Combustible Cigarette and Smokeless Tobacco Product Preparations Differentially Regulate Intracellular Calcium Mobilization in HL60 Cells

Changes in the level of intracellular calcium ([Ca²⁺]_i) are central to leukocyte signaling and immune response. Although evidence suggests that cigarette smoking affects inflammatory response via an increase in intracellular calcium, it remains unclear if the use of smokeless tobacco (e.g., moist snuff) elicits a similar response. In this study, we evaluated the effects of tobacco product preparations (TPPs), including total particulate matter (TPM) from 3R4F reference cigarettes, smokeless tobacco extract (STE) from 2S3 reference moist snuff, and nicotine alone on Ca²⁺ mobilization in HL60 cells. Treatment with TPM, but not STE or nicotine alone, significantly increased [Ca²⁺]_i in a concentration-dependent manner in HL60 cells. Moreover, TPM-induced [Ca²⁺]_i increase was not related to extracellular Ca²⁺ and did not require the activation of the IP3 pathway nor involved the transient receptor potential (TRP) channels. Our findings indicate that, in cells having either intact or depleted endoplasmic reticulum (ER) Ca²⁺ stores, TPM-mediated [Ca²⁺]_i increase involves cytosolic Ca²⁺ pools other than thapsigargin-sensitive ER Ca²⁺ stores. These results, for the first time, demonstrate that TPM triggers [Ca²⁺]_i increases, while significantly higher nicotine equivalent doses of STE or nicotine alone, did not affect [Ca²⁺]_i under the experimental conditions. In summary, our study suggests that in contrast with STE or nicotine preparations, TPM activates Ca²⁺ signaling pathways in HL60 cells. The differential effect of combustible and non-combustible TPPs on Ca²⁺ mobilization could be a useful in vitro endpoint for tobacco product evaluation.

Global gene expression profiles from PBMCs treated with reference tobacco product preparations

This Data in Brief article describes global gene expression profiles from human peripheral blood mononuclear cells (PBMCs) that were treated with preparations from reference combustible and non-combustible tobacco products (TPPs). PBMCs isolated from non-smokers were treated with three non-cytotoxic doses of aqueous preparations from 3R4F cigarettes, termed Whole Smoke-Conditioned Medium (WS-CM) and a single dose of 2S3 moist snuff, termed smokeless tobacco extract (STE). PBMCs were treated with the test articles for 3 hours and the extracted total RNA was reverse transcribed and hybridized to HTA 2.0 Genechip^® arrays and scanned using an Affymetrix GeneChip^® Scanner 3000. CEL files and CHP files were generated using an Affymetrix Expression console. The CEL files were submitted to the NCBI database with GEO accession number GSE110027. The results of the microarray analyses are found in this Data in Brief article. Ingenuity Pathway Analysis (IPA; Qiagen) was used to conduct core analyses of genes that were differentially expressed by high WS-CM or STE based on the Ingenuity Gene knowledge. Expression of several of the differentially expressed genes was confirmed by RT-PCR. Analyses of these data can be found in the article “Distinct gene expression changes in human peripheral blood mononuclear cells treated with different tobacco product preparations” [1].

Distinct gene expression changes in human peripheral blood mononuclear cells treated with different tobacco product preparations

Cigarette smoking exerts diverse physiological effects including immune suppression. To better characterize the biological effects of different categories of tobacco products, a genome-wide gene expression study was performed. Transcriptomic profiling was performed in PBMCs treated with different equi-nicotine units of aqueous extracts of cigarette smoke (termed Whole Smoke-Conditioned Medium, or WS-CM), or a single dose smokeless tobacco extract (STE) prepared from reference tobacco products. WS-CM induced dose-dependent changes in the expression of several genes. No significant expression differences between low WS-CM and media control were detected. However, transcripts were significantly affected by medium WS-CM (479), high WS-CM (2, 703), and STE (2, 156). The overlap between medium WS-CM and STE, and high WS-CM and STE, was minimal (34 and 65 transcripts, respectively). Hierarchical clustering revealed that gene expression profiles for STE and medium WS-CM co-clustered, while those affected by the high dose of WS-CM clustered distinctly. Functional analysis revealed that WS-CM, but not STE, uniquely affected genes involved in immune cell development and inflammatory response. Cascades of upstream regulators (e.g., TNF, IL1β, NFƙB) were identified for the observed gene expression changes and generally suppressed by WS-CM, but not by STE. Collectively, these findings demonstrate that combustible and non-combustible tobacco products elicit distinct biological effects, which could explain the observed chronic immune suppression in smokers.

Role of Oxidative Stress in the Suppression of Immune Responses in Peripheral Blood Mononuclear Cells Exposed to Combustible Tobacco Product Preparation

Cigarette smoking is a major risk factor for several human diseases. Chronic inflammation, resulting from increased oxidative stress, has been suggested as a mechanism that contributes to the increased susceptibility of smokers to cancer and microbial infections. We have previously shown that whole-smoke conditioned medium (WS-CM) and total particulate matter (TPM) prepared from Kentucky 3R4F reference cigarettes [collectively called as combustible tobacco product preparations (TPPs)] potently suppressed agonist-stimulated cytokine secretion and target cell killing in peripheral blood mononuclear cells (PBMCs). Here we have investigated the role of oxidative stress from TPPs, which alters inflammatory responses in vitro. Particularly, we investigated the mechanisms of WS-CM-induced suppression of select cytokine secretions in Toll-like receptor (TLR) agonist-stimulated cells and target cell killing by effector cells in PBMCs. Pretreatment with N-acetyl cysteine (NAC), a precursor of reduced glutathione and an established anti-oxidant, protected against DNA damage and cytotoxicity caused by exposure to WS-CM. Similarly, secretion of tumor necrosis factor (TNF), interleukin (IL)-6, and IL-8 in response to TLR-4 stimulation was restored by pretreatment with NAC. Target cell killing, a functional measure of cytolytic cells in PBMCs, is suppressed by WS-CM. Pretreatment with NAC restored the target cell killing in WS-CM treated PBMCs. This was accompanied by higher perforin levels in the effector cell populations. Collectively, these data suggest that reducing oxidative stress caused by cigarette smoke components restores select immune responses in this ex vivo model.

Effect of combustible tobacco product preparations on neutrophil-like cells

Chronic exposure to cigarette smoking causes inflammation and immune suppression, which are known to contribute to smoking-related diseases and increased susceptibility of smokers to microbial infections. Neutrophils play an essential role in innate immune responses to protect against microbial infections. However, there is limited information on how smoking impacts innate immunity, particularly neutrophil functions. The use of neutrophils in research is limited due to their short lived nature. Therefore, alternate sources for neutrophil-like cells have been sought. Treatment with DMSO, results in differentiation of the HL60 cells to neutrophil-like cells, which provides an alternate model for assessment of certain neutrophil functions. In this study, we have differentiated HL60 cells with DMSO to neutrophil-like cell phenotype. The differentiated cells were characterized by the expression of CD11b and phagocytosis, and assessed the effects of exposure to different tobacco products. We assessed the effect of combustible cigarette whole smoke conditioned medium (WS-CM) and smokeless tobacco (ST) extracts, prepared from reference tobacco products, on the neutrophil-like cells on cell migration and phagocytic function. A dose-dependent decrease in the migration and phagocytosis was observed on treatment with WS-CM, but not with ST extracts. These findings suggest that neutrophil-like cells can be utilized to assess the effects of combustible and non-combustible tobacco products. Further, these results show that combustible and non-combustible tobacco products differentially impact neutrophil functions in this model.

