Sulfamethoxazole induces a switch mechanism in T cell receptors containing TCRVβ20-1, altering pHLA recognition

T cell receptors (TCR) containing Vβ20-1 have been implicated in a wide range of T cell mediated disease and allergic reactions, making it a target for understanding these. Mechanics of T cell receptors are largely unexplained by static structures available from x-ray crystallographic studies. A small number of molecular dynamic simulations have been conducted on TCR, however are currently lacking either portions of the receptor or explanations for differences between binding and non-binding TCR recognition of respective peptide-HLA. We performed molecular dynamic simulations of a TCR containing variable domain Vβ20-1, sequenced from drug responsive T cells. These were initially from a patient showing maculopapular eruptions in response to the sulfanilamide-antibiotic sulfamethoxazole (SMX). The CDR2β domain of this TCR was found to dock SMX with high affinity. Using this compound as a perturbation, overall mechanisms involved in responses mediated by this receptor were explored, showing a chemical action on the TCR free from HLA or peptide interaction. Our simulations show two completely separate modes of binding cognate peptide-HLA complexes, with an increased affinity induced by SMX bound to the Vβ20-1. Overall binding of the TCR is mediated through a primary recognition by either the variable β or α domain, and a switch in recognition within these across TCR loops contacting the peptide and HLA occurs when SMX is present in the CDR2β loop. Large binding affinity differences are induced by summed small amino acid changes primarily by SMX modifying only three critical CDR2β loop amino acid positions. These residues, TYRβ57, ASPβ64, and LYSβ65 initially hold hydrogen bonds from the CDR2β to adjacent CDR loops. Effects from SMX binding are amplified and traverse longer distances through internal TCR hydrogen bonding networks, controlling the overall TCR conformation. Thus, the CDR2β of Vβ20-1 acts as a ligand controlled switch affecting overall TCR binding affinity.

Mechanism of dendritic epidermal T cell-mediated tolerance induction and inhibition of proliferation

Dendritic epidermal T cells (DETC) comprise a unique population of T cells that reside in mouse epidermis and whose function remains unclear. Most DETC express a $\gamma\delta$ TCR, although some, including our DETC line, AU16, express an $\alpha\beta$ TCR. Additionally, AU16 cells express CD3, Thy-1, CD45, CD28, B7, and AsGM-1. Previous studies in our laboratory demonstrated that hapten-conjugated AU16 could induce specific immunologic tolerance in vivo and inhibit T cell proliferation in vitro. Both these activities are antigen-specific, and the induction of tolerance is non-MHC-restricted. In addition, AU16 cells are cytotoxic to a number of tumor cell lines in vitro. These studies suggested a role for these cells in immune surveillance. The purpose of my studies was to test the hypothesis that these functions of DETC (tolerance induction, inhibition of T cell proliferation, and tumor cell killing) were mediated by a cytotoxic mechanism. My specific aims were (1) to determine whether AU16 could prevent or delay tumor growth in vivo; and (2) to determine the mechanism whereby AU16 induce tolerance, using an in vitro proliferation assay. I first showed that AU16 cells killed a variety of skin tumor cell lines in vitro. I then demonstrated that they prevented melanoma growth in C3H mice when both cell types were mixed immediately prior to intradermal (i.d.) injection. Studies using the in vitro proliferation assay confirmed that DETC inhibit proliferation of T cells stimulated by hapten-bearing, antigen-presenting cells (FITC-APC). To determine which cell was the target, $\gamma$-irradiated, hapten-conjugated AU16 were added to the proliferation assay on d 4. They profoundly inhibited the proliferation of naive T cells to $\gamma$-irradiated, FITC-APC, as measured by ($\sp3$H) TdR uptake. This result strongly suggested that the T cell was the target of the AU16 activity because no APC were present by d 4 of the in vitro culture. In contrast, the addition of FITC-conjugated splenic T cells (SP-T) or lymph node T cells (LN-T) was less inhibitory. Preincubation of the T cells with FITC-AU16 cells for 24 h, followed by removal of the AU16 cells, completely inhibited the ability of the T cells to proliferate in response to FITC-APC, further supporting the conclusion that the T cell was the target of the AU16. Finally, AU16 cells were capable of killing a variety of activated T cells and T cell lines, arguing that the mechanism of proliferation inhibition, and possibly tolerance induction is one of cytotoxicity. Importantly, $\gamma\delta$ TCR$\sp+$ DETC behaved, both in vivo and in vitro like AU16, whereas other T cells did not. Therefore, these results are consistent with the hypothesis that AU16 cells are true DETC and that they induce tolerance by killing T cells that are antigen-activated in vivo. ^

