected to be applicable to being able to skew endothelial cells from having a tumor-protective role to a host-protective role.     

Selective localization of tumor-immune spleen cells at the tumor challenge site after adoptive transfer of line 10 tumor immunity in strain 2 guinea pigs

In this study, the distribution of immune spleen cells was investigated after adoptive transfer of immunity in inbred strain 2 guinea pigs. Spleen cells obtained from line 10 immune donor animals became specifically restimulated in vitro with 3 M KCl-extracted line 10 soluble proteins, but not with 3 M KCl-extracted line 1 or liver proteins. After 4 days culture in vitro, these specifically restimulated immune spleen cells retained their antitumor activity in vivo after adoptive transfer. The specifically restimulated immune spleen cells were radiolabeled with [3H]thymidine, 1 X 10(8) viable cells were adoptively transferred in tumor-bearing guinea pigs, and their distribution was investigated. As controls for the specific localization of the immune cells at the line 10 tumor, the presence of labeled cells was studied in the contralateral transplanted line 1 hepatoma as well as in cellular inflammatory reactions elicited by injection with incomplete Freund's adjuvant (IFA) and complete Freund's adjuvant (CFA). A significantly higher localization of the labeled immune spleen cells in the line 10 tumor and the first and second draining lymph nodes of the line 10 challenge site were found when compared to the influx of these cells in the line 1 tumor and the nontumor antigen-related inflammatory reactions. Because our immune donor animals were immunized with a mixture of line 10 cells and BCG, these animals are immune to both. Line 10 immune spleen cells were restimulated in vitro with PPD and were radiolabeled. These PPD-restimulated immune spleen cells showed no preferential localization at the line 10 tumor challenge site but, as expected, a tendency for localization at the CFA (H37Ra) injection site. Furthermore, PPD-reactive spleen cells from BCG-immunized guinea pigs showed a significantly higher accumulation at the CFA injection site compared to the IFA injection site and the line 10 and line 1 tumor challenge site. From the results, it is concluded that line 10 tumor-immune and BCG-immune spleen cells are two distinct cell populations, and that the existence of cross-reacting antigens between BCG and the line 10 hepatocarcinoma are of no importance for the rejection of the line 10 tumor by immune spleen cells.     

Regulation of the production of immune interferon and cytotoxic T lymphocytes by interleukin 2

The activation of alloantigen-specific cytotoxic T lymphocyte precursors is dependent upon the presence of both macrophages and helper T cells or regulatory molecules derived from these facilitative cells. Three biochemically distinct helper factors have been identified: interleukin 1 (macrophage-derived), Interleukin 2 (T cell derived), and immune interferon. All 3 factors are found in supernatants of mixed lymphocyte cultures (MLC), however, the removal of macrophages from these cultures completely ablates the production of these factors as well as the induction of cytotoxic T lymphocytes (CTL). The addition of IL 2 to these macrophage-depleted MLC restores the ability of responder T cells to: 1) bypass the requirement for macrophage soluble function, 2) produce immune interferon, and 3) generate CTL. The kinetics and dose response of immune interferon production in response to IL 2 correlates with the generation of CTL. The production of immune interferon as well as the generation of CTL requires T cells, alloantigen, and IL2. Furthermore, the induction of CTL by IL2 was neutralized by the addition of anti-immune interferon. These data suggest that: 1) the regulation of immune interferon production is based on a T to T cell interaction mediated by IL 2, and 2) immune interferon production may be required for IL 2 induction of CTL. These findings are consistent with the hypothesis that the induction of CTL involves a linear cell-factor interaction in which IL 1 (macrophage-derived) stimulates T cells to produce IL 2, which in turn stimulates other T cells to produce immune interferon and become cytotoxic.     

