Thomas G. Rand

Inflammation-associated gene transcription and expression in mouse lungs induced by low molecular weight compounds from fungi from the built environment

Few metabolites from fungi found indoors have been tested for inflammatory mediators endpoints in primary cultures of alveolar macrophages or in vivo. In this study, mice were intratracheally instilled with a single dose comprising 4x10(-5)moletoxin/kg lung wt dose of either atranone C, brevianamide, cladosporin, mycophenolic acid, neoechinulin A & B, sterigmatocystin or TMC-120A. These toxins are from fungi common on damp building materials. The dose used was comparable to the estimated doses of possible human exposure. Hematoxylin and eosin (H&E) histology and Alcian Blue/Periodic Acid Schiff (AB/PAS) histochemistry were used to evaluate lungs for time course (4h and 12h post-exposure (PE)) inflammatory and toxic changes. Reverse-transcription (RT)-PCR based arrays were also employed to evaluate time course inflammation-associated gene transcription in lung tissues of the different toxins. Immunohistochemistry (IHC) was used to probe MIP-2 and Tnf-alpha protein expression in treatment lungs to determine whether responses correspond with gene transcription data. Both histology and histochemistry revealed that toxin exposed lungs at 12h PE showed evidence of inflammation. H&E revealed that bronchioli were lined with irregularly thickened and sometimes sloughing epithelium and bronchiolar spaces supported infiltration of leukocytes, cellular and mucus-like debris while alveolar spaces supported swollen macrophages and modest amorphous debris accumulations. All toxin-instilled lungs exhibited copious mucus production and alveolar macrophages with red stained cytoplasm on bronchiolar surfaces, especially at 12h PE. Array analysis of 83 inflammation-associated genes extracted from lung tissue demonstrated a number of patterns, compared to controls. 82 genes assayed at 4h PE and 75 genes at 12h PE were significantly altered (p< or =0.05; >or =1.5-fold or < or =-1.5-fold change) in the different treatment animal groups. Expression of transcriptionally regulated genes was confirmed using immunohistochemistry that demonstrated MIP-2 and Tnf-alpha staining in respiratory bronchiolar epithelia, alveolar macrophages and alveolar type II cells. The transcriptional regulation in these genes in the treatment groups suggests that they may serve central roles in the immunomodulation of toxin-induced pro-inflammatory lung responses. Hierarchical cluster analysis revealed significant patterns of gene transcription linking the response of the toxins at equimolar doses in three groups: (1) brevianamide, mycophenolic acid and neoechinulin B, (2) neoechinulin A and sterigmatocystin, and (3) cladosporin, atranone C and TMC-120. The results further confirm the inflammatory nature of metabolites/toxins from such fungi can contribute to the development of non-allergenic respiratory health effects.

Measurement of xenon diffusing capacity in the rat lung by hyperpolarized 129Xe MRI and dynamic spectroscopy in a single breath-hold

We used the dual capability of hyperpolarized 129Xe for spectroscopy and imaging to develop new measures of xenon diffusing capacity in the rat lung that (analogously to the diffusing capacity of carbon monoxide or DLCO) are calculated as a product of total lung volume and gas transfer rate constants divided by the pressure gradient. Under conditions of known constant pressure breath‐hold, the volume is measured by hyperpolarized 129Xe MRI, and the transfer rate is measured by dynamic spectroscopy. The new quantities (xenon diffusing capacity in lung parenchyma (DLXeLP)), xenon diffusing capacity in RBCs (DLXeRBC), and total lung xenon diffusing capacity (DLXe)) were measured in six normal rats and six rats with lung inflammation induced by instillation of fungal spores of Stachybotrys chartarum. DLXeLP, DLXeRBC, and DLXe were 56 ± 10 ml/min/mmHg, 64 ± 35 ml/min/mmHg, and 29 ± 9 ml/min/mmHg, respectively, for normal rats, and 27 ± 9 ml/min/mmHg, 42 ± 27 ml/min/mmHg, and 16 ± 7 ml/min/mmHg, respectively, for diseased rats. Lung volumes and gas transfer times for LP (TtrLP) were 16 ± 2 ml and 22 ± 3 ms, respectively, for normal rats and 12 ± 2 ml and 35 ± 8 ms, respectively, for diseased rats. Xenon diffusing capacities may be useful for measuring changes in gas exchange associated with inflammation and other lung diseases. Magn Reson Med, 2006.

