Mitochondrial shape changes: orchestrating cell pathophysiology

Mitochondria are highly dynamic organelles, the location, size and distribution of which are controlled by a family of proteins that modulate mitochondrial fusion and fission. Recent evidence indicates that mitochondrial morphology is crucial for cell physiology, as changes in mitochondrial shape have been linked to neurodegeneration, calcium signalling, lifespan and cell death. Because immune cells contain few mitochondria, these organelles have been considered to have only a marginal role in this physiological context—which is conversely well characterized from the point of view of signalling. Nevertheless, accumulating evidence shows that mitochondrial dynamics have an impact on the migration and activation of immune cells and on the innate immune response. Here, we discuss the roles of mitochondrial dynamics in cell pathophysiology and consider how studying dynamics in the context of the immune system could increase our knowledge about the role of dynamics in key signalling cascades.     

Granulocyte macrophage colony-stimulating factor has come of age: From a vaccine adjuvant to antiviral immunotherapy

GM-CSF acts as a pro-inflammatory cytokine and a key growth factor produced by several immune cells such as macrophages and activated T cells. In this review, we discuss recent studies that point to the crucial role of GM-CSF in the immune response against infections. Upon induction, GM-CSF activates four main signalling networks including the JAK/STAT, PI3K, MAPK, and NFκB pathways. Many of these transduction pathways such as JAK/STAT signal via proteins commonly activated with other antiviral signalling cascades, such as those induced by IFNs.GM-CSF also helps defend against respiratory infections by regulating alveolar macrophage differentiation and enhancing innate immunity in the lungs. Here, we also summarize the numerous clinical trials that have taken advantage of GM-CSF’s mechanistic attributes in immunotherapy. Moreover, we discuss how GM-CSF is used as an adjuvant in vaccines and how its activity is interfered with to reduce inflammation such as in the case of COVID-19. This review brings forth the current knowledge on the antiviral actions of GM-CSF, the associated signalling cascades, and its application in immunotherapy.     

The complexity of the CD4 T-cell responses: old and new T-cell subsets

The T-cell compartment of the immune system reacts to an enormous variety of antigens, including self antigens, due to its a wide repertoire of T-cell clones. Self-reactive T cells undergo a negative selection process resulting in apoptosis of T cells with high affinity for self-peptides. Self-reactive T cells escaped to negative selection are then controlled by natural T regulatory (Treg) cells. Regulation also controls excessive effector T-cell responses. Three types of effector T cells are recognized: T helper 1 (Th1) cells, which protect against intracellular bacteria; Th2 cells, which play a role against parasites; Th17 cells, which would face extracellular bacteria, but also are involved in autoimmunity. Effector T-cell polarization is determined by the complex interaction of antigen-presenting cells with naive T cells and involves a multitude of factors, including the dominant cytokine environment, costimulatory molecules, type and load of antigen presented and signaling cascades. The decision for the immune response to go in a certain direction is based not onto one signal alone, rather onto many different elements acting synergistically, antagonistically and through feedback loops leading to activation of Th1, Th2, or Th17 responses. Both Th1 and Th2 can be suppressed by adaptive Treg cells through contact-dependent mechanisms and/or cytokines.     

Modulation of T-cell function by type I interferon

Production of type I interferon (IFN-α/β) is a common cellular response to virus infection. IFN-α/β has a dual role in combating infection, triggering innate antiviral mechanisms and stimulating the generation of an adaptive immune response. This review focuses on the effects of IFN-α/β on one particular immune cell type, the T cell, and the impact of IFN-α/β-mediated signalling in T cells on the immune response. The critical role of T-cell responsiveness to IFN-α/β for the generation of productive T-cell responses after infections with certain viruses in vivo is discussed in the context of in vitro experiments investigating the mechanisms by which IFN-α/β modifies T-cell function. These studies reveal complex effects of IFN-α/β on T cells, with the consequences of exposure to IFN-α/β depending on the context of other signals received by the T cell.     

WNT signalling in the immune system: WNT is spreading its wings

WNT proteins are secreted morphogens that are required for basic developmental processes, such as cell-fate specification, progenitor-cell proliferation and the control of asymmetric cell division, in many different species and organs. In blood and immune cells, WNT signalling controls the proliferation of progenitor cells and might also affect the cell-fate decisions of stem cells. Recent studies indicate that WNT proteins also regulate effector T-cell development, regulatory T-cell activation and dendritic-cell maturation. WNT signalling seems to function as a universal mechanism in leukocytes to establish a pool of undifferentiated cells for further selection, effector-cell maturation and terminal differentiation. WNT signalling is therefore subject to strict molecular control, and dysregulated WNT signalling is implicated in the development of haematological malignancies.     

Regulation of phospholipase C gamma isoforms in haematopoietic cells: why one, not the other?

Phospholipase C gamma (PLCgamma) isoforms are critical for the generation of calcium signals in haematopoietic systems in response to the stimulation of immune receptors. PLCgamma is unique amongst phospholipases in that it is tightly regulated by the action of a number of tyrosine kinases. It is itself directly phosphorylated on a number of tyrosines and contains several domains through which it can interact with other signalling proteins and lipid products such as phosphatidylinositol 3,4,5-trisphosphate. Through this network of interactions, PLCgamma is activated and recruited to its substrate, phosphatidylinositol 4,5-bisphosphate, at the membrane. Both isoforms of PLCgamma, PLCgamma1 and PLCgamma2, are present in haematopoietic cells. The signalling cascade involved in the regulation of these two isoforms varies between cells, though the systems are similar for both PLCgamma1 and PLCgamma2. We will compare these cascades for both PLCgamma1 and PLCgamma2 and discuss possible reasons as to why one form of PLCgamma and not the other is required for signalling in specific haematopoietic cells, including T lymphocytes, B lymphocytes, platelets, and mast cells.     

