Molecular basis for costimulation of human T lymphocytes

Parra, Eduardo.

January 1998

Thesis (doctoral)--Lund University, 1998. / Added t.p. with thesis statement inserted.

T cells Receptors, Antigen, T-Cell.

Tregs that accumulate in the encephalomyocarditis virus-infected mouse brain: Origin, compartmentalization, function, and gene signature

Puhr, Sarah

January 2017

It is well recognized that regulatory T cells (Tregs) are immunosuppressive, by which they prevent systemic autoimmunity throughout life. Beyond this stereotypical function, however, a growing body of evidence demonstrates that Tregs in distinct tissues, including the visceral adipose tissue, dystrophic muscle, the flu-infected lung, and wounded skin can acquire unique functions directed by their local environment. Tregs in these tissues can employ a wide variety of mechanisms to accumulate and acquire tissue-specific function, including conversion from conventional T cells, canonical T cell receptor (TCR)-dependent expansion and non-canonical, TCR-independent, cytokine-dependent expansion. Intriguingly, the niche-specific function of tissue Tregs can be independent of, and mutually exclusive of, their immunosuppressive capacity. Together, this recent literature reveals that Tregs can accumulate in discrete tissue sites through non-canonical mechanisms, and in response to niche-specific cues can acquire distinct functions, which distinguish them from their peripheral, lymphoid Treg counterparts. Other tissue Treg populations remain to be identified and characterized. Moreover, it is unknown whether other tissue Tregs rely on non-canonical mechanisms of accumulation, and exhibit functions distinct from the typical Treg immunosuppressive role. Tregs are known to accumulate in the CNS during infection, injury and inflammation. The CNS is an organ with distinctive architecture that maintains a regulated interaction with the peripheral immune system due to its critical function and poor regenerative capacity. While it is known that Tregs broadly protect against excessive tissue pathology in the diseased CNS, the origin, localization, function, mechanism of accumulation, and gene signature of CNS-infiltrating Tregs have not been studied, likely due to the challenge of isolating these rare cells and distinguishing them from circulating cells left over after perfusion. Here, we establish a safe model of CNS infection using encephalomyocarditis virus and employ a series of methods to locate, monitor and isolate CNS-infiltrating Tregs free from contamination from the circulation. We show that a distinct population of thymus-derived Tregs accumulates within the cerebrospinal fluid (CSF) of the EMCV-infected CNS, independently of lymph node priming. Tregs function in this unique niche to limit excessive tissue pathology. While CNS Tregs maintain expression of core Treg signature genes, including FoxP3, their global transcriptome is more similar to that of conventional T cells (Tcons) harvested from the infected CNS than to that of peripheral Tregs. Bioinformatics analysis reveals that genes shared by CNS Tcons and CNS Tregs are also shared by Tregs and Tcons from injured muscle and from the visceral adipose tissue of aged mice, indicating that tissue inflammation and injury, rather than viral infection per se, contribute to CNS Treg accumulation, function and phenotype. Additionally, we observe that CNS Treg accumulation during infection is associated with a simultaneous increase in meningeal/choroid plexus dendritic cells (m/chDCs), which are professional antigen presenting cells that localize to the gates of the CNS. Splenic cDC and peripheral lymphoid Treg homeostasis are linked, and both populations can be artificially increased by treatment with the DC-poietin and adjuvant, Ftlt3L. Therefore, we hypothesized that CNS Tregs and m/chDCs may also be linked and could also be manipulated by Flt3L treatment. Indeed, treatment with Flt3L in conjunction with EMCV infection results in enhanced CNS Treg and m/chDC accumulation, independent of Flt3 receptor expression on Tregs. In an effort to determine if dendritic cells mediate CNS Treg increase during infection, we turned to a DC-ablative mouse model in which all CD11c-expressing cells express the catalytic subunit of diphtheria toxin and are depleted. Surprisingly, while splenic cDCs are completely abrogated in these mice, a portion of m/chDCs persists, unaffected. Moreover, CNS Tregs accumulate normally in these mice during infection. This data suggests an unappreciated heterogeneity in m/chDCs, and indicates that those that remain unaffected in these mice may mediate CNS Treg accumulation during infection. While characterizing m/chDC heterogeneity, we found that m/chDCs comprise three distinct subsets with unknown potential. Whereas m/chDCs were previously considered to be a homogeneous, CD45hiB220-CD11c+MHCII+ population, we have found them to contain three subsets, distinguishable by IRF8 and FcR-γ expression. This finding paves the way for further study of the origin, localization, and division of labor between these three m/chDC subsets. In summary, our studies clarify the distinct compartmentalization, lymph node-independent accumulation, and inflammation-associated gene signature of CNS Tregs. Most importantly, these findings have implications for neuro-immune cross-talk, particularly at the interface of the CSF and brain parenchyma. That is, neural progenitors extend their apical domains into the CSF of the ventricles, and therefore may be subject to regulation by CSF-borne Tregs. Further, while many studies have focused on the differences between tissue Treg subsets, we find a core set of genes expressed by CNS Tregs, injured muscle Tregs and VAT Tregs. This data suggests that common mechanisms may be used for therapeutic manipulation of these cells.

