Project description:Oleaginous yeasts are capable of accumulating high levels of intracellular storage lipids from excess carbon during times when other key nutrients are limited. The basidiomycete yeast Rhodosporidium toruloides is an emerging host for microbial cell factory applications thanks to its naturally high lipid and carotenoid production. However, the engineering toolbox in this non-model host is limited and is currently a bottleneck for implementation of metabolic engineering strategies. In this study, we performed differential gene expression analysis with the goal to identify promoters that are strongly induced or repressed by nitrogen-limitation, a condition that is commonly used to induce lipid accumulation in oleaginous yeasts. The genome-wide transcriptional response of R. toruloides BOT-A2 was analysed using RNAseq during exponential growth and nitrogen-starvation, with either glucose or xylose as the sole carbon source. To validate the differential gene expression findings, reporter genes were constructed by placing the candidate promoters in control of a fluorescent protein, integrated in BOT-A2 and evaluated in vivo.

Project description:Nitrogen limitation is a major regulator to initiate lipid overproduction in oleaginous fungi. To examine the influence of nitrogen starvation, chemiostat cultures of R. toruloides in defined media with abundant ammonium (MM) or minute ammonium (MM-N) were performed to obtain steady-state samples. Then Illumina's digital gene expression (DGE) technology was used for high-throughput transcriptome profiling of these samples.

Project description:Nitrogen limitation is a major regulator to initiate lipid overproduction in oleaginous fungi. To examine the influence of nitrogen starvation, chemiostat cultures of R. toruloides in defined media with abundant ammonium (MM) or minute ammonium (MM-N) were performed to obtain steady-state samples. Then Illumina's digital gene expression (DGE) technology was used for high-throughput transcriptome profiling of these samples. Two samples cultured in minimum media with abundant ammonium (MM) or minute ammonium (MM-N)

Project description:Systems analysis of phosphate-limitation induced lipid accumulation by the oleaginous yeast Rhodosporidium toruloides

Project description:Acinetobacter baumannii is an ESKAPE pathogen that rapidly develops resistance to antibiotics and persists for extended periods in the host or on abiotic surfaces. Survival in environmental stress such as phosphate scarcity, represents a clinically significant challenge for nosocomial pathogens. In the face of phosphate starvation, certain bacteria encode adaptive strategies, including the substitution of glycerophospholipids with phosphorus-free lipids. In bacteria, phosphatidylethanolamine, phosphatidylglycerol, and cardiolipin are conserved glycerophospholipids that can form lipid bilayers, particularly in the presence of other lipids. Here, we demonstrate that in response to phosphate limitation, conserved regulatory mechanisms induce alternative lipid production in A. baumannii. Specifically, phosphate limitation induces formation of three lipids, including amine-containing ornithine and lysine aminolipids. Mutations that inactivate aminolipid biosynthesis exhibit fitness defects relative to wild type in colistin growth and killing assays. Furthermore, we show that other Gram-negative ESKAPE pathogens accumulate aminolipids under phosphate limiting growth conditions, suggesting aminolipid biosynthesis may represent a broad strategy to overcome cationic antimicrobial peptide-mediated killing.

Project description:We combined transcriptional and metabolite analyses to monitor the effect of N deficiency at different molecular levels in order to get better insight on the acclimation strategies P. tricornutum employs under nitrogen limitation. Physiological data like neutral lipid measurement, cell growth and other cell chemistry measurements further complemented our molecular data. We showed that P. tricornutum is able to remobilize nitrogen through catabolism of various internal nitrogen-containing resources such as amino acids and proteins. N starvation was also accompanied by reduction in pigment pools as well as photosynthetic capacity. The global expression data showed that majority of metabolic changes were related to carbon and lipid metabolism. Decreased levels of carbon skeletons due to suppression of the Calvin cycle was compensated by breakdown of chrysolaminaran leading to up-regulation of OPPP, glycolysis, pyruvate metabolism and TCA cycle. These pathways provide precursors for fatty acid biosynthesis. In addition, remodeling of membrane lipids and up-regulation of the de novo TAG biosynthetic pathway was further supported by physiological measurements of neutral lipids, indicating TAG accumulation under N limitation. Our study gives a detailed image of adaptation of P. tricornutum to N starvation, and can be used for future metabolic manipulations to increase TAG production.

Project description:Thraustochytrids of the genera Schizochytrium and Aurantiochytrium accumulate oils rich in the essential, marine n3 fatty acid docosahexaenoic acid (DHA). DHA production in Aurantiochytrium sp T66 was studied with the aim to provide more knowledge about factors that affect the DHA-productivities and the contributions of the two enzyme systems used for fatty acid synthesis in thraustochytrids, fatty acid synthetase (FAS) and PUFA-synthase. Fermentations with nitrogen starvation, which is well-known to initiate lipid accumulation in oleaginous organisms, were compared to fermentations with nitrogen in excess where lipid accumulation was obtained by oxygen limitation. The specific productivities of fatty acids originating from FAS were considerably higher under nitrogen starvation than with nitrogen in excess, while the specific productivities of DHA were the same at both conditions. Global transcriptome analysis showed significant up-regulation of FAS under N-deficient conditions, while the PUFA-synthase genes were only marginally upregulated. Neither of them was upregulated under O2-limitation where nitrogen was in excess, suggesting that N-starvation mainly affects the FAS and may be less important for the PUFA-synthase. The transcriptome analysis also revealed responses likely to be related to the generation of reducing power (NADPH) for fatty acid synthesis.

