Zhengyu Ma

Strength of PD-1 signaling differentially affects T-cell effector functions

High surface expression of programmed death 1 (PD-1) is associated with T-cell exhaustion; however, the relationship between PD-1 expression and T-cell dysfunction has not been delineated. We developed a model to study PD-1 signaling in primary human T cells to study how PD-1 expression affected T-cell function. By determining the number of T-cell receptor/peptide-MHC complexes needed to initiate a Ca2+ flux, we found that PD-1 ligation dramatically shifts the dose–response curve, making T cells much less sensitive to T-cell receptor–generated signals. Importantly, other T-cell functions were differentially sensitive to PD-1 expression. We observed that high levels of PD-1 expression were required to inhibit macrophage inflammatory protein 1 beta production, lower levels were required to block cytotoxicity and IFN-γ production, and very low levels of PD-1 expression could inhibit TNF-α and IL-2 production as well as T-cell expansion. These findings provide insight into the role of PD-1 expression in enforcing T-cell exhaustion and the therapeutic potential of PD-1 blockade.

Surface-anchored monomeric agonist pMHCs alone trigger TCR with high sensitivity.

At the interface between T cell and antigen-presenting cell (APC), peptide antigen presented by MHC (pMHC) binds to the T cell receptor (TCR) and initiates signaling. The mechanism of TCR signal initiation, or triggering, remains unclear. An interesting aspect of this puzzle is that although soluble agonist pMHCs cannot trigger TCR even at high concentrations, the same ligands trigger TCR very efficiently on the surface of APCs. Here, using lipid bilayers or plastic-based artificial APCs with defined components, we identify the critical APC-associated factors that confer agonist pMHCs with such potency. We found that CD4+ T cells are triggered by very low numbers of monomeric agonist pMHCs anchored on fluid lipid bilayers or fixed plastic surfaces, in the absence of any other APC surface molecules. Importantly, on bilayers, plastic surfaces, or real APCs, endogenous pMHCs did not enhance TCR triggering. TCR triggering, however, critically depended upon the adhesiveness of the surface and an intact T cell actin cytoskeleton. Based on these observations, we propose the receptor deformation model of TCR triggering to explain the remarkable sensitivity and specificity of TCR triggering.

Complement Receptor 3 Ligation of Dendritic Cells Suppresses Their Stimulatory Capacity

To activate T cells effectively, dendritic cells (DCs) must provide three separate signals, MHC-Ag, costimulatory molecules (such as CD80 and CD86), and proinflammatory cytokines (such as IL-12). These three signals are up-regulated in the presence of “danger signals” such as LPS or viral nucleic acids. Evidence suggests that DCs providing only the first two of these signals cannot successfully stimulate T cells. Apoptotic cells have been proposed to suppress DC immunogenicity through the ligation of apoptotic cell receptors. Complement receptor 3 (CR3) and CD36 have been suggested to be important in this process, although the mechanism by which this modulation occurs is still unclear. We demonstrate that ligation of CR3, but not CD36, directs DCs to increase surface MHC and costimulatory molecules, while suppressing inflammatory cytokine release. CR3 modulation of DCs does not require a type I IFN response, does not involve the specific regulation of the MyD88- or Toll/IL-1R domain-containing adaptor-inducing IFN-β-dependent TLR signaling pathways, and occurs even in the absence of danger signals. The functional outcome of this process is poor Ag-specific stimulation of CD4 and CD8 T cells by CR3-ligated DCs both in naive response as well as upon subsequent challenge with normal DCs. We propose that CR3 provides a “nondanger” signal that suppresses the stimulatory capacity of DCs.

The receptor deformation model of TCR triggering

Through T cell receptors (TCRs), T cells can detect and respond to very small numbers of foreign peptides among a huge number of self‐peptides presented by major histocompatibility complexes (pMHCs) on the surface of antigen‐presenting cells (APCs). How T cells achieve such remarkable sensitivity and specificity through pMHC‐TCR binding is an intensively pursued issue in immunology today;the key question is how pMHC‐TCR binding initiates, or triggers, a signal from TCRs. Multiple competing models have been proposed, none of which fully explains the sensitivity and specificity of TCR triggering. What has been omitted from existing theories is that the pMHC‐TCR interaction at the T cell/APC interface must be under constant mechanical stress, due to the dynamic nature of cell‐cell interaction. Taking this condition into consideration, we propose the receptor deformation model of TCR triggering. In this model, TCR signaling is initiated by conformational changes of the TCR/CD3 complex, induced by a pulling force originating from the cytoskeleton and transmitted through pMHC‐TCR binding interactions with enough strength to resist rupture. By introducing mechanical force into a model of T cell signal initiation, the receptor deformation model provides potential mechanistic solutions to the sensitivity and specificity of TCR triggering. Ma, Z., Janmey, P. A., Finkel, T. H. The receptor deformation model of TCR triggering. FASEB J. 22, 1002–1008 (2008)

T cell receptor triggering by force

Antigen recognition through the interaction between the T cell receptor (TCR) and peptide presented by major histocompatibility complex (pMHC) is the first step in T cell-mediated immune responses. How this interaction triggers TCR signalling that leads to T cell activation is still unclear. Taking into account the mechanical stress exerted on the pMHC-TCR interaction at the dynamic interface between T cells and antigen presenting cells (APCs), we propose the so-called receptor deformation model of TCR triggering. In this model, TCR conformational change induced by mechanical forces initiates TCR signalling. The receptor deformation model, for the first time, explains all three aspects of the TCR triggering puzzle: mechanism, specificity, and sensitivity.

