A dynamic flux in natural killer cell subsets as a function of the duration of alcohol ingestion.

BACKGROUND: Chronic ethanol (EtOH) consumption is associated with a wide variety of immune abnormalities including changes in T cells, B cells, dendritic cells, and natural killer (NK) cells. However, there is conflicting information as to the direction of such immune changes. The hypothesis that was tested in this report is that, for NK cells, the changes can vary as a function of the duration of alcohol ingestion. METHODS: Using the Meadows-Cook murine model of chronic alcohol ingestion, the changes in NK cell function and subset distribution were examined as a function of the duration of alcohol ingestion. RESULTS: Acute alcohol ingestion resulted in decreased number and cytotoxic function of NK cells with no effect on intracellular interferon gamma expression. These abnormalities normalized after 12 to 14 days of alcohol ingestion and there was an increase of NK cell number and cytotoxicity after 8 weeks of continued EtOH ingestion. Ten weeks of continued alcohol consumption results in a significant decrease in the Ly49H+ CD11b+ CD27- splenic NK cell subset; this difference continued to be significant at 30 weeks. CONCLUSIONS: This report may explain some of the conflicting data in the literature that examined NK cell activity in alcoholic patients. It is apparent that various abnormalities can be seen in NK cell activity and subset distribution with the flux being a function of the duration of alcohol ingestion. The demonstration of a decrease in the Ly49H+ subset (which is known to be involved in resisting murine cytomegalovirus infection) may explain the reported increase in susceptibility to some viral infections in chronic alcohol abuse. Another novel finding is that changes of some subsets of NK cells are not evident until at least 10 weeks of continued EtOH consumption.

Alcohol and inflammation and infection: clinical and experimental systems--summary of the 2010 Alcohol and Immunology Research Interest Group Meeting.

The 15th annual meeting of the Alcohol and Immunology Research Interest Group was held on November 19, 2010, at Loyola University Medical Center in Maywood, IL. This year, the focus of the meeting was on alcohol's effect on the immune system in both clinical and experimental systems. The event consisted of three sessions, which featured plenary talks from invited speakers along with oral presentations from selected abstracts, in addition to a poster session. Participants presented a variety of information on ethanol-induced effects on infection susceptibility and resolution, oxidative stress, and organ inflammation. Specifically, speakers presented new insights on the mechanism of alcohol-mediated deleterious effects in the lung, liver, skin, and neuroendocrine system, as well as on immune cells in both in vivo and in vitro systems. Additional oral presentations suggested possible mechanisms of how alcohol-induced reactive oxygen species promote immune dysregulation both locally and systemically.

Mechanisms by which chronic ethanol feeding limits the ability of dendritic cells to stimulate T-cell proliferation.

BACKGROUND: As initiators of immune responses, dendritic cells (DCs) are required for antigen (Ag)-specific activation of naïve T cells in the defense against infectious agents. The increased susceptibility to and severity of infection seen in chronic alcoholics could be because of impaired DCs initiation of naïve T-cell responses. Specifically, these DCs may not provide adequate Signals 1 (Ag presentation), 2 (costimulation), or 3 (cytokine production) to these T cells. METHODS: Using the Meadows-Cook murine model of chronic alcohol abuse, the ability of ethanol (EtOH)-exposed DCs to stimulate T-cell proliferation, acquire and process Ag, express costimulatory molecules, and produce inflammatory cytokines was assessed. RESULTS: Normal naïve T cells primed by EtOH-exposed DCs showed decreased proliferation in vitro and in vivo, compared to water-fed control mice. These EtOH-exposed DCs, after activation by CpG or tumor necrosis factor alpha (TNFα), were less able to upregulate costimulatory molecules CD40, CD80, or CD86, and produced less IL-12 p40, TNFα, and IFNα than DCs from water-fed mice. TLR9 and TNF receptor expression were also reduced in/on EtOH-exposed DCs. No evidence of defective Ag acquisition or processing as a result of EtOH feeding was identified. CONCLUSIONS: Inadequate proliferation of normal T cells following stimulation by EtOH-exposed DCs is likely a result of diminished Signal 2 and Signal 3. Lack of adequate inflammatory stimulation of EtOH-exposed DCs because of diminished receptors for inflammatory mediators appears to be at least partially responsible for their dysfunction. These findings provide a mechanism to explain increased morbidity and mortality from infectious diseases in alcoholics and suggest targets for therapeutic intervention.

