Project description:Physiological and biochemical changes occur in onion (Allium cepa L.) bulbs during the transition from dormancy to sprout suppression and subsequent sprout growth. These include changes in the concentrations of flavor compounds, carbohydrates, mineral elements and plant growth regulators (PGRs). Detailed analyses of these changes and the impact of different post-harvest techniques, designed to prolong storage life, have not been undertaken. We developed the first onion oligonucleotide microarray to determine differential gene expression in onion during curing and storage, with transcriptional changes supporting biochemical and physiological analyses. Samples of RNA were prepared from onions of two cultivars, ‘Wellington’ (brown, long-storing) and ‘Sherpa’ (brown, average-storing), grown according to normal commercial practice at various physiological ages, viz, freshly harvested, cured, pre-sprouting and sprouting. Three biological replicates for each time (harvest, cured, before sprouting, sprouting), curing temperature (20, 28°C) and cultivar (Wellington, Sherpa) combination (n = 42).

Project description:Onion is regarded as non-climacteric. In onion, ethylene can suppress sprouting however, the ethylene binding inhibitor, 1-MCP can also suppress sprout growth although it is unknown how ethylene and 1-MCP elicit the same response. In this study, onion bulbs were treated with 10 μL L-1 ethylene or 1 μL L-1 1-MCP individually or in combination for 24 h at 20°C before or after curing (six weeks) at 20 or 28°C then stored at 1°C. Following curing, a subset of these same onion bulbs was stored separately under continuous air or ethylene (10 μL L-1) at 1°C Six treatments were chosen for microarray analysis; four samples were taken before curing immediately after treatment with ethylene or 1-MCP or ethylene and 1-MCP in combination for 24 h at 20°C. The other two samples and two were taken at the end of storage following 6 weeks curing at 28°C andafter 29 weeks cold storage (1°C) in continuous air or continuous ethylene totalling 35 weeks storage. The four pre-curing samples used were untreated (control) or treated with EB, MB or EMB and the two samples after storage were control bulbs stored in continuous ethylene or air at 1°C. There were three biological replicates of each of the six treatments making 18 samples in total.

Project description:Silver nanoparticles (AgNPs) are widely used nanomaterials in both commercial and clinical biomedical applications, but the molecular mechanisms underlying their activity remain elusive. In this work we profiled proteomics and redox proteomics changes induced by AgNPs in two lung cancer cell lines: AgNPs sensitive Calu-1 and AgNPs resistant NCI-H358. We show that AgNPs induce changes in protein abundance and reversible oxidation in a time and cell line dependent manner impacting key cellular processes such as protein translation and modification, lipid metabolism, bioenergetics and mitochondrial dynamics. Supporting confocal microscopy and transmission electron microscopy (TEM) data further emphasize mitochondria as a target of AgNPs toxicity differentially impacting mitochondrial networks and morphology in Calu-1 and NCI-H358 lung cells.

Project description:Transcriptional profiling of zebrafish larvae comparing control with AgNO3 or AgNPs exposed zebrafish larvae. Three-condition experiment, Control vs. AgNO3 and Control vs. AgNPs exposed zebrafish. Biological replicates: 6 control replicates, 6 AgNO3 replicates and 6 AgNPs replicates.

Project description:Genome-wide translational profiling of rng3-65 compared to wild type cells. We used sucrose gradients to separate RNAs according to the number of associated ribosomes (a surrogate for translational efficiency). Preparation of the extracts and fractionation was carried out as described in Lackner et al, 2007 (Mol Cell 26(1):145-55). The fractions were pooled into four groups (1 closest to the top, i.e. not associated with ribosomes and 4 closest to the bottom, i.e., associated with polysomes). RNA was extracted from the pools and the corresponding pools from wild type and mutant cells were directly compared using DNA microarrays. Changes in translation are expected to alter the number of ribosomes associated with specific transcripts, and therefore result in a redistribution of the RNAs across the different fractions.

