Project description:The aim of this work was to identify functional features that are specific of human Treg cells, through the identification of genes that are differentially expressed: 1/ in activated Treg clones versus activated Thelper clones; 2/ in Th clones activated in the presence versus the absence of TGFb; 3/ in suppressed Th clones, i.e. Th clones activated in the presence of Treg clones, versus controls. Keywords: TCR activation

Project description:The toxicity and toxicogenomics of selected anatase and rutile nanoparticles (NP) and bulk titanium dioxide (TiO2) particles were evaluated in the soil nematode Caenorhabditis elegans. Results indicated that bulk or nano-TiO2 particles were slightly toxic to soil nematode C. elegans, as measured by reproduction EC50 values ranging from 4 to 32 mg/L. Whole-genome microarray results indicated that the regulation of glutathione-S-transferase gst-3, cytochrome P450 cypp33-c11, stress resistance regulator scl-1, oxidoreductase wah-1, and embryonic development pod-2 genes were significantly affected by nano-sized and bulk TiO2 particles. More specifically, it was determined that anatase particles exerted a greater effect on metabolic pathways, whereas rutile particles had a greater effect on developmental processes. The up-regulation of the pod-2 gene corroborated the phenotypic effect observed in the reproduction test. Our results demonstrated that C. elegans is a good genomic model for nano-TiO2 toxicity assessment.

Project description:Nanoparticles (<100 nm) are engineered to have unique physico-chemical properties compared to their larger counterparts. Nanosilver (nAg) is the most prevalent nanoparticle in consumer products due to its strong antimicrobial action. While nAg toxicity at high concentrations has been well described, the potential for sublethal effects at or below regulatory guidelines is relatively unknown. Amphibian metamorphosis is mediated by thyroid hormone (TH) and can be precociously induced by the addition of exogenous hormone. Low concentrations of nAg have been shown to disrupt TH-dependent responses in cultured premetamorphic Rana catesbeiana tadpole tail fin. The present study examined the effects of exposure to an environmentally relevant concentration (6 µg/L) of either nAg or ionic silver (iAg) on premetamorphic tadpoles in the absence and presence of exogenous TH. Disruption of thyroid hormone-mediated signalling in brain and liver transcriptomes was evaluated using the MAGEX cDNA microarray.

Project description:Tyrosine hydroxylase (TH) is a highly regulated enzyme that catalyses the rate-limiting step in the biosynthesis of dopamine (DA) and other catecholamines. Mutations and dysfunction in this enzyme lead to DA deficiency and parkinsonisms of different severity. An understanding of TH deficiency at the level of structure and stability has been lacking to date, as only structures of truncated TH forms have been available. Here, we used cryoEM and XL-MS to determine the high-resolution structure of full-length human tetrameric TH in the absence and presence of the end-product and feedback inhibitor DA bound to the active site

Project description:Purpose: In order to detect the unpredictable risks of the cumulative nanoparticles infiltrated everywhere in the whole body after systematic administration Methods: By using RNA-seq, we systematically studied the transcriptomic response of multi-organs from mice and tissue specific (stem) cells to the hydroxyapatite (HA) nano-delivery system. Results: We show that HA could differentially influence gene expression, immune response, cell proliferation, stress, apoptosis, metabolic, ion transport activity, cell signaling and epigenetic activity across tissues and tissue specific (stem) cells.

Project description:The aim of this work was to identify functional features that are specific of human Treg cells, through the identification of genes that are differentially expressed: 1/ in activated Treg clones versus activated Thelper clones; 2/ in Th clones activated in the presence versus the absence of TGFb; 3/ in suppressed Th clones, i.e. Th clones activated in the presence of Treg clones, versus controls. Experiment Overall Design: Two to four million cells of human T cell clones were collected at rest (time point = 0) or after activation with coated anti-CD3 and soluble anti-CD28 antibodies (time points = 6, 24 or 41hrs). RNA was extracted for hybridization on Affymetrix microarrays.

Project description:We used genome-wide transcriptional profiling by microarray to assess the contribution of pneumolysin on macrophage innate immune responses to the TIGR4 strain of Streptococcus pneumoniae (Spn). We focused on the early transcriptional responses at 4 hours after inoculation of human blood monocyte-derived macrophage cultures with Spn at a multiplicity of 10 bacteria to each cell. We compared transcriptomes in the presence and absence of wildtype or pneumolysin-deficient TIGR4 Spn, and also in the presence and absence of cytochalasin D to assess whether there is a differential effect of pneumolysin on innate immune responses with and without bacterial internalisation.