Oseltamivir treatment prevents the increased influenza virus disease severity and lethality occurring in chronic ethanol consuming mice.

BACKGROUND: Chronic consumption of ethanol (EtOH) is well recognized to lead to defective innate and adaptive immune responses and increase the severity of pulmonary infections. Our own studies have demonstrated that chronic EtOH consumption decreases CD8 T-cell immunity to influenza virus infections (IAV) leading to severe infections and mortality. Interestingly, antiviral treatment of IAVs has been shown to be compromised in mice and humans that are immuno-deficient. It is known that EtOH can alter the pharmacokinetics of antivirals. Therefore, the effectiveness of influenza antiviral therapy during chronic ethanol consumption remains in question. METHODS: BALB/c mice were placed on 18% (w/v) EtOH in their drinking water for 8 weeks. Chronic EtOH consuming and water controls were then treated with 10 mg/kg oseltamivir orally and infected intranasally with influenza virus 4 hours post-oseltamivir treatment. The mice were then treated with oseltamivir twice daily until day 7 postinfection. Influenza disease severity was measured by morbidity and mortality, pulmonary viral titers, and histology. RESULTS: Chronic EtOH consuming mice infected with IAV and treated with oseltamivir have decreased morbidity and mortality, pulmonary viral titers, and pulmonary pathology compared to untreated EtOH mice. CONCLUSIONS: Despite the severe immune defect seen in chronic EtOH mice as well as the potential for EtOH to inhibit the conversion of oseltamivir into an active form, treatment with oseltamivir reduces viral shedding as well as disease severity. These data suggest that the combination of a limited adaptive immune response plus the anti-IAV drug oseltamivir is sufficient to curb high mortality and mediate resolution of IAVs in mice chronically consuming ethanol.

Fetal exposure to ethanol has long-term effects on the severity of influenza virus infections.

Alcohol use by pregnant women is a significant public health issue despite well-described risks to the fetus including physical and intellectual growth retardation and malformations. Although clinical studies are limited, they suggest that in utero alcohol exposure also results in significant immune deficiencies in naive neonates. However, little is known about fetal alcohol exposure (FAE) effects on adult infections. Therefore, to determine the long-term effects of FAE on disease susceptibility and the adult immune system, we infected FAE adult mice with influenza virus. In this study, we demonstrate that mice exposed to ethanol during gestation and nursing exhibit enhanced disease severity as well as increased and sustained pulmonary viral titers following influenza virus infection. Secondary exposure to alcohol as an adult further exacerbates these effects. Moreover, we demonstrate that FAE mice have impaired adaptive immune responses, including decreased numbers of virus-specific pulmonary CD8 T cells, a decreased size and frequency of pulmonary B cell foci, and reduced production of influenza-specific Ab following influenza infection. Together, our results suggest that FAE induces significant and long-term defects in immunity and susceptibility to influenza virus infection and that FAE individuals could be at increased risk for severe and fatal respiratory infections.

Chronic ethanol induces inhibition of antigen-specific CD8+ but not CD4+ immunodominant T cell responses following Listeria monocytogenes inoculation.

Chronic ethanol consumption results in immunodeficiency. Previous work with chronic ethanol-fed mice has shown reduced splenic weight and cellularity, including reduced numbers of CD8+ T cells. However, antigen-specific CD8+ and CD4+ T cell responses in chronic ethanol-fed mice have been studied relatively little. We have used an attenuated Listeria monocytogenes strain DPL 1942 (LM DeltaactA) to inoculate mice and subsequently used CD4+ and CD8+ immunodominant peptides of LM to measure the CD4+ and CD8+ T cell responses after chronic ethanol exposure. We found no major differences between control and ethanol-fed mice in the kinetics and persistence of antigen-specific CD4+ T cells in response to an immunodominant LM peptide, as measured by intracellular IFN-gamma staining. In contrast to CD4+ responses, three methods of in vitro antigen presentation indicated that the primary response of CD8+ T cells to several different epitopes was reduced significantly in mice chronically fed ethanol. Antigen-specific CD8+ T cells were also reduced in chronic ethanol-fed mice during the contraction phase of the primary response, and memory cells evaluated at 29 and 60 days after inoculation were reduced significantly. BrdU proliferation assays showed that in vivo proliferation of CD8+ T cells was reduced in ethanol-fed mice, and IL-2-dependent in vitro proliferation of naive CD8+ T cells was also reduced. In conclusion, these results suggest that antigen-specific CD4+ T cell responses to LM are affected little by chronic ethanol consumption; however, antigen-specific CD8+ T cell responses are reduced significantly, as are in vivo and in vitro proliferation. The reduction of antigen-specific CD8+ T cells may contribute strongly to the immunodeficiency caused by ethanol abuse.

