Project description:This proteomics dataset characterizes photosystem-centered molecular responses of the green microalga Tetraselmis chuii under nonylphenol stress. Quantitative protein profiling reveals coordinated remodeling of light-harvesting complexes, enhanced photoprotection, energy metabolism reprogramming, and repair-associated pathways underlying active photosynthetic resilience to anthropogenic chemical exposure.

Project description:The urgent need to address water scarcity underscores the importance of enhancing plant drought resistance. This study investigates whether pretreatment with abscisic acid (ABA) activates early stress signaling, thereby improving barley drought response when subsequently exposed to drought conditions. Although the individual responses to drought and ABA are well-documented, their synergistic effects in barley warrant further investigation. This study examines the impact of ABA on barley drought resilience through an experimental design that incorporates four distinct treatments: optimal watering, ABA application at 60 days post-sowing, and two drought stress treatments - one with and the other without prior ABA application. Key physiological parameters, such as photosynthesis, stomatal conductance and chlorophyll content, were analyzed in conjunction with transcriptomics. The results suggest that ABA pretreatment initiates early stomatal closure and elevates the expression of essential genes like NCED1, BG8, and HvA22, priming barley for improved drought resistance. During the drought, ABA-pre-treated barley maintained high chlorophyll levels, indicating sustained photosynthetic activity, a trend that persisted across treatments during the post-drought recovery phase. Furthermore, ABA pre-treatment was found to preserve photosystem II efficiency during drought conditions. Transcriptomic analyses revealed distinct gene expression profiles, alternative splicing profile and isoform switching, highlighting the molecular complexities of ABA role in drought response. These alterations span stress response, metabolic pathways, and DNA modification processes, providing a comprehensive view of ABA treatment's regulatory and metabolic impacts. In conclusion, ABA pretreatment strengthens barley drought defense by fostering stomatal closure and gene activation, guiding research strategies grounded in ABA and suggesting that genotypes with elevated ABA levels could have enhanced resilience and recovery capabilities.

Project description:Photosynthetic bacterium with chlorophyll d

Project description:The mechanisms of acclimating to a nitrogen-fluctuating environment are necessary for the survival of aquatic cyanobacteria in their natural habitats, but our understanding is still far from complete. Here, the synthesis of phycobiliprotein is confirmed to be much earlier than that of photosystem components during recovery from nitrogen chlorosis and an unknown protein Ssr1698 is discovered to be involved in this synthetic process. The unknown protein is further identified as a c-type heme oxygenase (cHO) in tetrapyrrole biosynthetic pathway and catalyzes the opening of heme ring to form biliverdin IXα, which is required for phycobilin production and ensuing phycobiliprotein synthesis. In addition, the cHO-dependent phycobiliprotein is found to be vital for the growth of cyanobacterial cells during chlorosis and regreening through its nitrogen-storage and light-harvesting functions, respectively. Collectively, the cHO expressed preferentially during recovery from nitrogen chlorosis is identified in photosynthetic organisms and the dual function of this enzyme-dependent phycobiliprotein is proposed to be an important mechanism for acclimation of aquatic cyanobacteria to a nitrogen-fluctuating environment.

Project description:Bisphenol A (BPA) is a widespread environmental contaminant with well-documented toxic effects on aquatic organisms; however, the mechanism of microalgal resilience toward BPA remain insufficiently understood. In this study, an integrated approach combining flow cytometry and multi-omics analyses was employed to investigate the temporal physiological and molecular responses of the marine microalga Tetraselmis chuii following acute BPA exposure.

Project description:Linear tetrapyrrole (bilin)-based phytochrome sensors optimize photosynthetic light capture by mediating massive gene reprogramming in land plants, yet surprisingly, many sequenced chlorophyte (green) algae lack phytochrome genes. Previous studies on the heme oxygenase (hmox1) mutant of Chlamydomonas reinhardtii suggest that bilin biosynthesis in plastids is needed for regulation of a limited nuclear gene network implicated in oxygen detoxification during dark to light transitions. The hmox1 mutant is unable to grow photoautotrophically and poorly acclimates to increased illumination even in the presence of acetate. Here we show that these phenotypes reflect the reduced accumulation of PSI reaction centers as well as a loss of PSI and PSII antennae complexes during photoacclimation. Phenotypically, the hmox1 mutant is similar to the chlorophyll biosynthesis mutants, gun4, crd1 and cth1. However, many of the hmox1 phenotypes can be rescued by the application of exogenous biliverdin IXα, the bilin product of HMOX1; this rescue is independent of photosynthesis but strongly dependent upon blue light. RNA-Seq comparisons of hmox1, 4A+ wild type and two genetically complemented lines also reveal that bilins restore regulation of a small network of photosynthesis-associated nuclear genes. These include genes responsible for chlorophyll biosynthesis (CHLI1/2), PSI light-harvesting (LHCA4) and naphthoquinone metabolism (MEN2), all of which show reduced photoinduction in the hmox1 mutant. We propose that a bilin-based, blue light sensory system is responsible for the maintenance of a functional photosynthetic apparatus in light-grown C. reinhardtii. This critical and possibly ancestral role for bilins may be responsible for retention of bilin biosynthesis in all eukaryotic photosynthetic species.