T cells--Receptors

Picornaviruses

Immunosuppression

Immunology

T cells

The influence of aryl hydrocarbon receptor activation on T cell fate

Funatake, Castle J.

01 May 2006

2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD) and related compounds are well-recognized for their immunosuppressive activity, which is mediated through an intracellular receptor and transcription factor, aryl hydrocarbon receptor (AhR). Laboratory animals exposed to TCDD are less resistant to infection and have severely impaired humoral and cell-mediated immune responses. This dissertation addressed the hypothesis that exposure to TCDD disrupts early events during the activation of CD4⁺ T cells, leading to their premature loss from the spleen. Initially, ovalbumin (OVA)-specific CD4⁺ T cells from transgenic DO11.10 mice were used to monitor the effects of TCDD on activated antigen-specific T cells. A graft-versus-host (GVH) model, in which T cells from C57B1/6 (B6) mice are injected into C57B1/6 x DBA/2 Fl (Fl) mice, was used to study the role of AhR specifically in the T cells in response to TCDD. B6 donor T cells (from AhR[superscript +/+] or AhR[superscript -/-] mice) respond to DBA/2 antigens in Fl mice and a CD4-dependent CTL response is generated. In both models, exposure to TCDD significantly decreased the number of responding CD4⁺ T cells in the spleen beginning on day 4 after initiation of the response. Exposure to TCDD altered the phenotype of OVA-specific CD4⁺ T cells beginning on day 2 after immunization with OVA. These studies also suggested that apoptosis was not the primary mechanism responsible for the loss of CD4⁺ T cells from the spleen in TCDD-treated mice. Exposure to TCDD induced AhR-dependent changes in the phenotype of B6 donor CD4⁺ T cells such that a subpopulation of CD25⁺ cells was increased in TCDD-treated Fl mice, and these cells had in vitro functional characteristics consistent with regulatory T (Treg) cells. Exposure to TCDD increased the frequency of donor CD4⁺ T cells producing interleukin (IL)-2. In addition, increased expression of CD25 in TCDD-treated mice was correlated with increased signaling through the IL-2 receptor. However, IL-2 alone was not sufficient to mimic the potent immunosuppressive effects of TCDD. These results suggest that TCDD suppresses T cell immunity in part by inducing and/or expanding a subpopulation of Treg cells by a mechanism that may involve IL-2. / Graduation date: 2006