Localization of Satratoxin-G in Stachybotrys chartarum Spores and Spore-Impacted Mouse Lung Using Immunocytochemistry

Satratoxin-G (SG) is the major macrocyclic trichothecene mycotoxin produced by Stachybotrys chartarum (atra) and has been implicated as a cause of a number of animal and human health problems including pulmonary hemorrhage in infants. However, there is little understanding where this toxin is localized in the spores and mycelial fragments of this species or in the lung impacted by SG-sequestered spores. The purpose of this study was to evaluate the distribution of SG in S. chartarum spores and mycelium in culture, and spore-impacted mouse lung in vivo, using immunocytochemistry. SG was localized predominately in S. chartarum spores with moderate labelling of the phialide-apex walls. Labelling was primarily along the outer plasmalemma surface and in the inner wall layer. Only modest labelling was observed in hyphae. Toxin localization at these sites supports the position that spores contain the highest satratoxin concentrations and that the toxin is constitutively produced. In impacted mouse lung, highest SG labelling was detected in lysosomes, along the inside of the nuclear membrane in nuclear heterochromatin and RER within alveolar macrophages. Alveolar type II cells also showed modest labelling of the nuclear heterochromatin and RER. There was no evidence that the toxin accumulated in the neutrophils, fibroblasts, or other cells associated with the granulomas surrounding spores or mycelial fragments. These observations indicate that SG displays a high degree of cellular specificity with respect to its uptake in mouse lung. They further indicate that the alveolar macrophages play an important role in the sequestration and immobilization of low concentrations of the toxin.

Comparison of Inflammatory Responses in Mouse Lungs Exposed to Atranones A And C from Stachybotrys Chartarum

Stachybotrys chartarum isolates can be separated into two distinct chemotypes based on the toxins they produce. One chemotype produces macrocyclic trichothecenes; the other produces atranones (and sometimes simple trichothecenes, e.g., trichodermol and trichodermin). Studies using in vivo models of lung disease revealed that exposure to spores of the atranone producing S. chartarum isolates led to a variety of immunotoxic, inflammatory, and other pathological changes. However, it is unclear from these studies what role the pure atranone toxins sequestered in spores of these isolates exert on lung disease onset. This study examined dose-response (0.2, 1.0, 2.0, 5.0, or 20 μg atranone/animal) and time-course (3, 6, 24, and 48 h postinstillation [PI]) relationships associated with inflammatory cell and proinflammatory chemokine/cytokine responses in mouse lungs intratracheally instilled with two pure atranones (either A or C) isolated from S. chartarum. High doses (2.0 to 20 μg toxin/animal) of atranone A and C induced significant inflammatory responses manifested as differentially elevated macrophage, neutrophil, macrophage inflammatory protein (MIP)-2, tumor necrosis factor (TNF) and interleukin (IL)-6 concentrations in the bronchioalveolar lavage fluid (BALF) of intratracheally exposed mice. Compared to controls, BALF macrophage and neutrophil numbers were increased to significant levels from 6 to 48 h (PI). Except for macrophage numbers in atranone A treatment animals, cells exhibited significant dose dependent-like responses. The chemokine/cytokine marker responses were significantly and dose-dependently increased from 3 to 24 h PI and declined to nonsignificant levels at 48 h PI. The results suggest not only that atranones are inflammatory but also that they exhibit different inflammatory potency with different toxicokinetics. Data also suggest that exposure to these toxins in spores of S. chartarum in contaminated building environments could contribute to inflammatory lung disease onset in susceptible individuals.

Effects of low molecular weight fungal compounds on inflammatory gene transcription and expression in mouse alveolar macrophages.