Gene expression profiles associated with cigarette smoking and moist snuff consumption

Background

Among the different tobacco products that are available on the US market, cigarette smoking is shown to be the most harmful and the effects of cigarette smoking have been well studied. US epidemiological studies indicate that non-combustible tobacco products are less harmful than smoking and yet very limited biological and mechanistic information is available on the effects of these alternative tobacco products. For the first time, we characterized gene expression profiling in PBMCs from moist snuff consumers (MSC), compared with that from consumers of cigarettes (SMK) and non-tobacco consumers (NTC).

Results

Microarray analysis identified 100 differentially expressed genes (DEGs) between the SMK and NTC groups and 46 DEGs between SMK and MSC groups. However, we found no significant differences in gene expression between MSC and NTC. Both hierarchical clustering and principle component analysis revealed that MSC and NTC expression profiles were more similar than to SMK. Random forest classification identified a subset of DEGs which predicted SMK from either NTC or MSC with high accuracy (AUC 0.98).

Conclusions

PMBC gene expression profiles of NTC and MSC are similar to each other, while SMK exhibit distinct profiles with alterations in immune related pathways. In addition to discovering several biomarkers, these studies support further understanding of the biological effects of different tobacco products.

Trial registration

ClinicalTrials.gov. Identifier: NCT01923402. Date of Registration: August 14, 2013. Study was retrospectively registered.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-017-3565-1) contains supplementary material, which is available to authorized users.

Role of oxidative stress in the suppression of immune responses in peripheral blood mononuclear cells exposed to combustible tobacco product preparations

Cigarette smoking is a major risk factor for several human diseases. Chronic inflammation, resulting from increased oxidative stress, has been suggested as a mechanism that contributes to the increased susceptibility of smokers to cancer and microbial infections. We have previously shown that whole smoke-conditioned medium (WS-CM) and total particulate matter (TPM) prepared from Kentucky 3R4F reference cigarettes potently suppressed agonist-stimulated cytokine secretion and target cell killing in peripheral blood mononuclear cells (PBMCs) under ex vivo conditions. Here, we sought to investigate the role of oxidative stress from cigarette smoke exposure in the compromised immunity observed in smokers. Particularly, we investigated the mechanisms of WS-CM and TPM induced suppression of select cytokine secretions in TLR agonist-stimulated cells, and target cell killing by effector cells in PBMCs. Pre-treatment with N-acetyl cysteine (NAC), a precursor of reduced glutathione and an established antioxidant, protected against DNA damage and cytotoxicity caused by exposure to WS-CM and TPM. Similarly, secretion of IFN-γ, TNF, IL-6 and IL-8 in response to TLR-4 stimulation was restored by NAC. Target cell killing, which is used as a functional measure of cytolytic cells in PBMCs, is suppressed by WS-CM. Pretreatment with NAC restored the target cell killing in WS-CM treated PBMCs. This was accompanied by higher perforin levels in the effector cell populations. Collectively, these data suggest that reducing oxidative stress caused by cigarette smoke components restores select immune responses in this ex vivo model.

Methods to evaluate cytotoxicity and immunosuppression of combustible tobacco product preparations

Among other pathophysiological changes, chronic exposure to cigarette smoke causes inflammation and immune suppression, which have been linked to increased susceptibility of smokers to microbial infections and tumor incidence. Ex vivo suppression of receptor-mediated immune responses in human peripheral blood mononuclear cells (PBMCs) treated with smoke constituents is an attractive approach to study mechanisms and evaluate the likely long-term effects of exposure to tobacco products. Here, we optimized methods to perform ex vivo assays using PBMCs stimulated by bacterial lipopolysaccharide, a Toll-like receptor-4 ligand. The effects of whole smoke-conditioned medium (WS-CM), a combustible tobacco product preparation (TPP), and nicotine were investigated on cytokine secretion and target cell killing by PBMCs in the ex vivo assays. We show that secreted cytokines IFN-γ, TNF, IL-10, IL-6, and IL-8 and intracellular cytokines IFN-γ, TNF-α, and MIP-1α were suppressed in WS-CM-exposed PBMCs. The cytolytic function of effector PBMCs, as determined by a K562 target cell killing assay was also reduced by exposure to WS-CM; nicotine was minimally effective in these assays. In summary, we present a set of improved assays to evaluate the effects of TPPs in ex vivo assays, and these methods could be readily adapted for testing other products of interest.

Regulation of gene expression by tobacco product preparations in cultured human dermal fibroblasts

Skin fibroblasts comprise the first barrier of defense against wounds, and tobacco products directly contact the oral cavity. Cultured human dermal fibroblasts were exposed to smokeless tobacco extract (STE), total particulate matter (TPM) from tobacco smoke, or nicotine at concentrations comparable to those found in these extracts for 1h or 5h. Differences were identified in pathway-specific genes between treatments and vehicle using qRT-PCR. At 1h, IL1α was suppressed significantly by TPM and less significantly by STE. Neither FOS nor JUN was suppressed at 1h by tobacco products. IL8, TNFα, VCAM1, and NFκB1 were suppressed after 5h with STE, whereas only TNFα and NFκB1 were suppressed by TPM. At 1h with TPM, secreted levels of IL10 and TNFα were increased. Potentially confounding effects of nicotine were exemplified by genes such as ATF3 (5h), which was increased by nicotine but suppressed by other components of STE. Within 2h, TPM stimulated nitric oxide production, and both STE and TPM increased reactive oxygen species. The biological significance of these findings and utilization of the gene expression changes reported herein regarding effects of the tobacco product preparations on dermal fibroblasts will require additional research.