T cells -- Immunology

Tetrachlorodibenzodioxin -- Toxicology

T cells -- Receptors

Spatial Organization of CD28 Modulates T-cell Activation

Chen, Haoqian

January 2016

T-cells are central to our success as a species. They confer specific and long-term immunity in a process known as adaptive immunity. During adaptive immune response, pathogen ingested by peripheral sentinel cells are brought to the local lymph nodes and presented to T-cells. T-cell recognizes the antigen via its receptor complex (TCR-CD3). The high affinity binding primes the cell for activation. With a positive costimulationary signal from CD28, the T-cell is fully activated, resulting in IL-2 secretions and cellular proliferation. Clinicians are increasingly harnessing the adaptive immune system to combat diseases such as cancer. Specifically, T-cells are activated and expanded ex vivo for adoptive immunotherapies. The ability to modulate T-cell activation is crucial in engineering appropriate effector cell populations for therapeutics. The focus of this thesis is to address the functional impact of CD28 spatial organization on T-cell activation. It has been observed that the spatial segregation of CD3 and CD28 by a few microns has resulted in poor activation of human T-cells. Lck, a Src family kinase (SFK) emerges as the instigator of the phenomenon. The kinase is associated with both CD3 and CD28 signal cascades. We propose a reaction diffusion model to describe the delicate balance between protein mobility and Lck de-activation. The work in this dissertation describes two probes to investigate Lck kinase activity, which permit real-time imaging of both the initiation of pLck activity and its duration. A FRET reporter is constructed to study the spatial and temporal initiation of the kinase activity. Embedded with the Lck membrane domain and contained a substrate for pLck to phosphorylate, the FRET biosensor reports the Lck kinase activity in real-time. Using microprinting to control CD3 and CD28 spatial organizations, the FRET reporter reveals that while T-cells require CD28 for significant IL-2 secretion, CD3 engagement is essential to initiate cellular activation through a spike in pLck kinase activity. Spatially, the reporter shows heightened kinase activity concentrated at the center of the cells upon CD3 engagement. To study the duration of pLck activity, a recruitment reporter is made. CD3 is found ubiquitously throughout the cellular membrane. And its activation by pLck induces the recruitment of a pair of tandem SH2-domain. The recruitment probe (also containing a pair of tandem SH2-domain) revealed curtailed pLck kinase activity due to CD3-CD28 segregation. Ultimately, understanding CD28 modulation of T-cell activation is clinically relevant as it provides new opportunities and targets for the development of therapeutics.

Immune response

T cells--Receptors

T cells--Therapeutic use

Biomedical engineering

Mechanisms of immune regulation in HIV disease

Lim, Andrew Yih-Fan

January 2008

[Truncated abstract] HIV infection compromises the ability of the host to mount effective immune responses. In untreated HIV disease, immune activation drives high rates of cell turnover and apoptosis, ultimately leading to abnormal and dysregulated cellular function. Immune activation may also induce the expansion of CD4+ regulatory T (Treg) cell populations capable of suppressing anti-HIV responses. Treatment with antiretroviral therapy (ART) allows the recovery of CD4+ T cell numbers in most patients. Persistent deficiencies in the number and function of CD4+ T cells seen in a proportion of individuals may reflect elevated numbers of Treg cells or an imbalanced regulatory-to-effector cytokine milieu. Furthermore, some patients develop paradoxical illnesses associated with the recovery of cellular function, known as immune restoration disease (IRD). The first part of this thesis addresses the role of CD4+ Treg cells in untreated and treated HIV disease. The second part addresses the phenotype of immune cells that express IL-10 and its receptor in untreated and treated patients, and the role of IL-10 in mycobacterial IRD. Firstly, several cell surface markers were evaluated to find a flow cytometry assay that could be used routinely to identify CD4+ Treg cells in HIV-infected patients. I tested CD25, GITR, CTLA-4, NRP-1 and LAG-3, but their expression did not mirror the expression of FoxP3, an intracellular transcription factor specific to CD4+ Treg cells (Chapter 2). Two published studies then described the use of CD127 to identify CD4+FoxP3+ Treg cells in humans. Using CD127, I determined the proportions and numbers of CD4+ Treg cells in untreated HIV-infected patients and in patients in their first year of ART. Proportions of CD4+ Treg cells correlated with the proportions of activated (HLA-DRHI) CD4+ T cells and with plasma HIV RNA levels in untreated patients, but showed an inverse correlation with CD4+ T cell count. In both untreated and treated patients, the proportions and numbers of FoxP3+ cells that expressed CD8 were significantly higher than in uninfected donors. This was clearest in patients with CD4+ T cell counts below 300/'L (Chapter 3). This body of work suggests that the frequencies of CD4+ Treg cells are directly related to the level of HIV-associated immune activation. Phenotyping of FoxP3+CD4+ Treg cells in untreated and treated patients and in uninfected donors revealed that co-expression of CD45RO, CD28, CTLA-4 and markers of activation were similar in all HIV-infected patients and controls. ii FoxP3+CD8+ T cells exhibit lower levels of CD45RO, CD28 and CTLA-4, but higher expression of PD-1 and CD57 (Chapter 4). This suggests that FoxP3+CD8+ T cells may have a reduced functional capacity. It is unclear whether they have regulatory activity by virtue of FoxP3 expression. ... Both patients produced higher levels of IFN? compared with IL-10 in response to mycobacterial antigens. In contrast, patients who experienced uneventful immune reconstitution produced higher levels of IL-10 (Chapter 6). Part 1 of this thesis highlights the importance of using specific cellular markers to identify CD4+ Treg cells, and confirms CD127 as a valuable marker for routine monitoring of blood Treg cells. Part 2 of this thesis demonstrates the important regulatory role of IL-10 in patients receiving ART.