Integrin function in T cell activation recapitulated in tumor growth

An in vitro model using highly purified freshly isolated T cells demonstrated that immobilized ligands for the integrin $\alpha4\beta1$ could cooperate to enhance mitogen signals delivered by coimmobilized anti-CD3 specfic monoclonal antibody OKT3. Costimulation through $\alpha4\beta1$ integrin lead to enhanced proliferation which depended on expression of both IL-2 as well as IL-2 receptor. The transcription factors NF-AT, AP-1, and NF-$\kappa$B, which are involved in the regulation of IL-2 as well as other cytokine genes, were weakly induced by anti-CD3 stimulation alone in electromobility shift assays, but were augmented significantly with $\alpha4\beta1$ costimulation. These results suggested that $\alpha4\beta1$ ligands delivered a growth promoting signal which could synergize with signals induced by engagement of the TCR/CD3 complex, and also suggested a dual function for integrins in both localization and subsequent delivery of a growth promoting signal for T lymphocytes. Integrin involvement in lymphocyte trafficking has been employed as a model for understanding tumor cell metastasis. Therefore we have extended the duality of integrin function in both homing and subsequent delivery of a growth promoting signal to include a role for integrins in providing growth stimulation for tumor cells. Using a gastric derived tumor line, inhibition of adhesion to substrate leads to G0/G1 cell cycle arrest, reduced cyclin A expression, and reduced phospholipid synthesis. This effect could be reversed upon $\alpha2\beta1$ integrin mediated reattachment to collagen. These observations demonstrated a role for an integrin in the growth regulation of a tumor line. The small GTP-binding protein Rho, implicated in phospholipid synthesis, can be inactivated by the ADP-ribosylation exoenzyme C3 from C. botulinum. Addition of C3 to cell cultures inhibited the growth promoting effect due to integrin mediated adhesion. Taken together, these results are consistent with a model for cooperative interaction between integrins and Rho leading to enhanced phospholipid synthesis and mitogen signaling. This model may provide a basis for understanding the phenomena of integrin costimulation in T cell activation. ^

Molecular analysis of the human $\gamma$-chain T cell receptor genes

In our studies we have focused on the issue of variability and diversity of the $\gamma$ (or $\delta)$ chain T cell receptor (TCR) genes by studying cDNA transcripts in peripheral blood mononuclear cells or $\gamma\delta$ TCR+ T cell clones. The significance of these studies lies in the better understanding of the molecular biology of the $\gamma\delta$ T cell receptor as well as in answering the question whether certain molecular forms predominate in $\gamma\delta$ T cells exhibiting specific immunologic functions. We establish that certain $\gamma$-chain TCR genes exhibit particular patterns of rearrangements in cDNA transcripts in normal individuals. V$\gamma$I subgroup were shown to preferentially rearrange to J$\gamma$2C$\gamma$2 gene segments. These preferential VJC rearrangements, may have implications regarding the potential for diversity and polymorphism of the $\gamma$-chain TCR gene. In addition, the preferential association of V$\gamma$I genes with J$\gamma$2C$\gamma$2, which encode a non-disulfide-linked $\gamma\delta$ TCR, suggests that $\gamma$ chains utilizing V$\gamma$I are predominantly expressed as non-disulfide-linked $\gamma\delta$ TCR heterodimers. The implications of this type of expression remain to be determined. We identified two alternative splicing events of the $\gamma$-chain TCR genes occurring in high frequency in all the normal individuals examined. These events may suggest additional mechanisms of regulation and control as well as diversification of $\gamma\delta$ TCR gene expression. The question whether particular forms of $\gamma$ or $\delta$-chain TCR genes are involved in HLA Class I recognition by specific $\gamma\delta$ cytotoxic T cell clones was addressed. Our results indicated that the T cell clones expressed identical $\gamma$ but distinct $\delta$-chains suggesting that the specificity for recognition of HLA-A2 or HLA-A3 may be conferred by the $\delta$-chain TCR. The issue of the degree of diversity and polymorphism of the $\delta$-chain TCR genes in a patient with a primary immunodeficiency (Omenn's syndrome) was addressed. A limited pattern of rearrangements in peripheral blood transcripts was found, suggesting that a limited $\gamma\delta$ TCR repertoire may be expressed in this particular primary immunodeficiency syndrome. Overall, our findings suggest that $\delta$-chain TCR genes exhibit the potential for significant diversity and that there are certain preferential patterns of expression that may be associated with particular immunologic functions. ^

