Activation-induced apoptosis of mature T cells is dependent upon the level of surface TCR but not on the presence of the CD3 zeta ITAM

Activation-induced cell death (AICD) occurs primarily in recently activated T cells after a second TCR triggering. Since a threshold in the activation status may be critical for AICD, it is likely that the CD3 ITAM, docking sites for tyrosine kinases, regulate AICD. A 'threshold model' for AICD was tested by using two targeted mutant mouse strains lacking either the zeta chain (CD3zeta-/-) or the ITAM of the zeta chain (CD3zeta-/-:Tgzetadelta67-150). Although the T cells from the CD3zeta-/- mice express extremely low levels of surface TCR, a subpopulation (approximately 18%) of activated T cells could be induced to express TCR/FcepsilonRI gamma by using a powerful polyclonal activation protocol. These activated TCR/FcRI gamma T cells were capable of undergoing AICD, but its induction required 10 times as much anti-CD3epsilon mAb as that required for AICD of wild-type T cells. Thus, the intensity of AICD correlated with the level of CD3 expression and was less efficient with activated, CD3zeta(-/-)-derived T cells. By contrast, AICD of T cells from the CD3zeta-/-:Tgzetadelta67-150 mice could be induced with low doses of anti-CD3epsilon mAb and the extent of AICD was comparable to T cells from wild-type mice. The AICD induced in T cells from CD3-/-, CD3zeta-/-:Tgzetadelta67-150 and normal controls was specifically inhibited by Fas-Ig fusion proteins. Our data support the 'threshold model' of AICD by demonstrating that AICD is controlled by the strength of T cell activation.     

CD38 is functionally dependent on the TCR/CD3 complex in human T cells

One of the functions of surface CD38 is the induction of phosphorylation of discrete cytoplasmic substrates and mobilization of cytoplasmic calcium (Ca2+). The present work addresses the issue of whether the signaling mediated via CD38 operates through an independent pathway or, alternatively, is linked to the TCR/CD3 signaling machinery. We studied the signals elicited through CD38 by the specific agonistic IB4 monoclonal antibody (mAb) by monitoring the levels of cytoplasmic Ca2+ and the induced phenotypic and functional variations in T cell growth. IB4 mAb presented the unique ability to increase cytoplasmic Ca2+ levels, which correlated with the phosphorylation of the PLC-gamma1. These effects were blocked by phorbol 12-myristate 13-acetate (PMA) and were dependent on the presence of a functional TCR/CD3 surface complex, no effects being recorded on mutant Jurkat cells lacking part of the CD3 structures. CD38 signaling appeared to share with TCR/CD3 the ability to induce apoptotic cell death in Jurkat T cells, an event paralleled by specific up-regulation of the Fas molecule and inhibited by cyclosporin A. CD28, a costimulatory molecule, is synergized by increasing CD38-induced apoptotic cell death. The results indicate the existence of a strong functional interdependence between CD38 and TCR/CD3.     

TCR selection and allelic exclusion in RAG transgenic mice that exhibit abnormal T cell localization in lymph nodes and lymphatics

RAG-1 and RAG-2 are developmentally regulated genes that are essential for V(D)J recombination and lymphocyte development. Expression of RAG-1 and RAG-2 by thymocytes is normally limited to cells that have not completed selection. We have previously documented that persistent expression of the recombinase activating genes (RAG) in transgenic mice results in aberrant thymic development, altered lymphatic microanatomy, and a profound immunodeficiency. Here we further document the pathologic changes found in TG.RAG-1,2 mice and examine the role of TCR recombination and positive and negative thymic selection, as well as allelic exclusion, in the etiology of the phenotype. We find that neither selection nor TCR allelic exclusion can be overcome by transgenic expression RAG-1 and RAG-2 under the control of an lck promoter.     