Differential regulation of human T cell and NK cell function by tobacco product preparations (P4339)

NK cells and T cells play essential roles in innate and adaptive immune responses by protecting against microbial infections and in tumor surveillance. While smoking is known to cause immunosuppression, it is unclear how the use of smokeless tobacco (ST) products affects immune responses. We investigated immunological responses to exposure of reference tobacco product preparations (TPPs) using poly I:C and LPS-stimulated PBMCs. The TPPs included whole smoke-conditioned media (WS-CM) and total particulate matter (TPM) prepared from 3R4F reference cigarettes, 2S3 moist snuff smokeless tobacco extracted in complete artificial saliva (ST/CAS), and nicotine. WS-CM and TPM treatment resulted in dose-dependent reductions in the expression of intracellular IFN-γand TNF-α in NK cells and T cells, secretion of several cytokines by PBMCs and the inhibition of cytolytic activity of effector cells in PBMCs. Although interference from the vehicle effects confounded the interpretation of data from cells exposed to ST/CAS, some immunosuppressive effects were evident only at high doses. Treatment with nicotine caused minimal immunosuppression in this system. These data suggest that the function of human NK cells and T cells is impacted by exposure to TPPs, on an equi-nicotine unit basis, as follows: WS-CM > TPM >ST/CAS> nicotine. These findings support the hypothesis that immune-suppression from smoking is linked to a higher incidence of microbial infections and cancer among smokers.

Complete artificial saliva alters expression of proinflammatory cytokines in human dermal fibroblasts

Complete artificial saliva (CAS) is a saliva substitute often used as a vehicle for test articles, including smokeless tobacco products. In the course of a study employing normal adult human dermal fibroblasts (HDFa) as a model in vitro, we discovered that CAS as a vehicle introduced a significant change in the expression of proinflammatory cytokines. To determine the effects of CAS on gene expression, real-time quantitative reverse-transcriptase PCR gene array analysis was used. Results indicate that robust changes in the expression of the proinflammatory cytokine interleukin 8 (IL8) and the vascular cell adhesion molecule 1 (VCAM1) occur within 5h of exposure to CAS. To determine whether CAS also alters cytokine release into the culture media, cytometric bead array assays for human inflammatory cytokines were performed. Analysis shows that CAS induced the release of IL8 and IL6. This study focused on determining which components in CAS were responsible for the proinflammatory response in HDFa. The following components were investigated: α-amylase, lysozyme, acid phosphatase, and urea. Results demonstrated that enzymatically active α-amylase induced gene expression for proinflammatory cytokines IL8, IL6, tumor necrosis factor-α, and IL1α and for VCAM1. Therefore, it is important to carefully evaluate the "vehicle effects" of CAS and its components in in vitro toxicology research.

Rapid isolation of leukocyte subsets from fresh and cryopreserved peripheral blood mononuclear cells in clinical research

Isolation and processing blood into leukocyte subsets are important processes in research. Although methods have been developed to fractionate small volumes of blood, optimizing the methods and balancing the underlying costs are often necessary. The need for such optimization is particularly critical when processing larger volumes of blood. We describe a simple and reproducible method for processing larger volumes of fresh blood rapidly and consistently, which yields peripheral blood mononuclear cells (PBMCs) and leukocyte subsets with high purity (81-96%; n=13) and higher yields relative to stored blood. RNA isolated from these cells was found to be suitable for downstream applications. Blood stored for 24 hours (n=4) before processing resulted in significantly lower yields of PBMCs (58 percent lower), T cells (52 percent lower), B cells (21 percent lower) and monocytes (25 percent lower) compared to fresh blood. However, the purity of the fractionated cells was comparable to that obtained with fresh blood. Furthermore, we report that the yield and purity of the leukocyte subsets isolated from cryopreserved PBMCs (n=4) were not compromised.

IFNgamma-producing, virus-specific CD8+ effector cells acquire the ability to produce IL-10 as a result of entry into the infected lung environment

It has become clear that T cells with the potential to negatively regulate the immune response are normal constituents of the immune system. These cells often mediate their effects through the production of immunosuppressive factors. At present our understanding of how these cells are generated is limited. Here we report the presence of a population of IL-10-producing, virus-specific CD8+ T cells in the lungs of mice following acute respiratory infection. These cells were only found at minimal levels in the spleen and draining lymph node; instead they were restricted primarily to the infected lung tissue. A major finding from this study is demonstration that the ability to produce IL-10 can be acquired by IFNgamma-producing effector cells following entry into the infected lung. These studies suggest IL-10 production is the result of further differentiation of an antigen-specific CD8+ T cell that is governed by signals present in infected lung tissue.

Pivotal Advance: Nonfunctional lung effectors exhibit decreased calcium mobilization associated with reduced expression of ORAI1

CD8(+) T cells play a critical role in the clearance of respiratory pathogens. Thus, it is surprising that functional inactivation of lung effectors has been observed in many models of viral infection. Currently, the molecular defect responsible for the shut-off of function in these cells is unknown. In the present study, we addressed this question using a model of respiratory infection with the paramyxovirus SV5. Nonfunctional cells were found to exhibit decreases in SOCE, resulting in reduced NFAT1 activation. Notably, function could be restored by the provision of increased levels of extracellular calcium. The reduced ability to mobilize calcium was associated with reduced expression of ORAI1, the CRAC channel subunit. These findings reveal a previously unknown mechanism for the negative regulation of function in effector T cells.

Loss of function in virus-specific lung effector T cells is independent of infection

Recently, several studies, including those with respiratory syncytial virus, mouse pneumovirus, and simian virus 5, have reported that virus-specific CD8+ effector cells entering the lung as a result of respiratory infection undergo significant loss of function. The impaired function in these cells has been proposed to be the result of infection-induced changes in the lung. Although virus-specific effects may contribute to regulation of T cells in the lung, the findings from this study provide evidence that the basal lung environment is sufficient to promote loss of function in effector cells. Loss of function occurs within 48 h of entry into the lung and is most evident in cells residing in the lung parenchyma. These findings suggest an additional paradigm for the immunoregulation of effector cells that enter the lung as a result of virus infection.

TLR-4 and -6 agonists reverse apoptosis and promote maturation of simian virus 5-infected human dendritic cells through NFkB-dependent pathways

Infection of primary cultures of human immature monocyte-derived dendritic cells (moDC) with the paramyxovirus Simian Virus 5 (SV5) results in extensive cytopathic effect (CPE) and induction of apoptosis, but DC maturation pathways are not activated. In this study, we investigated the relationship between SV5-induced apoptosis and the lack of DC maturation. Reducing CPE and apoptosis in SV5-infected immature DC by the addition of a pancaspase inhibitor resulted in only low level expression of maturation markers CD40, CD80 and CD86, suggesting that SV5 infection either actively blocked maturation pathways or failed to provide sufficient signals to activate maturation. To distinguish between these hypotheses, SV5-infected immature DC were challenged with agonists that stimulate toll-like receptors (TLRs). Treatment with the TLR-4 agonist LPS or TLR-6 agonist FSL1 enhanced cell surface expression of CD40, CD80 and CD86 on SV5-infected cells to levels approaching that of mock-infected TLR-treated moDC, but treatment with agonists for TLR-2, -3, -5 or -8 had little effect. Addition of TLR-4 or -6 agonists to SV5-infected DC also dramatically reduced CPE and apoptosis, but the levels of viral protein and virus yield were not affected. Similarly, SV5-infected immature moDC were matured by treatment with IL-1beta, and these mature infected cells also showed reduced CPE and apoptosis. In the presence of NFkB inhibitors, TLR-4 and -6 agonists did not promote maturation or reduce apoptosis of SV5-infected DC, indicating that maturation and cell survival were both dependent on signaling through NFkB-dependent pathways. Our results suggest a model whereby SV5 replication induces apoptosis in immature DC but fails to provide strong maturation signals, while activation of NFkB-dependent pathways by exogenous ligands can lead to moDC maturation and override SV5-induced cell death.

