Project description:Iron (Fe) and copper (Cu) are essential metal micronutrients that are necessary for many redox reactions. The uptake of these metals is tightly regulated in plants. Some redox processes can alternatively use Fe-containing proteins or Cu-containing proteins, depending on nutritional status. Copper deficiency can rescue a Cucumis melo Fe uptake deficient mutant, and Fe deficiency can result in increased accumulation of Cu. However, the system responsible for Fe-deficiency-regulated Cu-uptake is unknown. To understand the genes and gene networks associated with Fe-deficiency regulated Cu uptake and Fe-Cu cross-talk, we conducted transcriptomic profiling of roots and rosettes of spl7 (a Cu uptake deficient mutant in arabidopsis) and Col-0 (WT) grown under Fe, Cu and simultaneous Fe and Cu deficiency conditions.

Project description:The host restricts Mycobacterium tuberculosis (Mtb) access of transition metal ions to inhibit its growth. Cu is essential for the survival of Mtb, but Cu excess is toxic. During co-evolution, Mtb has developed various mechanisms to maintain copper homeostasis. In this report, we firstly found Mtb Rv0102 encoded membrane protein is critical for Mycobacterium Cu uptake. The intracellular Cu level of M. smegmatis (Ms) Rv0102 homolog MSMEG_4702 knockout strain decreased threefold than the wild type, the deletion mutant was more tolerant to higher Cu level. This indicates that Rv0102 is significant for Cu homeostasis and resistance to Cu toxicity. Knocking out the homologous gene MMAR_0267 in M. marinum (Mm) also enhanced its virulence in zebrafish and improved its survival within macrophages. In THP-1 cells infected with Mm, Mm MMAR_0267 deletion mutants’ intracellular survival increased fourfolds and accompanied by less cell apoptosis. Cu deficiency down-regulates the transcription of the M. marinum virulence factor CFP-10, dampening the STING cytosolic signaling in macrophages, fewer IFN-β and less cell apoptosis. These results suggest that Cu is an important factor in inducing cell apoptosis. In summary, mycobacteria can effectively counteract the host's early key nutritional immune mechanisms by regulating copper metabolism, to increase its virulence.

Project description:Copper (Cu) is an essential metal micronutrient, and a fungal pathogens' ability to thrive in diverse niches across a broad range of bioavailable copper levels is vital for host-colonization and fungal-propagation. Recent transcriptomic studies have imple-mented that trace metal acquisition is important for the propagation of the white nose syndrome (WNS) causing fungus, Pseudogymnoascus destructans, on bat hosts. This report characterizes the P. destructans transcriptional response to Cu-withholding and Cu-over-load stress. We identify 583 differently expressed genes (DEGs) that respond to Cu-with-holding stress and 667 DEGs that respond to Cu-overload stress. We find that P. de-structans the Cu-transporter genes CTR1a and CTR1b, as well as two homologs to Crypto-coccus neoformans Cbi1/BIM1 VC83_03095 (BLP2) and VC83_07867 (BLP3) are highly reg-ulated by Cu-withholding stress. We identify a cluster of genes, VC83_01834 – VC83_01837, that are regulated by Cu bioavailability, which we identify as the Cu Re-sponsive gene Cluster (CRC). We find that chronic exposure to elevated Cu levels leads to an increase in genes associated with DNA repair and DNA replication fidelity. A com-parison of our transcriptomic data sets with P. destructans at WNS fungal infection sites reveals several putative fungal virulence factors that respond to environmental copper stress.

Project description:Anthropogenic pollution has increased the levels of heavy metals in the environment. Bacterial populations continue to thrive in highly polluted environments and bacteria must have mechanisms to counter heavy metal stress. We chose to examine the response of the environmentally-relevant organism Pseudomonas aeruginosa to two different copper treatments. A short, 45 min exposure to copper was done in the Cu shock treatment to examine the immediate transcriptional profile to Cu stress. The Cu adapted treatment was designed to view the transcriptional profile of cells that were actively growing in the presence of Cu. Keywords: stress response

Project description:The Staphylococcus aureus strain Newman uses the dithiol-containing repressor CstR to sense sulfide stress via reactive sulfur species (RSS), allowing transcription of a mitochondrial-like sulfide oxidation system, the core of which is genetically linked to methicillin resistance determinants in MRSA strains. The cytoplasm maintains an excess of reduced relative to oxidized low molecular weight (LMW) thiols that are protective against oxidative stress and transition metal (Zn, Cd and Cu) toxicity, buffering these ions to low “free” concentrations via formation of coordination complexes. We hypothesize that unregulated H2S perturbs the LMW thiol pool by generating RSS; these, in turn, react with CstR cysteines (C31, C60), induce cst derepression, and are cleared by cst-encoded enzymes. These results show that sulfide stress induces the cst operon and a zinc starvation response, represses cysteine biosynthesis, and generally represses genes that are induced by acute oxidative stress; in addition, strong repression of the expression of staphylococcal virulence factors is observed in the ∆cstR strain.