MHC class II transport from lysosomal compartments to the cell surface is determined by stable peptide binding, but not by the cytosolic domains of the alpha- and beta-chains

Inside APCs, MHC class II molecules associate with antigenic peptides before reaching the cell surface. This association takes place in compartments of the endocytic pathway, more related to endosomes or lysosomes depending on the cell type. Here, we compared MHC class II transport from endosomal vs lysosomal compartments to the plasma membrane. We show that transport of MHC class II molecules to the cell surface does not depend on the cytosolic domains of the alpha- and beta-chains. In contrast, the stability of the alphabeta-peptide complexes determined the efficiency of transport to the cell surface from lysosomal, but not from endosomal, compartments. In murine B lymphoma cells, SDS-unstable and -stable complexes were transported to the cell surface at almost similar rates, whereas after lysosomal relocalization or in a cell line in which MHC class II molecules normally accumulate in lysosomal compartments, stable complexes were preferentially addressed to the cell surface. Our results suggest that when peptide loading occurs in lysosomal compartments, selective retention and lysosomal degradation of unstable dimers result in the expression of highly stable MHC class II-peptide complexes at the APC surface.     

Cooperative interaction between alpha- and beta-chains of hepatocyte growth factor on c-Met receptor confers ligand-induced receptor tyrosine phosphorylation and multiple biological responses

Hepatocyte growth factor (HGF) is a heterodimeric molecule composed of the alpha-chain containing the N-terminal hairpin domain, four kringle domains, and the serine protease-like beta-chain. We prepared HGF/NK4 and HGF/beta from the entire HGF after single-cut digestion with elastase. HGF/NK4 contains the N-terminal hairpin and four kringle domains, while HGF/beta is composed of the C-terminal 16 amino acids of the alpha-chain and the entire beta-chain, linked by a disulfide bridge. HGF/NK4 competitively inhibited the binding of 125I-HGF to the receptor, and affinity cross-linking analysis indicated that HGF/NK4 alone can bind to the c-Met receptor. In contrast, HGF/beta alone did not competitively inhibit the binding of 125I-HGF to the receptor and did not bind to the c-Met/HGF receptor. Scatchard analysis and affinity cross-linking experiments indicated that HGF/beta specifically binds to c-Met in the presence of HGF/NK4 but not HGF/NK2. Neither HGF/NK4 nor HGF/beta alone induced mitogenic, motogenic (cell scattering), and morphogenic (induction of branching tubulogenesis) responses; however, HGF/beta did induce these biological responses in the presence of HGF/NK4. Consistent with these results, although neither HGF/NK4 alone nor HGF/beta alone induced tyrosine phosphorylation of the c-Met/HGF receptor, HGF/beta induced tyrosine phosphorylation of the receptor when c-Met/HGF receptor was occupied by HGF/NK4. These results indicate that HGF/beta binds to the c-Met/HGF receptor that is occupied by HGF/NK4 and induces receptor tyrosine phosphorylation and the subsequent biological activities of HGF. We propose that there exists a unique cooperative interaction between alpha- and beta-chains, this interaction leading to beta-chain-dependent receptor tyrosine phosphorylation and subsequent biological responses.     

Cloning of the novel gene intelectin, which is expressed in intestinal paneth cells in mice

OBJECTIVE: The purpose of our study was to assess the accuracy of CT-guided biopsy of musculoskeletal neoplasms with respect to technique, anatomic site, and histology. MATERIALS AND METHODS: During a 3-year period (January 1992 to December 1994), 176 core needle biopsies and 45 fine-needle aspirations were performed under CT guidance on patients with musculoskeletal neoplasms. To assess the accuracy of these procedures, we compared the diagnosis at biopsy with the final diagnosis as determined at the time of definitive treatment of the lesion. All biopsy findings were categorized as a primary malignancy (excluding round cell lesions), round cell lesion, local recurrence, or metastatic carcinoma. In addition, each lesion was analyzed according to which biopsy technique was used, whether frozen tissue section or rapid cytologic evaluation was used, and at which anatomic site the mass was found. RESULTS: The accuracy for needle biopsy was 93% and that for fine-needle aspiration was 80%. The complication rate for both techniques was less than 1%. Accuracy rates for the four categories of primary malignancy, round cell lesion, local recurrence, and metastatic carcinoma were 87%, 75%, 94%, and 100%, respectively. The mismatch rates were similar in soft-tissue lesions (5/52) and bone lesions (16/169). Diminished accuracy was associated with round cell lesions (20%) and lesions located in the spine or the perivertebral region (20%). Nondiagnostic and insufficient specimens were found in 18 (8%) of the 221 patients. CONCLUSION. CT-guided biopsy of musculoskeletal malignancies is a safe and effective procedure if performed by a team of clinicians, pathologists, and radiologists who possess subspecialty expertise.     

