Project description:The MS analysis is part of a wider study into chlorophyll biosynthesis. There is previous evidence, from both pulldown and CN-PAGE/immunoblot analyses that the enzyme Mg-protoporphyrin IX methylester cyclase (Cyc1), which catalyses the formation of the the fifth (E) ring in chlorophyll, associates with a protein of unknown function called Ycf54. There is also evidence for the association of Cyc1 with other enzymes in the chlorophyll biosynthetic pathway, eg. POR, ChlP and DVR. In the MS part of this study, FLAG-tagged Cyc1 was used to capture proteins from a Synechocystis cell lysate, with a comparison of FLAG-Cyc1 strains against wild-type and Ycf54 deletion backgrounds. MS-based quantification of the amounts of POR, ChlP and DVR relative to the Cyc1 bait supported evidence by immunoblotting of a significant reduction in these co-isolated proteins in the Ycf54 deletion strain.

Project description:Monitor changes in the proteome of senescing leaves, using protein MS data obtained from the same leaf groups used for imaging. Arabidopsis thaliana mature leaves were grouped according to their chlorophyll content: Dark Green (DG), Green (G), Light Green (LG) and Yellow (Y), containing 100, 45, 25 and 6.5% chlorophyll relative to DG, respectivelyArabidopsis thaliana mature leaves were grouped according to their chlorophyll content: Dark Green (DG), Green (G), Light Green (LG) and Yellow (Y), containing 100, 45, 25 and 6.5% chlorophyll relative to DG, respectively

Project description:There are 16 organ samples (dry seeds, 24H imbibed seeds, 48H imbibed seeds, juvenile rosette, adult rosette, senescence leaves, cauline leaves, stems, young buds, mature flower buds, flowers, young siliques, mature siliques and old siliques) with triplicates. There are 17 samples of different environmental samples (0 h white, 1 h white, 6 h white, 24 h white, dark, blue, far-red and red lights, control, cold 2h, cold 6h, hot 2h, hot 6h, NaCl 2h, NaCl 6h, dry 2h and dry 6h) with triplicates. For 12 organs, three lines of plants were grown in soil under the long-day conditions of 16 hours light at 22℃. Samples were collected from each of juvenile rosette leaves, adult rosette leaves, cauline leaves, stems, young flower buds (sepals were closed and petals are not visible), mature flower buds (petals are visible), flowers, young siliques filled with white seeds, mature siliques filled with green seeds, old yellowing siliques (2-month-old) and senescence rosettes. Root tissues were collected from 2-week-old plants growing on 1% agar plates containing Murashige and Skoog (MS). Callus were collected from cultured CIM (callus induction medium) containing B5 medium supplemented with 20 g liter–1 glucose, 0.5 mg liter–1 2,4-D, and 0.1 mg liter–1 kinetin. Dry seed was defined to be after-ripened seeds for 4 weeks. Imbibed seeds are collected from seeds imbibed on the moistened paper for 24 and 48 hours under the continuous light at 22℃. In light irradiations, wild type (WT) seeds were plated on MS plates. For the time course experiment of white light, the plates were placed at 4°C in darkness for at least 2 days prior to receiving 6 h red light irradiation to synchronize germination. Then, plates were placed in the dark for 3 days and then exposed to white fluorescent light (100 μmol m–2 s–1) for 1, 6 and 24 h. For monochromatic light experiment, WT seedlings were grown in continuous red light, blue light, far-red light, or darkness for 6 days after red light irradiation. The light intensity used was 0.17 μmol m–2 s–1 for red light, 1.16 μmol m–2 s–1 for blue light and 0.53 μmol m–2 s–1 for far-red light. All abiotic stress samplings were collected from plants grown for 2 weeks on MS plates under 2 and 6 hours of abiotic stress conditions at the continuous light at 22℃. For drought stress treatment, plants were transferred and dehydrated onto the dried filter paper in the covered plastic dishes. For heat and cold stress treatments, the covered plastic dishes with plants were transferred directly from 22 to 37 and 2℃ respectively. For salinity stress treatment, plants were transferred onto the filter paper moistened with MS plates including 200mM NaCl.

Project description:Plastids communicate with the nucleus by means of retrograde plastid signals. The far-red (FR) light insensitive Arabidopsis mutant laf6 disrupted in a plastid-localised ABC-like protein (atABC1) accumulates the plastid signal protoporphyrin IX (proto IX) and has attenuated nuclear gene expression (Moller et al.2001 Genes Dev. 15:90-103). Our data suggests that proto IX accumulation results in hypocotyl elongation in response to FR light and we have demonstrated that by inhibiting the plastid localised protoporphyrinogen IX oxidase (PPO) using flumioxazin wild-type plants phenocopy laf6 by accumulating proto IX with a concomitant loss of hypocotyl growth inhibition in a dose-dependent manner. It is at present unclear what effect increased proto IX has on nuclear gene expression and how this is integrated with photomorphogenic responses such as hypocotyl elongation.

