Project description:Diatom cell walls, made of nanostructured silica, are of interest in diverse areas ranging from cellular structure, to hierarchical organization in biomineralization, to nanotechnology. Thus far, only cell surface proteins and proteins tightly associated with silica matrix have been characterized, and essential components of the silica deposition vesicle (SDV) are unknown, including components of the SDV membrane, cytoskeletal-interacting proteins, and proteins involved in trafficking associated with the SDV. Thus, an understanding of most of the molecular components and the dynamics of cellular processes involved in cell wall synthesis is lacking. In this work we report the first whole-cell response analysis using whole genome microarrays to identify genes potentially involved in diverse aspects of diatom cell division or cell wall synthesis. Thalassiosira pseudonana transcript profiles from precise time points, known to be associated with specific cell wall formation processes in cell-cycle synchronized cultures, suggests that this gene set includes extracellular proteins, silica matrix proteins, and proteins involved in signal transduction, vesicle trafficking, and transport. Protein localization experiments further confirm the first discovery of proteins associated with the SDV membrane. We propose that these proteins provide the interface between extra-SDV organization by the cytoskeleton and intra-SDV organization of silica polymerization determinants, which lead to the higher order organization of diatom silica structure. Analyzed mRNA from 0, 2, 4, 7, 8 and 9 hr of synchronized cell cycle using the Affymetrix GeneChip whole genome tiling array. Initial analysis of gene level expression was performed using Affymetrix Expression Console Software, version 1.1. No biological replicates were performed. 0 hr is used as reference point.

Project description:T. pseudonana tiling arrays were used to validate gene models and to predict new genes in the genome of this diatom. The tiling array data validated transcription of about 41% (4,653) of the 11,390 computationally predicted genes. An additional 1,132 transcripts were identified that did not correspond to modeled genes with few of these transcripts (<17%) predicted to encode proteins with homology (e-value < 10-05) to publicly available proteins. These newly identified transcripts have an average length of 1,549 bp, comparable to the average length of the computationally derived genes. Whole genome tiling arrays were conducted under silicon replete and deplete growth conditions to identify new genes involved in the synthesis of the diatom silica cell wall. Keywords: silicon, stress response, cell wall

Project description:T. pseudonana tiling arrays were used to validate gene models and to predict new genes in the genome of this diatom. The tiling array data validated transcription of about 41% (4,653) of the 11,390 computationally predicted genes. An additional 1,132 transcripts were identified that did not correspond to modeled genes with few of these transcripts (<17%) predicted to encode proteins with homology (e-value < 10-05) to publicly available proteins. These newly identified transcripts have an average length of 1,549 bp, comparable to the average length of the computationally derived genes. Whole genome tiling arrays were conducted under silicon replete and deplete growth conditions to identify new genes involved in the synthesis of the diatom silica cell wall. We analyzed 2 sets of arrays (8 arrays each): one from growth under silicon replete and another one from growth under silicon deplete conditions.

Project description:The diatom cell wall, or frustule, is a highly complex, three-dimensional structure consisting of nanopatterned silica as well as proteins and other organic components. While some key components have been identified, knowledge on frustule biosynthesis is still fragmented. The model diatom Thalassiosira pseudonana was subjected to silicon (Si) shift-up and shift-down situations. Cellular and molecular signatures, dynamic changes and co-regulated clusters representing the hallmarks of cellular and molecular responses to changing Si availabilities were characterised. 62 silaffin-like proteins (SFLPs), two kinases and a novel family of putatively frustule-associated transmembrane proteins induced by Si shift-up and a possible role in frustule biosynthesis were identified. A separate cluster analysis performed on all significantly regulated SFLPs, as well as fourteen new proteins with silaffin-like motifs, resulted in the classification of silaffins, cingulins and SFLPs into distinct clusters. The genes in the Si-responsive clusters are in general highly divergent, but positive selection does not seem to be the driver behind this variability. This study provides a high-resolution map over transcriptional responses to changes in Si availability in T. pseudonana. Hallmark Si-responsive genes are identified, characteristic motifs and domains are classified, and taxonomic and evolutionary implications outlined and discussed.

Project description:To identify the molecular components involved in diatom cell division, global transcript level changes were monitored over the silicon-synchronized cell cycle the model diatom Thalassiosira pseudonana.

Project description:Proteins associated with diatom silica are likely involved in the biogenesis of the complex, species-specific morphologies of the biomineral, but only very few such proteins have been identified. In this project we extracted and identified proteins from three related, but morphologically distinct, species of centric diatoms: Thalassiosira pseudonana, Thalassiosira oceanica and Cyclotella cryptica.

