Richard T. Sawyer

Influence of MHC CLASS II in Susceptibility to Beryllium Sensitization and Chronic Beryllium Disease

A glutamic acid at residue 69(Glu69) in the HLA-DPB1 gene (Glu69) is associated with chronic beryllium disease (CBD) and possibly beryllium sensitization (BeS). This study tested the hypothesis that MHC class II polymorphisms are important in susceptibility to BeS and CBD and that the Glu69 variant is related to markers of disease severity. Genomic DNA was obtained from BeS (n = 50), CBD (n = 104), and beryllium-exposed nondiseased (Be-nondiseased) (n = 125) subjects. HLA-DPB1, -DRB1, and -DQB1 genotypes were determined by (sequence-specific primers) PCR. Disease severity was assessed by pulmonary function and exercise testing. A higher frequency of the DPB1 Glu69 gene was found in CBD and BeS compared with the Be-nondiseased subjects, with odds ratios of 10.1 for CBD vs Be-nondiseased and 9.5 for BeS vs Be-nondiseased. The majority of BeS and CBD subjects displayed non-0201 Glu69 alleles. Glu69 homozygosity was higher in the CBD subjects, while BeS subjects were intermediate and Be-nondiseased lowest. DRB1*01 and DQB1*05 phenotypes were reduced in CBD vs Be-nondiseased subjects, while DRB1*13 and DQB1*06 were associated with CBD in the absence of Glu69. Markers of disease severity, including a lower forced vital capacity, diffusion capacity for carbon monoxide, PaO2 at rest, maximum workload on exercise testing, and a higher arterial-alveolar gradient at rest, were associated with Glu69 homozygosity. We conclude that DPB1 Glu69 is a marker of sensitization and not specific for disease. Glu69 homozygosity acts as a functional marker associated with markers of CBD severity.

Chronic beryllium disease: a model interaction between innate and acquired immunity.

Beryllium (Be) is a lightweight and durable metal useful to a variety of manufacturing processes. With the use of Be in industrial settings, a number of health effects were noted including acute pneumonitis, sensitization to Be, interstitial lung disease and dermatological disease. Interstitial mononuclear cell inflammation and granuloma formation are the primary processes that occur in the lungs of Be-exposed workers, resulting in chronic beryllium disease (CBD). Recent studies have begun to describe the role of Be in the pathogenesis of CBD. These studies reveal that the hosts response to Be involves components of the innate immune system or inflammatory responses. Inflammatory responses to Be can establish a state of acquired, Be antigen-specific, cell-mediated immunity. Despite triggering both the innate and acquired immune responses, Be is not eliminated from the host. Rather, it establishes pathways leading to chronic granulomatous inflammation. We will examine recent studies describing the hosts cellular and molecular responses to Be, responses that promote granuloma formation.

Secondary ion mass spectroscopy demonstrates retention of beryllium in chronic beryllium disease granulomas.

Objective: We hypothesized that beryllium (Be) might persist in lung granulomas in patients with chronic beryllium disease (CBD). Methods: A total of 33 Be-exposed ceramics workers underwent transbronchial biopsy. They were classified based on histopathology and Be-lymphocyte proliferation test as CBD or other categories. Lung tissue sections were analyzed using secondary ion mass spectroscopy. Results: Be was detected in the lungs of all Be-exposed groups. Be levels were increased within the granulomas of patients with CBD compared with the Be levels outside granulomas. Notably, Be was detectable in the lungs of CBD patients who had ceased exposure to Be an average of 9 years previously. Conclusions: Be was detected in the lungs of all Be-exposed subjects, with the highest levels of persistent Be inside CBD lung granulomas. Be antigen persistence may help explain the chronicity of this granulomatous disorder.