Vaccination with BV8S2 protein amplifies TCR-specific regulation and protection against experimental autoimmune encephalomyelitis in TCR BV8S2 transgenic mice

TCR determinants overexpressed by autopathogenic Th1 cells can naturally induce a second set of TCR-specific regulatory T cells. We addressed the question of whether immune regulation could be induced naturally in a genetically restricted model in which a major portion of TCR-specific regulatory T cells expressed the same target TCR BV8S2 chain as the pathogenic T cells specific for myelin basic protein (MBP). We found vigorous T cell responses to BV8S2 determinants in naive mice that could be further potentiated by vaccination with heterologous BV8S2 proteins, resulting in the selective inhibition of MBP-specific Th1 cells and protection against experimental encephalomyelitis. Moreover, coculture with BV8S2-specific T cells or their supernatants reduced proliferation, IFN-gamma secretion, and encephalitogenic activity of MBP-specific T cells. These results suggest that immune regulation occurs through a nondeletional cytokine-driven suppressive mechanism.     

The glutathione level of retinal Müller glial cells is dependent on the high-affinity sodium-dependent uptake of glutamate

The dependence of intracellular glutathione, an important radical scavenger, on the extracellular glutamate and cystine concentration and the velocity of the high affinity sodium/glutamate transporter was studied in freshly-isolated Müller glial cells of the guinea-pig, kept in vitro for up to 11 h. To this end the relative Müller cell glutathione levels were measured using the fluorescent dye monochlorobimane, using different concentrations of glutamate and cystine in Ringer solution. In some experiments L-buthionine-[S,R]-sulfoximine, a blocker of glutathione synthesis, or L-trans-pyrrolidine-2,4-dicarboxylic acid and L-alpha-aminoadipic acid, inhibitors of glutamate uptake, were added. The Müller cells maintained about 80% of the normal glutathione level when maintained in Ringer solution containing 100 microM glutamate for 11 h. When under these conditions 100 microM cystine was added, the glutathione level increased to values, which were even higher than those at the beginning of the incubation period. Addition of cystine without glutamate caused a run down of the glutathione level to about 45% of the normal level, which is comparable to the run down in pure Ringer solution. Likewise, application of L-buthionine-[S,R]-sulfoximine (5 mM) lead to a strong run down of the glutathione level even in glutamate/cystine (100 microM)-containing solution. A similar suppressing effect was observed using L-trans-pyrrolidine-2,4-dicarboxylic acid and L-alpha-aminoadipic acid in the presence of 100 microM cystine and glutamate. We conclude that the intracellular glutamate concentration of the Müller cells is determined by the extracellular glutamate concentration and the velocity of the sodium/glutamate uptake. Consequently, cystine uptake into Müller cells, which is performed by the cystine/glutamate antiporter, is fueled by the sodium/glutamate transporter with intracellular glutamate. Both glutamate and cystine are also substrates for glutathione synthesis. The glutathione level is logically limited by the capacity of the sodium/glutamate transporter to provide glutamate intracellularly for, first, cystine uptake and, second, direct insertion into glutathione. Accordingly, the glutathione level is reduced when the sodium/glutamate transporter is blocked. Thus, a diminution of the glutathione level should be taken into consideration when the effects of sodium/glutamate uptake failure and reduced intracellular glutamate concentrations are discussed.     