Loss of function in effector T cells is a consequence of residence in the normal lung environment (92.3)

It is well accepted that the lung environment is immunosuppressive. This is in part related to the presence of immunosuppressive mediators even in the absence of ongoing infection. Recently a number of studies have reported the loss of function of CD8+ effector cells that enter the lung following viral infection. The impaired function of these cells was proposed to be the result of infection induced changes in the lung. However, our recent findings suggest an alternative model. Our data provide evidence that the normal lung environment is sufficient to promote loss of function in effector cells. Transfer of an established CTL line into naïve BALB/c mice resulted in a significant loss of function in lung resident cells within 48 hours. At the time of transfer cells were 95% functional; however 48 hours post-transfer only 25% of cells produced IFNγ in response to peptide stimulation. Similar findings were obtained following transfer of effector cells generated by short-term culture of Listeria p60-specific TCR transgenic splenocytes or by in vivo Listeria infection. Importantly loss of function was restricted to lung parenchymal cells as airway or spleen resident cells retained function at levels similar to pre-transfer cultures. These findings suggest a new paradigm for the immunoregulation of effector cells in the lung. Understanding the mechanism responsible for the loss of function may lead to therapeutics that can prevent this outcome in cases where an increased number of effectors is desired or promote it in cases where pathogenic effector cells are present.

A simian virus 5 (SV5) P/V mutant is less cytopathic than wild-type SV5 in human dendritic cells and is a more effective activator of dendritic cell maturation and function

Human epithelial cells infected with the parainfluenza virus simian virus 5 (SV5) show minimal activation of host cell interferon (IFN), cytokine, and cell death pathways. In contrast, a recombinant SV5 P/V gene mutant (rSV5-P/V-CPI-) overexpresses viral gene products and is a potent inducer of IFN, proinflammatory cytokines, and apoptosis in these cells. In this study, we have compared the outcomes of wild-type (WT) SV5 and rSV5-P/V-CPI- infections of primary human dendritic cells (DC), important antigen-presenting cells for initiating adaptive immune responses. We have tested the hypothesis that a P/V mutant which activates host antiviral responses will be a more potent inducer of DC maturation and function than WT rSV5, which suppresses host cell responses. Infection of peripheral blood mononuclear cell-derived immature DC with WT rSV5 resulted in high levels of viral protein and progeny virus but very little increase in cell surface costimulatory molecules or secretion of IFN and proinflammatory cytokines. In contrast, immature DC infected with the rSV5-P/V-CPI- mutant produced only low levels of viral protein and progeny virus, but these infected cells were induced to secrete IFN-alpha and other cytokines and showed elevated levels of maturation markers. Unexpectedly, DC infected with WT rSV5 showed extensive cytopathic effects and increased levels of active caspase-3, while infection of DC with the P/V mutant was largely noncytopathic. In mixed-culture assays, WT rSV5-infected DC were impaired in the ability to stimulate proliferation of autologous CD4+ T cells, whereas DC infected with the P/V mutant were very effective at activating T-cell proliferation. The addition of a pancaspase inhibitor to DC infected with WT rSV5 reduced cytopathic effects and resulted in higher surface expression levels of maturation markers. Our finding that the SV5 P/V mutant has both a reduced cytopathic effect in human DC compared to WT SV5 and an enhanced ability to induce DC function has implications for the rational design of novel recombinant paramyxovirus vectors based on engineered mutations in the viral P/V gene.

Altered function in CD8+ T cells following paramyxovirus infection of the respiratory tract

For many respiratory pathogens, CD8+ T cells have been shown to play a critical role in clearance. However, there are still many unanswered questions with regard to the factors that promote the most efficacious immune response and the potential for immunoregulation of effector cells at the local site of infection. We have used infection of the respiratory tract with the model paramyxovirus simian virus 5 (SV5) to study CD8+ T-cell responses in the lung. For the present study, we report that over time a population of nonresponsive, virus-specific CD8+ T cells emerged in the lung, culminating in a lack of function in approximately 85% of cells specific for the immunodominant epitope from the viral matrix (M) protein by day 40 postinfection. Concurrent with the induction of nonresponsiveness, virus-specific cells that retained function at later times postinfection exhibited an increased requirement for CD8 engagement. This change was coupled with a nearly complete loss of functional phosphoprotein-specific cells, a response previously shown to be almost exclusively CD8 independent. These studies add to the growing evidence for immune dysregulation following viral infection of the respiratory tract.

Chemokines in autoimmune diseases

Autoimmune diseases like multiple sclerosis (MS) and insulin-dependent diabetes (IDD) are believed to be mediated by pathogenic CD4+ autoreactive T cells which mediate selective destruction of specific host cells. Interrupting the trafficking of such T cells from host circulation to the sites of pathology, such as the central nervous system in the case of MS and the pancreas in the case of IDD, potentially offers a novel opportunity for therapeutic intervention in these diseases. The following summarizes our evolving thoughts on the role of the chemokine network in MS and IDD, and focuses on the chemokine receptor CXCR3 as a potential target for impeding T-cell-mediated destruction in these disease settings.

Localization of soluble major histocompatibility class II-peptide complexes on T cell surface

Affinity purified major histocompatibility (MHC)-peptide complexes are heterodimeric cell surface glycoproteins and are known to recognize antigen-specific CD4(+) T cell receptors (TCRs). In general, the affinity of MHC-peptide complexes to TCRs are considered very low with a K(D) of 5 x 10(-5) M and, therefore, stabilization of these complexes on T cell surface was not reported earlier. This could be due to (1) incomplete occupancy of MHC molecules with antigenic peptides, (2) variability of the binding constant of peptides to MHC molecules, (3) presence of endogenously bound peptides in MHC preparations, or (4) a combination of these. Using well-characterized HLA-DR2 complex loaded with a high affinity immunodominant epitope analog from human myelin basic protein (MBP), which shows release of gamma-IFN by specific stimulation of transformed human T cell clone (SS8T). The present report demonstrates a method for the localization of bound MHC class II-peptide complexes on T cell surface by backscatter electron imaging using in-lens Field Emission Scanning Electron Microscopy (FESEM). The localization is specific to the complex recognized by the TCR on MHC class II (DR2) and MBP peptide restricted human T cells.