Chronic alcohol consumption increases the severity of murine influenza virus infections.

Respiratory infections with both seasonal as well as potential pandemic Influenza viruses represent a significant burden on human health. Furthermore, viruses such as Influenza are increasingly recognized as important etiologic agents in community acquired pneumonia. Within the U.S. alone, approximately 12.9 million people are heavy drinkers and chronic abuse of alcohol is known to increase the risk and severity of community acquired pneumonia. Given the lack of knowledge regarding Influenza disease in this population, we determined the effects of chronic alcohol consumption on Influenza virus infection. Herein, we report that mice exposed to chronic ethanol have sharp increases in morbidity, mortality, and pulmonary virus titers relative to controls. These increases in influenza severity correspond with inhibited pulmonary influenza-specific CD8 T cell responses. Further, chronic ethanol consumption results in an enhanced pulmonary lesion severity, similar to that recently described for pandemic influenzas. Together, our results suggest that chronic alcohol consumption may increase the risk for severe influenza virus infections by altering the pulmonary inflammatory environment and CD8 T cell response.

Effects of chronic ethanol feeding on murine dendritic cell numbers, turnover rate, and dendropoiesis.

BACKGROUND: Chronic alcoholics have increased susceptibility to and severity of infection, which are likely to be a result of impaired immune defense mechanisms. The contribution of dendritic cells (DC) to these immune defense changes is not well understood. Alterations in DC numbers, dendropoiesis, and lifespan have not been specifically studied in vivo in chronic ethanol (EtOH) exposure models. As DC play an essential role in initiating immune responses, alterations in these DC characteristics would help explain changes observed in adaptive immune responses. METHODS: Mice received 20% EtOH (w/v) in the drinking water for up to 28 weeks, with mouse chow ad libitum. In EtOH-fed and water control mice, DC were enumerated by flow cytometry. The effect of EtOH on DC precursor numbers was determined by differentiation in vitro in the presence of granulocyte-macrophage colony-stimulating factor and interleukin-4, and the effect of an EtOH environment on untreated DC differentiation was measured following bone marrow transfer to irradiated hosts. DC turnover rate was also examined by bromodeoxyuridine incorporation and loss. RESULTS: The percentage and absolute numbers of DC were decreased in spleen and increased in thymus beginning as early as 4 weeks of EtOH feeding. In addition, the overall cellularity of spleen and thymus were altered by this regimen. However, chronic EtOH consumption did not adversely affect DC precursor numbers, differentiation abilities, or turnover rates. CONCLUSIONS: Decreased splenic DC numbers observed following chronic murine EtOH consumption are not because of altered DC precursor numbers or differentiation, nor increased DC turnover rate. Similarly, increased thymic DC numbers are not the result of alterations in DC precursor differentiation or turnover rate. Compartment size plays a role in determining splenic and thymic DC numbers following chronic EtOH feeding. EtOH-induced alterations in total DC numbers provide several mechanisms to partially explain why chronic alcoholics have increased susceptibility to infections.

Alcohol and inflammation and immune responses: summary of the 2006 Alcohol and Immunology Research Interest Group (AIRIG) meeting.