T cells -- Receptors

AIDS (Disease)

Cellular immunity

HIV infections

Immune response -- Regulation

<>.

Jiang, Ning.

January 2005

Thesis (M. S.)--Biomedical Engineering, Georgia Institute of Technology, 2006. / Committee Chair: Zhu, Cheng; Committee Member: Babensee, Julia; Committee Member: Dustin, Michael; Committee Member: Garcia, Andres; Committee Member: Jo, Hanjoong; Committee Member: van der Merwe, Anton. Part of the SMARTech Electronic Thesis and Dissertation Collection. Non-Latin script record

The effects of Toll-like receptor (TLR) agonists on human nicDC-NK mediated memory/effector T-cell development

Unknown Date

There is compelling evidence that smokers are less responsive to vaccination. We reported that both therapeutic and prophylactic vaccines fail to protect and cure animals from disease due to negative effects of nicotine on DCs’ ability to generate effector T cells. We have been investigating whether vaccine formulated with TLR agonist(s) could potentially overcome the immunosuppressive effects of nicotine on human DC-NK cross-talk essential for effector T cell generation. Monocyte-derived DCs and nicDCs were stimulated with individual and combined TLR agonists prior to co-culture with purified T cells. The phenotypes and cytokine profiles of T cell were assessed using Flow Cytometry and ELISA, respectively. We found nicDCs cultured with TLR-8/7 alone or in combination with TLR-3 produce quantitatively and qualitatively similar IFN-γ producing effector T cells when compared to control DCs. Our data suggest that the addition of appropriate TLR agonist to vaccine formulation could potentially overcome the immunosuppression seen in smokers, thereby containing the spread of infectious disease to vulnerable population / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2015 / FAU Electronic Theses and Dissertations Collection

Cell membranes

Cell receptors

Evidence based medicine

Immune system

Molecular biology

T cells -- Receptors

Tobacco -- Physiological effects

Effects of toll-like receptor 2 ligands on T-cell responses to mite allergen in humans

Taylor, Rebecca Chantelle

January 2007

[Truncated abstract] The last few decades have witnessed an increase in the prevalence, morbidity and economic burden associated with asthma and allergic disease. This rising incidence cannot be completely explained by changes in genetic factors or by improvements in diagnostic procedures. Environmental factors, particularly those associated with a westernised lifestyle, are considered to be involved in this increase. In the late 1980’s Strachan was the first to link environmental factors with allergic disease, this theory became to be known as the ‘hygiene hypothesis’. This hypothesis links the “cleaner” more “healthy ” environment we now live in, with an increased risk of developing allergic disease. This effect is highlighted by studies linking farm and animal exposure (rich in microbial compounds) during early life with a decrease in allergic disease. Since then numerous studies have been undertaken to ascertain the factors present in the microbe rich environment, which elicit this protective effect. Many studies have revolved around endotoxin, however microbial components (mainly from Gram-positive bacteria) which signal through Toll-like receptor 2 (TLR2), have also shown that they can alter the allergic immune response. In mice models TLR2 has been shown to both exacerbate and inhibit allergic disease. The above research highlights the need for further studies into the effect of TLR2 ligands, and to define the mechanisms by which they exert their effects in human allergic disease. These mechanisms will be relevant to understanding the pathogenesis of allergy, but also might provide novel ways to treat allergy. The aims of the study outlined in this thesis were to determine whether in vitro exposure to TLR2 ligands could modify the established immune response to house dust mite allergen (HDM), and to examine the mechanisms by which this occurs. ... The addition of glucocorticoids to LTA enhanced the ability of this TLR2 ligand to inhibit IL-5 and IL-13 production by HDM-activated blood mononuclear cells. In conclusion, this study shows that TLR2 ligands have the ability to inhibit the Th2 response to mite allergen in previously sensitized individuals by an as yet unknown mechanism. However the findings described herein do provide an impetus for future studies designed to uncover novel mechanisms by which allergic responses can be ameliorated, and may open new treatment modalities.