Interaction of small molecules with specific immune receptors: the p-i concept and its consequences

Drugs may stimulate the immune system by forming stable new antigenic complexes consisting of the drug or drug metabolite which is covalently bound to a protein or peptide (hapten-carrier complex). Both, B- and T-cell immunity may arise, the latter directed to hapten modified peptides presented by HLA molecules. Beside this immunological stimulation, drugs can also stimulate the immune system through binding by non-covalent bonds to proteins like immune receptors. This so-called “pharmacological interaction with immune receptors” concept (“p-i concept”) may occur with HLA or TCR molecules themselves (p-i HLA or p-i TCR), and not the immunogenic peptide. It is a type of “off-target” activity of the drug on immune receptors, but more complex as various cell types, cell interactions and functionally different T cells are involved. In this review the conditions which lead to activation of T cells by p-i are discussed: important factors for a functional consequence of drug binding is the location of binding (p-i HLA or p-i TCR); the exact site within these immune receptors; the affinity of binding and the finding that p-i HLA can stimulate the immune system like an allo-allele. The p-i concept is able to solve some puzzles of drug hypersensitivity reactions and are a basis to better treat and potentially avoid drug hypersensitivity reactions. Moreover, the p-i concept shows that in contrast to previous beliefs small molecules do interact with immune receptors with functional consequence. But these interactions are not based on “immune recognition”, are at odds with some immunological concepts, but may nevertheless open new possibilities to understand and even treat immune reactions

Oxypurinol directly and immediately activates the drug-specific T cells via the preferential use of HLA-B*58:01

Allopurinol (ALP) hypersensitivity is a major cause of severe cutaneous adverse reactions and is strongly associated with the HLA-B*58:01 allele. However, it can occur in the absence of this allele with identical clinical manifestations. The immune mechanism of ALP-induced severe cutaneous adverse reactions is poorly understood, and the T cell-reactivity pattern in patients with or without the HLA-B*58:01 allele is not known. To understand the interactions among the drug, HLA, and TCR, we generated T cell lines that react to ALP or its metabolite oxypurinol (OXP) from HLA-B*58:01(+) and HLA-B*58:01(-) donors and assessed their reactivity. ALP/OXP-specific T cells reacted immediately to the addition of the drugs and bypassed intracellular Ag processing, which is consistent with the "pharmacological interaction with immune receptors" (p-i) concept. This direct activation occurred regardless of HLA-B*58:01 status. Although most OXP-specific T cells from HLA-B*58:01(+) donors were restricted by the HLA-B*58:01 molecule for drug recognition, ALP-specific T cells also were restricted to other MHC class I molecules. This can be explained by in silico docking data that suggest that OXP binds to the peptide-binding groove of HLA-B*58:01 with higher affinity. The ensuing T cell responses elicited by ALP or OXP were not limited to particular TCR Vβ repertoires. We conclude that the drug-specific T cells are activated by OXP bound to HLA-B*58:01 through the p-i mechanism.

