Project description:The widespread presence of microplastics (MPs) in freshwater systems has raised concerns about their potential ecotoxicity on aquatic organisms. In this study, we evaluated the effects of four MPs with different compositions, namely polyethylene (PE), polystyrene (PS), polyvinyl chloride (PVC) and polypropylene (PP), on freshwater microalgae Chlamydomonas reinhardtii. PS and PVC MPs caused greater growth inhibition and stronger oxidative stress response than PP and PE MPs. Proteomics analysis was employed to explore the mechanical understanding of the composition-dependent toxicity of MPs on microalgae. Proteins involved in photosynthesis processes were identified as contributors to the diverse responses of microalgae to differently composed MPs. Photosynthesis activity of algae, including pigment content and photoprotective response, was determined to reflect the distinct effect of the four MPs. The indicated down-regulated expression of photosynthetic proteins by proteomics analysis was further confirmed using western blot, with PVC and PS showing greater impacts on their expression reduction. Our findings not only show the composition-dependent effect of MPs on microalgae but also provide important insights into the molecular mechanism of MPs’ toxicity on natural phytoplankton species.

Project description:Microalgae remain an important feedstock for the production of biofuels and bioproducts. Discovery of new species drives innovation for biotransformation, where bioengineering and other technological advances can significantly optimize performance. Production is predicated on deep knowledge of algal behavior predicted from genomic and phenotypic studies. However, prediction and manipulation of behavior, particularly for scale up, remains a challenge. Understanding the contribution of epigenetic processes to algal function provides another piece of this complex puzzle for achieving bioeconomy goals. Utilizing Nannochloropsis species as a model, we provide a methodological framework for investigating epigenetic processes, specifically DNA methylation, in new species and demonstrate best practices for discerning novel epigenetic modifications. We demonstrate specific forms of DNA methylation can be overlooked by traditional epigenetic analysis strategies. Using high-throughput, lower cost techniques, we provide evidence demonstrating Nannochloropsis gaditana and N. salina lack the most ubiquitous forms of eukaryotic DNA methylation (5mC and 5hmC) and instead employ N6-adenine methylation (6mA), commonly found in bacteria, in their genomes.

Project description:Nanoscale zero valent iron (nZVI) is used to remediate aquifers polluted by organochlorines or heavy metals and was also suggested to eliminate harmful algal blooms. nZVI can therefore affect microorganisms in the vicinity of the application area, including microalgae. However, studies on early transcriptomic effects of microalgae after exposure to nZVI are rare. Here, we described the early physiological and transcriptomic response of the freshwater ecological indicator green microalga, Raphidocelis subcapitata ATCC 22662, to 100 mg/L of reactive nZVI and non-reactive nano-magnetite (nFe3O4). The combined effect of shading and the release of total iron from nZVI posed a short-term inhibition effect leading to 15 % of deformed cells and cytosol leakage, while cells viability increased after 24 h. nZVI triggered a more pronounced transcriptomic response with (7380 differentially expressed genes [DEGs]) compared to nFe3O4 (4601 DEGs) after 1 h. nZVI, but not nFe3O4 increased the expression of genes function in DNA repair and replication, while deactivated carbohydrate-energy metabolisms, mitochondria signaling, and transmembrane ion transport. This study highlights an early fate assessment of algal cells under nZVI and nFe3O4 exposure using next-generation risk assessment methods and will serve as valuable information for safe and sustainable application of nZVI in water remediation.

Project description:To investigate the mechanism by which the microalgae-yeast co-culture system promotes wastewater denitrification. We concluded that microalgae and yeast exhibit a mutually beneficial relationship in the co-culture system. Microalgae nitrogen metabolism can be influenced by both miRNA and mRNA, and the presence of yeast stimulates gene expression in microalgae.

Project description:This experiment aimed at characterising the modulatory role of murine induced Neural Stem Cells (iNSCs) and Neural Stem Cells (NSCs) on macrophages (MPs) exposed to LPS in vitro. Naïve MPs were polarized into an M1-like phenotype with LPS, and then co-cultured with 1:1 ratios of iNSCs in a trans-well system that avoids cell-to-cell contacts. Naïve MPs, LPS-stimulated MPs and LPS-stimulated MPs co-cultured with NSCs were used as controls.