Rapid identification of antigenic T-cell epitopes by extracellular acidification rate signals

We used a silicon-based biosensor, a microphysiometer, to measure real-time extracellular acidification rate signals associated with T lymphocyte responses to peptide ligands interacting with the T-cell receptor (TCR). We compared these effector responses with those of interferon-gamma (IFN-gamma) production, and T-cell proliferation. Within minutes, major histocompatibility complex (MHC)-bound peptides on antigen-presenting cells (APCs) engaged the TCR to increase acidification rates of the extracellular media was measured by microphysiometer. We exposed two myelin peptide-specific human T-cell clones, MSF132E11 (DRB1*1501 restricted) and TOM3A6 (DRB5*0101 restricted), to truncated analogues of the parent MBP 84-102 peptide, in the presence of MHC restricted human antigen-presenting cells, and measured the extracellular acidification rate signal changes, IFN-gamma production and T-cell proliferation. The core epitopes recognized by these clones were identified by microphysiometer and found to be MBP 88-100 and MBP 91-100, respectively. These epitopes were identical to those identified by the IFN-gamma and proliferation assays. We conclude that measurement of real-time extracellular acidification rate signals by the microphysiometer may facilitate rapid identification of human T-cell epitopes involved in immune disorders and the development of specific T-cell antagonists.

Peptide binding inhibits aggregation of soluble MHC class II in solution

Affinity-purified major histocompatability complex (MHC) class II molecules are known to bind antigenic peptide in vitro. This peptide-bound MHC class II is known to undergo a change in structure upon stable binding of antigenic peptide. Previous results from our, and other laboratories, have suggested a relationship between MHC class II structure and peptide association that enables class II to enter into a stable conformation upon peptide binding. In this report we describe that stable binding of high-affinity antigenic peptide to MHC class II molecule results in transition of aggregated purified MHC class II proteins to a stable heterodimeric state. Such transition was demonstrated by using purified human HLA-DR2 class II molecule and high-affinity myelin basic protein (MBP) 83-102)Y83 peptide. Highly aggregated purified DR2 (high molecular weight; HMW) was first separated from heterodimer (low molecular weight: LMW) in the presence of 50-fold molar excess of MBP(83-102)Y83 peptide. We then show that the aggregated HMW preparation can be successfully converted into a stable dimer by further incubation with MBP(83-102)Y83 and changing various binding parameters such as pH, temperature, reducing agent, and peptide concentrations. Under optimized conditions, the highly aggregated inactive DR2 molecules can be completely loaded with the antigenic peptide. The transformed heterodimers with bound peptide prepared by this method are biologically active, as shown by their ability to induce the production of gamma-interferon by SS8T-transformed human T cells. These results suggest that in solution, MHC class II molecules may be aggregated in the absence of bound peptide. Such aggregated MHC class II molecules can be converted to stable and biologically active heterodimers in the presence of high-affinity antigenic peptide.

Identification of core structure and critical T cell receptor contact residues in an antigenic peptide by measuring acidification rates

A silicon-based biosensor microphysiometer measures real time cell response by monitoring an increase in extracellular acidification rate in response to ligands for specific membrane receptors. We used the microphysiometer to identify the minimal structure and critical residues of an antigenic peptide for its interaction with T cell receptor (TCR) using a synthetic peptide analog of human myelin basic protein (MBP) corresponding to residues 84-102 [MBP(83-102)Y83]. MBP(83-102)Y83 peptide analogs were allowed to interact with TCRs on a DRB5*0101-restricted Herpes virus saimiri (HVS) transformed human T cell clone (SS8T) which also contains major histocompatibility complexes (MHC) class II (DR2) molecules. Cultured SS8T cells were exposed to 11 N-terminus and 11 C-terminus truncated peptides separately in the microphysiometer chambers to determine the minimal amino acid residues required for the T cell response. In parallel, 13 analogs of the MBP(83-102)Y83 peptide with single alanine substitutions were tested in this assay to identify critical amino acid residues involved in TCR interactions. A minimal core length of MBP(91-100) peptide and residues F-91, K-93, N-94, I-95 and V-96 were essential for TCR interaction. Acidification rate measurements correlated well with enhanced levels of gamma-IFN (interferon gamma) and TNF-beta cytokine production and suggested that the increase in the extracellular acidification rate is a direct result of early T cell signaling events.

T-cell receptor-mediated signal transduction in transformed human T-cells

Recently it has been shown that purified complexes of major histocompatibility (MHC) class II and antigenic peptide can recognize T-cell receptors (TCRs) on virally transformed CD4+ T-cells in vitro. It is not clearly understood whether peptide bound to purified MHC II molecules (MHC-P), or to MHC II molecules on the surface of antigen-presenting cells (APC-peptide), initiate similar or different signals in transformed human T-cells. To address this question, the expression of protein tyrosine kinases (PTKs), their phosphorylation, and the effect of various kinase inhibitors were investigated using transformed T- and B-cells. HLA-DR2- and MBP(84-102)-restricted cloned T-cells (SS8T) immortalized with herpes saimiri virus (HSV) and DR2-expressing lymphoblastoid B cells transformed with Epstein-Barr virus (EBV) were utilized in this study. The expression and phosphorylation of three major PTKs (1ck-56, fyn-59, zap-70) involved in signaling through the TCR were analyzed by enhanced chemiluminescence blots. T-cells exposed to soluble MHC-P complex did not show altered expression of 1ck-56 protein. In contrast, a decrease in 1ck expression was observed in SS8T cells when TCRs were engaged with APC-peptide. Upon interaction with the TCR, both MHC-P complex and APC-peptide showed increased fyn-59 protein expression and phosphorylation. In our experiments using immortalized T- and B-cells, the expression of zap-70 protein remained unchanged. When T-cells were exposed to herbimycin and H-7, inhibitors of PTKs and protein kinase C (PKC) pathways, respectively, a dose-dependent decrease in gamma-IFN levels was observed with both systems. However, in the presence of genestein, another PTK inhibitor, such decrease in gamma-IFN was observed only in the case in which T-cells were exposed to MHC-P complexes. These results together suggest that the occupancy of TCRs in transformed T-cells by soluble MHC-P complex and APC-peptide differs with respect to the 1ck expression, although both can induce signals that lead to increased fyn activity and its phosphorylation. In addition, genestein showed differential inhibitory effect on gamma-IFN production by T-cells exposed to APC-peptide and MHC-P complexes, suggesting that the TCR occupancy by MHC-P complex and APC-peptide have subtle differences in PTK pathways.

