Detection of perforin and granzyme A mRNA in infiltrating cells during infection of mice with lymphocytic choriomeningitis virus

The analysis of gene expression in cytotoxic T cells by in situ hybridization of serial liver and brain sections from mice infected with lymphocytic choriomeningitis virus (LCMV) and immunostaining with T cell marker- and virus-specific antibodies revealed a close histological association of infiltrating lymphocytes expressing the perforin and granzyme A genes with virally infected cells. Maximal frequency of perforin and granzyme A mRNA-containing cells on liver sections preceded by about 2 days maximal LCMV-specific cytotoxicity of the lymphoid liver infiltrating cells. These results are most consistent with an involvement of perforin and granzyme A in cell-mediated cytotoxicity in vivo.     

Tissue-specific segregation of TCRgamma delta+ NKT cells according to phenotype TCR repertoire and activation status: parallels with TCR alphabeta+NKT cells

Whereas the majority of NKT cells in the mouse express an alpha beta TCR (NKTalpha beta cells), a small subset of NKT cells express a gamma delta TCR (NKTgamma delta). Here we have systematically analyzed the phenotype, TCR repertoire and activation status of NKTgamma delta cells in the thymus, liver, spleen and bone marrow of normal C57BL/6 mice. Our data indicate that NKTgamma delta cells segregate in a tissue-specific manner according to these parameters. While most NKTgamma delta cells in the thymus and liver have a recently activated CD62L(lo) phenotype and a TCR repertoire that is heavily biased to Vgamma1.1 and Vdelta6.3, the majority of NKTgamma delta cells in the spleen and bone marrow are CD62L(hi) and have a much less biased TCR repertoire. Moreover, expression of NK markers is high on NKTgamma delta cells in spleen and bone marrow but low in thymus and liver. Collectively our results reveal a tissue-specific segregation of NKTgamma delta cells that is strikingly similar to that recently described for CD1d-dependent and Cd1d-independent NKTalpha beta cells. We therefore propose that chronic TCR activation by tissue-specific endogenous ligands is a generic property of NKT cells of both the alpha beta and gamma delta lineages.     

Favorably tipping the balance between cytopathic and regulatory T cells to create transplantation tolerance

Therapeutic application of broadly reactive anti-T cell antibodies can lead not only to potent immunosuppression but also to profound and long-lived T cell depletion. We reasoned that a strategy that almost exclusively targets activated cytopathic donor reactive T cells and spares immunoregulatory networks might prove to be an exceptionally potent and highly selective means of producing long-term engraftment and tolerance. Herein we show that the combined administration of rapamycin and agonist IL-2- and antagonist IL-15-related cytolytic fusion proteins provides for long-term engraftment/tolerance in exceptionally stringent allotransplant models by (1) limiting the early expansion of activated T cells, (2) preserving and even exaggerating their subsequent apoptotic clearance, and (3) further amplifying the depletion of these activated T cells by antibody-dependent mechanisms, while (4) preserving CD4+CD25+ T cell-dependent immunoregulatory networks.     

Kinetic fluorescence RT-PCR is highly sensitive for detection of germ-cell-tumor-specific transcripts in peripheral blood

The aim of our study was to determine whether conventional staging in patients with testicular germ-cell-tumors (GCT) could be supplemented by quantification of beta-human choriogonadotropin mRNA levels in peripheral blood using kinetic fluorescence RT-PCR. Blood samples from 41 patients with GCT of different clinical stages (CS) were pre-therapeutically examined by kinetic fluorescence RT-PCR with the LightCycler for beta-human chorionic gonadotropin (beta-HCG) mRNA expression levels. The controls comprised of samples taken from patients 3 months after treatment, from patients with inflammatory testicular diseases or non-germ-cell-tumors and from healthy males (n=66). Six positive results [cut-off level: normalized beta-HCG mRNA (Nbeta-HCG) >400 relative gene expression (RGE)] were found in controls (specificity 90.9%, 95% CI: 76.9-97.3%). The overall ratio of positive PCR results in the group of GCT patients was 82.92% (34/41) (CS I 18/23, CS IIa-b 6/7, CS >IIb 10/11) (sensitivity 82.9%, 95% CI: 65.1-91.2%). The average Nbeta-HCG level in patients with clinical stage I tumors was 63772.0+/-125720.5 (mean +/- standard deviation) relative gene expression (RGE), 35076.0+/-52253.5 RGE in those with CS IIa-b tumors and 87298.3+/-120895.3 RGE in those with CS >IIb tumors. Kinetic fluorescence RT-PCR for tumor-specific gene products is, in contrast to qualitative RT-PCR, a promising approach to improve conventional staging in clinical low-stage testicular germ-cell-tumors. With high specificity, its sensitivity is higher than that of the corresponding serum tumor marker (82.92% vs 48.72%).     

