Project description:The capacity of plant regeneration in different ecotypes of Arabidopsis largely varies. However, the mechanism underlying this process remains exclusive. Here, we identified a critical thioredoxin gene DCC1 in determining natural variation for shoot regeneration in Arabidopsis. Functional loss of DCC1 resulted in the repression of shoot regeneration. DCC1 encodes a thioredoxin, which was localized in mitochondria. DCC1 directly interacted with CARBONIC ANHYDRASE 2 (CA2) to regulate the mitochondrial respiratory complex activity and mediate the Reactive Oxygen Species (ROS) level. Defects of DCC1 or CA2 caused the increased ROS level. To understand the regulatory mechanism of DCC1-mediated ROS in shoot regeneration, we analyzed the transcript levels of wild type Col-0 and the mutant dcc1 calli during shoot regeneration by RNA-seq. Three biological repeats of wild type Co-0 and the mutant dcc1 calli were used for RNA sequencing. Total RNAs were isolated from the calli of wild type Col-0 and the mutant dcc1 cultured on shoot-induction medium. The RNA-seq was performed using the Illumina Hiseq 2500. The raw reads were aligned to the genome sequences of TAIR10 using Tophat2 software. The gene expression levels were measured in FPKM, and many critical genes were identified to be involved in shoot regeneration.

Project description:Plants can regenerate from a variety of tissues on culturing in appropriate media. However, the metabolic shifts involved in callus formation and shoot regeneration are largely unknown. The metabolic profiles of callus generated from tomato (Solanum lycopersicum) cotyledons and that of shoot regenerated from callus were compared with the pct1-2 mutant that exhibits enhanced polar auxin transport and the shr mutant that exhibits elevated nitric oxide levels. The transformation from cotyledon to callus involved a major shift in metabolite profiles with denser metabolic networks in the callus. In contrast, the transformation from callus to shoot involved minor changes in the networks. The metabolic networks in pct1-2 and shr mutants were distinct from wild type and were rewired with shifts in endogenous hormones and metabolite interactions. The callus formation was accompanied by a reduction in the levels of metabolites involved in cell wall lignification and cellular immunity. On the contrary, the levels of monoamines were upregulated in the callus and regenerated shoot. The callus formation and shoot regeneration were accompanied by an increase in salicylic acid in wild type and mutants. The transformation to the callus and also to the shoot downregulated LST8 and upregulated TOR transcript levels indicating a putative linkage between metabolic shift and TOR signalling pathway. The network analysis indicates that shift in metabolite profiles during callus formation and shoot regeneration is governed by a complex interaction between metabolites and endogenous hormones.

Project description:Plants are aerobic organisms that rely on molecular oxygen for respiratory energy production. Hypoxic conditions, with oxygen levels ranging between 1% and 5%, usually limit aerobic respiration and affect plant growth and development. Here, we demonstrate that hypoxic microenvironment induced by active cell proliferation during the two-step plant regeneration process intrinsically represses the regeneration competence of callus in Arabidopsis thaliana. Hypoxia-repressed plant regeneration was mediated by the RELATED TO APETALA 2.12 (RAP2.12) protein, a member of the Ethylene Response Factor VII (ERF-VII) family. The hypoxia-activated RAP2.12 protein promoted salicylic acid (SA) biosynthesis and defense responses, inhibiting pluripotency acquisition and de novo shoot regeneration in calli. RAP2.12 could bind directly to the SALICYLIC ACID INDUCTION DEFICIENT 2 (SID2) gene promoter and activate SA biosynthesis, repressing plant regeneration via a PLETHORA (PLT)-dependent pathway. The rap2.12 mutant calli exhibited enhanced shoot regeneration, which was impaired by SA treatment. Taken together, our findings demonstrate that cell proliferation-dependent hypoxic microenvironment reduces cellular pluripotency and plant regeneration through the RAP2.12–SID2 module.

Project description:Plants are aerobic organisms that rely on molecular oxygen for respiratory energy production. Hypoxic conditions, with oxygen levels ranging between 1% and 5%, usually limit aerobic respiration and affect plant growth and development. Here, we demonstrate that hypoxic microenvironment induced by active cell proliferation during the two-step plant regeneration process intrinsically represses the regeneration competence of callus in Arabidopsis thaliana. Hypoxia-repressed plant regeneration was mediated by the RELATED TO APETALA 2.12 (RAP2.12) protein, a member of the Ethylene Response Factor VII (ERF-VII) family. The hypoxia-activated RAP2.12 protein promoted salicylic acid (SA) biosynthesis and defense responses, inhibiting pluripotency acquisition and de novo shoot regeneration in calli. RAP2.12 could bind directly to the SALICYLIC ACID INDUCTION DEFICIENT 2 (SID2) gene promoter and activate SA biosynthesis, repressing plant regeneration via a PLETHORA (PLT)-dependent pathway. The rap2.12 mutant calli exhibited enhanced shoot regeneration, which was impaired by SA treatment. Taken together, our findings demonstrate that cell proliferation-dependent hypoxic microenvironment reduces cellular pluripotency and plant regeneration through the RAP2.12–SID2 module.

