Project description:Thermoacidophilic archaea are found in heavy metal-rich environments and, in some cases, these microorganisms are causative agents of metal mobilization through cellular processes related to their bioenergetics. Given the nature of their habitats, these microorganisms must deal with the potentially toxic effect of heavy metals. Here, we show that two thermoacidophilic Metallosphaera species with nearly identical (99.99%) genomes differed significantly in their sensitivity and reactivity to uranium. M. prunae, isolated from a smoldering heap on a uranium mine in Thuringen, Germany, could be viewed as a “spontaneous mutant” of M. sedula, an isolate from Pisciarelli solfatara near Naples, Italy. M. prunae tolerated U3O8 and U(VI) to a much greater extent than M. sedula. Within 15 minutes following exposure to “U(VI) shock”, M. sedula, and not M. prunae, exhibited transcriptomic features associated with severe stress response. Furthermore, within 15 minutes post-U(VI) shock, M. prunae, and not M. sedula, showed evidence of substantial degradation of cellular RNA. This suggested that transcriptional and translational processes were aborted as a dynamic mechanism for resisting U toxicity; by 60 minutes post-U(VI) shock, RNA integrity in M. prunae recovered, and known modes for heavy metal resistance were activated. In addition, M. sedula rapidly oxidized solid U3O8 to soluble U(VI) for bioenergetic purposes, a chemolithoautotrophic feature not previously reported. M. prunae, however, did not solubilize solid U3O8 to any significant extent, thereby not exacerbating U(VI) toxicity. These results point to uranium extremophily as an adaptive, rather than intrinsic, feature for Metallosphaera species, driven by environmental factors.

Project description:Thermoacidophilic archaea are found in heavy metal-rich environments and, in some cases, these microorganisms are causative agents of metal mobilization through cellular processes related to their bioenergetics. Given the nature of their habitats, these microorganisms must deal with the potentially toxic effect of heavy metals. Here, we show that two thermoacidophilic Metallosphaera species with nearly identical (99.99%) genomes differed significantly in their sensitivity and reactivity to uranium. M. prunae, isolated from a smoldering heap on a uranium mine in Thuringen, Germany, could be viewed as a M-bM-^@M-^\spontaneous mutantM-bM-^@M-^] of M. sedula, an isolate from Pisciarelli solfatara near Naples, Italy. M. prunae tolerated U3O8 and U(VI) to a much greater extent than M. sedula. Within 15 minutes following exposure to M-bM-^@M-^\U(VI) shockM-bM-^@M-^], M. sedula, and not M. prunae, exhibited transcriptomic features associated with severe stress response. Furthermore, within 15 minutes post-U(VI) shock, M. prunae, and not M. sedula, showed evidence of substantial degradation of cellular RNA. This suggested that transcriptional and translational processes were aborted as a dynamic mechanism for resisting U toxicity; by 60 minutes post-U(VI) shock, RNA integrity in M. prunae recovered, and known modes for heavy metal resistance were activated. In addition, M. sedula rapidly oxidized solid U3O8 to soluble U(VI) for bioenergetic purposes, a chemolithoautotrophic feature not previously reported. M. prunae, however, did not solubilize solid U3O8 to any significant extent, thereby not exacerbating U(VI) toxicity. These results point to uranium extremophily as an adaptive, rather than intrinsic, feature for Metallosphaera species, driven by environmental factors. The study comprises 9 Samples, described in detail below. MprAU_MseAU: Transcriptional analysis of the response of Metallosphaera prunae (Mpr) and Metallosphaera sedula(Mse) to chemolithoautotrophic conditions (0.1 wt% Uranium octaoxide with CO2 supplementation in headspace). This experiment was done to identify the key terminal oxidases which responded to a Uranium oxide while doing inter-species comparison between Mpr and Mse. Transcriptional response of the terminal oxidase clusters proved that certain key genes play a role in the vastly different physiologies of these two species. MprN_MprU60: Transcriptional analysis of the response of Metallosphaera prunae (Mpr) to 60 min of Uranium shock. This experiment was done to analyze the differential transcription of Mpr cells challenged with 1 mM uranyl acetate shock (U shock) compared to normal growth. The Uranium cultures were harvested 60 min after the shock. MprN_MseN: Differential transcription of Metallosphaera species under normal growth conditions. This experiment was done to analyze the differential transcription of Mpr cells compared with Mse cells at mid log phase. MprN_MprU3h: Transcriptional response of Metallosphaera prunae (Mpr) to 3h of Uranium shock compared to normal growth. This experiment was done to analyze the differential transcription of Mpr cells challenged with 1 mM uranyl acetate shock (U shock) . The Uranium cultures were harvested 3 h after the shock. MseN_MseU15: Transcriptional response of Metallosphaera sedula (Mse) to 15 min of Uranium shock. This experiment was done to analyze the differential transcription of Mse cells challenged with 1 mM uranyl acetate shock (U shock) compared to normal growth. The Uranium cultures were harvested 15 min after the shock. MseN_MseU60: Transcriptional response of Metallosphaera sedula to 60 min of Uranium shock. Mse cells were grown upto mid log phase after which the cells were subjected to U shock and harvested 60 min later. Biological repeats were done for both experimental conditions. MseN_MseU3h: Transcriptional response of Metallosphaera sedula (Mse) to 3h of Uranium shock compared to normal growth. This experiment was done to analyze the differential transcription of Mse cells challenged with 1 mM uranyl acetate shock (U shock) . The Uranium cultures were harvested 3 h after the shock. MseU15_MseU60: Transcriptional response of Metallosphaera sedula to 15 min of Uranium shock compared with 60 min of Uranium shock. This experiment was done to analyze the differential transcription of Mse cells challenged with 1 mM uranyl acetate shock (U shock) . The Uranium cultures were harvested 15 min and 60 min after the shock. MprU3h_MseU3h: Differential transcription of Metallosphaera cells under Uranium shock. This experiment was done to analyze the differential transcription of Metallosphaera sedula (Mse) and Metallosphaera prunae (Mpr) challenged with 1 mM uranyl acetate.