Beryllium-stimulated apoptosis in macrophage cell lines

In vitro stimulation of bronchoalveolar lavage cells from patients with chronic beryllium disease (CBD) induces the production of TNF-alpha. We tested the hypothesis that beryllium (Be)-stimulated TNF-alpha might induce apoptosis in mouse and human macrophage cell lines. These cell lines were selected because they produce a range of Be-stimulated TNF-alpha. The mouse macrophage cell line H36.12j produces high levels of Be-stimulated TNF-alpha. The mouse macrophage cell line P388D.1 produces low, constitutive, levels of TNF-alpha and does not up-regulate Be-stimulated TNF-alpha production. The DEOHS-1 human CBD macrophage cell line does not produce constitutive or Be-stimulated TNF-alpha. Apoptosis was determined by microscopic observation of propidium iodide stained fragmented nuclei in unstimulated and BeSO(4)-stimulated macrophage cell lines. BeSO(4) induced apoptosis in all macrophage cell lines tested. Beryllium-stimulated apoptosis was dose-responsive and maximal after 24 h of exposure to 100 microM BeSO(4). In contrast, unstimulated and Al(2)(SO(4))(3)-stimulated macrophage cell lines did not undergo apoptosis. The general caspase inhibitor BD-fmk inhibited Be-stimulated macrophage cell line apoptosis at concentrations above 50 microM. Our data show that Be-stimulated macrophage cell line apoptosis was caspase-dependent and not solely dependent on Be-stimulated TNF-alpha levels. We speculate that the release of Be-antigen from apoptotic macrophages may serve to re-introduce Be material back into the lung microenvironment, make it available for uptake by new macrophages, and thereby amplify Be-stimulated cytokine production, promoting ongoing inflammation and granuloma maintenance in CBD.

Beryllium-stimulated production of tumor necrosis factor-α by a mouse hybrid macrophage cell line

Chronic beryllium disease (CBD) results from exposure to the light-weight metal beryllium (Be). In vitro stimulation of bronchoalveolar lavage cells from CBD subjects causes the production of high levels of TNF-alpha, IFN-gamma and IL-6. We tested the hypothesis that Be-stimulation might induce the production of TNF-alpha by macrophage cell lines. We observed that H36.12j cells (12j), a mouse hybrid macrophage cell line, but not other mouse and human macrophage cell lines, produced TNF-alpha upon Be-stimulation. The response was maximal at 100 microM BeSO4 and did not occur when 12j cells were stimulated with either aluminum sulfate or cobalt sulfate. Beryllium-stimulated the production of 725+/-25 pg/ml (mean +/- SEM) TNF-alpha protein by 12j cells as measured by ELISA of culture supernatants after 24 h. As measured by RT-PCR, Be-stimulated 12j cell TNF-alpha protein production was accompanied by an increased intracellular TNF-alpha mRNA at 3 and 24 h. The addition of 10U or 100U of rMu-IFN-gamma to Be-stimulated 12j cells further increased TNF-alpha production 1.5-4 fold (1.6+/-0.1 ng/ml) respectively. Bacterial lipopolysaccharide (LPS, 1 microg/ml) stimulated production of TNF-alpha in 12j culture supernatants after 6 h (515+/-151 pg/ml). This early versus late TNF-alpha production suggests that LPS and Be both stimulate 12j cell TNF-alpha synthesis, but through different pathways. We report for the first time, the direct effects of Be stimulation on the ability of 12j cells to produce TNF-alpha. The 12j cell line, contrasted with other macrophage hybrids that do not respond to Be-stimulation, may provide a useful tool to evaluate the mechanisms by which Be stimulates macrophage cytokine production, and by which T cell derived IFN-gamma amplifies TNF-alpha production in granulomatous diseases.

Modulation of Lymphocyte Proliferation by Antioxidants in Chronic Beryllium Disease