Soluble MHC II-peptide complexes induce antigen-specific apoptosis in T cells

Soluble major histocompatibility (MHC) class II molecules in association with antigenic peptide recognize T cell receptors (TCRs) on CD4+ T cells. Such recognition of MHC II-peptide complexes by T cells in the absence of costimulatory signals is known to induce T cell nonresponsiveness. The present study describes that recognition of TCRs by MHC class II-peptide complexes induces antigen-specific apoptosis in a T cell clone independently of nonresponsiveness. Apoptosis was demonstrated in a murine T cell clone (4R3.9) restricted for IAk in association with a peptide analog of myelin basic protein [MBP(1-14)A4]. A dose- and time-dependent T cell death was observed upon incubation of 4R3.9 T cells with purified IAk-MBP(1-14)A4 complexes. The specificity of T cell apoptosis was shown by incubating 4R3.9 T cells with irrelevant IAs-MBP(90-101) complexes. The DNA fragmentation as a result of apoptosis was demonstrated by agarose gel electrophoresis and by pulsing T cells with BrdU followed by the detection of BrdU-labeled DNA fragments using an antibody enzyme-linked immunosorbent assay. The expression level of two regulatory intracellular proteins, bcl-2 and bax, involved in apoptosis showed a decrease in bcl-2 and an increase in bax with time. Finally, the nuclear shrinkage and chromatin condensation, typical hallmark of apoptosis, have been demonstrated by transmission electron microscopy of complex-treated T cells. Since the T cell clone (4R3.9) used in this study failed to show nonresponsiveness by IAk-MBP(1-14)A4 complexes, our results suggest that apoptosis induced by purified MHC class II-peptide complexes may involve distinct pathways rather than T cell nonresponsiveness. Such antigen-specific apoptosis may have significant clinical relevance in deleting autoreactive T cells in various autoimmune diseases.

Functionally active recombinant alpha and beta chain-peptide complexes of human major histocompatibility class II molecules

Major histocompatibility (MHC) class II molecules are cell surface heterodimeric (alphabeta) glycoproteins that display processed antigens to T cell receptors (TCRs) of CD4-positive T cells. The present study describes that individual recombinant alpha and beta chains of human MHC class II molecules lacking the transmembrane region (alpha-Tm and beta-Tm) are capable of binding antigenic peptide and that these complexes of chain-peptide are recognized by TCRs to induce antigen-specific apoptosis in restricted T cells. The alpha-Tm and the beta-Tm of human HLA-DR2 (DRB5*0101) were cloned, expressed in Escherichia coli, and purified in large scale by conventional chromatographic methods. The in vitro binding of an immunodominant epitope from the myelin basic protein (MBP-(83-102)Y83) to purified DR2 alpha-Tm and DR2 beta-Tm was demonstrated with biotinylated and fluoresceinated MBP-(83-102)Y83 peptide. The specificity of the MBP-(83-102)Y83 peptide binding to both DR2 alpha-Tm and DR2 beta-Tm was demonstrated in a competitive peptide binding assay. When exposed to a transformed T cell clone (SS8T) restricted to DR2(DRB5*0101) and MBP-(84-102) peptide, complexes of DR2 alpha-Tm and DR2 beta-Tm with MBP-(83-102)Y83 peptide were able to specifically recognize TCRs as measured by the increase in gamma-interferon (gamma-IFN) cytokine. Such recognition of TCRs by soluble alpha-MBP-(83-102)Y83 and beta-MBP-(83-102)Y83 complexes led to the induction of antigen-specific apoptosis in SS8T cells as measured by double fluorescence flow cytometry and electron microscopy. These results provide the first evidence that soluble complexes of antigenic peptide and individual chains of human MHC class II molecules lacking the transmembrane region can recognize TCRs and induce antigen-specific apoptosis in T cells. Since activated CD4-positive T cells are involved in pathogenesis of various autoimmune diseases, the apoptosis triggered by individual soluble chain-peptide complexes has significant potential for eliminating autoreactive T cells.

Mechanisms of resistance to 6-aminonicotinamide

Several cell lines resistant to 6-aminonicotinamide (6-AN) have been isolated, some selected with 6-AN and others with tiazofurin. These cell lines have been characterized with respect to several parameters including cross-resistance to tiazofurin, ability to metabolize 6-AN or tiazofurin to the respective analog metabolites of NAD, accumulation of 6-phosphogluconate in the presence of drug, and levels of NAD pyrophosphorylase (EC 2.7.7.1). Cell lines selected with 6-AN (ANR) are not cross-resistant to tiazofurin and have retained the ability to synthesize the NAD analogs, 6-aminonicotinamide adenine dinucleotide (6-ANAD), the phosphorylated derivative (6-ANADP) and thiazole-4-carboxamide adenine dinucleotide (TAD) when treated with 6-AN or tiazofurin respectively. The cell lines selected with tiazofurin are all cross-resistant to 6-AN; the most resistant of the lines are unable to form the NAD analog metabolites in detectable amounts and appear deficient in NAD pyrophosphorylase (EC 2.7.7.1) activity, the enzyme that is presumably responsible for their formation. The parent CHO line accumulates 6-phosphogluconate in the presence of 6-AN indicating inhibition of 6-phosphogluconate dehydrogenase. Of the resistant cell lines only two of them accumulate this intermediate.

Antigen-specific apoptosis in immortalized T cells by soluble MHC class II-peptide complexes

The recognition of T cell receptors (TCR) by purified major histocompatibility complex (MHC) class II-peptide complexes in the absence of costimulatory signals leads to the induction of T cell non-responsiveness or anergy. In a recent study using human T cell clones, it was observed that prolonged incubation of resting T cells with soluble MHC II-peptide complexes appears to result in T cell apoptosis. The present study shows that the engagement of TCR by soluble MHC II-peptide complexes also results in antigen-specific apoptosis in immortalized T cells. Apoptosis was demonstrated in a herpes saimiri virus (HSV) transformed human T cell clone (SS8T) restricted for HLA-DR2 in association with an epitope from the myelin basic protein [MBP(84-102)]. A dose- and time-dependent T cell death was observed upon incubation of SS8T cloned T cells with purified complexes of native human HLA-DR2 and MBP(83-102)Y83 peptide. The specificity of T cell apoptosis was demonstrated by exposing SS8T cells with DR2 alone and DR2 bound to another high affinity epitope [MBP(124-143)] from the same MBP. Recently, we have shown that the complexes of HLA-DR2 and [MBP(83-102)Y83] can be reconstituted by refolding Escherichia coli expressed individual DR2 alpha and beta (B5*0101) polypeptide chains lacking the transmembrane region. When SS8T cloned T cells were exposed to purified reconstituted rDR2.MBP(83-102)Y83 complexes, similar apoptosis of T cells was observed. Agarose gel analysis of T cells incubated with complexes showed a degradation of celluar deoxyribonucleic acid (DNA) to oligonucleosomal bands, a characteristic of apoptosis. The quantitative detection of DNA strand breaks was performed by pulsing T cells with 5-bromo-2'-deoxyuridine (BrdU) followed by the detection of BrdU-labelled DNA fragments using an antibody sandwich enzyme-linked immuno assay (ELISA). The fragmentation of DNA was also measured by double fluorescence flow cytometry by 3' end labelling of fragmented DNA with biotinylated-deoxyuridine triphosphate (dUTP) in the presence of terminal deoxynucleotide transferase (TdT) enzyme. The expression of the bcl-2 protein in SS8T cells following TCR engagement by soluble MHC II-peptide complexes was monitored by chemiluminescence blot analysis using anti-bcl-2 monoclonal antibody. Finally, the nucleosomal condensation of T cells following complex treatment, characteristics of typical apoptosis, was demonstrated by transmission electron microscopy. These results suggest that the binding of soluble MHC class II-peptide complexes to TCR induces antigen-specific apoptosis in transformed CD4 positive T cells in vitro. Such induction of apoptosis by soluble MHC II-peptide complexes may provide a novel therapeutic strategy to delete autoreactive T cells in various autoimmune diseases.