Project description:Reversible protein phosphorylation is one of the major mechanisms in the regulation of protein expression and protein activity, controlling physiological functions of the important human pathogen Staphylococcus aureus. Phosphorylations at serine, threonine and tyrosine are known to influence for example protein activity in central metabolic pathways and the more energy-rich phosphorylations at histidine, aspartate or cysteine can be found as part of two component system sensor domains or mediating bacterial virulence. In addition to these well-known phosphorylations, the phosphorylation at arginine residues plays an essential role. Hence, the deletion mutant S. aureus COL ΔptpB (protein tyrosine phosphatase B) was studied since the protein PtpB is assumed to be an arginine phosphatase. A gel-free approach was applied to analyse the changes in the phosphoproteome of the deletion mutant ΔptpB and the wild type in growing cells, thereby focusing on the occurrence of phosphorylation on arginine residues. In order to enhance the reliability of identified phosphorylation sites at arginine residues, a subset of arginine phosphorylated peptides was chemically synthesised. Combined spectral libraries based on phosphoenriched samples, synthetic arginine phosphorylated peptides and classical proteome samples provide a sophisticated tool for the analysis of arginine phosphorylations. This way, 212 proteins phosphorylated on serine, threonine, tyrosine or arginine residues were identified within the mutant ∆ptpB and 102 in wild type samples. Among them, 207 arginine phosphosites were identified exclusively within the mutant ∆ptpB, widely distributed along the whole bacterial metabolism. This identification of putative targets of PtpB allows further investigation of the physiological relevance of arginine phosphorylations and provides the basis for reliable quantification of arginine phosphorylations in bacteria.

Project description:The Gram positive bacterium Staphylococcus aureus plays an important role as an opportunistic pathogen and causative agent of nosocomial infections. As research gained insight into host specific adaptation and a broad range of virulence mechanisms, S. aureus evolved as a model organism for human pathogens. Hence, the investigation of staphylococcal proteome expression and regulation supports the understanding of the pathogenicity and relevant physiology of this organism. This study focused on the analysis of protein regulation by reversible protein phosphorylation, in particular on arginine residues. Therefore, both proteome and phosphoproteome of S. aureus COL wild type were compared with the arginine phosphatase deletion mutant S. aureus COL ΔptpB under control and stress conditions in a quantitative manner. A gel-free approach, adapted to the special challenges of arginine phosphorylation, was applied to analyze the phosphoproteome of exponential growing cells after oxidative stress caused by sublethal concentrations of H2O2. Together with phenotypic characterization of S. aureus COL ΔptpB, this study disclosed first insights into the physiological role of arginine phosphorylations in Gram positive pathogens. The spectral library based quantification of phosphopeptides finally allowed to link arginine phosphorylation to staphylococcal oxidative stress response, amino acid metabolism and virulence.

Project description:We had a mutant that might be affected for certain protein translation. Triplicate samples were taken from mutant and wild type, each labeled individually for iTRAQ labels. Plant were taken at early vegetative grwoth state for total protein extraction and fractionation, followed by trypsin digestion and peptide analysis using LC-MS/MS.

Project description:The goal of the project was global identification of CARM1 substrates. Arginine methylation landscapes were profiled and compared in wild type and CARM1 knockout cells to determine in vivo substrates of CARM1.

Project description:Calcium Dependent Protein Kinases (CDPKs) play important function in calcium signaling at various stage of Plasmodium falciparum. CDPK7 is one such kinase, which plays a crucial role in the development of Plasmodium falciparum parasite. In order to understand the function of PfCDPK7, we performed comparative phosphoproteomic analysis of PfCDPK7 knockout mutant and wild-type lines. In brief, proteins from PfCDPK7 knockout mutant and wild-type parasites were isolated, digested with trypsin and labelled with iTRAQ tags. Phosphopeptides were then enriched from iTRAQ labeled peptides and subjected to LC-MS/MS analysis. This led to the identification of putative substrates of PfCDPK7 in the parasites. A comparative proteomic analysis was performed to measure the protein abundance changes in the PfCDPK7 mutant parasites.

Project description:The wild type strain and patA deletion mutant of Mycobacterium smegmatis were determined proteomically