Influence of muscle fiber orientation on water and metabolite relaxation times, magnetization transfer, and visibility in human skeletal muscle

PURPOSE To gain a deeper understanding of the influence of skeletal muscle fiber orientation on metabolite visibility, magnetization transfer from water, and water proton relaxation rates in (1) H MR spectra. METHODS Non-water-suppressed MR spectroscopy was performed in tibialis anterior muscle (TA) of 10 healthy adults, with the TA oriented either parallel or at the magic angle to the 3T field. Spectra were acquired with metabolite-cycled PRESS, and water inversion from 50 to 2510 ms before excitation. Water proton T2 relaxation was sampled with STEAM with echo times from 12 to 272 ms. RESULTS Apparent concentrations of total creatine (tCr), taurine, and trimethylammonium compounds were reduced by 29% to 67% when TA was parallel to B0 . Both tCr peak areas were strongly correlated to the methylene peak splitting. Magnetization transfer rates from water to tCr CH3 were not significantly different between orientations. Water T1 s were similar between orientations, but T2 s were statistically significantly shorter by 1 ms in the parallel orientation (P = 0.002). CONCLUSION Muscle metabolite visibilities in MR spectroscopy and water T2 times depend substantially on muscle fiber orientation relative to B0 . In contrast, magnetization transfer rates appear to depend on muscle composition, rather than fiber orientation. Magn Reson Med, 2015. © 2015 Wiley Periodicals, Inc.

Mutation of the ER retention receptor KDELR1 leads to cell-intrinsic lymphopenia and a failure to control chronic viral infection

Endoplasmic reticulum (ER)-resident proteins are continually retrieved from the Golgi and returned to the ER by Lys-Asp-Glu-Leu (KDEL) receptors, which bind to an eponymous tetrapeptide motif at their substrate's C terminus. Mice and humans possess three paralogous KDEL receptors, but little is known about their functional redundancy, or if their mutation can be physiologically tolerated. Here, we present a recessive mouse missense allele of the prototypical mammalian KDEL receptor, KDEL ER protein retention receptor 1 (KDELR1). Kdelr1 homozygous mutants were mildly lymphopenic, as were mice with a CRISPR/Cas9-engineered frameshift allele. Lymphopenia was cell intrinsic and, in the case of T cells, was associated with reduced expression of the T-cell receptor (TCR) and increased expression of CD44, and could be partially corrected by an MHC class I-restricted TCR transgene. Antiviral immunity was also compromised, with Kdelr1 mutant mice unable to clear an otherwise self-limiting viral infection. These data reveal a nonredundant cellular function for KDELR1, upon which lymphocytes distinctly depend.

Drug Hypersensitivity: How Drugs Stimulate T Cells via Pharmacological Interaction with Immune Receptors.

Small chemicals like drugs tend to bind to proteins via noncovalent bonds, e.g. hydrogen bonds, salt bridges or electrostatic interactions. Some chemicals interact with other molecules than the actual target ligand, representing so-called 'off-target' activities of drugs. Such interactions are a main cause of adverse side effects to drugs and are normally classified as predictable type A reactions. Detailed analysis of drug-induced immune reactions revealed that off-target activities also affect immune receptors, such as highly polymorphic human leukocyte antigens (HLA) or T cell receptors (TCR). Such drug interactions with immune receptors may lead to T cell stimulation, resulting in clinical symptoms of delayed-type hypersensitivity. They are assigned the 'pharmacological interaction with immune receptors' (p-i) concept. Analysis of p-i has revealed that drugs bind preferentially or exclusively to distinct HLA molecules (p-i HLA) or to distinct TCR (p-i TCR). P-i reactions differ from 'conventional' off-target drug reactions as the outcome is not due to the effect on the drug-modified cells themselves, but is the consequence of reactive T cells. Hence, the complex and diverse clinical manifestations of delayed-type hypersensitivity are caused by the functional heterogeneity of T cells. In the abacavir model of p-i HLA, the drug binding to HLA may result in alteration of the presenting peptides. More importantly, the drug binding to HLA generates a drug-modified HLA, which stimulates T cells directly, like an allo-HLA. In the sulfamethoxazole model of p-i TCR, responsive T cells likely require costimulation for full T cell activation. These findings may explain the similarity of delayed-type hypersensitivity reactions to graft-versus-host disease, and how systemic viral infections increase the risk of delayed-type hypersensitivity reactions.