T cells -- Receptors

House dust mites

Asthma -- Pathophysiology

Toll-like receptor (TLR)

Th2 cytokines

Allergy

Atopy

Innate immunity

Thymic stromal cells : population dynamics and their role in thymopoiesis

Gray, Daniel Herbert Donald

January 2003

Abstract not available

T cells -- Differentiation

T cells -- Receptors

Epithelial cells

Thymus -- Immunology

Thymus -- Physiology

Monoclonal antibodies

Cell surface antigens

Lymphocytes

Chemokines -- Receptors

Flow cytometry

Studies On The Roles Of Intracellular Ca2+ And Reactive Oxygen Species During CD4+ T Cell Activation : Influence Of Signal Strength

Ahmed, Asma

07 1900

Optimal CD4+ T cell activation is key to the generation of a productive immune response. Naïve circulating CD4+ T cells are quiescent under normal conditions and undergo activation only upon encounter of the T cell receptor (TCR) with Major Histocompatibility Complex (MHC)-encoded class II molecules on antigen presenting cells (APCs). Processed antigens (derived from pathogens, tumors or self tissue during autoimmunity) in complex with MHC class II are recognized by specific TCRs on CD4+ T cells. After this encounter, the highly complex and regulated process of CD4+ T cell activation results in the differentiation of naïve T cells into effectors and their clonal expansion. Apart from binding to its cognate peptide-MHC-II complex, several other factors define the extent and magnitude of T cell activation. This context is an important determinant of the nature of the subsequent T cell response. One of the factors involved is the strength of the signal (SOS) which is delivered to the cell upon ligation of the TCR to the MHC-peptide complex. The SOS, which can vary from weak to strong, is determined by the affinity/avidity of the TCR for the MHC-peptide complex, antigen concentrations, the duration of engagement, etc. Extreme weak or strong signals can lead to non-productive T cell responses with the former resulting mostly in anergy and the latter in cell death. Signals of optimal strength are the ones that translate into functional T cell responses. However, mechanisms by which signal strength information is translated into distinct T cell responses are still not very well understood. Binding of the TCR to the MHC-peptide complex triggers several signaling cascades and leads to generation of intracellular signaling intermediates, including Ca2+. Rise in intracellular Ca2+ levels is one of the first events to occur upon initiation of T cell activation. The initial increase is brought about due to release of Ca2+ from intracellular smooth endoplasmic reticulum stores. Once intracellular stores have been emptied, the increase is sustained by a process termed as capacitative Ca2+ entry, involving opening of Ca2+ channels in the plasma membrane known as Ca2+ release activated channels (CRACs). Consequently, Ca2+ flows from the extracellular milieu into the cell. A sustained Ca2+ increase is essential for activation of the transcription factor, NF-AT whose primary job is to initiate transcription of IL-2, a cytokine crucial for CD4+ T cell proliferation. The other intracellular signaling intermediates which are the focus of work presented in this study are reactive oxygen species (ROS). TCR signaling leads to generation of ROS, which may be either mitogenic or detrimental to T cell activation. Low levels of ROS, especially H2O2, inactivate phosphatases leading to activation of kinases and signaling pathways resulting in increased proliferation. However, high levels of ROS cause oxidative stress leading to reduced T cell activation, hyporesponsiveness and death. The experimental system used for this study consists of purified mouse lymph node CD4+ T cells. These cells were activated with varying strengths of the primary signal to better understand the roles of Ca2+ and ROS in modulating T cell activation and function. The signal strength was either varied by addition of different concentrations of ionomycin or thapsigargin, pharmacological agents that increase intracellular Ca2+ concentrations. Alternatively, signal through the surface TCR-CD3 complex was initiated using anti-CD3 in two modes: soluble (weak signal) or plate immobilized (strong signal). Increasing concentrations of ionomycin or thapsigargin or changing the mode of anti-CD3 from soluble to plate bound enhances IL-2 amounts, thereby converting a weak signal to a strong one. The work presented has been divided into three parts, each dealing with a distinct aspect of T cell activation. I. SOS and CTLA4-CD80/CD86 interactions: The binding of the TCR to its cognate MHC-peptide complex delivers the primary signal. However, this alone is not sufficient to drive T cell activation and an additional costimulatory signal emanating from the binding of CD28, a constitutively expressed receptor on T cells, to its ligands CD80 and CD86 is required. Another receptor that binds to CD80 and CD86 is CTLA-4 although it does so with a ~100 fold higher affinity. CTLA-4, unlike CD28, is expressed upon T cell activation and is considered to downregulate T cell activation. Its role as a negative regulator is highlighted by the phenotype of