Project description:Haematococcus pluvialis is a green microalga of commercial interests due to its ability to produce a high value ketocarotenoid, astaxanthin. As a non-model species that lacks a well annotated genome, omics analyses such as transcriptomics and proteomics analysis have often been used together with physiological and biochemical analysis to explore pathways of interest. However, interpretation of these datasets remains challenging. In this work, TMT-based proteomics and phosphoproteomics analyses were conducted on Haematococcus cells grown under favorable conditions (green stage biomass) and high-light stress conditions (red stage biomass). Phosphoproteins were enriched using titanium dioxide before LC-MS/MS analysis. Our proteomics and phosphoproteomics analyses identified 1394 proteins and 569 phosphosites on 366 phosphoproteins, respectively. Of these, 1315 proteins and 396 phosphosites on 314 phosphoproteins were quantifiable, among which 370 proteins and 121 phosphosites on 94 phosphoproteins were differentially expressed. Using an improved analysis pipeline that combines Blast2GO, KEGG, and DAVID to analyze differentially expressed proteins and phosphoproteins, total identified proteins increased from 255 to 322 and total identified phosphoproteins increased from 59 to 70, which were 26.28% and 18.64%, respectively, higher than with the UniProt analysis alone. Using this pipeline, a previously uncharacterized protein and phosphoprotein were identified as an ATPase subunit B and a phosphofructokinase, respectively, and further confirmed with translated genomic and transcriptomic data. This work provides the first example of phosphoproteomics analysis in H. pluvialis, while the proteomics and phosphoproteomics analysis pipelines described here may be useful to analyze omics data from other non-model algal species.

Project description:The species of two bacterial colonies were determined by sequencing their DNA and comparing it with databases. Their adaptation to extreme conditions (conditions similar to those found in the planet Mars) were studied by proteomics, comparing the proteome obtained from a culture under standard laboratory conditions with the proteome obtained from a culture under extreme conditions. The techniques used were 2-DE electrophoresis, Difference in gel electrophoresis (2-D DIGE) and protein analysis by mass spectrometry Matrix Assisted Laser Desorption/ Ionization – Time of Flight (MALDI-TOF).

Project description:The species of two bacterial colonies were determined by sequencing their DNA and comparing it with databases. Their adaptation to extreme conditions (conditions similar to those found in the planet Mars) were studied by proteomics, comparing the proteome obtained from a culture under standard laboratory conditions with the proteome obtained from a culture under extreme conditions. The techniques used were 2-DE electrophoresis, Difference in gel electrophoresis (2-D DIGE) and protein analysis by mass spectrometry Matrix Assisted Laser Desorption/ Ionization – Time of Flight (MALDI-TOF).

Project description:Diverse aerobic bacteria use atmospheric hydrogen (H2) and carbon monoxide (CO) as energy sources to support growth and survival. Though recently discovered, trace gas oxidation is now recognised as a globally significant process that serves as the main sink in the biogeochemical H2 cycle and sustains microbial biodiversity in oligotrophic ecosystems. While trace gas oxidation has been reported in nine phyla of bacteria, it was not known whether archaea also use atmospheric H2. Here we show that a thermoacidophilic archaeon, Acidianus brierleyi (Thermoproteota), constitutively consumes H2 and CO to sub-atmospheric levels. Oxidation occurred during both growth and survival across a wide range of temperatures (10 to 70°C). Genomic analysis demonstrated that A. brierleyi encodes a canonical carbon monoxide dehydrogenase and, unexpectedly, four distinct [NiFe]-hydrogenases from subgroups not known to mediate aerobic H2 uptake. Quantitative proteomic analyses showed that A. brierleyi differentially produced these enzymes in response to electron donor and acceptor availability. A previously unidentified group 1 [NiFe]-hydrogenase, with a unique genetic arrangement, is constitutively expressed and upregulated during stationary phase and aerobic hydrogenotrophic growth. Another archaeon, Metallosphaera sedula, was also found to oxidize atmospheric H2. These results suggest that trace gas oxidation is a common trait of aerobic archaea, which likely plays a role in their survival and niche expansion, including during dispersal through temperate environments. These findings also demonstrate that atmospheric H2 consumption is a cross-domain phenomenon, suggesting an ancient origin of this trait, and identify previously unknown microbial and enzymatic sinks of atmospheric H2 and CO.

Project description:By using heterotrophic proteome as reference, 169 proteins were found to change their abundance during autotrophic growth. The up-regulated proteins indicated that M. cuprina fixed CO2 through the previously identified 3-HB-CoA/4-HB-CoA cycle and obtained energy by oxidation of elemental sulfur as energy source under autotrophic growth. Enzymes/proteins involved in semi- and non-phosphorylating Entner-Doudoroff (ED) pathway were down-regulated. We also found that some transporter proteins changed their abundances, suggest that they were likely playing pivotal roles for growth under the respective conditions.