Cellular glutathione peroxidase is the mediator of body selenium to protect against paraquat lethality in transgenic mice

A case-control study was conducted between 1992 and 1996 in six Italian areas. It included 537 women with colon cancer, 291 women with rectal cancer and 2081 control women in hospital for acute conditions, unrelated to hormonal or gynaecological diseases. A higher age at menopause was associated with increased colon cancer risk (odds ratio (OR) for > or = 53 years compared with < 50 years = 1.39, 95% confidence interval (CI) 1.04-1.87). Among parous women, a significant trend of decreasing colon cancer risk with increasing number of births was seen for colon (OR for > or = 4 births compared with 1 birth = 0.62, 95% CI 0.42-0.90), but not for rectal cancer. Nulliparous women, however, were at lower risk than women with a single birth, and age at first birth was directly associated with risk. While oral contraceptive use showed no significant influence, ever users of hormone replacement therapy had a reduced risk of rectal cancer (OR = 0.56, 95% CI 0.31-1.01). Thus, the association of colorectal cancer with reproductive and menstrual factors is neither strong nor consistent.     

Separation and detection of the alpha- and beta-chains of hemoglobin of a single intact red blood cells using capillary electrophoresis/electrospray ionization time-of-flight mass spectrometry

A single intact red blood cell (erythrocyte) was injected into a capillary electrophoresis column, and following in-capillary lysing the alpha- and beta-chains of the hemoglobin (approximately 450 amol) were separated and detected using capillary electrophoresis/electrospray ionization time-of-flight mass spectrometry. The mass specta of the electropherogram peaks of the alpha and beta chains showed identifiable peaks corresponding to multiply protonated and sodiated alpha- and beta-chains of hemoglobin.     

Analysis of the human ferrochelatase promoter in transgenic mice

Ferrochelatase catalyzes the chelation of ferrous iron and protoporphyrin to form heme. It is expressed as a housekeeping gene in all cells, but is upregulated during erythropoiesis. Ferrochelatase activity is deficient in the inherited disease protoporphyria as a result of heterogeneous mutations. Although human ferrochelatase is transcribed from a single promoter in both nonerythroid and erythroid cells, previous studies using transient transfection assays failed to demonstrate erythroid-specific increased expression from 4.0 kb of the human ferrochelatase promoter containing the erythroid cis-elements, GATA and NF-E2. The present study analyzes the in vivo regulation of the ferrochelatase gene to provide insights into the mechanism of its erythroid-specific enhancement. Transgenic (TG) mouse lines were generated in which the luciferase reporter gene was driven by either a 150-bp ferrochelatase minimal promoter (-0.15 TG) or by a 4.0 kb extended 5' upstream region (-4.0 TG). Expression of the -4.0 TG transgene was generally consistent with the endogenous gene during embryonic development and in nonerythroid and erythroid tissues as demonstrated by Northern blotting and mRNA in situ hybridization. The -4.0 TG was expressed at a higher level than the -0.15 TG in nonerythroid and erythroid tissues, including during extramedullary erythropoiesis induced by n-acetylphenylhydrazine injection. The enhanced erythroid expression of the -4.0 TG correlates with the appearance of a DNase I hypersensitive site in the 5' flanking region of the transgene. Therefore, in the context of chromosomal integration, the 5' flanking region of the ferrochelatase gene is necessary and sufficient to confer high levels of transgene expression in erythroid tissue.     