The inflammatory potential and molecular mechanisms underscoring inflammatory responses of lung cells to compounds from fungi that grow on damp building materials is poorly understood in vitro. In this study we evaluated the effect of pure fungal compounds on potentiating acute inflammatory response in primary mouse alveolar macrophages (AMs) and tested the hypothesis that AM responses to low molecular weight fungal compounds exhibit temporal and compound specificity that mimic that observed in the whole lung. Transcriptional responses of 13 inflammation/respiratory burst-associated genes (KC=Cxcl1, Cxcl2, Cxcl5, Cxcl10, Ccl3, Ccl112, Ccl20, IL-1β, Il-6, ifi27 Tnfα, iNOS and Blvrb) were evaluated in mouse AMs exposed to a 1ml (10(-8)mol) dose of either pure atranone C, brevianimide, cladosporin, curdlan, LPS, neoechinulin A & B, sterigmatocystin or TMC-120A for 2h, 4h and 12h PE using customized reverse transcription (RT)-PCR based arrays. Multianalyte ELISA was used to measure expression of 6 pro-inflammatory cytokines common to the transcriptional assays (Cxcl1, Cxcl10, Ccl3, IL1β, Ifn-λ and Tnf-α) to determine whether gene expression corresponded to the transcription data. Compared to controls, all of these compounds induced significant (≥2.5-fold or ≤-2.5-fold change at p≤0.05) time- and compound-specific transcriptional gene alterations in treatment AMs. The highest number of transcribed genes were in LPS treatment AMs at 12h PE (12/13) followed by neoechinulin B at 4h PE (11/13). Highest fold change values (>30) were associated with KC, Cxcl2, Cxcl5 and IL1β genes in cells exposed to LPS. Compound exposures also induced significant (p≤0.05) time- and compound-specific pro-inflammatory responses manifest as differentially elevated Cxcl1, Cxcl10, Ccl3, Ifn-λ and Tnf-α concentrations in culture supernatant of treatment AMs. Dissimilarity in transcriptional responses in AMs and our in vivo model of lung disease is likely attributable to whole lung vs. isolated cell responsive and dose differences between the two studies. The results not only indicate that low molecular weight compounds from fungi that grow in damp built environments are potently pro-inflammatory in vitro, it further highlights the important role AMs play in innate lung defence, and against exposure to low molecular weight fungal compounds. These observations further support our position that exposure to low molecular weight compounds from indoor-associated fungi may provoke some of the inflammatory health effects reported from humans in damp building environments. They also open up a hypothesis building process that could explain the rise of non-atopic asthma associated with fungi.

Histological, immunohistochemical and morphometric changes in lung tissue in juvenile mice experimentally exposed to Stachybotrys chartarum spores

Stachybotrys chartarum is an important toxigenic fungus often associated with chronically wet cellulose-based building materials. The purpose of this study was to evaluate some histological, immunohistochemical and morphometric changes in mouse lung tissues exposed intratracheally to either 50 μl of 1.4 × 106S. chartarum spores (≤35 ng toxin/kg BW), isosatratoxin-F (35ng/kg BW),50 μl of 1.4 × 106Cladosporium cladosporioides spores, or 50 μl saline. Exposure of lung tissues to S. chartarum or C. cladosporioides spores resulted in granuloma formation at the sites of spore impaction. Some of the lung tissues impacted by S. chartarum spores also showed erythrocyte accumulation in the alveolar air space, dilated capillaries engorged with erythrocytes, and hemosiderin accumulation at spore impaction sites, which were features not noted in the C. cladosporioides-spore treated animals. Immunohistochemistry revealed reduced collagen IV distribution in lung granulomas in S. chartarum-treated animals especially at 48 and 72 hr post-exposure compared to that in lungs of mice with C. cladosporioides-spore induced granulomas. Quantitative analysis of pooled S. chartarum and C. cladosporioides spore impacted lungs revealed significant depression (P < 0.05) of alveolar air space from 71.4 ± 6.1 in untreated animals to 56.04 ± 6.1 in the S. chartarum- and 60.24 ± 5.5% in the C. cladosporioides-spore treated animals. It also revealed that alveolus air space in S. chartarum treated animals declined significantly from 63.74 ± 3.1% at12 hr post-exposure to 42.94 ± 7.9% at 72 hr post-exposure and was increased to 54.84 ± 5.2% at 96 hr post-exposure. Alveolus air space in C. cladosporioidestreated animals also decreased significantly from 64.84 ± 7.1% at 12 hr exposure to 54.94 ± 5.4% at 48 hr post-exposure and was increased to 64.64 ± 10.1% at 96 hr post-exposure. It also revealed significant (P <0.05) alveolar accumulation of erythrocytes from 1.24 ± 1.4% in the untreated animals to 3.44 ± 1.5% in the pooled S. chartarum spore treated animals. Erythrocyte abundance in S. chartarum treated animals increased significantly (P <0.001) from 2.14 ± 1. 7% at 12 hr post-exposure to 5.54 ± 1.5% at 72 hr and 4.94 ± 1.4% at 96 hr post-exposure. These results further reveal that exposure to S. chartarum spores elicit tissue responses in vivo significantly different from those associated with exposure to pure trichothecene toxin and to spores of a non-toxigenic fungus.