RATIONALEnOccupational exposure to beryllium (Be) can result in chronic granulomatous inflammation characterized by the presence of Be-specific CD4+ T cells. Studies show that oxidative stress plays a role in the pathogenesis of chronic inflammatory disorders.nnnOBJECTIVESnWe hypothesized that Be-induced oxidative stress modulates the proliferation of Be-specific CD4+ T cells.nnnMETHODSnThirty-three subjects with chronic beryllium disease (CBD), 15 subjects with beryllium sensitization, and 28 healthy normal control subjects were consecutively enrolled from the Occupational and Environmental Health Clinic of the National Jewish Medical and Research Center.nnnMEASUREMENTS AND MAIN RESULTSnAll studies were performed with Ficoll-Hypaque-isolated peripheral blood mononuclear cells from subsets of the study subjects. Decreased intracellular levels of the thiol antioxidants, glutathione and cysteine, were observed in peripheral blood mononuclear cells from subjects with beryllium sensitization and CBD, as compared with healthy control subjects. Beryllium stimulation decreased intracellular thiol antioxidants by more than 40%, accompanied by increased reactive oxygen species levels and the proliferation of Be-specific blood CD4+ T cells from subjects with CBD. Be-induced T-cell proliferation was inhibited by treatment with the thiol antioxidant N-acetylcysteine or the catalytic antioxidant manganese(III) 5,10,15,20-tetrakis(4-benzoic acid)porphyrin (MnTBAP). MnTBAP treatment also inhibited T-cell proliferation in response to the unrelated, MHC class II-restricted antigen tetanus toxoid. Treatment of CBD blood lymphocytes, but not antigen-presenting cells, with MnTBAP decreased Be-induced T-cell proliferation by more than 40%.nnnCONCLUSIONSnBeryllium can mediate a thiol imbalance leading to oxidative stress that may modulate the proliferation and clonal expansion of Be-specific blood CD4+ T cells. These data suggest that Be-induced oxidative stress plays a role in the pathogenesis of granulomatous inflammation in CBD.

Beryllium-stimulated in vitro migration of peripheral blood lymphocytes

Inhalation of beryllium (Be) induces both inflammatory and metal antigen-specific immune responses in the lungs characterized by mononuclear cell infiltration and granuloma formation (chronic beryllium disease, CBD). We tested the hypothesis that Be-salts might increase the in vitro migration of peripheral blood mononuclear cells (PBMC). PBMC are mixed cells, consisting of lymphocytes and monocytes. We compared their responses to populations of both purified blood lymphocytes, and purified blood monocytes. Purified blood monocytes and lymphocytes, isolated by Percoll gradients and centrifugal elutriation from normal human subjects (n = 6), were exposed to graded concentrations (0.01 to 100 microM) of BeSO4 or to the control metal-salt Al2(SO4)3. Migratory responses of stimulated PBMC were measured in Boyden Chambers. As controls, PBMC mixed cells or purified lymphocytes or purified monocytes were unstimulated or stimulated with a positive chemoattractant, Zymosan-A treated pooled, normal human serum (ZAS). The migration index (MI) was defined as the distance (micrometers) that cells migrated through a 5 micron filter. The MI for unstimulated PBMC mixed cells was 75+/-4 whereas the MI for ZAS-stimulated PBMC mixed cells was 124+/-4 (P < or = 0.05, Tukey-Kramer). The MI for BeSO4 -stimulated (100 microM) PBMC mixed cells was 136+/-4. The observed increase in the BeSO4-stimulated PBMC mixed cell migration was significant down to 0.1 microM BeSO4. BeSO4, BeCl2 and BeF2, tested at 100 and 10 microM, were equally effective at inducing PBMC mixed cell migration. Equimolar concentrations of Al2(SO4)3 were not as effective at inducing PBMC mixed cell migration, MI < 100 at 100 microM, and did not induce PBMC mixed cell migration at concentrations below 1 microM. The migration of purified monocytes through filters was not increased in response to either BeSO4 or Al2(SO4)3 compared to controls, but did respond to ZAS (MI = 100+/-4). Purified lymphocytes migrated in response to stimulation with all concentrations of BeSO4 tested (100 microM MI = 133+/-9), and Al2(SO4)3 (100 microM MI = 85+/-8). There were no significant differences in the MI for PBMC mixed cells or for purified lymphocytes at the concentrations of BeSO4 tested. Our data show that Be directly induces the in vitro migration of PBMC mixed cells and purified blood lymphocytes, and not purified blood monocytes, across a broad range of Be concentrations. This induction of migration was independent of the molecular form of the Be-salt. Inhaled Be, by promoting lymphocyte emigration to the lung, may create a microenvironment that favors a Be-antigen-specific T-lymphocyte response, chronic inflammation, and CBD.

