Project description:Dedifferentiation signifies the capacity of somatic cells to acquire stem cell-likeproperties. This process characterizes the transition of differentiated plant cells toprotoplasts (plant cells devoid of cell walls), a transition accompanied by widespreadchromatin decondensation. Transcriptome profiling of dedifferentiating cells revealedstriking similarities with senescing cells; both display a large increase in the expressionof genes of specific transcription factor (TF) families including ANAC, WRKY, bZIPand C2H2. We further showed that leaves induced to senesce by exposure to dark displaycharacteristic features of dedifferentiating cells including widespread chromatindecondensation, disruption of the nucleolus and condensation of rRNA genes.Considering that premature senescence can be induced by various stress conditions, ourresults suggest that plant cells response to certain stresses converges on cellulardedifferentiation whereby cells first acquire stem cell-like state prior to acquisition of anew cell fate (e.g., reentry into the cell cycle, or death).

Project description:Dedifferentiation signifies the capacity of somatic cells to acquire stem cell-likeproperties. This process characterizes the transition of differentiated plant cells toprotoplasts (plant cells devoid of cell walls), a transition accompanied by widespreadchromatin decondensation. Transcriptome profiling of dedifferentiating cells revealedstriking similarities with senescing cells; both display a large increase in the expressionof genes of specific transcription factor (TF) families including ANAC, WRKY, bZIPand C2H2. We further showed that leaves induced to senesce by exposure to dark displaycharacteristic features of dedifferentiating cells including widespread chromatindecondensation, disruption of the nucleolus and condensation of rRNA genes.Considering that premature senescence can be induced by various stress conditions, ourresults suggest that plant cells response to certain stresses converges on cellulardedifferentiation whereby cells first acquire stem cell-like state prior to acquisition of anew cell fate (e.g., reentry into the cell cycle, or death). Experiment Overall Design: Labeled cRNA was prepared and hybridized to Affymetrix ATH1 GeneChips, 4 biological repeats (2 Ler and 2 kyp-2) for protoplasts and 3 biological repeats for leaves (2 Ler and 1 kyp-2). Experiment Overall Design: Partek data processing results linked below as supplementary file.

Project description:Phytohormone salicylic acid (SA) is a crucial component of plant-induced defense against biotrophic pathogens. Although the key players of the SA pathway are known, there are still gaps in the understanding of the molecular mechanism and the regulation of particular steps. In our previous research, we showed in Arabidopsis suspension cells that n-butanol, which specifically modulates phospholipase D activity, significantly suppresses the transcription of the pathogenesis related (PR-1) gene, which is generally accepted as the SA pathway marker. In the presented study, we have investigated the site of n-butanol action in the SA pathway. We were able to show in Arabidopsis plants treated with SA that n-butanol inhibits the transcription of defense genes (PR-1, WRKY38). Fluorescence microscopy of Arabidopsis thaliana mutants expressing 35S::NPR1-GFP (nonexpressor pathogenesis related 1) revealed significantly decreased nuclear localization of NPR1 in the presence of n-butanol. On the other hand, n-butanol did not decrease the nuclear localization of NPR1 in 35S::npr1C82A-GFP and 35S::npr1C216A-GFP mutants constitutively expressing NPR1 monomers. Mass spectrometric analysis of plant extracts showed that n-butanol significantly changes the metabolic fingerprinting while t-butanol had no effect. We found groups of the plant metabolites, influenced differently by SA and n-butanol treatment. Thus, we proposed several metabolites as markers for n-butanol action.

Project description:Phytochrome is a ubiquitous photoreceptor of plants and is encoded by a small multigene family. We have shown recently that a functional nuclear localization signal may reside within the COOH-terminal region of a major member of the family, phytochrome B (phyB) (Sakamoto, K., and A. Nagatani. 1996. Plant J. 10:859-868). In the present study, a fusion protein consisting of full-length phyB and the green fluorescent protein (GFP) was overexpressed in the phyB mutant of Arabidopsis to examine subcellular localization of phyB in intact tissues. The resulting transgenic lines exhibited pleiotropic phenotypes reported previously for phyB overexpressing plants, suggesting that the fusion protein is biologically active. Immunoblot analysis with anti-phyB and anti-GFP monoclonal antibodies confirmed that the fusion protein accumulated to high levels in these lines. Fluorescence microscopy of the seedlings revealed that the phyB-GFP fusion protein was localized to the nucleus in light grown tissues. Interestingly, the fusion protein formed speckles in the nucleus. Analysis of confocal optical sections confirmed that the speckles were distributed within the nucleus. In contrast, phyB-GFP fluorescence was observed throughout the cell in dark-grown seedlings. Therefore, phyB translocates to specific sites within the nucleus upon photoreceptor activation.