Project description:Silver nanoparticles (AgNPs), which have been used extensively in consuming products and eventually released into the natural environment, have aroused concerns recently because of their potentially harmful effects on human beings following various routes of exposure. As the liver is one of the largest accumulation and deposition sites of circulatory AgNPs, it is important to evaluate the hepatotoxicity induced by AgNPs. However, the acting mechanisms of AgNPs-induced hepatotoxicity are still elusive to a great extent. Herein, we investigated the hepatotoxic effects of AgNPs using a comparative proteomics approach. First, we evaluated the cytotoxicity of different-sized AgNPs and found that the cancerous liver cells were generally more sensitive than the normal liver cells. Next, proteomics results suggested that HepG2 and L02 cells showed distinct adaptive responses upon AgNPs exposure. HepG2 cells respond to stresses by adapting energy metabolism, upregulating metallothionein expression and increasing the expression of antioxidants, while L02 cells protect themselves by increasing DNA repair and macro-autophagy. Besides, mitochondrial ROS has been identified as one of the causes of AgNPs-induced hepatotoxicity. Collectively, our results revealed that hepatic cancer cells and normal cells cope with AgNPs in notably different pathways, providing new insights into mechanisms underlying AgNPs-induced hepatotoxicity.

Project description:Among all the food-related nanoparticles consumed every day, silver nanoparticles (AgNPs),due totheir anti-microbial properties, are one of the most commonly utilized. Despite this, the effects of sub-lethal concentrations of AgNPs, especially on gut biofilms, has been poorly investigated. To address these issues, we investigated the proteomic response of a mono-species Escherichia coli gut biofilm, used as in-vitro human gut model, to chronic and acute exposure of sub-lethal concentrations(1 µg/mL) of AgNPs. We used a new gel and label-free proteomic approach based on shotgun nanoflow scale liquid chromatography-tandem mass spectrometry (LC-MS/MS) that, respect to the traditional proteomic investigation, allows a higher dynamic range of quantification of the whole proteome. To assess all different possible exposure scenarios, we compared the total proteome of four samples: untreated cells, cells treated with AgNPs for 24h (acute treatment), for 96h (chronic treatment), and cells grown in the presence of AgNPs for 96h and treated again for 24h (acute and chronic treatment). Proteomic profiling provided new insight into the mechanisms exerted by AgNPs highlighting the important role of the bacterial biofilm in protecting intestinal epithelial cells. Among the 1917 proteins identified, 216 were ANOVA significant and several pathways resulted altered including biofilm formation, bacterial adhesion, ROS stress response and glucose utilization.

Project description:In eukaryotes, regulation of mRNA translation enables a fast, localized and finely tuned expression of gene products. Within the translation process, the first stage of translation initiation is most rigorously modulated by the actions of eukaryotic initiation factors (eIFs) and their associated proteins. These 11 eIFs catalyze the joining of the tRNA, mRNA and rRNA into a functional translation complex. Their activity is influenced by a wide variety of extra- and intracellular signals, ranging from global, such as hormone signaling and unfolded proteins, to specific, such as single amino acid imbalance and iron deficiency. Their action is correspondingly comprehensive, in increasing or decreasing recruitment and translation of most cellular mRNAs, and specialized, in targeting translation of mRNAs with regulatory features such as a 5’ terminal oligopyrimidine tract (TOP), upstream open reading frames (uORFs), or an internal ribosomal entry site (IRES). In mammals, two major pathways are linked to targeted mRNA translation. The target of rapamycin (TOR) kinase induces translation of TOP and perhaps other subsets of mRNAs, whereas a family of eIF2 kinases does so with mRNAs containing uORFs or an IRES. TOR targets translation of mRNAs that code for proteins involved in translation, an action compatible with its widely accepted role in regulating cellular growth. The four members of the eIF2 kinase family increase translation of mRNAs coding for stress response proteins such as transcription factors and chaperones. Though all four kinases act on one main substrate, eIF2, published literature demonstrates both common and unique effects by each kinase in response to its specific activating stress. This suggests that the activated eIF2 kinases regulate the translation of both a global and a specific set of mRNAs. Up to now, few studies have attempted to test such a hypothesis; none has been done in mammals. We use array analysis to determine the global mRNA shift into polysomes following a stress response, and to compare the translational response following activation of GCN2 versus PERK, two of the four eIF2alpha kinases. Experiment Overall Design: Gcn2 wild-type or knockout mouse liver were perfused with complete amino acids media or media lacking methionine for RNA extraction and hybridization of Affymetrix microarrays. RNA was extracted from unfractionated liver samples and polysome fraction of samples separated on sucrose density gradient. To minimize biological variations, we pooled RNA from two perfused liver samples to use in each array analysis. The conditions were total and polysome fraction of Gcn2+/+, +Met or -Met; total and polysome fraction of Gcn2-/-, +Met or -Met. Each array analysis was done in duplicate.