Constitutive IL-2 mRNA expression in lymphocytes, infected with the intracellular parasite Theileria parva.

Theileria parva-infected lymphoblastoid cell lines of T or B cell origin were examined for IL-2 mRNA expression. T. parva-infected T cell lines could be of the CD4-CD8-, CD4+CD8-, CD4-CD8+, or CD4+CD8+ phenotype and express alpha beta or gamma delta TCR. By Northern blot analysis and amplification by the polymerase chain reaction, IL-2 mRNA could be detected in all T. parva-infected cell lines tested. IL-2 mRNA expression was also shown to be dependent on the continuous presence of the parasite in the host cell cytoplasm, because elimination of the parasite by treatment of T. parva-infected cell cultures with the theilericidal drug BW720c resulted in the disappearance of detectable IL-2 mRNA. The effect of anti-IL-2 antibodies on the proliferation of T. parva-infected cells was also tested. Inhibition experiments suggest that although IL-2 mRNA can be detected in all cell lines tested, not all T. parva-infected cell lines are dependent on IL-2 for their proliferation. Our data provide the first example for the constitutive expression of IL-2 mRNA in T and B cells caused by infection with an intracellular parasite.

Immune restoration of patients with chronic myelogenous leukemia in complete cytogenetic remission

Imatinib mesylate (IM) and Interferon-alfa (IFN-α) are currently the two most efficacious therapies for patients with chronic myelogenous leukemia (CML). IFN-α induces durable complete cytogentic remission (CCR) in about 25% of CML patients whereas IM, a tyrosine kinase inhibitor, induces CCR in 50% of patients who are resistant to IFN-α and in 75% of patients in early chronic phase of CML. However, the detection of minimal residual disease without clinical relapse suggests that host immune surveillance plays a very important role in controlling the progression of disease. ^ T lymphocytes and dendritic cells (DC) are the two most crucial players in the immune system. In my study, we focused on the effects of treatment with either IM or IFN-α on the functions of both DC and T cells, as exemplified by the ability of DC to present antigen to T cells and activated T cells to synthesize cytokines. Our studies show that cytokine production by T cells activated through the T-cell receptor (TCR) was significantly lower in CML patients treated with IM, but not with IFN-α, when compared with activated T cells of control subjects. Suppression of T cell function by IM albeit transient and reversible, was through the downregulation of the phosphorylation of Zap-70, Lck, and LAT. ^ Our data also show that the myeloid DC (DC1) and the plasmacytoid DC (DC2) are lower in chronic phase CML. Whereas neither therapy restored the level of DC2 to normal levels, the number of DC1 was normalized by either therapy. However, only IFN-α, and not IM, restored DC2 function to normal, as exemplified by the production of IFN-α in response to exposure to live influenza virus. Moreover, in vitro differentiation and maturation of DC1 from monocyte precursors in patients receiving either therapy was not normal and was reflected in their ability to present antigen to autologous T cells. ^ In summary, we report that there are differences in immune responses of CML patients treated with IM or IFN-α that may be the result of long-term effects on the host immune system by the individual therapy. ^