Ctla4 -/-mice which die of massive lymphoproliferation. However, there have also been reports of some plasticity in the effects mediated by CTLA-4. Previous work from our laboratory showed that CTLA-4-CD80/CD86 interactions could either inhibit or stimulate T cell activation depending on the SOS. To identify the molecular mediators of the differential effects of CTLA-4, the role of Ca2+ and ROS was evaluated. During activation with phorbol myristate acetate (PMA) and low amounts of ionomycin, intracellular amounts of Ca2+ were greatly reduced upon blockade of CTLA-4-CD80/CD86 interactions. Further experiments demonstrated that CTLA4-CD80/CD86 interactions reduced cell cycling upon activation with PMA and high amounts of ionomycin or thapsigargin (strong SOS) but the opposite occurred with PMA and low amounts of ionomycin or thapsigargin (weak SOS). These results were confirmed by activating cells with anti-CD3 either in the soluble or plate bound form. Considerably higher amounts of intracellular Ca2+ were present in cells activated with plate bound anti-CD3 compared to those activated with soluble anti-CD3. These amounts, further augmented by CTLA-4-CD80/CD86 interactions, probably became toxic to cells as increased proliferation was observed, using reagents that blocked these interactions. The opposite, however, was seen in cells activated with soluble anti-CD3. Also, CTLA4-CD80/CD86 interactions enhanced the generation of ROS. Studies with catalase revealed that H2O2 is required for IL-2 production and cell cycle progression during activation with a weak SOS. However, the high amounts of ROS produced during activation with a strong SOS reduced cell cycle progression. Together, this study identifies intracellular Ca2+ and ROS to play important roles in the modulation of T cell responses by CTLA4-CD80/CD86 interactions. II. SOS and CD4 downregulation: This study was initiated to identify early T cell functional responses that would help predict the strength of the primary signal. Using the in vitro culture system of varying signal strengths, it was found that CD4 surface expression was controlled by signal strength. CD4 is a surface glycoprotein expressed on the TH subset along with the TCR. It performs two main functions: First, binding to MHC class II and strengthening the TCR-MHC interaction, i.e. functioning as a coreceptor. Second, due to its association with p56lck a src family tyrosine kinase, the presence of CD4 along with the TCR enhances signal transduction. Also, CD4 acts as a receptor for entry for the AIDS virus. It is known that CD4 is downregulated from the surface and degraded upon T cell activation by a protein kinase-C dependent process in human and mouse T cells. Experiments presented in this study showed increased CD4 downregulation with a strong signal. The roles of intracellular mediators were assessed and high intracellular Ca2+ amounts, but not PMA activation, was required for sustained CD4 downregulation. Also, increased H2O2 amounts in cells activated with a strong SOS inhibited CD4 downregulation. Most interestingly, the pattern of CD4 downregulation was different between peripheral T cells and thymocytes, suggesting a correlation with CD4+ T cell development. III. Modulation of CD4+ T cell activation by small molecule plant growth regulators: An important area of investigation in T cell biology is the identification of molecules that modulate T cell activation. Towards this end, the mechanisms by which small molecule plant growth regulators, naphthalene acetic acid (NAA), 2,4 dichlorophenoxyacetic acid (2,4D) and indole acetic acid (IAA), influence CD4+ T cell activation was studied. It is useful to recall that IAA is the natural auxin present in plants, NAA is a synthetic auxin and 2,4D is a herbicide. These compounds, but not structurally similar control molecules, increased the activation and IL-2 production in CD4+ T cells activated with either soluble anti-CD3 or a combination of PMA and ionomycin. An investigation into the mechanisms of action by these compounds revealed increased early generation of intracellular ROS and Ca2+. Interestingly, the nature of their effects was found to rely on the strength of the primary signal: IL-2 and proliferation were increased in cells activated with a weak signal, but lowered proliferation was observed in cells activated with a strong signal. Cells activated with strong signal posses high amounts of ROS and Ca2+ and further increase in their amounts by IAA, NAA and 2,4D resulted in growth suppression. However, augmentation of Ca2+ and ROS amounts in cells activated with a weak signal was mitogenic. The role of these compounds during in vivo T cell responses needs to be addressed. Taken together, results presented in this study emphasize the importance of the role of SOS in determining T cell responses. In addition, the roles of Ca2+ and ROS downstream of the primary signal in modulating CD4+ T cell activation were demonstrated.

Signal Transduction

Biomedical Signal Processing

T Cells - Receptors

T Cells - Activation

Reactive Oxygen Species

Major Histocompatibility Complex

T Cell Responses

T Cell Signalling

Biomedical Engineering