Metabolism and action of benzamide riboside in Chinese hamster ovary cells

Benzamide riboside (3-(1-deoxy-beta-D-ribofuranosyl)benzamide, BR) a new analog of nicotinamide riboside, is toxic to Chinese hamster ovary cells and inhibits guanine nucleotide synthesis in a manner comparable to that of tiazofurin (2-beta-D-ribofuranosylthiazole-4-carboxamide). Adenosine kinase deficient cells demonstrate slight resistance but retain the ability to form the NAD analog, benzamide adenine dinucleotide (BAD). HPLC analysis of BAD containing cells is described. A BR resistant cell line was isolated that demonstrates cross-resistance to both tiazofurin and 6-aminonicotinamide, suggesting a common metabolic step; enzymatic analysis indicates reduced levels of NAD pyrophosphorylase in these cells. BR toxicity was only partially reversed or prevented by the presence of guanosine, suggesting either that BR inhibits guanine salvage to some extent or, more probably, that BR can, at high concentration, inhibit cell growth by another mechanism in addition to inhibition of guanine nucleotide synthesis. Cells incubated with BR for several hours retain the ability to salvage exogenously provided guanosine. The demonstration that BAD can be phosphorylated by NAD kinase, presumably to form BADP, suggests that this metabolite may be formed in cells and may have inhibitory activity at high concentrations of BR.

Stimulation of T cells by antigen-presenting cells is kinetically controlled by antigenic peptide binding to major histocompatibility complex class II molecules

Activation of CD4+ T cells by antigenic peptide involves the interaction of major histocompatibility complex (MHC) class II-peptide complexes on the surface of antigen-presenting cells (APCs) with T-cell receptors. This report describes the kinetics of T-cell triggering by exogenous antigenic peptides in the presence of APCs. A rapid specific increase in extracellular acidification rate is observed within minutes upon exposure of A.E7 T cells (restricted for IEk and moth cytochrome c peptide containing residues 88-103) and 4R3.9 T cells (restricted for IAk and myelin basic protein peptide containing residues 1-14 [AcMBP-(1-14)]) to their cognate peptides in the presence of CH27 cells bearing both IAk and IEk MHC class II molecules. Pretreatment of cloned T cells, but not APCs, with herbimycin A resulted in complete inhibition of triggering events, indicating that the acidification response is mediated by T-cell second messenger pathways. This rapid assay for 4R3.9 T-cell stimulation showed increased T-cell triggering activity for AcMBP-(1-14)-A4 and MBP-(1-14)-M4 peptides compared to the native AcMBP-(1-14)-K4. By using the previously determined kinetic constants for MBP-(1-14)-A4 reactions with IAk, it is possible to show that at the lowest peptide concentrations the kinetics of T-cell triggering are limited by the kinetics of the peptide binding to MHC class II molecules.

Refolding and reconstitution of functionally active complexes of human leukocyte antigen DR2 and myelin basic protein peptide from recombinant alpha and beta polypeptide chains

Major histocompatibility complex (MHC) class II molecules are cell surface heterodimeric glycoproteins consisting of one alpha and one beta polypeptide chain of similar size. These molecules play a critical role in immune recognition by displaying processed antigens to CD4-positive T helper cells. Several attempts to express the MHC class II molecules by recombinant methods in various systems resulted in either failure or poor recovery of the intact heterodimer. The present study describes our successful effort to refold and reconstitute HLA DR2 heterodimer from individually expressed alpha and beta polypeptide chains lacking the transmembrane hydrophobic regions in Escherichia coli, in the presence of an immunodominant epitope analog from human myelin basic protein (b-MBP(83-102)Y83). The reconstituted DR2 heterodimer complex was selectively purified from unfolded alpha and beta chains using heterodimer-specific monoclonal antibody (L243) coupled to a solid support. The detection of two polypeptide chains in the purified refolded DR2-peptide complex preparations was accomplished by Western blot analysis and enzyme-linked immunosorbent assay using heterodimer- and chain-specific polyclonal antibodies, and the presence of equimolar amounts of both alpha chain and beta chain in the reconstituted complex preparation was confirmed by a double label experiment. The quantitation of the bound peptide in complex preparation was measured by incubating two chains in the presence of 125I-labeled peptide. An increase in the yield of refolded and reconstituted DR2-peptide complexes was observed with increasing peptide concentration in the reaction mixture. Finally, the functional activity of the reconstituted DR2 complexes was measured by their ability to stimulate gamma-interferon production by SS8T cloned T cells in an antigen-specific and dose-dependent manner. These results demonstrate that biologically active complexes of human DR2.b-MBP (83-102)Y83 can be prepared by proper folding of human leukocyte antigen DR2 alpha and beta chains in the presence of antigenic peptide. The yield of such DR2 heterodimers with bound peptide is several thousand-fold higher over native DR2 purified from transformed B cells. Since purified MHC class II-peptide complexes have been shown to prevent autoimmune diseases in various animal models, reconstituted heterodimer complexes may have significant clinical relevance in antigen-specific treatment of various autoimmune diseases. In addition, such complexes with increased yield will provide better understanding of the trimolecular interactions between MHC-peptide and T cell receptor.

Antigenic peptide binding to MHC class II molecules at increased peptide concentrations

Affinity-purified major histocompatibility complex (MHC) class II molecules are known to bind antigenic peptides in vitro. The percentage of MHC class II molecules occupied with such peptides is usually very low and varies significantly depending upon the sequence and size of a given antigenic peptide. The present study describes a method by which complete saturation of affinity-purified MHC class II with antigenic peptide can be achieved by simply incubating purified MHC class II molecules at neutral pH in the presence of several 100-fold molar excess of antigenic peptide. Complexes of human HLA-DR2 and a peptide analog from human myelin basic protein MBP (83-102)Y83 were selected for this study. The on-rate kinetic results showed saturation of MHC class II occupancy at 300-500-fold molar excess peptide concentrations. The specificity of the MBP (83-102)Y83 peptide binding to HLA-DR2 at higher peptide concentration was demonstrated by incubating an equivalent amount of another epitope from myelin basic protein [MBP (1-14) peptide] as well as by competitive binding assays. The quantitation of bound peptide was carried out using biotinylated-MBP (83-102)Y83 peptide which showed 100-125% occupancy of HLA-DR2 with a recovery of 100%. The presence of a single peptide entity in purified complexes was confirmed by reverse-phase narrowbore HPLC analysis of the acid extracted supernatant and by mass spectrometry analysis. Two-dimensional gel electrophoresis (IEF/SDS) of purified HLA-DR2 and DR2.MBP (83-102)Y83 complexes showed the absence of various endogenous polypeptides in 100% loaded complexes. These results demonstrate that higher peptide concentrations can be useful in generating MHC class II-peptide complexes of defined composition. Such complexes of MHC class II occupied with a single peptide may have significant clinical relevance for antigen-specific therapy of various autoimmune diseases and may provide better understanding of MHC-peptide-TCR interactions.

