COMT Val158Met modulates subjective responses to intravenous nicotine and cognitive performance in abstinent smokers.

The catechol-O-methyltransferase (COMT) Val158Met polymorphism may be a risk factor for nicotine addiction. This study examined the influence of the COMT Val158Met polymorphism on subjective, physiological and cognitive effects of intravenous (IV) nicotine use in African Americans (AAs; n=56) and European Americans (EAs; n=68) smokers. Overnight abstinent smokers received saline followed by 0.5 and 1.0 mg per 70 kg doses of nicotine, administered 30 min apart. Smokers with valine (Val)/Val genotype, compared with methionine (Met) carriers, had greater negative subjective effects from IV nicotine and had more severe withdrawal severity following overnight abstinence from smoking. Women with Val/Val genotype reported greater difficulty concentrating and irritability than men with Val/Val or Met carrier genotypes. The Val/Val genotype was associated with better performance on the math task and in AA smokers it was associated with greater systolic blood pressure. These results support the rationale of pharmacologically inhibiting COMT to aid with smoking cessation among Val/Val genotype smokers.

Southeast Asian origins of five Hill Tribe populations and correlation of genetic to linguistic relationships inferred with genome-wide SNP data.

In Thailand, the term Hill Tribe is used to describe populations whose members traditionally practice slash and burn agriculture and reside in the mountains. These tribes are thought to have migrated throughout Asia for up to 5,000 years, including migrations through Southern China and/or Southeast Asia. There have been continuous migrations southward from China into Thailand for approximately the past thousand years and the present geographic range of any given tribe straddles multiple political borders. As none of these populations have autochthonous scripts, written histories have until recently, been externally produced. Northern Asian, Tibetan, and Siberian origins of Hill Tribes have been proposed. All purport endogamy and have nonmutually intelligible languages. To test hypotheses regarding the geographic origins of these populations, relatedness and migrations among them and neighboring populations, and whether their genetic relationships correspond with their linguistic relationships, we analyzed 2,445 genome-wide SNP markers in 118 individuals from five Thai Hill Tribe populations (Akha, Hmong, Karen, Lahu, and Lisu), 90 individuals from majority Thai populations, and 826 individuals from Asian and Oceanean HGDP and HapMap populations using a Bayesian clustering method. Considering these results within the context of results ofrecent large-scale studies of Asian geographic genetic variation allows us to infer a shared Southeast Asian origin of these five Hill Tribe populations as well ancestry components that distinguish among them seen in successive levels of clustering. In addition, the inferred level of shared ancestry among the Hill Tribes corresponds well to relationships among their languages.

Atopic asthma: differential activation phenotypes among memory T helper cells.

BACKGROUND: T cells have been implicated in the pathogenesis of atopic asthma. We have previously shown that memory T helper cells (CD4+CD45RO+) are preferentially activated relative to naïve T helper cells (CD4+CD45RA+) after bronchial allergen challenge. However, specific T helper subpopulations that are activated in atopy and/or asthma remain undefined. OBJECTIVE: To determine the T helper subpopulations and activation phenotypes relevant to acute and stable asthma that may be common with or distinct from atopy. METHODS: Two groups of atopic asthmatics (ten acute and nine stable asthmatics) and two non-asthmatic groups (14 non-asthmatic atopics and eight normal non-atopic controls) were analysed. Ten acute asthmatics were assessed in the emergency room during an acute episode (FEV1 43.6% +/- 18.4). Nine stable asthmatics were assessed during a symptom-free period (FEV1 85% +/- 6). Using multiple colour flow cytometry we analysed T cell subpopulations and the expression of IL-2-receptor (IL-2R) and MHC-class II antigens (MHC II) on naïve and memory T helper cells in the peripheral blood of asthmatic and non-asthmatic groups. RESULTS: Atopic asthmatics (acute and stable) had an increased percentage of memory T helper cells expressing IL-2R compared with normal non-atopics (mean SD 16.1 +/- 6%, 12.4 +/- 2% and 7.7 +/- 1.8%, P < 0.05) but not compared with non-asthmatic atopics (10 +/- 3.5%). Naïve T helper cells had low expression of IL-2R and MHC II in all four groups. MHC II antigen expression was increased in memory T helper cells of asthmatics (acute and stable) compared with normal non-atopics (13.9 +/- 7.5, 10.6 +/- 5 and 4.9 +/- 2.5, P < 0.05) but not compared with non-asthmatic atopics (7.92 4). A novel finding was that IL-2R and the MHC II molecules were mainly expressed in non-overlapping populations and coexpression was found predominantly on memory T helper cells. Asthmatics (acute and stable) had higher proportion of double positive memory T helper cells (IL-2R+MHC II+) compared with both non-asthmatic groups (P < 0.05). CONCLUSIONS: We demonstrate a differential expression of IL-2R+ and MCH II+ on CD45RO+ T helper cells that would suggest that there are three subsets of activated memory T helper cells in asthmatics. Two non-overlapping IL-2R+ or MHC II+ CD45RO+ T helper cells and a third subpopulation of activated cells that coexpress IL-2R and MHC II (double positives). This latter subpopulation is significantly higher in asthmatics (acute or stable) compared with both non-asthmatic groups, suggesting a specific T helper activation phenotype distinct to atopic asthmatics as compared with atopic non-asthmatics.