Project description:We report the application of RNA-seq technology for highthroughput profiling of photosynthetic and non-photosynthetic seeds of Arabidopsis chlorophyll synthase mutant seeds. By generating over 21 GB of sequence data from these seeds, we showed that genes involved in oil accumulation in non-photosynthetic seeds were significantly induced compared to photosynthtic seeds. Additionally we found that genes involved in the plastidal oxidative pentos phosphate pathway were significantly upregulated in the non-photosynthetic seed opposite to photosynthetic seeds. Overall our RNA-seq analysis revealled the genes and pathway interaction underpinining oil accumulation in non-photosynthetic seeds.

Project description:The heme branch of tetrapyrrole biosynthesis contributes to the regulation of chlorophyll levels. However, the molecular mechanism underlying the balance between chlorophyll and heme synthesis remains elusive. Here, we identified a dark green leaf mutant dg, which contains high levels of chlorophyll b, from an ethyl methanesulfonate (EMS) -induced mutant library of Chinese cabbage. The dg phenotype is attributed to a nonsynonymous homozygous mutation in ferrochelatase 2 (BrFC2), leading to an arginine (R) to lysine (K) amino acid substitution in the conserved chlorophyll a/b-binding motif (CAB) of BrFC2. Overexpression of mutated BrFC2 (dBrFC2) in Chinese cabbage results in a pronounced phenotype associated with the dark green leaves, in contrast to transgenic lines overexpressing wild-type BrFC2 with a low-chlorophyll phenotype. Increased dBrFC2 homodimer formation stimulates heme production in dg compared with wildtype BrFC2. Moreover, we found that dBrFC2 interacts with protochlorophyllide oxidoreductase B1 and B2 (BrPORB1 and BrPORB2) to enhance their binding ability to substrate protochlorophyllide (Pchlide), thereby promoting BrPORBs-catalyzed production of chlorophyllide (Chlide) that can be directly converted into chlorophyll. Our results reveal that dBrFC2 is a strong gain-of-function mutation contributing to balancing heme and chlorophyll synthesis via a novel regulatory mechanism in which dBrFC2 promotes BrPORB enzymatic reaction to enhance chlorophyll synthesis.

Project description:A photosynthetic organism with a unique low ratio of chlorophyll a to chlorophyll d

Project description:<p>This project aims to elucidate the molecular mechanism underlying the stable golden-yellow phenotype and enhanced protein accumulation in an&nbsp;Auxenochlorella pyrenoidosa&nbsp;mutant (CX41) generated by ARTP mutagenesis. Through comparative analysis between the wild-type (FACHB-9) and mutant strains under dark heterotrophic fermentation, we integrate phenotypic data (growth, pigment, and biochemical composition), extensive targeted metabolomics (focused on carotenoids), untargeted metabolomics, and transcriptome sequencing (RNA-Seq). Our findings reveal a hierarchical regulatory cascade: (1) Dysregulation of tetrapyrrole metabolism, leading to chlorophyll synthesis blockage and protoporphyrin IX depletion; (2) Massive downregulation of the photoprotective gene&nbsp;PSBS&nbsp;and collapse of the xanthophyll cycle, resulting in chronic plastid-derived oxidative stress; (3) Oxidative stress-driven global metabolic reprogramming, characterized by the downregulation of glycogen and lipid synthesis pathways, and redirection of carbon and nitrogen flux toward amino acid and protein biosynthesis, particularly proline and arginine. This study provides comprehensive omics data to understand how ARTP mutagenesis creates a high-protein, chlorophyll-free industrial microalga and offers insights into metabolic engineering for sustainable microbial protein production.</p>