The 11th annual meeting of the Alcohol and Immunology Research Interest Group was held at Loyola University Medical Center, Maywood, Illinois on November 17, 2006. The Alcohol and Immunology Research Interest Group meeting is held annually to exchange new findings and ideas that arise from ongoing research examining the effects of alcohol intake on the immune system. The event consisted of five sessions, two of which featured plenary talks from invited speakers, two with oral presentations from selected abstracts, and a final poster session. Participants presented new data on a variety of topics including the effects of ethanol on key cells of the immune system (neutrophils, dendritic cells, NK cells), B cell responses, the capacity to clear infectious agents, and the barrier functions of skin, lung, and intestine.

A practical method of chronic ethanol administration in mice.

Mice provide a useful model for the study of immune deficiency caused by chronic alcohol abuse. Their suitability is related to several factors, including in particular the extensive knowledge base in the immunology of mice already existing in the literature. Specific modeling of the immunodeficiency of the chronic human alcoholic requires that ethanol must be administered to the model for a significant portion of its life span. In mice, it has proven to be necessary to administer ethanol daily for up to 32 wk or longer to observe all the immune abnormalities that occur in middle-aged alcoholic humans. Such time spans are problematic with many of the common protocols for ethanol administration. It has been shown by others and confirmed by our group that the most practical way of accomplishing such long protocols is by administering ethanol in water as the only choice of water. Details of management of the chronic ethanol mouse colony are described here that are necessary for the success of such studies, including methods for initiating ethanol administration, maintenance of barrier protection, monitoring weight gain, strain differences and fetal alcohol exposure.

Polyclonal and antigen-specific responses of T cells and T cell subsets.

Evaluation of the functional responses of T cells is of importance in determining the mechanism(s) of immunodeficiency resulting from chronic alcohol abuse and other conditions that lead to immune dysfunction. Mice that are chronically exposed to 20% (w/v) ethanol in water develop immunodeficiency and have T cells with abnormal activation profiles, reduced total numbers, increased CD4/CD8 ratios, and an increased memory/naïve phenotype ratio. These cells also have abnormal antigen-specific responses after inoculation of the ethanol mice with model infectious organisms. Study of the functional abnormalities of these cells requires a reliable system that can present appropriate activation stimuli in vitro for the generation of polyclonal or antigen-specific responses in enriched or purified T cells, free of the influence of previously ethanol exposed accessory cells. In this chapter, we describe protocols to assess the T cell response to polyclonal stimulation through the T cell receptor and the use of a model infectious disease bacterium, Listeria monocytogenes, that allows evaluation of the T-cell response to specific peptide epitopes of the bacterium after previous inoculation.

Chronic ethanol consumption decreases murine Langerhans cell numbers and delays migration of Langerhans cells as well as dermal dendritic cells.

BACKGROUND: Chronic alcoholics experience increased incidence and severity of infections, the mechanism of which is incompletely understood. Dendritic cells (DC) migrate from peripheral locations to lymph nodes (LN) to initiate adaptive immunity against infection. Little is known about how chronic alcohol exposure affects skin DC numbers or migration. METHODS: Mice received 20% EtOH in the drinking water for up to 35 weeks. Baseline Langerhans cell (LC) and dermal DC (dDC) numbers were enumerated by immunofluorescence (IF). LC repopulation after inflammation was determined following congenic bone marrow (BM) transplant and ultraviolet (UV) irradiation. Net LC loss from epidermis was determined by IF following TNF-alpha or CpG stimulation. LC and dDC migration into LN was assessed by flow cytometry following epicutaneous FITC administration. RESULTS: Chronic EtOH consumption caused a baseline reduction in LC but not dDC numbers. The deficit was not corrected following transplantation with non-EtOH-exposed BM and UV irradiation, supporting the hypothesis that the defect is intrinsic to the skin environment rather than LC precursors. Net loss of LC from epidermis following inflammation was greatly reduced in EtOH-fed mice versus controls. Ethanol consumption for at least 4 weeks led to delayed LC migration into LN, and consumption for at least 8 weeks led to delayed dDC migration into LN following epicutaneous FITC application. CONCLUSIONS: Chronic EtOH consumption causes decreased density of epidermal LC, which likely results in decreased epidermal immunosurveillance. It also results in altered migratory responsiveness and delayed LC and dDC migration into LN, which likely delays activation of adaptive immunity. Decreased LC density at baseline appears to be the result of an alteration in the skin environment rather than an intrinsic LC defect. These findings provide novel mechanisms to at least partially explain why chronic alcoholics are more susceptible to infections, especially those following skin penetration.