CD23 and allergic pulmonary inflammation: potential role as an inhibitor.

CD23, a receptor for immunoglobulin E, is expressed at increased levels in asthmatic and atopic individuals and has been associated with disorders characterized by chronic inflammation. Using an established murine model, we employed several complementary strategies to investigate the role of CD23 in allergic pulmonary inflammation and airway hyperresponsiveness (AHR). Specifically, these approaches included the modulation of CD23 function in vivo by administration of anti-CD23 monoclonal antibody (mAb) or Fab fragments to wild-type mice and the analysis of CD23-deficient mice. Administration of anti-CD23 mAb, but not anti-CD23 Fab fragments, produced attenuation of pulmonary inflammation, AHR, and CD8(+) T-cell activation. On the basis of a model that the anti-CD23 mAb transduces, whereas the Fab fragment inhibits, CD23 signaling, these results suggest that CD23 negatively regulates pulmonary inflammation and AHR. This hypothesis is supported by our observation that CD23-deficient mice developed increased inflammation and AHR after sensitization and challenge with allergen. Together, these results indicate that CD23 negatively regulates pulmonary inflammation and airway hyperreactivity.

Detection of rare apoptotic T cells in vivo.

The flow cytometric analysis of apoptosis in lymphocytes from in vivo samples has been difficult because of the low frequency of apoptotic events. To overcome this obstacle, many investigators have relied on in vitro incubations to increase the number of apoptotic cells before analysis. In this report, we show that an adaptation of the terminal deoxynucleotidyl transferase (TdT)-mediated dUTP-digoxigenin nick-end labeling (TUNEL) assay for use in flow cytometry can be used to detect rare apoptotic lymphocytes from freshly harvested LN suspensions. This approach is both specific and extremely sensitive. This method also is amenable to multiparameter analyses and allows a phenotypic analysis of these rare apoptotic cells. However, we observed that some monoclonal antibodies can stain apoptotic-but not viable-cells nonspecifically. Therefore, the specificity of all antibodies to stain apoptotic cells was confirmed in competition assays.

Analysis of T-cell activation after bronchial allergen challenge in patients with atopic asthma.