Project description:The use of protoplasts in plant biology has become a convenient tool for the application of transient gene expression. This model system has allowed the study of plant responses to biotic and abiotic stresses, protein location and trafficking, cell wall dynamics, and single-cell transcriptomics, among others. Although well-established protocols for isolating protoplasts from different plant tissues are available, they have never been used for studying plant cells using cryo electron microscopy (cryo-EM) and cryo electron tomography (cryo-ET). Here we describe a workflow to prepare root protoplasts from Arabidopsis thaliana plants for cryo-ET. The process includes protoplast isolation and vitrification on EM grids, and cryo-focused ion beam milling (cryo-FIB), with the aim of tilt series acquisition. The whole workflow, from growing the plants to the acquisition of the tilt series, may take a few months. Our protocol provides a novel application to use plant protoplasts as a tool for cryo-ET.

Project description:Using cell sorting technique, we collected Arabidopsis root hair protoplasts (transgenic line harboring root hair specific gene promoter ::GFP, here named GFP) and nonGFP protoplasts( whole root except root hair). Then, we extracted total proteins and RNA for proteome and RNASeq. RNAseq data have already been deposited into NCBI (accession numbers SRR364677 and SRR364678). Total proteins were separated by 1D SDS-PAGE, followed by gel slicing, in gel digested and run ESI-LC-MS/MS on LTQ Orbitrap Velos. We set two biological repeats and each sample was scanned two times (two technique repeats). We then combined all ms/ms raw data from all fractions and technique repeats from one biological sample into one file to indentify proteins by searching Arabidopsis protein database with software Proteome Discoverer (with two searching engines mascot and sequester). Protocol: Protoplasts from EXP7 and non-GFP protoplastswere stored at -80°C, thawed on ice for 5 min, vortexed several times and suspended in 5 x volume of pre-cooled acetone (-20°C) containing 10% (v/v) trichloroacetic acid (TCA) and 0.07% (v/v) 2-mercaptoethanol. Proteins were then precipitated for 2 h at −20°C after thorough mixing. Proteins were collected by centrifuging at 35,000 g (JA-20 108 rotor, Beckman J2-HS) at 4°C for 30 min. The supernatant was removed and the protein pellets were washed three times with cold acetone containing 0.07% (v/v) 2-mercaptoethanol and 1 mMphenylmethanesulfonylfluoride. Protein pellets were dried by lyophilization and stored at -80°C, or immediately extracted using Laemmli buffer (63 mM TrisHCl pH 6.8, 10% glycerol, 2% SDS, 0.0025% bromophenol blue). Protein concentration was determined using Pierce protein assay kit (Pierce, Rockford). Proteins from each sample were separated using a Bis-Tris precast gradient gel (4−16%, Bio-Rad) according to the manufacturer’s instructions. After electrophoresis, the gel was Coomassie-stained using the Colloidal Blue Staining Kit (Invitrogen). The protocol used for in-gel trypsin digestion of proteins in gels was adapted from the method described in Shevchenko et al. (1996). Briefly, protein bands were manually excised and each band was cut into small pieces (~0.5 mm). The gel pieces were washed three times with a solution containing 50% methanol and 5% acetic acid for 2 h, twice with a solution containing 25 mM NH4HCO3 in 50% acetonitrile for 10 min each, and then the gel pieces were dried in a vacuum centrifuge. Reduction of proteins in gel pieces was performed with DTT and alkylation with iodoacetamide, and the gel pieces were washed and dried in a vacuum centrifuge. A trypsin solution in 25 mM NH4HCO3 containing 75 to 100 ng of sequencing grade modified trypsin (Promega) in 25-40 µl was added and incubated with gel pieces for 12-16 h at 37°C. To recover the tryptic peptides, a solution of 30 µl containing 5% formic acid and 50% acetonitril was added to the gel pieces, agitated in a vortex for 30-60 min and withdrawn into a new tube. The recovery was repeated once with 15 µl solution and the resulting two recovers were combined and dried in a vacuum centrifuge. The dried pellet was re-dissolved in 10-20 µl of 0.1% formic acid for LC-MS/MS analysis.