Project description:Heavy metals residue in the natural ecosystem had become one global environmental problem that was eager to solve. Due to the non-biodegradability, organism could deposit excessive heavy metals elements into tissues. Existing literature proposed that prolonged heavy metals enrichment had comprehensive toxicity to multi-organs of vertebrates. However, little research focus on the molecular mechanism for the hepatotoxicity of heavy metal enrichment to Chiroptera. In the present study, ten Hipposideros armiger individuals from Yingde City (YD, relatively pollution-free) and Chunwan City (CW, excessive heavy metals emission) were dissected while environment samples were also obtained. To corroborate the toxicity mechanism of heavy metals to bats liver, multi-omics, pathology and molecular biology methods were performed. Our results showed that more Cd and Pb elements were significantly enriched in bats liver and food sources in the CW group. In addition, prolonged heavy metals accumulation disturbed the hepatic transcription profiling associated with solute carriers family, ribosome pathway, ATP usage and heat shock proteins. Excessive heavy metals enrichment also altered the relative abundance of typical gut microbe taxa to inhibit the tight-junction protein expression. We also found that the levels of superoxide dismutase, glutathione peroxidase and glutathione were decreased while ROS density and malondialdehyde content were elevated after excessive heavy metals enrichment. Besides, hepatic fat accumulation and inflammation injury were also observed under the excessive heavy metals enrichment while the metabolism biomarkers contents were decreased. Therefore, prolonged heavy metals enrichment would induce a series of hepatotoxicity by disturbing the microbes-gut-liver axis and hepatic transcription modes, which could decrease the overall metabolism level in bats. Our study provided protection strategy for biodiversity conservation and raised public attention to environment pollution.