Human memory T cell differentiation into Th2-like effector cells is dependent on IL-4 and CD28 stimulation and inhibited by TCR ligation

Freshly isolated memory T cells primarily produced IL-2 and small amounts of IL-4 and IFN-gamma after stimulation in vitro. Priming for 5 days in vitro with anti-CD28 monoclonal antibodies (mAb) alone markedly increased production of IL-4. In comparison to fresh cells, the increase in the amount of IL-4 secreted reflected a marked increase in the number of IL-4-producing cells. Stimulation with immobilized anti-CD3 mAb during priming limited subsequent IL-4 production. By contrast, IFN-gamma production from in vitro primed memory T cells was directly correlated to the concentration of priming anti-CD3 mAb. IL-2 production by all restimulated cells was decreased. The differentiation of IL-4-producing cells could be blocked by antibody to IL-4 and enhanced by the addition of recombinant IL-4 as well as antibody to IFN-gamma. Of note, the IL-4-producing effector cells induced from in vitro priming derived from the early CD27pos memory T cell subset, whereas the small CD27neg differentiated memory subset produced IL-4 without in vitro priming. The results indicate that memory T cells can be directed to differentiate into IL-4-producing effector cells by stimulation via CD28 and IL-4, whereas increasing engagement of the TCR limits Th2 memory cell differentiation.     

A shift from negative to positive selection of autoreactive T cells by the reduced level of TCR signal in TCR-transgenic CD3 zeta-deficient mice

T cell selection is thought to be determined through the interaction between TCR and Ag/MHC. However, the contribution of the level of TCR signal to thymic selection remains unclear. To address this issue, we analyzed T cell selection of male Ag (HY)-specific TCR transgenic (HYTg) mice crossed with CD3 zeta-deficient (zeta KO) mice (HYTg/zeta KO), which have impaired signaling through TCR. In male HYTg/zeta KO mice, the number of thymocytes was comparable to that in normal mice, and almost all the peripheral T cells were HY specific, although these positively selected cells were anergic to male Ag. From these observations, the decrease in TCR signaling by CD3 zeta deficiency resulted in both the avoidance of negative selection and the acquisition of positive selection of autoreactive T cells in male HYTg/zeta KO mice. There was a shift of T cell selection from positive to no selection of HY-specific T cells in female HYTg/zeta KO mice also. Collectively, these findings suggest that the level of TCR signal directly regulates T cell selection; furthermore, the findings have integrated the models of T cell selection into a concept based on the quantity of TCR signal.     

Cardiac-specific overexpression of mouse cardiac calsequestrin is associated with depressed cardiovascular function and hypertrophy in transgenic mice

Calsequestrin is a high capacity Ca2+-binding protein in the sarcoplasmic reticulum (SR) lumen. To elucidate the functional role of calsequestrin in vivo, transgenic mice were generated that overexpressed mouse cardiac calsequestrin in the heart. Overexpression (20-fold) of calsequestrin was associated with cardiac hypertrophy and induction of a fetal gene expression program. Isolated transgenic cardiomyocytes exhibited diminished shortening fraction (46%), shortening rate (60%), and relengthening rate (60%). The Ca2+ transient amplitude was also depressed (45%), although the SR Ca2+ storage capacity was augmented, as suggested by caffeine application studies. These alterations were associated with a decrease in L-type Ca2+ current density and prolongation of this channel's inactivation kinetics without changes in Na+-Ca2+ exchanger current density. Furthermore, there were increases in protein levels of SR Ca2+-ATPase, phospholamban, and calreticulin and decreases in FKBP12, without alterations in ryanodine receptor, junctin, and triadin levels in transgenic hearts. Left ventricular function analysis in Langendorff perfused hearts and closed-chest anesthetized mice also indicated depressed rates of contraction and relaxation of transgenic hearts. These findings suggest that calsequestrin overexpression is associated with increases in SR Ca2+ capacity, but decreases in Ca2+-induced SR Ca2+ release, leading to depressed contractility in the mammalian heart.     