A synthetic peptide from the third hypervariable region of major histocompatibility complex class II beta chain as a vaccine for treatment of experimental autoimmune encephalomyelitis

Experimental autoimmune encephalomyelitis (EAE) is a class II major histocompatibility complex (MHC)-restricted, T-cell-mediated, demyelinating autoimmune disease of the central nervous system and represents a model for human multiple sclerosis. The present study demonstrates that vaccination of SJL/J mice with an 18-amino acid synthetic peptide from the third hypervariable region of the murine class II MHC IAs beta chain (IAs beta 58-75; 18-mer peptide) is capable of eliciting auto-anti-IAs antibodies specific for the IAs beta chain and preventing and treating EAE. A similar approach may be useful in the treatment of human autoimmune diseases in which susceptibility is linked to class II MHC genes.

The role of N-linked oligosaccharides of MHC class II antigens in T cell stimulation

A specific increase in T cell extracellular acidification rate has been demonstrated recently when complexes of purified MHC class II molecules and antigenic peptides interact with T cell receptors (TCRs) on cloned T cells. The present study shows that such measurements of an increase in extracellular acidification rate can be used to evaluate the functional role of various N-linked oligosaccharides of MHC class II antigens. Affinity-purified murine IAk and IAs were deglycosylated in the presence of aspargine-amidase enzyme and were characterized by SDS-polyacrylamide gel electrophoresis. The complete removal of all three N-linked oligosaccharides from the alpha/beta heterodimer was confirmed by four different lectin-linked Western blot analyses. Similar to the native heterodimer, both deglycosylated IAk and deglycosylated IAs were fully capable of binding synthetic antigenic peptides derived from myelin basic protein (MBP). When equivalent amount of glycosylated and deglycosylated class II-peptide complexes were exposed to restricted cloned T cells, identical increases in T cell extracellular acidification rates were observed. The specificity of such increases in extracellular acidification rate was demonstrated by exposing cloned T cells to irrelevant complexes of glycosylated and deglycosylated class II and antigenic peptides. These results show how measurement of extracellular acidification rate can be used to study structure-function correlations of ligand-receptor interactions, and support an earlier observation that N-linked oligosaccharides of murine MHC class II molecules are not involved in either antigenic peptide binding or T cell recognition.

Intramolecular charge heterogeneity in purified major histocompatibility class II alpha and beta polypeptide chains

Major histocompatibility (MHC) class II antigens are heterodimeric cell surface glycoproteins consisting of an alpha and a beta chain. Although one-dimensional SDS-polyacrylamide gel electrophoresis analysis of purified MHC class II antigens shows a single diffuse band for each chain, multiple spots of identical molecular size were observed for each chain when analyzed by two-dimensional electrophoresis. The basis of this heterogeneity has not been clearly defined and has been predicted partially to be due to glycosylation and/or phosphorylation of the mature protein. To investigate the role of the three N-linked oligosaccharides of the alpha and beta chains in determining the isoelectric point of each chain, affinity-purified MHC class II antigens from human and rat sources were deglycosylated using asparagine amidase. The complete enzymatic removal of all three N-linked oligosaccharides was confirmed by SDS-polyacrylamide gel electrophoresis as well as by four different lectin-linked Western blot analyses. Two-dimensional gel analysis of the deglycosylated molecules shows no significant difference from the fully glycosylated chains. We have expressed truncated forms of the HLA DR2 chains which lack the transmembrane and cytoplasmically exposed regions in Escherichia coli. Two-dimensional electrophoresis of these single chains also reveal multiple banding patterns. The two-dimensional banding patterns described are unaffected by exposure to acidic or basic conditions, increased gel running time in the first dimension, treatment of the proteins with alkaline phosphatase to remove any potential phosphorylation, or preincubation in the presence of iodoacetamide. Multiple forms of recombinant alpha and beta chains were also observed in Tris-glycine-urea gels which merged into a single band in the presence of SDS. In addition, partially fractionated bands from preparative isoelectric focusing gels, when refocused, showed an identical number of multiple spots spanning the same range of isoelectric points. These results together suggest that each polypeptide chain of MHC class II antigens may exist in multiconformational forms, and the observed charge heterogeneity is independent of glycosylation and phosphorylation of the proteins.

Separation of complexes of major histocompatibility class II molecules and known antigenic peptide by metal chelate affinity chromatography

A small fraction of affinity-purified MHC class II molecules are known to bind antigenic peptides in vitro. No simple method with acceptable recovery exists for separation of complexes of a known antigenic epitope and MHC class II from empty MHC class II and complexes of MHC class II and endogenously bound peptide. Here we describe an one step metal chelate affinity chromatography method to purify complexes of MHC class II and antigenic peptide of known composition. Complexes of human HLA-DR2 (DRB1*1501/DRB5*0101) and a peptide analog from human myelin basic protein MBP(84-102) containing a 6 histidine tag (6 x His) and a tyrosine residue at the N-terminus end [6 x His-MBP(83-102)Y83] were prepared and purified. The absence of residual free 6 x His-MBP peptide in the complex preparations were confirmed by gel filtration and TLC analyses. The purified complexes were applied onto Ni2+.nitrilotriacetic acid (Ni2+.NTA)-agarose affinity support and 6 x His-tagged peptide class II complexes were selectively eluted with imidazole-containing buffer. The quantitation of bound peptide in the eluted complexes showed 100% occupancy of HLA-DR2 (DRB1*1501/DRB5*0101) with [6 x His-MBP(83-102)Y83] peptide with a recovery of 50-75%. The presence of a single peptide entity in the eluted complexes was confirmed by reverse-phase narrowbore HPLC analysis of the acid-extracted supernatant and by amino acid sequencing analyses. As expected, no endogenous polypeptide was detected in the Ni2+.NTA eluted complexes when analyzed by two-dimensional IEF gel electrophoresis. Finally, we demonstrate that both MBP(84-102) and [6 x His-MBP(83-102)Y83] peptides were equally capable of stimulating restricted T cell line in the presence of autologous antigen presenting cells (APCs). These results demonstrate that metal chelate affinity chromatography can be used to prepare MHC class II-peptide complexes containing single peptide. Such complexes of class II molecules containing known peptide have significant clinical relevance for antigen-specific therapy of various autoimmune diseases and may provide better understanding of the trimolecular interaction between MHC class II, antigenic peptide and T cell receptor (TCR).