Project description:Animal-algal photosymbioses are a unique group of symbiotic relationships in which animals harbor photosynthetic algae within their cells and tissues. Both marine and freshwater sponges host algal endosymbionts. In previous work, we demonstrated that freshwater sponges can acquire these endosymbionts horizontally through algal infection and that potentially conserved evolutionary pathways may lead to the establishment of the endosymbioses including those involved in endocytosis, ion transport, vesicle-mediated transport, innate immunity, redox regulation, and metabolic processes. Here, we show that algal symbionts can be transferred vertically from algal-bearing overwintering gemmules to adult sponges, and that their proliferation is enhanced by light. Sponges grown under light conditions harbored higher algal loads than those in the dark; however, algae were still able to proliferate and persist in sponges reared in the dark, occupying similar spatial locations to those grown in light. RNA-Seq analysis of algal-bearing sponges across developmental stages in light and dark conditions revealed genetic regulatory pathways involved in the transmission and establishment of the endosymbiosis. Differential expression analysis indicated that the endocytosis and SNARE pathways regulate the internalization and transport of algae at the earliest stage of hatching under light conditions and later in development under dark conditions, potentially contributing to the recruitment of endosymbiotic algae. In sponges hatched in the dark, genes involved in vesicle acidification are regulated, alongside changes in the expression of genes in the pentose phosphate pathway - a key metabolic route involved in redox homeostasis and circadian rhythm regulation via NADPH metabolism, is observed. E. muelleri serves as a versatile model system, supported by robust genomic and transcriptomic resources, for studying host-symbiont interactions. It offers a unique opportunity to investigate the molecular signaling and environmental factors that shape symbiosis in a system where the host can exist with or without algal endosymbionts, symbionts can be acquired either horizontally or vertically, and proliferation of the algae can occur with or without photosynthesis.

Project description:Background: Microalgae are promising feedstocks for production of renewable biofuels and value-added bioproducts. Temperature and nitrogen supply are important environmental and nutritional factors affecting the growth and metabolism of microalgae, respectively. In this study, the growth and lipid accumulation of filamentous microalga Xanthonema hormidioides under different temperatures (5, 7, 10, 15, 20, 25, 27 and 30℃) and initial nitrogen concentrations (3, 9, 18 mM) were investigated, and its adaptive mechanisms of tolerance to low temperature and nitrogen stress were analysis by proteomics. Results: The optimum temperature range for the growth of X. hormidioides was between 15℃ and 20℃, and the algal cells had slow growth rate at 5℃ and could not survive at 30℃. The maximum biomass concentration was 11.73 g L-1 under the temperature of 20℃, and the highest total lipid content was 56.63% of dry weight. Low temperature did not change the fatty acids profiles but promoted the accumulation of unsaturated fatty acids of X. hormidioides. The maximum contents of palmitoleic acid, eicosapentaenoic acid and total fatty acid were 23.64%, 2.49% and 41.14% of dry weight, respectively. Proteomics was performed under three temperature (7、15、25℃), two nitrogen concentrations (3 and 18 mM) and two cultivation times (day3 and 12). A total of 6503 proteins were identified. In the low temperature, photosynthesis related proteins were down-regulation to protect the photosynthetic apparatus. The up-regulation of key enzymes DGAT and PDAT demonstrated the accumulation of TAGs under low nitrogen treatment. The proteins related to ribosome, phosphatidylinositol signaling system, antioxidant system and cold shock proteins (CSPs) in X. hormidioides were co-up-regulate under the treatment of low temperature, which can alleviate the damages induced by temperature stress and maintain the normal growth and metabolism of algal cells. Conclusions: X. hormidioides is a psychrotolerant microalga. It is an oleaginous filamentous microalga containing hyper palmitoleic acid and a certain amount of eicosapentaenoic acid with great potential for biofuel development, as well as for applications in nutritional health products and other industries.

Project description:Microplastics (MPs) as widespread contamination pose high risk for aquatic organisms.Intestinal microbiotahas have high interaction with immune system of host body. In this study, intestinal microbiota of zebrafish after Polystyrene (PS-MPs) exposure were characterized by 16S rDNA amplicon sequencing. We found that 100nm and 200μm PS-MPs exposure significantly increased diversity of intestinal microbiota and all the three sizes of PS-MPs increased abundance of pathogenic bacteria.

Project description:Co-growth of bacteria with the algal Thalassiosira rotula

Project description:<p>Environmental co-contamination presents significant challenges. To tackle these, while microbial consortia offer advantages over single-strain approaches, such as functional redundancy and synergistic degradation,&nbsp;rationally designing effective synthetic microbiomes specifically for complex co-contamination scenarios remains a major challenge. Here, we utilized our advanced genome-scale metabolic modeling (GSMM) tool, SuperCC, to simulate the metabolic&nbsp;behavior of communities consisting of six isolated key strains under single- and multi-carbon source conditions, mimicking single-pollutant or co-contamination scenarios respectively. By integrating multi-omics data with metabolic modeling of cultured consortia, we systematically elucidated key strain interaction networks and adaptive strategies under co-contamination. This revealed that the specific secretory products of broad-spectrum resource-utilizing bacteria serve as key metabolites driving cooperation and highlighted the pivotal role of indigenous keystone strains in stabilizing and enhancing community function. Consequently, we propose a novel and rational paradigm for consortium design: DHP-Com (Degrader-Helper-Potentiator). Synthetic microbiomes constructed based on this framework exhibited enhanced ecological fitness (survival and growth) and, most importantly, substantially improved remediation performance across diverse co-contamination scenarios. Our findings advance the practical application of GSMM predictions to decipher intricate multi-pollutant/multi-strain interaction networks, offering a powerful rational framework and robust methodological tools for engineering multi-functional and effective synthetic microbiomes for complex environmental remediation.</p>