Project description:Scaling up the functioning of synthetic circuits from microplates to bioreactors is far from trivial to achieve. We here test the scalability performance of a previously developed growth switch for increasing product yields in bacteria, based on external control of RNA polymerase expression. We show that, in liter-scale bioreactors operating in fed-batch mode, growth-arrested Escherichia coli cells are able to convert glucose to glycerol at an increased yield. A multi-omics quantification of the physiology of the cells shows that apart from acetate production, few metabolic side-effects occur, while a number of specific responses to growth slow-down and growth arrest are launched on the transcriptional level. These responses include the downregulation of genes involved in growth-associated processes, such as amino acid and nucleotide metabolism and translation, and the upregulation of heat shock genes. Interestingly, these transcriptional responses are buffered on the proteomic level, probably due to the strong decrease of the total mRNA concentration after the diminution of transcriptional activity and the absence of growth dilution of proteins. This transforms the growth-arrested cells in “bags of proteins“ with a functioning metabolism. More generally, the analysis shows that physiological characterization of bacterial cells hosting a synthetic circuit may reveal complex patterns of adaptation on different time-scales, dynamically interacting with the bioreactor environment.

Project description:The understanding of molecular events occurring in Chlorella during heterotrophy to photoautotrophy transition as well as sudden light stress and glucose starvation, are still largely unknown. To well grasp its cellular metabolism, particularly the regulation of biosynthesis and degradation pathways of lipid, protein and carbohydrates, as well as the diverse trophic adaptation affecting carbon partitioning during heterotrophy to photoautotrophy transition process, we sequenced the transcriptome (RNA-seq) in six time points to discover how transcriptional changes in C. pyrenoidosa modulate metabolic flux trends leading to intracellular components dynamic reassortment. Three independent biological experiments (biological replicates) were carried out in the same batch. In total, eighteen samples collected at six time points (0-, 24-, 72-h from heterotrophic cells and 2-, 8-, 24-h from phototrophic cells) were used for mRNA-Seq library preparation and then submitted to Solexa GA-IIx (Illumina, USA) for sequencing.

Project description:We have analysed the genome-wide distribution of RNA polymerase in E.coli upon acetate stress. We have used ChIP-chip of the ß subunit of RNA polymerase and we have assessed changes in RNA polymerase distribution following exposure to 8 mM acetate.

Project description:We have investigated the regulation of anchorage-independent growth (AIG) by basic fibroblast growth factor (bFGF) and 12-O-tetradecanoyl phorbol-13-acetate (TPA) in JB6 mouse epidermal cells in the context of wound repair versus carcinogenesis responses. bFGF induces an unusually efficient but reversible AIG response, relative to TPA-induced AIG which is irreversible. Distinct global gene expression profiles are associated with anchorage-independent colonies arising from bFGF-stimulated JB6 cells, relative to colonies arising from fully tumorigenic JB6 cells (RT101), including genes exhibiting reciprocal regulation patterns. Thus, while TPA exposure results in commitment to an irreversible and tumorigenic AIG phenotype, the AIG response to bFGF is reversible with essentially complete restoration of normal cell cycle check point control following removal of bFGF from growth medium. These results are consistent with the physiological role of bFGF in promoting wound healing, and suggest that natural mechanisms exist to reverse transformative cellular phenotypes associated with carcinogenesis. Experiment Overall Design: To determine whether there were shared transcriptional effects between reversible and irreversible AIG, we performed global microarray analyses on colonies isolated from soft agar for both bFGF-treated JB6 cells and fully tumorigenic JB6 cells from the RT101 cell line. Gene expression changes associated with colony formation were determined by comparison to respective monolayer control cells.

Project description:Organic acid secretion is a widespread physiological response of plants to alkalinity. However, the features of alkali-induced secretion of organic acid and the underlying mechanism are poorly understood. Herein, it was indicated that oxalate was the main organic acid synthesized and secreted in vine roots, and acetate synthesis and malate secretion were also promoted under NaHCO3 stress. NaHCO3 stress enhanced H+ efflux rate of vine roots, which was related to plasma membrane H+-ATPase activity. Transcriptomic profiling revealed that carbohydrate metabolism was the most significantly altered biological process under NaHCO3 stress; a total of seven genes related to organic acid metabolism were significantly altered, including two PEPCs and PEPCKs. Additionally, the expression levels of five ABC transporters, particularly ABCB19, as well as two malate transporter ALMT2s, were largely upregulated by NaHCO3 stress. Phosphoproteomic profiling demonstrated that the altered phosphoproteins were primarily related to binding, catalytic activity and transporter activity in light of their molecular functions. The phosphorylation levels of PEPC3, two plasma membrane H+-ATPases 4 and ABC transporters ABCB19 and PDR12 were significantly increased. Additionally, the inhibition of ethylene synthesis and perception completely blocked NaHCO3-induced organic acid secretion, while the inhibition of IAA synthesis reduced NaHCO3-induced organic acid secretion. Collectively, our results demonstrated oxalate as the main organic acid under alkali stress and the necessity of ethylene in mediating organic acid secretion, as well as further identified several candidate genes and phosphoproteins responsible for organic acid metabolism and secretion.