The roles of UPF3a and UPF3b in nonsense mediated decay

Nonsense-mediated decay (NMD) degrades aberrant transcripts containing premature termination codons (PTCs). The T-cell receptor (TCR) locus undergoes error-prone rearrangements that frequently acquire PTCs. Transcripts harboring PTCs from this locus are downregulated much more than transcripts from non-rearranging genes. Efficient splicing is essential for this robust downregulation. ^ Here I show that TCR NMD is unique in another respect: it is not impaired by RNAi-mediated depletion of the NMD factor UPF3b. This differentiates TCR transcripts from classical NMD (assayed using β-globin or triose phosphate isomerase transcripts), which does depend on UPF3b. Depletion of UPF3a, which encodes a gene related to UPF3b, also had no effect on TCR NMD. Mapping experiments identified TCR sequences that when deleted or mutated caused a switch to UPF3b dependence. Since UPF3b dependence was invariably accompanied by less efficient RNA splicing, this suggests that UPF3b-dependent NMD occurs when transcripts are generated by inefficient splicing. Microarray analysis revealed the existence of many NMD-targeted mRNAs from wild-type genes whose downregulation is impervious to UPF3b depletion. This suggests the existence of an alternative NMD pathway independent of UPF3b that is widely used to downregulate the level of both normal and mutant transcripts. ^ During the course of my studies, I also found that the function of UPF3a is fundamentally distinct from that of UPF3b in several aspects. First, classical NMD failed to be impaired by UPF3a depletion, whereas it was reversed by UPF3b depletion. Second, UPF3a depletion had no effect on NMD elicited by tethered UPF2, whereas UPF3b depletion blocked this response. Thus, UPF3a does not function in classical NMD. Third, UPF3b depletion upregulated the expression of UPF3a, whereas UPF3a depletion had no effect on UPF3b expression. This suggests that a UPF3b-mediated feedback network exists that regulates the UPF3a expression. Lastly, UPF3a depletion but not UPF3b depletion significantly upregulated TCR precursor RNAs. This suggests that UPF3a, not UPF3b, functions in the surveillance of precursor RNAs, which typically contain many PTCs in the introns. Collectively, my data suggests that UPF3a and UPF3b are not functionally redundant, as previously thought, but instead have separable functions. ^

Regulation of RNA splicing by nonsense mutations

Translation termination as a result of premature nonsense codon-incorporation in a RNA transcript can lead to the production of aberrant proteins with gain-of-function or dominant negative properties that could have deletrious effects on the cell. T-cell Receptor (TCR) genes acquire premature termination codons two-thirds of the time as a result of the error-prone programmed rearrangement events that normally occur during T-cell development. My studies have focused on the fate of TCR precursor mRNAs in response to in-frame nonsense mutations. ^ Previous published studies from our laboratory have shown that TCR precursor mRNAs are subject to nonsense mediated upregulation of pre-mRNA (NMUP). In this dissertation, I performed substitution and deletion analysis to characterize specific regions of TCR which are required to elicit NMUP. I performed frame- and factor-dependence studies to determine its relationship with other nonsense codon induced responses using several approaches including (i) translation dependence studies (ii) deletion and mutational analysis, as well as (iii) siRNA mediated knockdown of proteins involved. I also addressed the underlying molecular mechanism for this pre-mRNA upregulation by (i) RNA half-life studies using a c-fos inducible promoter, and (ii) a variety of assays to determine pre-mRNA splicing efficiency. ^ Using these approaches, I have identified a region of TCR that is both necessary and sufficient to elicit (NMUP). I have also found that neither cytoplasmic translation machinery nor the protein UPF1 are involved in eliciting this nuclear event. I have shown that the NMUP can be induced not only by nonsense and frameshift mutations, but also missense mutations that disrupt a cis splicing element in the exon that contains the mutation. However, the effect of nonsense mutations on pre-mRNA is unique and distinguishable from that of missense mutations in that nonsense mutations can upregulate pre-mRNA in a frame-dependent manner. Lastly, I provide evidence that NMUP occurs by a mechanism in which nonsense mutations inhibit the splicing of introns. In summary, I have found that TCR precursor mRNAs are subject to multiple forces involving both RNA splicing and translation that can either increase or decrease the levels of these precursor mRNAs. ^

Characterization of tumor-associated Foxp3+ regulatory T cells and de-novo induction by the tumor microenvironment