Project description:Adjacent stroma, including subepithelial fibroblasts, are believed to coordinate the differentiation process of epithelial cells, but the mechanisms are not well understood. Glial cell line-derived neurotrophic factor (GDNF) is expressed in the intestinal Pdgfra high subepithelial myofibroblasts (SEMFs), while the GDNF receptor RET is expressed in a subset of enteroendocrine cells (EECs), indicating regulatory crosstalk. In this experiment, single RET+ intestinal cells were sorted the gene expression profile was compared to non-RET cells. This provided knowledge about RET+ cell types. RET+ cells were upregulated with most of the EEC markers, indicating that RET+ cells are expressed in EECs. We also observed the differences in the gene expression profile of stromal-derived GDNF ligand on intestinal organoids. Organoids were derived from intestinal crypts of WT mice C57BL/6J and treated with 500ng/ml of Gdnf and Gfra1. GDNF-treated organoids induced the expression of EEC genes such as Pyy, Tac1, Tph1, and Cck, indicating enhanced differentiation of EC cell and L-I-N cell lineages. This highlights a stroma-epithelium crosstalk pathway regulating the differentiation of intestinal EEC subtypes.

Project description:Heavy metals are essential integral parts of cells and environmental toxicants, whose deregulation is associated with severe cellular dysfunction and various diseases. The Hippo pathway plays a critical role in organ size control and cancer development. In this study, we use RNA-Seq to investigate the role of the Hippo pathway in regulating heavy metal response gene transcription. Specifically, the difference of transcriptional profiles between the wild-type and the Hippo pathway kinases LATS1/2-deficient HEK293A cells was examined under control- and heavy metals zinc and cadimuim treated-conditions.

Project description:Background: Prolonged exposure to toxic heavy metals leads to deleterious health outcomes such as kidney injury and irreversible progression to chronic kidney disease. For example, veterans return from the battlefield with increasing amounts of retained metal fragments. Certain community water sources in the US are contaminated with varying levels of heavy metals, including uranium and lead. One of the key challenges is to detect damage to kidney tissue before glomerular filtration rate is affected. Methods: High-throughput transcriptomics (HTT) has recently been demonstrated have high sensitivity and specificity as a rapid and cost-effective assay for detecting tissue toxicity. To better understand the molecular signature of early kidney damage, we performed RNA-seq analysis on renal tissue using a rat model of soft tissue-embedded metal exposure. We them performed small RNA-seq analysis on serum samples from the same animals in an effort to identify miRNA biomarkers of kidney damage. Results: We found that metals, especially lead and depleted uranium, induces oxidative damage that mainly cause dysregulated mitochondrial gene expression. Utilizing publicly available single-cell RNA-seq datasets, we demonstrate that deep learning-based cell type decomposition effectively identified cells within the kidney that were affected by metal exposure. By combining random forest feature selection and statistical methods, we further identify miRNA-423 as a promising early systemic marker of kidney injury. Conclusion: Our data suggests that combining HTT and deep learning represents a promising approach for identifying cell injury in kidney tissue. We propose miRNA-423 as a potential serum biomarker for early detection of kidney injury.

Project description:Environmental contamination from heavy metals poses a global concern for the marine environment, as heavy metals are passed up the food chain and persist in the environment long after the pollution source is contained. Cnidarians, dating back to 700 million years ago, play an important role in shaping marine ecosystems, but environmental pollution profoundly affects their vitality. Among the cnidarians, the sea anemone Nematostella vectensis is an advantageous model for addressing questions in molecular ecology and toxicology as it tolerates extreme environments and its genome has been published. Here we employed a transcriptome-wide RNA-Seq approach to analyze N.vectensis molecular defense mechanisms against four heavy metals: Hg, Cu, Cd and Zn. Altogether, more than 5000 transcripts showed significant changes in gene expression, with Hg having the greatest impact on up-regulating transcripts, followed by Cu, Cd and Zn. We identified, for the first time, co-up-regulation of immediate-early transcription factors such as Egr1, AP1 and NF-κB. Time-course analysis of these genes revealed their early expression as rapidly as one hour after exposure to heavy metals, suggesting that they may complement or substitute for the roles of the metal mediating Mtf1 transcripton factor. We further characterized regulation of a large array of stress-response gene families including Hsp, ABC, CYP members and phytochelatin synthase that may regulate synthesis of the metal-binding phytochelatins instead of the methallothioneins that are absent from Cnidaria genome. This study provides mechanistic insight into heavy-metal toxicity in N.vectensis and sheds light on ancestral stress adaptations. 4 metals were tested in triplicates in comparison to control (4 replicates)