A permissive geometry model for TCR-CD3 activation

The T cell antigen receptor (TCR-CD3) is the most complex receptor known to date, consisting of eight transmembrane subunits. Its activation by an antigen is the initial step in an immune response. Here, we present the permissive geometry model explaining how antigen binding initiates intracellular signalling cascades. We propose that a dimeric antigen imposes its geometry on two TCR-CD3 receptors by simultaneously binding to both. This causes the TCRalphabeta subunits to rotate with respect to each other leading to displacement of the ectodomains of the associated CD3 dimers. This results in a scissor-like movement of the CD3 dimers that opens the cytoplasmic tails for interaction with signalling proteins, thus initiating signalling cascades.     

Conference highlight: do T cells care about the mitogen-activated protein kinase signalling pathways?

Mitogen-activated protein (MAP) kinases, which include the extracellular response kinases, p38 and c-Jun amino terminal kinases (JNK), play a significant role in mediating signals triggered by cytokines, growth factors and environmental stress. The JNK and p38 MAP kinases have been involved in growth, differentiation and cell death in different cell types. In the present paper, we describe how the JNK and p38 MAP kinase signalling pathways are regulated and their role during thymocyte development and the activation and differentiation of T cells in the peripheral immune system. The results from these studies demonstrate that the JNK and p38 MAP kinase signalling pathways regulate different aspects of T-cell mediated immune responses.     

Life and death in peripheral T cells

During the course of an immune response, antigen-reactive T cells clonally expand and then are removed by apoptosis to maintain immune homeostasis. Life and death of T cells is determined by multiple factors, such as T-cell receptor triggering, co-stimulation or cytokine signalling, and by molecules, such as caspase-8 (FLICE)-like inhibitory protein (FLIP) and haematopoietic progenitor kinase 1 (HPK1), which regulate the nuclear factor-kappaB (NF-kappaB) pathway. Here, we discuss the concepts of activation-induced cell death (AICD) and activated cell-autonomous death (ACAD) in the regulation of life and death in T cells.     

The role of ubiquitylation in nerve cell development

Nerve cell development in the brain is a tightly regulated process. The generation of neurons from precursor cells, their migration to the appropriate target sites, their extensive arborization and their integration into functional networks through synapse formation and refinement are governed by multiple interdependent signalling cascades. The function and turnover of proteins involved in these signalling cascades, in turn, are spatially and temporally controlled by ubiquitylation. Recent advances have provided first insights into the highly complex and intricate molecular pathways that regulate ubiquitylation during all stages of neural development and that operate in parallel with other regulatory processes such as phosphorylation or cyclic nucleotide signalling.     

Listeria monocytogenes virulence proteins induce surface expression of Fas ligand on T lymphocytes

Virulence factors secreted by Listeria monocytogenes are known to interfere with host cellular signalling pathways. We investigated whether L. monocytogenes modulates T-cell receptor signalling by examining surface expression of proteins known to be upregulated on activated T cells. In vitro culture of murine splenocytes with L. monocytogenes resulted in a specific and dose-dependent upregulation of Fas ligand (FasL). Induction of FasL expression was also observed for pathogenic Listeria ivanovii but not for non-pathogenic Listeria innocua, indicating involvement of Listeria virulence protein(s). Examination of L. monocytogenes strains deficient in different virulence genes demonstrated that FasL upregulation was dependent on the expression of two secreted proteins: listeriolysin O (LLO) and phosphatidylcholine-preferring phospholipase C (PC-PLC). Treatment of cells with purified proteins demonstrated that LLO was sufficient for inducing FasL, while PC-PLC synergized with LLO for the induction of FasL expression. FasL-expressing cells induced by L. monocytogenes were capable of killing Fas-expressing target cells. Furthermore, L. monocytogenes infection results in upregulation of FasL on T cells in mice. These results describe a novel function for LLO and PC-PLC and suggest that L. monocytogenes may use these virulence factors to modulate the host immune response.     

Regulation of T-cell activation by the cytoskeleton

To become activated, T cells must efficiently recognize antigen-presenting cells or target cells through several complex cytoskeleton-dependent processes, including integrin-mediated adhesion, immunological-synapse formation, cellular polarization, receptor sequestration and signalling. The actin and microtubule systems provide the dynamic cellular framework that is required to orchestrate these processes and ultimately contol T-cell activation. Here, we discuss recent advances that have furthered our understanding of the crucial importance of the T-cell cytoskeleton in controlling these aspects of T-cell immune recognition.     

Chimeric yellow fever/dengue virus as a candidate dengue vaccine: quantitation of the dengue virus-specific CD8 T-cell response

We have constructed a chimeric yellow fever/dengue (YF/DEN) virus, which expresses the premembrane (prM) and envelope (E) genes from DEN type 2 (DEN-2) virus in a YF virus (YFV-17D) genetic background. Immunization of BALB/c mice with this chimeric virus induced a CD8 T-cell response specific for the DEN-2 virus prM and E proteins. This response protected YF/DEN virus-immunized mice against lethal dengue encephalitis. Control mice immunized with the parental YFV-17D were not protected against DEN-2 virus challenge, indicating that protection was mediated by the DEN-2 virus prM- and E-specific immune responses. YF/DEN vaccine-primed CD8 T cells expanded and were efficiently recruited into the central nervous systems of DEN-2 virus challenged mice. At 5 days after challenge, 3 to 4% of CD8 T cells in the spleen were specific for the prM and E proteins, and 34% of CD8 T cells in the central nervous system recognized these proteins. Depletion of either CD4 or CD8 T cells, or both, strongly reduced the protective efficacy of the YF/DEN virus, stressing the key role of the antiviral T-cell response.