Gr-1+ CD11b+ myeloid-derived suppressor cells suppress inflammation and promote insulin sensitivity in obesity

Activation of immune cells, including macrophages and CD8(+) T cells, contributes significantly to the advancement of obesity and its associated medical complications, such as atherosclerosis, insulin resistance, and type 2 diabetes. However, how the activation of these immune cells is regulated in vivo remains largely unexplored. Here we show that a group of immature myeloid cells with cell surface markers of Gr-1(+) CD11b(+) are highly enriched in peripheral tissues (i.e. liver and adipose tissues) during obesity. Down-regulation of these cells in obese animals significantly increases inflammation and impairs insulin sensitivity and glucose tolerance, whereas elevation of these cells via adoptive transfer has the opposite effects. Mechanistically, we show that under obese conditions, the Gr-1(+) cells suppress proliferation and induce apoptosis of CD8(+) T cells and are capable of skewing differentiation of macrophages into insulin-sensitizing, alternatively activated M2 macrophages. Taken together, our study demonstrates that immature myeloid cells provide a checks-and-balances platform to counter proinflammatory immune cells in the liver and adipose tissue during obesity to prevent overt immune responses.     

Invariant natural killer T cells: bridging innate and adaptive immunity

Cells of the innate immune system interact with pathogens via conserved pattern-recognition receptors, whereas cells of the adaptive immune system recognize pathogens through diverse, antigen-specific receptors that are generated by somatic DNA rearrangement. Invariant natural killer T (iNKT) cells are a subset of lymphocytes that bridge the innate and adaptive immune systems. Although iNKT cells express T cell receptors that are generated by somatic DNA rearrangement, these receptors are semi-invariant and interact with a limited set of lipid and glycolipid antigens, thus resembling the pattern-recognition receptors of the innate immune system. Functionally, iNKT cells most closely resemble cells of the innate immune system, as they rapidly elicit their effector functions following activation, and fail to develop immunological memory. iNKT cells can become activated in response to a variety of stimuli and participate in the regulation of various immune responses. Activated iNKT cells produce several cytokines with the capacity to jump-start and modulate an adaptive immune response. A variety of glycolipid antigens that can differentially elicit distinct effector functions in iNKT cells have been identified. These reagents have been employed to test the hypothesis that iNKT cells can be harnessed for therapeutic purposes in human diseases. Here, we review the innate-like properties and functions of iNKT cells and discuss their interactions with other cell types of the immune system.     

Osteoimmunology: cytokines and the skeletal system

It has become clear that complex interactions underlie the relationship between the skeletal and immune systems. This is particularly true for the development of immune cells in the bone marrow as well as the functions of bone cells in skeletal homeostasis and pathologies. Because these two disciplines developed independently, investigators with an interest in either often do not fully appreciate the influence of the other system on the functions of the tissue that they are studying. With these issues in mind, this review will focus on several key areas that are mediated by crosstalk between the bone and immune systems. A more complete appreciation of the interactions between immune and bone cells should lead to better therapeutic strategies for diseases that affect either or both systems.     

Signalling shutdown strategies in aging immune cells

It is important for the resolution of inflammation that the number and activity of immune cells are reduced. Clearance of immune cells may be achieved by apoptosis and phagocytosis of cell fragments by macrophages. However, signalling shutdown by immune cells committed to apoptosis occurs early in the progression of these cells towards fragmentation and, it could be argued, is a key feature of apoptosis. There is surprisingly little known about the mechanisms that underlie this signalling shutdown, in particular the shutdown of Ca(2+) influx. The consequences and the potential mechanisms by which Ca(2+) influx shutdown is achieved are discussed. In addition, the potential consequences for cell signalling of cytochrome c release from mitochondria and of phosphatidyl-serine externalization are discussed. The aim of the review is therefore to highlight the evidence for various signalling shutdown strategies in immune cells that may limit their activity during progression towards apoptosis.     

Immunometabolism: Cellular Metabolism Turns Immune Regulator

Immune cells are highly dynamic in terms of their growth, proliferation, and effector functions as they respond to immunological challenges. Different immune cells can adopt distinct metabolic configurations that allow the cell to balance its requirements for energy, molecular biosynthesis, and longevity. However, in addition to facilitating immune cell responses, it is now becoming clear that cellular metabolism has direct roles in regulating immune cell function. This review article describes the distinct metabolic signatures of key immune cells, explains how these metabolic setups facilitate immune function, and discusses the emerging evidence that intracellular metabolism has an integral role in controlling immune responses.