Project description:Chlorophyll plays critical roles in photosynthetic light harvesting, energy transduction and plant development. In this study, a novel wucai (Brassica campestris L.) germplasm with green outer leaves and yellow inner leaves at the adult stage (W7-2) was used to examine chlorophyll metabolism response to cold acclimation. A green leaf wucai genotype without leaf color changes named W7-1 was selected as the control to evaluate the chlorophyll metabolism changes of W7-2. Compared to W7-1, the contents of chlorophyll a (Chl a) and chlorophyll b (Chl b) in W7-2 were significantly reduced at five developmental stages (13, 21, 29, 37 and 45 days after planting (DAP). An iTRAQ-based quantitative proteomic analysis was carried out at 21 and 29 DAP according to the leaf color changes in both of genotypes. A total of 1409 proteins were identified, of which 218 showed differential accumulations between W7-2 and W7-1 during the two developmental stages.

Project description:Transcriptome analysis in petals and leaves of chrysanthemums with different chlorophyll levels

Project description:The tetrapyrroles Mg-protoporphyrin IX (MgProto) and heme, in Chlamydomonas reinhardtii only synthesized within the chloroplast, have been implicated in retrograde control of nuclear gene expression in this unicellular green alga. However, feeding of the two tetrapyrroles to Chlamydomonas cultures growing in the dark has previously been shown to transiently induce 5 nuclear genes, among them three genes coding for the chloroplast heat shock proteins HSP70A, B and E. Here, we measured the impact of MgProto and hemin feeding in the dark on changes in gene expression at the genomic level. About 10% of the 10000 genes represented on the microarray showed a transient up or down regulation with a fold change of 4 or more (p ≤0.05). The two most prominent groups of regulated genes were those where both MgProto and heme caused either an up or down regulation. Minor regulatory groups consisted of genes which were either down- or up-regulated by one of the tetrapyrroles but not by the other. In contrast, feeding of protoporphyrin IX had no regulatory effect on a number of selected genes. Interestingly, 499 of the 982 responding genes were also regulated by heat shock; 85% of those showed the same response (up or down) as seen after MgProto/heme feeding, indicating a previously not anticipated role of MgProto and heme in stress response. Indeed, most prominent among the functional groups of annotated genes up or down regulated by the tetrapyrroles were those whose gene products are involved in protein folding and/or protein degradation. Striking is the virtual absence of regulated genes that encode constituents of the photosynthetic apparatus. This and the transient nature of changes in gene expression observed upon feeding of the tetrapyrroles suggest a signaling role of these plastid compounds in the adaptation of the alga to alterations in the environment.

Project description:5-ALA that can be metabolized to porphyrins, protoporphyrin IX and hemin antagonizes decreased synaptic plasticity and cognitive deficits seen in ATR-X model (AtrxΔE2) mice. Our findings suggest a potential therapeutic strategy to target G-quadruplexes and decrease cognitive impairment associated with ATR-X syndrome.

Project description:Gene expression signatures induced by transient ROS production were characterized in both mouse back skin and tail epidermis samples. A transient in situ ROS production in the tissue was activated by an adapted photodynamic treatment, using methyl aminolevulinate as a metabolic precursor of endogenous Protoporphyrin IX.

Project description:Phalaenopsis aprodite subsp. formosana is one of the most important species for Phalaenopsis breeding. A mutant line with variegated leaf is found in this species. The green leaves bear unstable yellow sectors. In order to investigate the molecular mechanism of the variegated mutant line, we sequenced the transcriptome of variegated mutant by Illumina's Solexa sequencing technology. The sequence analysis results showed 22,598 unigenes by de novo assembly method, and the average unigene length was 1,286 bp. The bioinformatics tools were used to screen the differential expression between green and yellow sectors of leaves. There were 389 differentially expressed unigenes were identified. In addition, Gene ontology (GO) and KEGG pathway analyses revealed diverse biological functions and processes from differentially expressed genes. In transcriptome analysis, seven differential expression gene between the green and yellow sectors of leaves can be identified as CHLM, CRD1, POR, CLH, SGR, psbA and Lhcb6 by RNA deep sequencing. The expression of candidate genes was confirmed using semi-quantitative reverse transcription (RT) PCR and real-time RT PCR. The result showed that the significantly differential expression of CLH and SGR between green and yellow sectors was confirmed. It is suggested that the overexpressed SGR gene promotes the function of chlorophyllase, leading to the rapid degradation of chlorophyll in yellow sector. It causes the chlorophyll to not accumulate in the yellow sector, as a result, the variegated leaves are shown.