Project description:Phytoplankton and bacteria form the base of marine ecosystems and their interactions drive global biogeochemical cycles. The effect of bacteria and bacteria-produced compounds on diatoms range from synergistic to pathogenic and can affect the physiology and transcriptional patterns of the interacting diatom. Here, we investigate physiological and transcriptional changes in the marine diatom Thalassiosira pseudonana induced by extracellular metabolites of a known antagonistic bacterium Croceibacter atlanticus. Mono-cultures of C. atlanticus released compounds that inhibited diatom cell division and elicited a distinctive phenotype of enlarged cells with multiple plastids and nuclei, similar to what was observed when the diatom was co-cultured with the live bacteria. The extracellular C. atlanticus metabolites induced transcriptional changes in diatom pathways that include recognition and signaling pathways, cell cycle regulation, carbohydrate and amino acid production, as well as cell wall stability. Phenotypic analysis showed a disruption in the diatom cell cycle progression and an increase in both intra- and extracellular carbohydrates in diatom cultures after bacterial exudate treatment. The transcriptional changes and corresponding phenotypes suggest that extracellular bacterial metabolites, produced independently of direct bacterial-diatom interaction, may modulate diatom metabolism in ways that support bacterial growth.

Project description:<p>In annually reoccurring patterns, microalgae form blooms that persist and decline thereby contributing massively to global biogeochemical cycles. The decline of blooms is mainly caused by nutrient limitation and goes ahead with the aging of individual algal cells. Nutrient intake can re-initiate proliferation, but the processes involved are poorly understood. By investigating the bloom-forming diatom Coscinodiscus radiatus, we demonstrate how algae recover after nutrient influx. The rejuvenation physiology of the algae is characterized by metabolomic re-organization and the formation of extracellular vesicles. Regulated pathways mediating aging are centered around the methionine cycle in C. radiatus. Vesicles shuttle reactive oxygen species, oxylipins and other harmful metabolites out of the old cells, thereby re-enabling their proliferation. Metabolic processes involved in aging and vesicle production are modulated by bacteria. Using chemical signaling bacteria can trigger vesicle production thereby releasing organic nutrients for their growth and supporting algal growth as well.</p><p><br></p><p><strong>Metabolomics analysis</strong>&nbsp;is reported in the current study&nbsp;<a href='https://www.ebi.ac.uk/metabolights/MTBLS5368' rel='noopener noreferrer' target='_blank'><strong>MTBLS5368</strong></a>.</p><p><strong>Metabolomics profiling of FACS purified EVs</strong>&nbsp;is reported in&nbsp;<a href='https://www.ebi.ac.uk/metabolights/MTBLS5401' rel='noopener noreferrer' target='_blank'><strong>MTBLS5401</strong></a>.</p>

Project description:<p>In annually reoccurring patterns, microalgae form blooms that persist and decline thereby contributing massively to global biogeochemical cycles. The decline of blooms is mainly caused by nutrient limitation and goes ahead with the aging of individual algal cells. Nutrient intake can re-initiate proliferation, but the processes involved are poorly understood. By investigating the bloom-forming diatom Coscinodiscus radiatus, we demonstrate how algae recover after nutrient influx. The rejuvenation physiology of the algae is characterized by metabolomic re-organization and the formation of extracellular vesicles. Regulated pathways mediating aging are centered around the methionine cycle in C. radiatus. Vesicles shuttle reactive oxygen species, oxylipins and other harmful metabolites out of the old cells, thereby re-enabling their proliferation. Metabolic processes involved in aging and vesicle production are modulated by bacteria. Using chemical signaling bacteria can trigger vesicle production thereby releasing organic nutrients for their growth and supporting algal growth as well.</p><p><br></p><p><strong>Metabolomics profiling of FACS purified EVs</strong>&nbsp;is reported in the current study&nbsp;<a href='https://www.ebi.ac.uk/metabolights/MTBLS5401' rel='noopener noreferrer' target='_blank'><strong>MTBLS5401</strong></a>.</p><p><strong>Metabolomics analysis</strong>&nbsp;is reported in&nbsp;<a href='https://www.ebi.ac.uk/metabolights/MTBLS5368' rel='noopener noreferrer' target='_blank'><strong>MTBLS5368</strong></a>.</p>

Project description:Nutrient-starvation induced lipid accumulation has been reported in diverse algae, including diatoms. Molecular mechanisms underlying lipid accumulation in nutrient-starved algae are of interest to inform genetic engineering strategies aimed at improving lipid productivity. Diatom cell walls are made of nanostructured silica which is a unique feature of the group and silicon deprivation induces both growth arrest and lipid accumulation. In this work, we report the whole cell transcript level response during silicon starvation induced lipid accumulation.