Thymocytes, pre-B cells, and organ changes in a mouse model of chronic ethanol ingestion--absence of subset-specific glucocorticoid-induced immune cell loss.

BACKGROUND: The well-known immune deficiency of the chronic alcoholic dictates the need for a long-term rodent ethanol administration model to evaluate the baseline immunologic effects of chronic ethanol abuse, and investigate the genetic determinants of those effects. Much published work with rodents has shown clearly that acute ethanol administration and short-term ethanol-containing liquid diets both cause elevated corticosterone and can cause significant thymocyte, pre-B cell and peripheral lymphocyte losses. Such losses may mask more subtle alterations in immune homeostasis, and in any case are generally short-lived compared with the span of chronic ethanol abuse. Thus, it is important to have a model in which long-term immune alterations can be studied free of corticosteroid-induced cell losses. METHODS: We have utilized chronic 20% (w/v) ethanol in water administration to several mouse strains for prolonged periods of time and evaluated serum corticosterone, immunologic stress parameters, and other organ changes by standard methods. RESULTS: We now confirm earlier reports that chronic ethanol in water administration to mice does not produce net elevations of corticosterone, although diurnal variation is altered. Importantly, there is neither selective loss of immune cell populations known to be corticosteroid sensitive, CD4+CD8+ thymocytes and pre-B cells, nor are changes observed in the histologic appearance of the thymus. Nonetheless, there are significant chronic ethanol effects in other tissues, including reduced heart weight, mild hepatic steatosis, alterations of gut flora, increased serum peptidoglycan, and as published elsewhere, immune system abnormalities. CONCLUSIONS: This model of ethanol administration is convenient, sustainable for up to 1 year, demonstrably feasible in several mouse strains, permits good weight gains in most strains, and results in significant changes in a number of organs. The administration method also will permit modeling of long-term steady abuse punctuated by major binges, and is suitable for supplementation studies using water soluble additives. Overall, the method is useful for a wide range of studies requiring a chronic low-stress method of ethanol administration.

Acute and chronic alcohol abuse modulate immunity.

This article represents the proceedings of the Alcohol and Immunology Research Interest Group (AIRIG) meeting, a satellite workshop held at the 37th Annual Meeting of the Society for Leukocyte Biology. The meeting was sponsored by the AIRIG and the National Institute on Alcohol Abuse and Alcoholism. The presentations were as follows: (1) Effects of Ethanol on Immune Response to Hepatitis C Virus by Jack R. Wands, (2) Alcohol and Alveolar Macrophage Dysfunction: The Role of Chronic Oxidant Stress by Lou Ann S. Brown, (3) T Cell Responses to Listeria monocytogenes in Mice on a Chronic Ethanol Exposure Protocol by Robert T. Cook, (4) Mechanisms of Acute and Chronic Alcohol Consumption on Severity of Viral Infections by the Liver and Pancreas by Thomas R. Jerrells, (5) Acute and Chronic Effects on Macrophage Ectodomain Shedding: Implications for Lung Host Defenses by Jay K. Kolls, (6) Increased Susceptibility to Pseudomonas Infection of Burn-Injured Mice Given Alcohol Before Injury by Elizabeth J. Kovacs, (7) Regulation of Tumor Necrosis Factor alpha Expression in Macrophages by Chronic Ethanol by Laura E. Nagy, and (8) Hepatitis C Virus Infection and Alcohol Use by Gyongyi Szabo. Meeting coorganizers were Elizabeth J. Kovacs, Lou Ann S. Brown, Thomas R. Jerrells, and Robert T. Cook.

Alcohol and inflammation and immune responses: summary of the 2005 Alcohol and Immunology Research Interest Group (AIRIG) meeting.