The first exon of the rat aldolase C gene is essential for restoring the chromatin structure in transgenic mice

A 13-kb fragment of the rat aldolase C gene contains sufficient information for gene expression. Transgenic mice carrying the 13-kb fragment showed restoration of chromatin structure and tissue-specific, copy number-dependent expression. To localize the regulatory elements responsible for restoring chromatin structure, several mutated constructs were used to produce transgenic mice. Three activities were examined: recreation of DNase hypersensitive sites, restoration of methylation status, and copy number-dependent expression. Deletions of the 3'-flanking region did not affect those activities. Deletion of seven introns affected the mRNA levels but not the restoration of the chromatin structure. The insertion of the LacZ gene into the first exon of the transgene interfered with both the restoration of the chromatin structure and the copy number-dependent expression in transgenic mice. DNase I footprinting assays revealed that brain-specific factors bind to the sequence disrupted by the LacZ insertion. These results suggest that the sequence in the first exon is essential for restoring the chromatin structure of the rat aldolase C gene.     

Neonatal exposure of TCR BV8S2 transgenic mice to recombinant TCR BV8S2 results in reduced T cell proliferation and elevated antibody response to BV8S2, and increased severity of EAE

Transgenic (Tg) mouse models are unique tools for investigating regulatory mechanisms of the immune system. Mice bearing a T cell receptor (TCR) BV8S2 transgene derived from an encephalitogenic T cell clone are highly susceptible to experimental autoimmune encephalomyelitis (EAE), a T cell-mediated neurological disorder. Although the pathogenesis of EAE is not yet fully understood, TCR-specific regulatory T cells seem to play a role in its remission and/or recovery process. In previous studies, we showed that immunization of BV8S2 Tg mice with recombinant BV8S2 protein induced TCR-specific T cells and protection against EAE, clearly indicating the persistence of a functional TCR regulatory network in spite of the highly skewed T cell repertoire. To further investigate the natural regulatory role of TCR-specific T cells, we evaluated the effect on EAE of inducing neonatal tolerance to heterologous (rat) and homologous BV8S2 proteins in Tg mice. Neonatal exposure to rat BV8S2 protein induced "split" tolerance, characterized by decreased T cell proliferation but increased antibody responses to both rat and mouse BV8S2 proteins that are known to be cross-reactive. When challenged as adults with an encephalitogenic emulsion, Tg mice tolerized with rat but not mouse BV8S2 protein developed more severe EAE compared to control mice. These results demonstrate that immunity to BV8S2 determinants in BV8S2 Tg mice is naturally induced and functions to limit the severity of EAE.     

Functional expression of the human angiotensinogen gene in transgenic mice

The renin-angiotensin system is a major determinant of arterial pressure and volume homeostasis in mammals through the actions of angiotensin II, the proteolytic digestion product of angiotensinogen. Molecular genetic studies in several human populations have revealed genetic linkage between the angiotensinogen gene and both hypertension and increased plasma angiotensinogen. Transgenic mice were generated with a human angiotensinogen genomic clone to develop an animal model to examine tissue- and cell-specific expression of the gene and to determine if overexpression of angiotensinogen results in hypertension. Human angiotensinogen mRNA was expressed in transgenic mouse liver, kidney, heart, adrenal gland, ovary, brain, and white and brown adipose tissue and, in kidney, was exclusively localized to epithelial cells of the proximal convoluted tubules. Plasma levels of human angiotensinogen were approximately 150-fold higher in transgenic mice than that found normally in human plasma. The blood pressure of mice bearing the human angiotensinogen gene was normal but infusion of a single bolus dose of purified human renin resulted in a transient increase in blood pressure of approximately 30 mm Hg within 2 min. These results suggest that abnormalities in the angiotensinogen gene resulting in increased circulating levels of angiotensinogen could potentially contribute in part to the pathogenesis of essential hypertension.     

Human gamma-interferon expression in the mammary gland of transgenic mice

Transgenic mice carrying a hybrid gene consisting of ovine beta-lactoglobulin gene sequences and human gamma-interferon (hIFN-g) cDNA were produced. hIFN-g expression in the mammary gland of two lactating transgenic founder females was found. The concentration of active hIFN-g in the milk was estimated as being ca. 1800 IU/ml. The hIFN-g ability to express in the mammary gland was found in the progeny of transgenic founder male.