Project description:Plants activate a number of defense reactions in response to pathogen attack. One of the major pathways involves biosynthesis of Salicylic Acid (SA), which acts as a signaling molecule that regulates local defense reaction at the infection site and in induction of systemic acquired resistance (SAR). SA is sensed and transduced by NPR1 protein, which is a redox sensitive protein that acts as a central transcription activator of many pathogenesis related and defense related genes. In its uninduced state NPR1 exists as an oligomer in the cytoplasm. Following pathogen attack and SAR induction, cells undergo a biphasic change in cellular redox, resulting in reduction of NPR1 to a monomeric form,which moves to the nucleus. Recently, it was shown that pathogen attack or SA treatment cause S-nitrosylation of NPR1, promoting NPR1 oligomerization and restricting it in the cytoplasm. We used A. thaliana mutants in cytosolic ASCORBATE PEROXIDASE, apx1, and plants expressing antisense CATALASE gene, as well as the CATALASE inhibitor 3-amino-1,2,4-triazole, to examine the effect of H2O2 on the pathogen-triggered translocation of the NPR1 to the nucleus. Our results show that the pathogen-triggered or SA-induced nuclear translocation is prevented by accumulation of H2O2 in the cytosol. Moreover, we show that increased accumulation of cytoplasmic ROS in apx1 mutants reduced the NPR1-dependent gene expression. We suggest that H2O2 has a signaling role in pathogenesis, acting as a negative regulator of NPR1 translocation to the nucleus, limiting the NPR1-dependent gene expression.

Project description:Transcriptional profiling of Arabidopsis in response to infection with TMV in the initial infection stage (0.5, 4 and 6 hours post inoculation). Analyze the relative transcriptome change of TMV*CP.MP- and TMV*rep-inoculated samples.

Project description:In plants, urea derives either from root uptake or protein degradation. Although large quantities of urea are released during senescence, urea is mainly seen as a short-lived nitrogen (N) catabolite serving urease-mediated hydrolysis to ammonium. Here, we investigated the roles of DUR3 and of urea in N remobilization. During natural leaf senescence urea concentrations and DUR3 transcript levels showed a parallel increase with senescence markers like ORE1 in a plant age- and leaf age-dependent manner. Deletion of DUR3 decreased urea accumulation in leaves, whereas the fraction of urea lost to the leaf apoplast was enhanced. Under natural and N deficiency-induced senescence DUR3 promoter activity was highest in the vasculature, but was also found in surrounding bundle sheath and mesophyll cells. An analysis of petiole exudates from wild-type leaves revealed that N from urea accounted for >13% of amino acid N. Urea export from senescent leaves further increased in ureG-2 deletion mutants lacking urease activity. In the dur3 ureG double insertion line the absence of DUR3 reduced urea export from leaf petioles. These results indicate that urea can serve as an early metabolic marker for leaf senescence, and that DUR3-mediated urea retrieval contributes to the retranslocation of N from urea during leaf senescence.

Project description:The ability to induce Arabidopsis protoplasts to dedifferentiate and divide provides a convenient system to analyze organelle dynamics in plant cells acquiring totipotency. Using peroxisome-targeted fluorescent proteins, we show that during protoplast culture, peroxisomes undergo massive proliferation and disperse uniformly around the cell before cell division. Peroxisome dispersion is influenced by the cytoskeleton, ensuring unbiased segregation during cell division. Considering their role in oxidative metabolism, we also investigated how peroxisomes influence homeostasis of reactive oxygen species (ROS). Protoplast isolation induces an oxidative burst, with mitochondria the likely major ROS producers. Subsequently ROS levels in protoplast cultures decline, correlating with the increase in peroxisomes, suggesting that peroxisome proliferation may also aid restoration of ROS homeostasis. Transcriptional profiling showed up-regulation of several peroxisome-localized antioxidant enzymes, most notably catalase (CAT). Analysis of antioxidant levels, CAT activity and CAT isoform 3 mutants (cat3) indicate that peroxisome-localized CAT plays a major role in restoring ROS homeostasis. Furthermore, protoplast cultures of pex11a, a peroxisome division mutant, and cat3 mutants show reduced induction of cell division. Taken together, the data indicate that peroxisome proliferation and CAT contribute to ROS homeostasis and subsequent protoplast division induction.