Are Ichthyosporea animals or fungi? Bayesian phylogenetic analysis of elongation factor 1α of Ichthyophonus irregularis

Ichthyosporea is a recently recognized group of morphologically simple eukaryotes, many of which cause disease in aquatic organisms. Ribosomal RNA sequence analyses place Ichthyosporea near the divergence of the animal and fungal lineages, but do not allow resolution of its exact phylogenetic position. Some of the best evidence for a specific grouping of animals and fungi (Opisthokonta) has come from elongation factor 1alpha, not only phylogenetic analysis of sequences but also the presence or absence of short insertions and deletions. We sequenced the EF-1alpha gene from the ichthyosporean parasite Ichthyophonus irregularis and determined its phylogenetic position using neighbor-joining, parsimony and Bayesian methods. We also sequenced EF-1alpha genes from four chytrids to provide broader representation within fungi. Sequence analyses and the presence of a characteristic 12 amino acid insertion strongly indicate that I. irregularis is a member of Opisthokonta, but do not resolve whether I. irregularis is a specific relative of animals or of fungi. However, the EF-1alpha of I. irregularis exhibits a two amino acid deletion heretofore reported only among fungi.

Comparison Of Immunomodulator mRNA and Protein Expression in the Lungs of Stachybotrys chartarum Spore-Exposed Mice

Stachybotrys chartarum is an important toxigenic fungus that has been associated with respiratory disease onset in animals and humans. It can be separated into macrocyclic trichothecene-producing and nonproducing chemotypes based on secondary metabolite production. However, effects of spores of the two chemotypes on lung inflammatory responses are poorly understood. In this study, real-time reverse-transcription polymerase chain reaction (RT-PCR) and enzyme linked immunosorbent assay (ELISA) were used to investigate time-course (1, 3, 6, 24, and 48 h postinstillation [PI]) relationships in mice intratracheally exposed to 300 spores/g body weight of a macrocyclic trichothecene-producing (JS 58-17) and a nonproducing (JS 58-06) S. chartarum isolate and of Cladosporium cladosporioides. There were marked differences in the magnitude and temporal patterns of mouse lung immune responses to intratracheal exposure to spores of these species at this spore dose. Both macrophage inflammatory protein 2 (MIP-2) and surfactant protein-D (SP-D) mRNA expression were significantly upregulated in lungs of JS 58-17-treated animals compared to that of all other treatment animals at 6 and 24 h PI. Heightened mRNA expression of these immunomodulators combined with comparatively depressed MIP-2 and tumor necrosis factor (TNF)-α protein expression suggests that the action of macrocyclic trichothecenes sequestered in 58-17 spores is involved. Interestingly, TNF-α protein expression in all spore treatment animal groups was also significantly increased over that in saline controls. Similarities in expression among all spore treatment animals suggest that chemicals other than toxic secondary metabolites, and possibly spore-sequestered 1,3-β-D-glucan, may contribute to lung pathogenesis.

Immunocytochemical localization of stachylysin in Stachybotrys chartarum spores and spore-impacted mouse and rat lung tissue

Stachylysin is a proteinaceous hemolytic agent that is produced by Stachybotrys chartarum. Stachylysin was found, using immunohistochemical and immunocytochemical methods, to be localized in S. chartarum spores/mycelia primarily in the inner wall suggesting that it is constitutively produced. Spores instilled in mouse or rat lung tissues resulted in granuloma formation, which showed the highest stachylysin concentration in the inner wall of the spore and near the spore, with less at distance indicating that it had diffused out from the spore. The in vitro high stachylysin producing strain (58-06) was also highest in vivo, based on immunohistochemistical staining. More stachylysin was observed in the mouse lung tissue at 72 h than at 24 h indicating that production/release is a relatively slow process. The localization of stachylysin in macrophage phagolysosomes suggests that these cells may be involved with hemolysin inactivation. This would be consistent with what is known about asp-hemolysin produced by Aspergillus fumigatus.

Chemotaxis of Zoospores of Two Fish-Egg-Pathogenic Strains of Saprolegnia diclina (Oomycotina: Saprolegniaceae) toward Salmonid Egg Chorion Extracts and Selected Amino Acids and Sugars

Abstract This study determines whether zoospores of two strains of the fish-pathogenic fungus Saprolegnia diclina are positively chemotactic toward concentration gradients of chorionic membrane extracts from live eggs of brook trout Salvelinus fontinalis, and seven amino acids and five simple sugars, under experimental conditions. Zoospores of both strains exhibited significant positive chemotaxis toward higher concentrations of chorionic membrane extracts, and arginine and alanine, but not toward the other amino acids or any of the sugars used in the assays. The results indicate that chemotaxis may have an important role in attracting zoospores of S. diclina toward live salmonid eggs. They also suggest that chemoattractants might be used in the development of strategies to control or eliminate saprolegniaceous infestations among salmonid eggs raised in hatcheries.