Project description:Non-integrating minimally sized Nano-S/MAR DNA vectors can be used to genetically modify dividing cells in place of integrating vectors such as lentivirus and sleeping beauty. They represent a unique genetic tool, which avoids vector-mediated genetic damage cells and the activation of innate immune responses. Previous work has shown that DNA vectors comprising the mammalian scaffold/matrix attachment region (S/MAR) element can provide persistent mitotic stability over hundreds of cell divisions, resisting epigenetic silencing and thereby allowing sustained transgene expression. The composition of the original S/MAR vectors does present some inherent limitations which reduce their stability and can provoke cellular toxicity. Here, we present a new system, the Nano-S/MAR, which drives higher transgene expression and has improved efficiency of establishment, due to their minimal impact on cellular processes and perturbation of the endogenous transcriptome. We show that these features enable the hitherto challenging genetic modification of patient-derived cells by using Nano-S/MARs to stably restore the tumour suppressor gene SMAD4 to a patient-derived SMAD4 knockout pancreatic cancer line. Nano-S/MAR modification does not alter the molecular or phenotypic integrity of the patient-derived cells in cell culture and xenograft mouse models. In conclusion, we show that this class of DNA vector can be used to persistently modify a wide range of cells, providing sustained high levels of transgene expression while avoiding the risks of insertional mutagenesis and other vector-mediated toxicity.

Project description:Non-integrating minimally sized Nano-S/MAR DNA vectors can be used to genetically modify dividing cells in place of integrating vectors such as lentivirus and sleeping beauty. They represent a unique genetic tool, which avoids vector-mediated genetic damage cells and the activation of innate immune responses. Previous work has shown that DNA vectors comprising the mammalian scaffold/matrix attachment region (S/MAR) element can provide persistent mitotic stability over hundreds of cell divisions, resisting epigenetic silencing and thereby allowing sustained transgene expression. The composition of the original S/MAR vectors does present some inherent limitations which reduce their stability and can provoke cellular toxicity. Here, we present a new system, the Nano-S/MAR, which drives higher transgene expression and has improved efficiency of establishment, due to their minimal impact on cellular processes and perturbation of the endogenous transcriptome. We show that these features enable the hitherto challenging genetic modification of patient-derived cells by using Nano-S/MARs to stably restore the tumour suppressor gene SMAD4 to a patient-derived SMAD4 knockout pancreatic cancer line. Nano-S/MAR modification does not alter the molecular or phenotypic integrity of the patient-derived cells in cell culture and xenograft mouse models. In conclusion, we show that this class of DNA vector can be used to persistently modify a wide range of cells, providing sustained high levels of transgene expression while avoiding the risks of insertional mutagenesis and other vector-mediated toxicity.

Project description:Silver nanoparticles cause toxicity in exposed organisms and are an environmental health concern. The mechanisms of silver nanoparticle toxicity, however, remain unclear. We examined the effects of exposure to silver in nano-, bulk- and ionic forms on zebrafish embryos (Danio rerio) using a Next Generation Sequencing approach in an Illumina platform (High-Throughput SuperSAGE). Significant alterations in gene expression were found for all treatments and many of the gene pathways affected, most notably those associated with oxidative phosphorylation and protein synthesis, overlapped strongly between the three treatments indicating similar mechanisms of toxicity for the three forms of silver studied. Changes in oxidative phosphorylation indicated a down-regulation of this pathway at 24h of exposure, but with a recovery at 48h. This finding was consistent with a dose-dependent decrease in oxygen consumption at 24h, but not at 48h, following exposure to silver ions. Overall, our data provide support for the hypothesis that the toxicity caused by silver nanoparticles is principally associated with bioavailable silver ions in exposed zebrafish embryos. These findings are important in the evaluation of the risk that silver particles may pose to exposed vertebrate organisms. mRNA profiles of whole zebrafish embryos at 24 and 48 hours post-fertilisation (hpf) exposed to silver in nano, bulk and ionic forms were generated by deep sequencing using HT-SuperSAGE (Illumina GA2).