The 10th annual meeting of the Alcohol and Immunology Research Interest Group (AIRIG) was held at Loyola University Medical Center, Maywood, Illinois on November 18, 2005. The AIRIG meeting was held to exchange new findings and ideas regarding the profound suppressive effects of alcohol exposure on the immune system. The event consisted of five sessions, two of which featured plenary talks from invited speakers, two with oral presentations from selected abstracts, and a final poster session. Participants presented a range of novel information focused on ethanol-induced effects on innate and adaptive immunity after either acute or chronic exposure. In particular, participants offered insights into the negative effects of ethanol on the innate processes of adhesion, migration, inflammation, wound repair, and bone remodeling. Presentations also focused on the means by which ethanol disrupts activation of macrophages and dendritic cells (DC), especially stimulation mediated by Toll-like receptor ligands. Additional talks provided new data on the means by which ethanol suppresses adaptive immunity, with an emphasis on DC-mediated activation of T cells, effector T cell activity, and T cell-driven B cell responses.

RSA 2004: combined basic research satellite symposium-mechanisms of alcohol-mediated organ and tissue damage: inflammation and immunity and alcohol and mitochondrial metabolism: at the crossroads of life and death session one: alcohol, cellular and organ damage.

This article summarizes content proceedings of a satellite meeting held at the 2004 Research Society on Alcoholism Annual Scientific Meeting in Vancouver, Canada. The aim of the satellite conference was to facilitate the interaction of scientists investigating the mechanisms of alcohol-mediated organ or tissue damage, and enable the discussion and sharing of new ideas and concepts that may be common in each of the organs or tissues affected by chronic ethanol consumption. The original planned program on immunity was expanded to incorporate a session on a closely related topic "Alcohol and Mitochondrial Metabolism: At the Crossroads of Life and Death" organized by Dr. Jan Hoek and Dr. Sam Zakhari. The conference was arranged into four sessions: 1) Alcohol, Cellular and Organ Damage 2) Toll-like receptors and Organ Damage 3) Alcohol and Mitochondrial Metabolism: At the Crossroads of Life and Death and 4) Hepatitis virus and alcohol interactions in Immunity and Liver Disease. The keynote address was given by Dr. Bruce Beutler from the Scripps Institute on "TLRs in Inflammation and Immunity."The Combined Basic Research Satellite Symposium entitled, "Mechanisms of Alcohol-Mediated Organ and Tissue Damage: Inflammation and Immunity and Alcohol and Mitochondrial Metabolism: At the Crossroads of Life and Death" was convened at the 2004 Research Society on Alcoholism meeting in Vancouver, BC. Session One featured five speakers who discussed various aspects of the role of the immune system in initiating or exacerbating cellular and organ damage following alcohol consumption. The presentations were (1) Innate Immune responses of Alcohol-exposed mice and macrophage-like cells following infections with Listeria monocytogenes by Robert T. Cook 2) Alcohol, cytokines and host defense by Kyle Happel 3) Decreased antigen presentation and anergy induced by alcohol in myeloid dendritic cells by Pranoti Mandrekar 4) Transcriptional regulation of TNF-alpha in human monocytes by chronic ethanol: role of the cellular redox state by Jay Kolls 5) Estrogen and gender differences in inflammatory responses after alcohol and burn injury by Elizabeth Kovacs. This session highlighted the growing information on the role of pattern recognition molecules in alcohol-mediated tissue damage or dysfunction. The new techniques and ideas presented will be helpful in future studies in this area of research, and should result in some exciting avenues of study.

T-cell activation after chronic ethanol ingestion in mice.

Chronic excessive consumption of ethanol causes immunodeficiency in human beings and in mice. Immunologic changes have been described in both species, including T-cell and innate immune system cell activation, among others. The features of chronic ethanol-induced activation have similarities in the two species, including an increased effector subset in both CD4+ and CD8+ T cells. There are also features of activation observed in the splenic macrophages of mice consuming ethanol chronically, including increased up-regulation of CD80 and CD86. Because these molecules are involved in T-cell-antigen-presenting cell interactions in vivo, it is of interest to ask whether these and other pathways of interaction are important in the T-cell activation and cytokine skewing described in chronic ethanol abuse. Preliminary findings from comparisons of wild-type, CD40 ligand knock-out, and CD28 knock-out C57BL/6 mice strongly support the suggestion of a critical role for T-cell-antigen-presenting cell interactions in the immune alterations observed in chronic ethanol abuse.

Chronic ethanol ingestion by mice increases expression of CD80 and CD86 by activated macrophages.