Project description:The intestinal epithelium is an immunologically active barrier adapted for a low oxygen environment. Its role is implicated in the pathophysiology of various diseases, including inflammatory bowel disease (IBD) and colorectal cancer. Patient-derived intestinal epithelial organoids (IEOs) mimic the architecture and cell type composition of the intestine and can be used for disease modeling and personalized drug screening. IEOs are usually cultured in atmospheric oxygen concentrations (20% oxygen) without accounting for the physiological hypoxia in the colonic epithelium, where the oxygen concentration range from 3% to <1%. Previously, we showed that human colon derived IEOs (colonoids) are viable and respond to the pro-inflammatory cytokines TNF and IL17 after short-term (40 hours) cultivation in low (2%) oxygen. We suggested that recapitulating the in vivo physiological oxygen environment (i.e., physioxia) will enhance the translational value of intestinal organoids as pre-clinical models. Here we evaluate whether human colonoids can be established and cultured in physioxia for the entire in vitro culture period and compare growth, differentiation, and immunological responses in colonoids at 2% and 20% oxygen. Growth from single cells to differentiated organoids was monitored by brightfield images captured throughout cultivation and evaluated with a linear mixed model. Cell composition in undifferentiated vs. differentiated colonoids was identified by immunofluorescence staining of cell markers and single-cell RNA-sequencing. Enrichment analysis was used to identify transcriptomic differences within cell populations. Pro-inflammatory stimuli induced chemokines and Neutrophil gelatinase-associated lipocalin (NGAL) release were analyzed by Multiplex profiling and ELISA. Direct response to a lower oxygen level was analyzed by enrichment analysis of bulk RNA sequencing data. Colonoids established in a 2% oxygen environment acquired a significantly larger cell mass compared to a 20% oxygen environment. There were significantly more cells with proliferation potential (KI67 positive) in undifferentiated than in differentiated colonoids; and significantly higher expression of cell markers for goblet cells (MUC2) and absorptive cells (MUC2 negative, CK20 positive) in differentiated colonoids. Enteroendocrine cells (CGA positive) were only present in differentiated colonoids. No differences in expression of any of the cell marker proteins were found between colonoids cultured in 2% and 20% oxygen, but the single-cell RNA-sequencing analysis identified differences in the transcriptome within stem-, progenitor- and differentiated cell clusters. Both colonoids grown at 2% and 20% oxygen secreted CX3CL1, CXCL2, CXCL5, CXCL6, CXCL10, CXCL12, CCL20, CCL25, and NGAL upon TNF + poly(I:C) treatment. However, there appeared to be a lower pro-inflammatory response in 2% oxygen. Reducing the oxygen environment from 20% to 2% in differentiated colonoids altered the expression of genes related to differentiation, metabolism, mucus lining, and immune networks. Our results suggest that colonoids studies can and should be performed in physioxia when the resemblance to in vivo conditions is important.