Project description:Anthropogenic pollution has increased the levels of heavy metals in the environment. Bacterial populations continue to thrive in highly polluted environments and bacteria must have mechanisms to counter heavy metal stress. We chose to examine the response of the environmentally-relevant organism Pseudomonas aeruginosa to two different copper treatments. A short, 45 min exposure to copper was done in the Cu shock treatment to examine the immediate transcriptional profile to Cu stress. The Cu adapted treatment was designed to view the transcriptional profile of cells that were actively growing in the presence of Cu. Experiment Overall Design: We analyzed 2 biological replicates of Pseudomonas aeruginosa exposed to a 45 min Cu shock as compared to a control that was exposed to HCl to bring the pH to similar levels. We analyzed 2 biological replicates of Pseudomonas aeruginosa that were grown in the presence of Cu for approx. 6h (Cu adapted) as compared to an untreated control.

Project description:Copper is a powerful antimicrobial and antiviral agent, which has interest through several biomedical applications. Nevertheless, how copper induces the cellular damage is not fully understood. Two main mechanisms are claimed to be involved, i.e. Cu catalyzed reactive oxygen species production (ROS) and replacements of other essential metal ions, such as Fe in Fe-S clusters by Cu. In the present work, we cumulate strong evidence for the importance of a third mechanism, which proposes that Cu damaging effects are due to its ability to cause massive protein aggregation in a ROS independent mechanism. We further show that Hsp33, a redox-regulated molecular chaperone in Escherichia coli, can prevent Cu-induced protein aggregation, suggesting an important role of the chaperoning system in defense against Cu-toxicity. A closer inspection of the mechanism of how Cu can activate Hsp33 revealed two intriguing features, i) a redox-state specificity of Cu+ vs Cu2+, and ii) an unprecedented mechanism of Hsp33-activation via a non-redox trans-metalation. Indeed, our data suggest that two Cu+ bind to the Zn-Cys4-finger site in Hsp33, which lead to a replacement of one Zn2+ by two Cu+ without Cys oxidation. In contrast, Cu2+ oxidizes the Cys in the Zn-finger, analogue to other oxidative stress effectors of Hsp33. Hence, the present results give several new insights in the antimicrobial mechanism of Cu and how bacteria defend against it.

Project description:We used digital gene expression (NlaIII sequence tags) and RNA-Seq to compare the transcriptomes of Cu-replete vs. Cu–deficient Chlamydomonas wild-type cells to reveal dozens of mRNAs whose abundance is modified. Half of the corresponding genes are targets of CRR1, a master regulator of nutritional copper sensing, and are associated with candidate CRR1 binding sites. The targets include many plastid-localized proteins, like FDX5 encoding a ferredoxin isoform, and CGL78, encoding a protein conserved in the green lineage, indicative of modified plastid metabolism. Immunoblot analysis and proteome profiles recapitulate the transcriptome profiles. New evidence for Cu sparing is suggested by up-regulation of AOF1 encoding a copper-independent but flavin-dependent amine oxidase and down-regulation of two metal- binding proteins. Genes encoding redox proteins, many of which function in lipid metabolism, are over-represented, which is compatible with the role of Cu in biology. Lipid profiles indicate a CRR1-dependent increase in Cu-deficient cells in the proportion of unsaturated (16:2, 16:3, 16:4, 18:2) fatty acids at the expense of the more saturated (16:0, 16:1, 18:0) precursors, especially on plastid galactolipids, which validates the increased expression of acyl-ACP and plastid-localized w-6 desaturases. CRR1-independent changes in the transcriptome suggest a role for Cu in oxygen sensing in Chlamydomonas. Sampling of Chlamydomonas CC-1021 (2137) and crr1-2, crr1:CRR1 mutant cells (the mutant is knock-down for the transcription factor crr1, which plays a key role in the transcriptional response to copper levels) cultivated in TAP or minimal medium under Cu-sufficient (control) and Cu-defficient conditions. poly-A purification, NlaIII digestion/random fragmentation

Project description:Copper (Cu) is an essential trace element required for mitochondrial respiration. We show that Cu drives coordinated metabolic remodeling of bioenergy, biosynthesis and redox homeostasis and progression of clear cell renal cell carcinoma (ccRCC). Cu stimulates tumor growth. Late-stage ccRCCs accumulate Cu and allocate it to cytochrome c oxidase stimulating bioenergy production. Cu induces TCA cycle-dependent oxidation of glucose and its utilization for biosynthesis of a glutathione pool that protects against H2O2 generated during mitochondrial respiration, therefore coordinating bioenergy production with redox protection.

Project description:Cupriavidus metallidurans CH34 is a metal resistant beta-proteobacterium. The genome of this bacterium contain many genes involved in heavy metal resistance. Gene expression of C. metallidurans was studied after the addition of of Zn(II), Cd(II), Cu(II), Ni(II), Pb(II), Hg(II) or Co(II). Keywords: Heavy metal stress response Cultures of C. metallidurans CH34 were grown at 30°C until OD reached 0.6 (mid- exponential phase cultures). Heavy metals (0.8 mM of Zn(II), 0.5 mM of Cd(II), 0.1 mM of Cu(II), 0.6 mM of Ni(II), 0.4 mM of Pb(II), 5 uM of Hg(II) and 0.5 mM of Co(II)) were added to the culture for 30 minutes induction time. Total RNA was extracted, reverse-transcribed and labeled with Cy3-dCTP for the control (without metal) and with Cy5-dCTP for each conditions (challenged with one metal). Labeled cDNA were (control and one condition) added to a spotted slide for overnight hybridization at 42°C. Slides were scanned with a laser at 532 and 635 nm.