Human T lymphocyte activation induces tyrosine phosphorylation of α-tubulin and its association with the SH2 domain of the p59fyn protein tyrosine kinase

A glutathione-S-transferase-src-homology domain 2 (GST-SH2) fusion protein was employed to identify molecules interacting with the protein tyrosine kinase p59^fyn. Among several proteins which bound to the fyn SH2 domain in lysates of human Jurkat T lymphocytes, α- and β-tubulin were identified by N-terminal sequencing. Further analysis established that α-tubulin exists as a tyrosine-phosphorylated protein in Jurkat cells, where it interacts with p59^fyn, but not with p56^lck. By contrast, in untransformed resting human T lymphocytes α-tubulin is not detectable as a tyrosine phosphorylated protein. However, following T cell activation, it becomes rapidly phosphorylated on tyrosine residues and subsequently associates with the SH2 domain of fyn. Interestingly, constitutively tyrosine-phosphorylated α-tubulin that is able to interact with the fyn-SH2 domain is expressed in peripheral blood T lymphoblasts isolated from leukemic patients in the absence of external stimulation.     

Activation of the endothelium by IL-1 alpha and glucocorticoids results in major increase of complement C3 and factor B production and generation of C3a.

Constitutive secretion of complement C3 and factor B by the endothelial cell (EC) is lowered by therapeutic concentrations of glucocorticoids such as hydrocortisone or dexamethasone, whereas regulatory protein factor H production is increased by these hormones. In contrast, the proinflammatory cytokine IL-1 alpha has a stimulatory effect on C3 and factor B secretion by the endothelium and an inhibitory effect on factor H secretion. In this study, we examined the combined effect of IL-1 alpha and glucocorticoids on C3 and factor B expression by the endothelial cell. When dexamethasone or hydrocortisone were added to IL-1 alpha, significant potentialization of IL-1 alpha-induced stimulation of C3 and factor B production was observed, occurring at various concentrations of either stimuli. Dose-response experiments indicate that, in vitro, optimal concentrations are in the range of 10(-7) to 10(-5) M for dexamethasone and 50-200 U for IL-1 alpha. In contrast, dexamethasone counteracts, in an additive way, the inhibitory effect of IL-1 alpha on regulatory complement protein factor H production by EC. Such a potentialization between glucocorticoids and IL-1 alpha was not observed for another marker of endothelial activation, IL-1 alpha-induced stimulation of coagulation tissue factor expression. The association of glucocorticoids and IL-1 alpha therefore appears to be a specific and major stimulus for the secretion of complement C3 and factor B, two acute-phase proteins, by the endothelium. As a result of the in vitro endothelium stimulation by glucocorticoids and IL-1 alpha, C3a is generated in the vicinity of the endothelial cell. This study further suggests that complement activation, with its deleterious consequences, may result from the stimulation of endothelium in situations where high levels of IL-1 alpha and endogenous glucocorticoids coexist, such as in septic shock.     

Tumor necrosis factor-mediated inhibition of interleukin-18 in the brain: a clinical and experimental study in head-injured patients and in a murine model of closed head injury.

Tumor necrosis factor (TNF) and interleukin-(IL)-18 are important mediators of neuroinflammation after closed head injury (CHI). Both mediators have been previously found to be significantly elevated in the intracranial compartment after brain injury, both in patients as well as in experimental model systems. However, the interrelation and regulation of these crucial cytokines within the injured brain has not yet been investigated. The present study was designed to assess a potential regulation of intracranial IL-18 levels by TNF based on a clinical study in head-injured patients and an experimental model in mice. In the first part, we investigated the interrelationship between the daily TNF and IL-18 cerebrospinal fluid levels in 10 patients with severe CHI for up to 14 days after trauma. In the second part of the study, the potential TNF-dependent regulation of intracerebral IL-18 levels was further characterized in an experimental set-up in mice: (1) in a standardized model of CHI in TNF/lymphotoxin-alpha gene-deficient mice and wild-type (WT) littermates, and (2) by intracerebro-ventricular injection of mouse recombinant TNF in WT C57BL/6 mice. The results demonstrate an inverse correlation of intrathecal TNF and IL-18 levels in head-injured patients and a TNF-dependent inhibition of IL-18 after intracerebral injection in mice. These findings imply a potential new anti-inflammatory mechanism of TNF by attenuation of IL-18, thus confirming the proposed "dual" function of this cytokine in the pathophysiology of traumatic brain injury.