Project description:The oleaginous green microalga Neochloris oleoabundans accumulates both starch and lipids to high levels under stress conditions such as nitrogen starvation. In order to steer the metabolism towards starch or lipids only, it is important to understand the mechanisms behind it. In this study physiological changes and gene expression upon nitrogen starvation were analysed in controlled flat-panel photobioreactors over both short- and long-term time-scales. Starch accumulation is transient and occurs rapidly within 24 hrs upon starvation, while lipid accumulation lasts longer and reaches a maximum after 4 days. The major fraction of accumulated lipids is composed of de novo synthesized neutral lipids - triacylglycerides (TAG) - and is characterized by a decreased composition of the polyunsaturated fatty acids (PUFAs) C18:3 and C16:3 and an increased composition of the mono-unsaturated and saturated fatty acids C18:1/C16:1 and C18:0/C16:0, respectively. RNA-sequencing revealed that genes related to starch biosynthesis and degradation show different temporal expression dynamics compared to those of lipid biosynthesis. An immediate rapid increase in starch synthesis gene expression is followed by an increase in starch degradation and decrease in starch synthesis gene expression. In contrast, increased gene expression for fatty acid and TAG synthesis is initiated later and occurs more gradually. Expression of several fatty acid desaturase (FAD) genes was decreased upon starvation, which corresponds to the observed changes to higher levels of mono-unsaturated and saturated fatty acids. Moreover, several homologs of transcription regulators that were implicated in controlling starch and lipid metabolism in other microalgae showed differential gene expression and might be key regulators of starch and lipid metabolism in N. oleoabundans as well. Promising candidates for future metabolic engineering are a DYRKP homolog that in Chlamydomonas acts as a negative regulator of carbon storage and photosynthetic efficiency under N-starvation, and two bZIP-type regulators that have been implicated to control several steps in microalgal TAG synthesis. Our data for the first time show the temporal dynamics of storage compound accumulation and transcriptional changes on a short- and long-term time-scale during nitrogen starvation in N. oleoabundans, and increases insight into the genetic foundation for starch and lipid metabolism in this microalga. This information and the identified target genes can now be used for metabolic engineering strategies towards tailored N. oleoabundans strains for industrial applications with increased lipid production and altered fatty acid composition.

Project description:Lysine lactylation (Kla) is a kind of novel post-translational modification (PTM), which participates in gene expression and various metabolic processes. Nannochloropsis, a significant oleaginous microalgae of economic significance, demonstrates a remarkable capacity for triacylglycerol (TAG) production under nitrogen stress. To elucidate the involvement of lactylation in lipid synthesis, we conducted ChIP-seq and mRNA-seq analyses to monitor lactylation modifications and transcriptome alterations in Nannochloropsis oceanica. In all, 2,057 genes showed considerable variation between nitrogen deprivation (ND) and nitrogen repletion (NR) conditions, comprising 853 upregulated genes and 1,204 downregulated genes. Moreover, a total of 5,375 differential Kla peaks were identified, including 5,331 gain peaks and 44 loss peaks under ND vs NR. The differential Kla peaks were primarily distributed in the promoter (<= 1 kb) (71.07%), 5’UTR (22.64%), and exon (4.25%). Integrative analysis of ChIP-seq, transcriptome, and previous proteome and lactylome data elucidates the potential mechanism by which lactylation promotes lipid accumulation under ND. Lactylation facilitates autophagy and protein degradation, leading to the recycling of carbon into the tricarboxylic acid (TCA) cycle, thereby providing carbon precursors for lipid synthesis. Additionally, lactylation induces the redirection of carbon from membrane lipids to TAG by upregulating lipases and enhancing the TCA cycle and β-oxidation pathways. This research reveals the regulatory functions of lactylation in lipid metabolism and gene expression in Nannochloropsis, offering a new perspective for the investigation of lipid biosynthesis.

Project description:Lysine lactylation (Kla) is a kind of novel post-translational modification (PTM), which participates in gene expression and various metabolic processes. Nannochloropsis, a significant oleaginous microalgae of economic significance, demonstrates a remarkable capacity for triacylglycerol (TAG) production under nitrogen stress. To elucidate the involvement of lactylation in lipid synthesis, we conducted ChIP-seq and mRNA-seq analyses to monitor lactylation modifications and transcriptome alterations in Nannochloropsis oceanica. In all, 2,057 genes showed considerable variation between nitrogen deprivation (ND) and nitrogen repletion (NR) conditions, comprising 853 upregulated genes and 1,204 downregulated genes. Moreover, a total of 5,375 differential Kla peaks were identified, including 5,331 gain peaks and 44 loss peaks under ND vs NR. The differential Kla peaks were primarily distributed in the promoter (<= 1 kb) (71.07%), 5’UTR (22.64%), and exon (4.25%). Integrative analysis of ChIP-seq, transcriptome, and previous proteome and lactylome data elucidates the potential mechanism by which lactylation promotes lipid accumulation under ND. Lactylation facilitates autophagy and protein degradation, leading to the recycling of carbon into the tricarboxylic acid (TCA) cycle, thereby providing carbon precursors for lipid synthesis. Additionally, lactylation induces the redirection of carbon from membrane lipids to TAG by upregulating lipases and enhancing the TCA cycle and β-oxidation pathways. This research reveals the regulatory functions of lactylation in lipid metabolism and gene expression in Nannochloropsis, offering a new perspective for the investigation of lipid biosynthesis.