Project description:The intestinal epithelium is an immunologically active barrier adapted for a low oxygen environment. Its role is implicated in the pathophysiology of various diseases, including inflammatory bowel disease (IBD) and colorectal cancer. Patient-derived intestinal epithelial organoids (IEOs) mimic the architecture and cell type composition of the intestine and can be used for disease modeling and personalized drug screening. IEOs are usually cultured in atmospheric oxygen concentrations (20% oxygen) without accounting for the physiological hypoxia in the colonic epithelium, where the oxygen concentration range from 3% to <1%. Previously, we showed that human colon derived IEOs (colonoids) are viable and respond to the pro-inflammatory cytokines TNF and IL17 after short-term (40 hours) cultivation in low (2%) oxygen. We suggested that recapitulating the in vivo physiological oxygen environment (i.e., physioxia) will enhance the translational value of intestinal organoids as pre-clinical models. Here we evaluate whether human colonoids can be established and cultured in physioxia for the entire in vitro culture period and compare growth, differentiation, and immunological responses in colonoids at 2% and 20% oxygen. Growth from single cells to differentiated organoids was monitored by brightfield images captured throughout cultivation and evaluated with a linear mixed model. Cell composition in undifferentiated vs. differentiated colonoids was identified by immunofluorescence staining of cell markers and single-cell RNA-sequencing. Enrichment analysis was used to identify transcriptomic differences within cell populations. Pro-inflammatory stimuli induced chemokines and Neutrophil gelatinase-associated lipocalin (NGAL) release were analyzed by Multiplex profiling and ELISA. Direct response to a lower oxygen level was analyzed by enrichment analysis of bulk RNA sequencing data. Colonoids established in a 2% oxygen environment acquired a significantly larger cell mass compared to a 20% oxygen environment. There were significantly more cells with proliferation potential (KI67 positive) in undifferentiated than in differentiated colonoids; and significantly higher expression of cell markers for goblet cells (MUC2) and absorptive cells (MUC2 negative, CK20 positive) in differentiated colonoids. Enteroendocrine cells (CGA positive) were only present in differentiated colonoids. No differences in expression of any of the cell marker proteins were found between colonoids cultured in 2% and 20% oxygen, but the single-cell RNA-sequencing analysis identified differences in the transcriptome within stem-, progenitor- and differentiated cell clusters. Both colonoids grown at 2% and 20% oxygen secreted CX3CL1, CXCL2, CXCL5, CXCL6, CXCL10, CXCL12, CCL20, CCL25, and NGAL upon TNF + poly(I:C) treatment. However, there appeared to be a lower pro-inflammatory response in 2% oxygen. Reducing the oxygen environment from 20% to 2% in differentiated colonoids altered the expression of genes related to differentiation, metabolism, mucus lining, and immune networks. Our results suggest that colonoids studies can and should be performed in physioxia when the resemblance to in vivo conditions is important.

Project description:Environmental contamination from heavy metals poses a global concern for the marine environment, as heavy metals are passed up the food chain and persist in the environment long after the pollution source is contained. Cnidarians, dating back to 700 million years ago, play an important role in shaping marine ecosystems, but environmental pollution profoundly affects their vitality. Among the cnidarians, the sea anemone Nematostella vectensis is an advantageous model for addressing questions in molecular ecology and toxicology as it tolerates extreme environments and its genome has been published. Here we employed a transcriptome-wide RNA-Seq approach to analyze N.vectensis molecular defense mechanisms against four heavy metals: Hg, Cu, Cd and Zn. Altogether, more than 5000 transcripts showed significant changes in gene expression, with Hg having the greatest impact on up-regulating transcripts, followed by Cu, Cd and Zn. We identified, for the first time, co-up-regulation of immediate-early transcription factors such as Egr1, AP1 and NF-κB. Time-course analysis of these genes revealed their early expression as rapidly as one hour after exposure to heavy metals, suggesting that they may complement or substitute for the roles of the metal mediating Mtf1 transcripton factor. We further characterized regulation of a large array of stress-response gene families including Hsp, ABC, CYP members and phytochelatin synthase that may regulate synthesis of the metal-binding phytochelatins instead of the methallothioneins that are absent from Cnidaria genome. This study provides mechanistic insight into heavy-metal toxicity in N.vectensis and sheds light on ancestral stress adaptations.