Regulatory T cells expressing the fork-head box transcription factor 3 (Foxp3) play a central role in the dominant control of immunological tolerance. Compelling evidence obtained from both animal and clinical studies have now linked the expansion and accumulation of Foxp3+ regulatory T cells associated with tumor lesions to the failure of immune-mediated tumor rejection. However, further progress of the field is hampered by the gap of knowledge regarding their phenotypic, functional, and the developmental origins in which these tumor-associated Foxp3+ regulatory T cells are derived. Here, we have characterized the general properties of tumor-associated Foxp3+ regulatory T cells and addressed the issue of tumor microenvironment mediated de-novo induction by utilizing a well known murine tumor model MCA-205 in combination with our BAC Foxp3-GFP reporter mice and OT-II TCR transgenic mice on the RAG deficient background (RAG OT-II). De-novo induction defines a distinct mechanism of converting non-regulatory precursor cells to Foxp3+ regulatory T cells in the periphery as opposed to the expansion of pre-existing regulatory T cells formed naturally during thymic T cell development. This mechanism is of particularly importance to how tumors induce tumor-antigen-specific suppressor cells to subvert anti-tumor immune responses. Our study has found that tumor-associated Foxp3+ regulatory T cells are highly activated, undergo vigorous proliferation, are more potent by in-vitro suppression assays, and express higher levels of membrane-bound TGF-β1 than non-tumor regulatory T cells. With Foxp3-GFP reporter mice or RAG OT-II TCR transgenic mice, we show that tumor tissue can induce detectable de-novo generation of Foxp3+ regulatory T cells of both polyclonal or antigen specific naïve T cells. This process was not only limited for subcutaneous tumors but for lung tumors as well. Furthermore, this process required the inducing antigen to be co-localized within the tumor tissue. Examination of tumor tissue revealed an abundance of myeloid CD11b+ antigen-presenting cells that were capable of inducing Foxp3+ regulatory T cells. Taken together, these findings elucidate the general attributes and origins of tumor-associated Foxp3+ regulatory T cells in the tumor microenvironment and in their role in the negative regulation of tumor immunity.^

cAMP regulates IL-2 receptor signaling in human T cells

Proper immune system function is dependent on positive and negative regulation of T cell signaling pathways. Full T cell activation requires sequential signaling through the T cell receptor (TCR), costimulatory molecules and the IL-2 receptor (IL-2R). The IL-2R associated Janus tyrosine kinase 3 (Jak3), as well as Signal transducer and activator of transcription 5 (Stat5), are required for normal T cell function and survival. Constitutive activation of Jak3 and Stat5 have been linked to cancers of hematopoietic origin, including certain lymphomas and leukemias. ^ The production of cAMP by adenylate cyclase has been shown to negatively regulate human TCR mediated cell proliferation. Since cAMP has been shown to negatively regulate T cell activation, we sought to investigate whether crosstalk exists between cAMP and IL-2R signaling. The first objective of this study was to determine the effect of cAMP on the activation of IL-2R signaling molecules Jak3 and Stat5. We found that the potent adenylate cyclase activator, forskolin, inhibited IL-2 activation of Jak3 and Stat5. Indeed, in vitro kinase assays and electrophoretic mobility shift assays verified a loss of Jak3 enzymatic activity and Stat5 DNA binding ability, respectively. Further analysis of IL-2R signaling showed that forskolin treatment reduced IL-2 induced association of the IL-2Rβ and γc chain. ^ Because cAMP activates protein kinase A (PKA), the second objective was to determine the role for PKA in the cAMP directed regulation of IL-2R signaling intermediates. Interestingly, forskolin induced serine phosphorylation of Jak3, suggesting that cAMP can directly regulate Jak3 via activation of a serine/threonine kinase. Indeed, phosphoamino acid analysis revealed that PKA was able to induce Jak3 serine phosphorylation in the human leukemia cell line MT-2. In addition, in vitro kinase assays established that PKA can directly inhibit Jak3 enzymatic activity. Collectively, these data indicate that cAMP negatively regulates IL-2R signaling via various effector molecules by a previously unrecognized mechanism. This new data suggests that the Jak3/Stat5 pathway may be regulated by various pharmacological agents that stimulate cAMP production and thus can be used to uncouple some types of T cell mediated diseases. ^