Project description:In eukaryotes, regulation of mRNA translation enables a fast, localized and finely tuned expression of gene products. Within the translation process, the first stage of translation initiation is most rigorously modulated by the actions of eukaryotic initiation factors (eIFs) and their associated proteins. These 11 eIFs catalyze the joining of the tRNA, mRNA and rRNA into a functional translation complex. Their activity is influenced by a wide variety of extra- and intracellular signals, ranging from global, such as hormone signaling and unfolded proteins, to specific, such as single amino acid imbalance and iron deficiency. Their action is correspondingly comprehensive, in increasing or decreasing recruitment and translation of most cellular mRNAs, and specialized, in targeting translation of mRNAs with regulatory features such as a 5’ terminal oligopyrimidine tract (TOP), upstream open reading frames (uORFs), or an internal ribosomal entry site (IRES). In mammals, two major pathways are linked to targeted mRNA translation. The target of rapamycin (TOR) kinase induces translation of TOP and perhaps other subsets of mRNAs, whereas a family of eIF2 kinases does so with mRNAs containing uORFs or an IRES. TOR targets translation of mRNAs that code for proteins involved in translation, an action compatible with its widely accepted role in regulating cellular growth. The four members of the eIF2 kinase family increase translation of mRNAs coding for stress response proteins such as transcription factors and chaperones. Though all four kinases act on one main substrate, eIF2, published literature demonstrates both common and unique effects by each kinase in response to its specific activating stress. This suggests that the activated eIF2 kinases regulate the translation of both a global and a specific set of mRNAs. Up to now, few studies have attempted to test such a hypothesis; none has been done in mammals. We use array analysis to determine the global mRNA shift into polysomes following a stress response, and to compare the translational response following activation of GCN2 versus PERK, two of the four eIF2alpha kinases. Experiment Overall Design: Perk wild-type or knockout mouse liver were perfused without or with 2,4-di-tert-butylhydroquinone (tBuHQ) for RNA extraction and hybridization of Affymetrix microarrays. RNA was extracted from unfractionated liver samples and polysome fraction of samples separated on sucrose density gradient. To minimize biological variations, we pooled RNA from two perfused liver samples to use in each array analysis. The conditions were total and polysome fraction of Perk+/+, -tBuHQ or +tBuHQ; total and polysome fraction of Perk-/-, -tBuHQ or +tBuHQ. Each array analysis was done in duplicate.

Project description:To investigate the patterns of global gene expression profiles modulated by the different sized AgNPs and to differentiate their modes of toxicity, zebrafish (Danio rerio) will be exposed to the AgNPs (50, and 150nm) and used for microarray analysis by Agilent Zebrafish Oligo Microarray system. 334 genes overlaped between AgNPs and Ag+ treatments in a total of 7,538 differential expressed genes. Immune response, antigen processing and presentation, response to estradiol stimulus and regulation of RNA metabolic process are most significant GO terms enriched in genes up regulated by four treatments. Neuroactive ligand-receptor interaction pathway was enriched among AgNP 50nm and AgNP 150nm activated genes, and specifically induced by AgNP 50nm include cell cycle and Toll-like receptor signaling pathways. The zebrafish larvae (72hpf) was exposed to AgNPs for 96hour. And then after total RNA extration from the each samples, the AgNPs related gene expression profiles identified using Agilent Zebrafish Oligo Microarray. Significant alterations in gene expression were found for all treatments and many of the gene pathways connected.