Ligation of CD28 by Its Natural Ligand CD86 in the Absence of TCR Stimulation Induces Lipid Raft Polarization in Human CD4 T Cells

Stimulation of resting CD4 T cells with anti-CD3/CD28-coated beads leads to rapid polarization of lipid rafts (LRs). It has been postulated that a major role of costimulation is to facilitate LR aggregation. CD86 is up-regulated or expressed aberrantly on immune cells in a wide array of autoimmune and infectious diseases. Using an Ig fusion with the extracellular domain of CD86 (CD86Ig) bound to a magnetic bead or K562 cells expressing CD86, we demonstrated that ligation of CD28 by its natural ligand, but not by Ab, induced polarization of LRs at the cell-bead interface of fresh human CD4 T cells in the absence of TCR ligation. This correlated with activation of Vav-1, increase of the intracellular calcium concentration, and nuclear translocation of NF-κB p65, but did not result in T cell proliferation or cytokine production. These studies show, for the first time, that LR polarization can occur in the absence of TCR triggering, driven solely by the CD28/CD86 interaction. This result has implications for mechanisms of T cell activation. Abnormalities in this process may alter T and B cell tolerance and susceptibility to infection.

Mechanical Force in T Cell Receptor Signal Initiation

In peripheral lymphoid organs, such as lymph nodes, T lymphocytes (T cells) actively scan the surface of antigen presenting cells (APCs) for evidence of pathogen invasion. Proteins of pathogens taken up by APCs are processed to short peptides and presented on the cell surface with major histocompatibility complexes (MHCs). Specific binding between peptide-MHC complexes (pMHCs) on APCs and T cell receptors (TCRs) on T cells initiate signaling cascades from TCRs that eventually lead to T cell activation and proliferation. Despite its importance, how pMHC-TCR binding triggers a signal from the TCR remains to be elucidated (van der Merwe and Dushek, 2011). The central question is: how does pMHC binding change the TCR/CD3 complex to a state that facilitates signaling events such as tyrosine phosphorylation of the ITAM domains of CD3?

The impact of Nucleofection® on the activation state of primary human CD4 T cells

Gene transfer into primary human CD4 T lymphocytes is a critical tool in studying the mechanism of T cell-dependent immune responses and human immunodeficiency virus-1 (HIV-1) infection. Nucleofection® is an electroporation technique that allows efficient gene transfer into primary human CD4 T cells that are notoriously resistant to traditional electroporation. Despite its popularity in immunological research, careful characterization of its impact on the physiology of CD4 T cells has not been documented. Herein, using freshly-isolated primary human CD4 T cells, we examine the effects of Nucleofection® on CD4 T cell morphology, intracellular calcium levels, cell surface activation markers, and transcriptional activity. We find that immediately after Nucleofection®, CD4 T cells undergo dramatic morphological changes characterized by wrinkled and dilated plasma membranes before recovering 1h later. The intracellular calcium level also increases after Nucleofection®, peaking after 1h before recovering 8h post transfection. Moreover, Nucleofection® leads to increased expression of T cell activation markers, CD154 and CD69, for more than 24h, and enhances the activation effects of phytohemagglutinin (PHA) stimulation. In addition, transcriptional activity is increased in the first 24h after Nucleofection®, even in the absence of exogenous stimuli. Therefore, Nucleofection® significantly alters the activation state of primary human CD4 T cells. The effect of transferred gene products on CD4 T cell function by Nucleofection® should be assessed after sufficient resting time post transfection or analyzed in light of the activation caveats mentioned above.

Improved method of preparation of supported planar lipid bilayers as artificial membranes for antigen presentation

T cell activation is the result of direct cell‐cell contact between T cells and antigen presenting cells (APCs), and of interactions between membrane‐bound ligands and receptors at the contact interface, the “immunological synapse.” Model APCs based upon supported fluid lipid bilayers have been used to dissect these complex molecular interactions and to facilitate real‐time microscopic observations. Nearly all studies have used liposome fusion‐based methods to make supported bilayers, and the biophysical properties of these membranes were not characterized in detail. Here, using both Langmuir‐Blodgett and liposome fusion techniques, we explored five different methods of lipid bilayer preparation on glass, mica, or dextran cushion substrates and characterized the stability, homogeneity, and fluidity of the bilayers with fluorescence microscopy and fluorescence recovery after photobleaching (FRAP). Most combinations of techniques and substrates led to unsatisfactory results, notably, a lack of homogeneity for liposome fusion on glass, low stability of bilayers on mica, and loss of fluidity of dextran‐cushioned bilayers in solutions containing protein. To overcome these deficits, we developed a technique that combines liposome fusion on glass and thermally enhanced bilayer expansion. The newly expanded pristine bilayer showed high degrees of stability, homogeneity, and fluidity. MHC and ICAM‐1 molecules anchored on the bilayer diffused freely and stimulated T cell calcium flux and adhesion, respectively. Microsc. Res. Tech., 2011.

REDD1 Is Essential for Optimal T Cell Proliferation and Survival

REDD1 is a highly conserved stress response protein that is upregulated following many types of cellular stress, including hypoxia, DNA damage, energy stress, ER stress, and nutrient deprivation. Recently, REDD1 was shown to be involved in dexamethasone induced autophagy in murine thymocytes. However, we know little of REDD1’s function in mature T cells. Here we show for the first time that REDD1 is upregulated following T cell stimulation with PHA or CD3/CD28 beads. REDD1 knockout T cells exhibit a defect in proliferation and cell survival, although markers of activation appear normal. These findings demonstrate a previously unappreciated role for REDD1 in T cell function.