BACKGROUND: T helper cells are a heterogeneous group of cells that have phenotypic and functional differences. Activated T helper cells have been found in peripheral blood after allergen challenge of subjects with atopic asthma, but the phenotypes of specific T helper subpopulation involved remains to be identified. OBJECTIVE: To characterize the T cell activation markers that may be regulated by allergens, we analyzed peripheral blood lymphocytes obtained before and after allergen challenge from subjects with atopic asthma. METHODS: We analyzed the distribution of the cell surface activation markers, interleukin 2 receptor (IL-2R) and major histocompatibility complex class II antigens (MHC II) among T helper subpopulations classified as naive (CD45RA) or memory (CD45RO) phenotypes. Nine adult subjects with atopic asthma underwent bronchoprovacative allergen inhalation and isocapnic cold air hyperventilation (ISH) challenge followed by serial spirometry. Peripheral blood mononuclear cells (PBMC) were isolated at baseline and 2 and 24 hours after challenge. Four-color flow cytometry was used to analyze the expression and distribution in vivo of IL-2R and MHC II activation markers on naive and memory T cell subsets after challenge. RESULTS: At 2 and 24 hours after allergen challenge, there was a significant increase in the CD45RO+IL-2R+ T helper cells compared with baseline (mean +/- SE, baseline, 12.5% +/- 1% versus 2 hours, 18.1% +/- 1% and 24 hours, 17.8% +/- 2%, p < 0.025). MHC II expression was not significantly increased after challenge on naive and memory T helper cells and coexpression of IL-2R and MHC II was only found in a small proportion of CD45RO+ T helper cells (2.7% +/- 1%). No changes of IL-2R or MHC II expression on T helper subsets were observed after ISH challenge in the same patients. We also found that 31% to 46% of T helper cells coexpress CD45RA and CD45RO simultaneously, and upregulation of IL-2-R and MHC II expression occurs only on those T helper cells that express CD45RO. CONCLUSIONS: We have found that T helper cells express both CD45RA and CD45RO isoforms, which suggests the existence of a transitional phenotype among naive and memory T helper cells in peripheral blood. In subjects with atopic asthma, our in vivo analysis characterizes two populations of activated memory T helper cells based on the expression of IL-2R or MHC II surface molecules after allergen challenge.

Synergistic induction of CTLA-4 expression by costimulation with TCR plus CD28 signals mediated by increased transcription and messenger ribonucleic acid stability.

T cell activation requires at least two signals transduced by the Ag-specific TCR plus a costimulatory receptor. The CD28 costimulatory molecule has been shown to promote T cell proliferation and cytokine production. CTLA-4, a cell surface molecule homologous to CD28, can function as a repressor of T cell activation. Thus, CTLA-4 and CD28 may have opposing functions during T cell activation. CTLA-4 is expressed at low levels on resting T cells and up-regulated after T cell activation. Regulation of CTLA-4 expression is critical to the normal regulation of immunity. For example, CTLA-4-deficient mice develop early onset lethal autoimmunity. We previously showed that CTLA-4 transcription is increased after T cell activation and that induction was controlled by 335 bp of CTLA-4 upstream sequence. In this work, we show that cell surface CTLA-4 expression is increased synergistically by TCR plus CD28 signals. Synergistic induction is mediated by two mechanisms: an enhanced rate of transcription and increased mRNA stability. In contrast to the regulation of IL-2 and IL-2R expression, which is inhibited by cyclosporin A-, but not rapamycin-dependent signal transduction pathways, CTLA-4 expression is inhibited by either cyclosporin A or rapamycin. Thus, synergistic induction of CTLA-4 expression requires both cyclosporin A- and rapamycin-dependent signals.

Inhibition of T cell costimulation abrogates airway hyperresponsiveness in a murine model.

Activation of naive T cells requires at least two signals. In addition to the well characterized interaction of the T cell antigen receptor with the antigen/MHC expressed on an antigen-presenting cell, T cell activation also requires costimulation by a second set of signals. The best characterized costimulatory receptor is CD28, which binds to a family of B7 ligands expressed on antigen-presenting cells. In asthma, although activated T cells play a role in the initiation and maintenance of airway inflammation, the importance of T cell costimulation in bronchial hyperresponsiveness had not been characterized. Therefore, we tested the hypothesis that inhibition of the CD28:B7 costimulatory pathway would abrogate airway hyperresponsiveness. Our results show that blockade of costimulation with CTLA4-Ig, a fusion protein known to prevent costimulation by blocking CD28:B7 interactions, inhibits airway hyperresponsiveness, inflammatory infiltration, expansion of thoracic lymphocytes, and allergen-specific responsiveness of thoracic T cells in this murine model of allergic asthma.

Fas modulation of apoptosis during negative selection of thymocytes.

A major mechanism maintaining immune tolerance is the deletion of potentially autoreactive thymocytes by apoptosis during development in the thymus. Previous reports suggest that apoptosis is induced by high avidity signals transduced via the T cell receptor; however, the role of signals transduced by other cell surface receptors during thymic selection remains poorly understood. Fas, a member of the TNF receptor family, has been shown to induce apoptosis in mature peripheral T cells; however, the effects of Fas on negative selection of thymocytes have not been previously detected. Using a sensitive terminal deoxynucleotidyl transferase method to detect apoptotic cells, we found that mutant Fas molecules in lpr mice decrease the sensitivity of thymocytes to T cell receptor-mediated apoptosis and that blockade of Fas-Fas ligand interactions in vivo can inhibit antigen-induced apoptosis of thymocytes in non-lpr mice. Thus, we have shown that Fas, in conjunction with antigen-specific signals, can modulate apoptosis during negative selection of thymocytes.