Beryllium-stimulation does not activate transcription factors in a mouse hybrid macrophage cell line.

We tested the hypothesis that beryllium (Be) could stimulate H36.12j cell (12j) TNF-alpha production by transcription factor-mediated pathways similar to those induced by either LPS- or IFN-gamma stimulation. Unstimulated 12j cells produce constitutive levels of TNF-alpha (175+/-18 pg/ml, mean +/- SEM) detected by ELISA of culture supernatants after 24 h. Beryllium-stimulated (100 microM BeSO4) 12j cell TNF-alpha (724+/-47 pg/ml) was observed after 24 h while LPS-stimulated (1 microg/ml) TNF-alpha (515+/-151 pg/ml) after 6 h. Recombinant-Mu-IFN-gamma (10 U) stimulated 12j cell TNF-alpha at lower levels (284+/-31 pg/ml) while rMu-IFN-gamma + Be-stimulated 12j cells produced 1195+/-225 pg/ml TNF-alpha. Constitutive levels of transcription factors were observed in unstimulated 12j cell nuclei. In LPS-stimulated 12j cells IkappaBalpha was degraded in the cytoplasm and increased levels of NF-kappaB were found in nuclei after 30 min. After 3 h there were increased levels of AP-1 and CREB, with increased amounts of Fos family, Jun B and Jun D transcription factors. In contrast, Be-stimulation failed to increase the levels of any transcription factor tested, NF-kappaB, AP-1, AP-2, CREB, C/EBP, Sp-1, Egr-1, Ets, NF-Y or Oct-1, in 12j cells. A pattern of increased transcription factors, similar to that observed for LPS-stimulation, was found in 12j cell nuclei after stimulation with rMu-IFN-gamma. However, NF-kappaB was increased at 3 h while AP-1 (Jun B and Jun D) and CREB were increased at 15 h. Co-stimulation of 12j cells with rMu-IFN-gamma + Be increased the levels of NF-KB in 12j cell nuclei at 3 h, and the levels of AP-1 and CREB at 15 h, however, only Jun B was increased. Our data show 12j cell TNF-alpha production was associated with increased levels of transcription factors present in nuclei with disparate kinetics and patterns of expression depending on the trigger. We reject our initial hypothesis and conclude that Be-stimulation signals 12j cell TNF-alpha synthesis via a transcription factor-independent pathway. Beryllium may induce novel pathways of macrophage cytokine gene regulation.

Sulfasalazine and mesalamine modulate beryllium-specific lymphocyte proliferation and inflammatory cytokine production.

Occupational exposure to beryllium (Be) results in Be sensitization (BeS) that can progress to pulmonary granulomatous inflammation associated with chronic Be disease (CBD). Be-specific lymphocytes are present in the blood of patients with BeS and in the blood and lungs of patients with CBD. Sulfasalazine and its active metabolite, mesalamine, are clinically used to ameliorate chronic inflammation associated with inflammatory bowel disease. We tested whether sulfasalazine or mesalamine could decrease Be-stimulated peripheral blood mononuclear cell (PBMC) proliferation in subjects with CBD and BeS and Be-induced cytokine production in CBD bronchoalveolar lavage (BAL) cells. CBD (n = 25), BeS (n = 12) and healthy normal control (n = 6) subjects were enrolled and ex vivo proliferation and cytokine production were assessed in the presence of Be and sulfasalazine or mesalamine. Be-stimulated PBMC proliferation was inhibited by treatment with either sulfasalazine or mesalamine. Be-stimulated CBD BAL cell IFN-γ and TNF-α cytokine production was decreased by treatment with sulfasalazine or mesalamine. Our data suggest that both sulfasalazine and mesalamine interfere with Be-stimulated PBMC proliferation in CBD and BeS and dampens Be-stimulated CBD BAL cell proinflammatory cytokine production. These studies demonstrate that sulfasalazine and mesalamine can disrupt inflammatory pathways critical to the pathogenesis of chronic granulomatous inflammation in CBD, and may serve as novel therapy for human granulomatous lung diseases.