Results from previous studies from our laboratory have shown that T cells obtained from the spleens of C57BL/6 mice that consumed ethanol chronically have increased expression of activation markers and increased second signal-independent production of interferon-gamma (IFN-gamma). We now report that in vitro-activated CD11b(+) splenocytes obtained from C57BL/6 and BALB/c mice that consumed ethanol chronically express increased levels of the T cell co-stimulatory molecules CD80 and CD86. CD11b(+) splenocytes encompass at least two populations: the CD11b(+)Gr.1(-) population, which is primarily monocytes-macrophages, and a smaller CD11b(+)Gr.1(+) population, which is in the myelocytic-monocytic cell series and contains precursors of both macrophages and neutrophils. Evaluation of cultures of purified CD11b(+) cells, obtained from mice that consumed ethanol chronically, incubated overnight, showed increased up-regulation of CD80 and CD86 expression on Gr.1(-) mouse splenic macrophages. Results of functional studies of purified CD11b(+) cells have demonstrated that CD11b(+) cells obtained from C57BL/6 mice that were exposed to ethanol chronically secrete higher levels, in comparison with the levels secreted by CD11b(+) cells obtained from control animals, of nitric oxide and several proinflammatory cytokines after stimulation by the oligodeoxynucleotide (ODN) CpG 1826. These findings indicate that CD11b(+) splenocytes are in some way sensitized to activating stimuli by chronic ethanol exposure in vivo. Such cells may contribute to systemic immunodysregulation, including T-cell activation, by providing abnormal second signals to T cells, or through excessive release of cytokines, such as interleukin (IL)-6 or IL-12.

Chronic ethanol consumption by mice results in activated splenic T cells.

Previous studies have shown that T cells from human alcoholics overexpress activation or memory markers such as human leukocyte antigen-DR, CD45RO, CD57, and CD11b and may have reduced levels of CD62L. In those studies, we demonstrated that the increased CD57(+) T cell population rapidly produces interferon-gamma (IFN-gamma) and tumor necrosis factor alpha, independent of a second signal requirement, consistent with an increased effector T cell population. In contrast to the length of alcohol abuse by human alcoholics, most work with mice has involved 2-week ethanol exposures or less, which result in decreased IFN-gamma responses. In the present work, we have evaluated C57Bl/6 or BALB/c mice, which were administered 20% w/v ethanol in water for 3-13 weeks. In these mice, rapid cytoplasmic IFN-gamma expression by T cells after stimulation through the T cell receptor was significantly increased versus normals. Studies of surface-activation markers showed that T cells from chronically ethanol-fed mice had reduced CD62L expression and an increased percentage of CD44(hi) T cells. The CD44(hi) subset was largely second signal-independent for secreted IFN-gamma and interleukin (IL)-4 production at early times after stimulation. The enriched T cells of chronic ethanol mice secreted more IFN-gamma and IL-4 than controls and equivalent IL-2 at early times after stimulation (6-24 h). The overall results support the concept that in humans and mice, chronic alcohol exposure of sufficient duration results in T cell activation or sensitization in vivo and an increased percentage of the effector/memory subset.

Aberrant T-cell antigen receptor-mediated responses in autoimmune lymphoproliferative syndrome.

Autoimmune Lymphoproliferative Syndrome (ALPS) is a disorder of defective lymphocyte apoptosis due to mutations of the Fas receptor and other molecules in the Fas signaling pathway. In addition to accumulation of CD4(-) CD8(-) double-negative (DN) T cells, many patients display a dysregulated cytokine pattern with dysfunctional T cells, suggesting Fas defects may impact pathways of T-cell activation/differentiation. Here, we report two novel mutations in the Fas receptor resulting in an ALPS phenotype. Utilizing flow cytometry, we found anti-CD3 activated CD4(+) T cells from these patients were incapable of fully upregulating activation markers (CD25, CD69, and CD40L) or producing interferon-gamma and IL-2. Additionally, DN T cells were unable to transduce proximal T-cell antigen receptor signals or produce cytokines. Furthermore, DN T cells overexpressed CD57 and phenotypically resembled end-stage effector cells. As DN T cells were essentially anergic, the clinical manifestations of autoimmunity are more likely to be a consequence of aberrant cytokine secretion within the CD4(+) T-cell subpopulation.