T cell activation in a murine model of asthma.

To determine the mechanisms by which inhaled antigens produce pulmonary inflammation and bronchial hyperreactivity, we have developed a murine model of asthma. BALB/c mice are sensitized and challenged with ovalbumin (OVA). Compared with mice treated with phosphate-buffered saline (PBS), OVA-treated mice developed increased lung resistance, decreased dynamic compliance, and greater methacholine reactivity. Bronchoalveolar lavage fluid revealed significant increases in the proportion of neutrophils and eosinophils. Tissue sections of OVA-treated mice demonstrated goblet cell metaplasia and focal perivascular and peribronchial infiltrates composed of lymphocytes, neutrophils, and eosinophils. Analysis of thoracic lymphocytes via flow cytometry revealed an expansion of both CD4+ and B cell populations, with increased expression of interleukin-2 receptor on CD4+ T cells, indicated increased activation. There was also increased expression of CD44 on CD4+ and CD8+ lymphocytes, suggesting an expansion of the local memory cell population. These findings support the hypothesis that activation of T lymphocytes mediates allergic pulmonary inflammation and bronchial reactivity in asthma.

Restriction of the TCR repertoire inhibits the development of memory T cells and prevents autoimmunity in lpr mice.

The lpr mutation, a disruption of the fas gene, induces spontaneous autoimmunity characterized by high titers of autoantibodies, lymphadenopathy, autoreactive T cells, and early mortality. The mechanism of autoimmunity, however, remains unknown. The driving force for disease could result from the T cell recognition of autoantigen or, alternatively, an intrinsic T cell defect that promotes autoreactivity. We investigated the role of antigen-TCR interaction in the pathogenesis of lpr autoimmunity by transferring the DO-11.10 TCR beta-chain transgene (Vbeta8.2-Dbeta1.1-Jbeta1.1) to the MRL-lpr/lpr background producing the MRL-lprbeta strain. Our results show that the MRL-lpr beta transgenic strain has increased survival, lower titers of autoantibodies, and decreased lymphadenopathy compared with nontransgenic littermates. These beneficial effects were associated with decreased expansion of CD4+ T cells expressing memory phenotypes (CD44+, CD45RB-, and LECAM-) in the transgenic compared with nontransgenic strains. A role for impaired recognition of autoantigen by T cells expressing the TCR transgene was suggested by comparing the phenotypes of Vbeta8.2+ (transgene+) vs Vbeta8.2- (transgene-) CD4+ T cells within the transgenic mice. These experiments show that Vbeta8.2- T cells, which express endogenously rearranged TCR, are the major contributors to the expansion of memory T cells in the transgenic mice. In contrast, T cells with memory phenotypes expand similarly in both the Vbeta8.2+ and Vbeta8.2- subsets of nontransgenic mice. Based on these results, we hypothesize that TCR recognition of autoantigen is a major contributor to autoimmunity in lpr mice and that T cells expressing a memory phenotype are perpetrators of this process.

Regulation of CTLA-4 expression during T cell activation.

T cell activation requires at least two distinct signals, including signaling via the Ag-specific TCR and a costimulatory pathway. The best characterized costimulatory pathway involves the CD28 molecule, which is expressed constitutively on T cells and binds the family of B7 counter-receptors on APCs. Inhibition of this costimulatory pathway prevents T cell activation and can lead to long-term T cell unresponsiveness or anergy. In contrast, CTLA4, which is homologous to CD28, has been shown to be a negative regulator of T cell activation. The CTLA4 molecule is not expressed on resting T cells, but is induced after the initial steps of T cell activation. To address the regulation of CTLA4 expression, we have analyzed CTLA4 at the level of cell surface expression, mRNA, rate of transcription, and rate of decay of message. Nuclear runoff results show an increase in the rate of transcription following T cell activation. Our analyses of non-T cells, including B cells, mastocytoma, and fibroblasts, by Northern blot analysis detect only T cell expression of CTLA4. Reporter gene analysis indicates that 335 bp of upstream CTLA4 sequence are sufficient to control inducibility. We have identified important regulatory regions that control inducible and cell-specific CTLA4 expression. These results also suggest that both positive and negative response elements modulate the transcriptional regulation of CTLA4 gene expression. Understanding the regulation of CTLA4 should provide insight into the regulation of T cell activation at the molecular level.

Plasticity of the T cell receptor repertoire in TCR beta-chain transgenic mice.

The potential alpha beta T cell receptor (TCR) repertoire in normal mice is extremely large and estimated by M. M. Davis and P. J. Bjorkman (Nature 334, 395, 1988) to include 5.2 x 10(18) different receptor molecules. This tremendous diversity provides the basis for T cell recognition of the universe of antigens including bacterial, viral, and allogeneic epitopes. Expression of a single TCR beta-chain transgene should alter the repertoire by limiting the available diversity, therefore, creating holes in the repertoire or producing TCR with decreased affinity. To determine the effect of drastically decreasing the size of the repertoire, we investigated T cell responses in TCR beta-chain transgenic mice expressing the V beta 8.2 transgene. Previous results showed that > 98% of T cells in these mice express the transgene; thus, the TCR repertoire is reduced by orders of magnitude. We tested the T cell responses of the transgenic mice and nontransgenic littermates to nine different MHC haplotypes in mixed lymphocyte reactions, five protein antigens, and eight immunogenic peptides. Surprisingly, the transgenic mice responded to all antigenic stimuli tested indicating the lack of a hole in the TCR repertoire. Interestingly, however, the response in every case was quantitatively lower than the response by the nontransgenic littermates. In contrast, transgenic and nontransgenic T cells responded equivalently to stimulation with mitogens or to stimulation with immobilized alpha-TCR mAb indicating that the transgenic T cells had a normal capacity to respond. To differentiate between decreased TCR affinity and decreased precursor frequency, we performed a limiting dilution analysis to the peptide antigens CI:NP and OVA324-339. The results showed approximately a three-to eight-fold decrease in the frequency of transgenic T cells responding to the peptide compared to nontransgenic littermates. We previously showed that the response to cI84-98 and PLP could be blocked with anti-V beta 8 mAb indicating that V beta 8.2-bearing T cells are capable of responding to peptide antigen. Analysis of TCR V alpha chain expression by PCR and flow cytometry showed similar V alpha expression in both the transgenic and the nontransgenic mice. These results demonstrate tremendous plasticity in the TCR repertoire permitting T cell responses by the transgenic mice to all antigens tested. However, the decreased magnitude of the responses may impair the capacity to defend against natural pathogens. Therefore, although the large TCR repertoire of normal mice may not be necessary to produce in vitro responses to many experimental antigens, it may confer survival benefits in natural environments.

Differential expression of activation markers during tolerance induction by superantigens in T-cell receptor (beta-chain) transgenic mice.

To investigate the process of tolerance induction we have developed an in vivo model using TCR beta-chain transgenic mice tolerized with the superantigen staphylococcal enterotoxin B. We have previously demonstrated that tolerized peripheral T cells were anergic when stimulated in vitro with immunogenic peptides, superantigens, mitogens, and immobilized anti-TCR mAb. However, the development of anergy is preceded by an induction phase which produces expansion followed by contraction of the peripheral T cell population presumably due to proliferation and programmed cell death, respectively. The current experiments focus on the induction phase of tolerance. A kinetic functional analysis showed that the inhibition of proliferation was apparent 2-3 days post-tolerization. Interestingly, the inhibition of proliferation correlated with the loss of IL-2R alpha expression, which occurred 2 days post-tolerization following an initial increase in IL-2R alpha expression. In addition, the expression of multiple activation markers including CD44, Ly-6A/E, and very early activation marker H1.2F3 is induced, whereas the expression of CD45RB is decreased during tolerance induction. Elevated expression of Ly-6A/E persists up to 28 days post-tolerization; however, altered expression of the other markers does not persist and near baseline levels of the other markers are noted 7 to 28 days post-tolerization. These results show that tolerance induction is an active process which has functional and phenotypic similarities to antigen-specific immunity. However, tolerance induction in our system differs from immunity in terms of the early loss of IL-2R alpha expression, the persistent increased expression of Ly-6A/E, and the lack of development of CD45RBlo memory-type T cells.