Project description:To increase production of the important pharmaceutical compounds, both mutagenesis approaches and rational engineering have been extensively applied. Mutagenesis approaches are most popular in industry, but their effects have not yet been studied very well. Here, we used microarrays to compare the transcriptomes of the S. clavuligerus wild type (ATCC 27064) strain and the DS48802 clavulanic acid high-producer strain, which has been obtained by classical strain improvement (mutagenesis). Streptomyces clavuligerus strains were grown in shake flasks. RNA was extracted after 70h and hybridized to microarrays.

Project description:The redox-sensing MarR/DUF24-type repressor YodB controls expression of the azoreductase AzoR1 and the nitroreductase YodC that are involved in detoxification of quinones and diamide in Bacillus subtilis. In the present paper, we identified YodB and its paralog YvaP (CatR) as repressors of the yfiDE (catDE) operon encoding a catechol-2,3-dioxygenase that also contributes to quinone resistance. Inactivation of both paralogs, CatR and YodB, results in full derepression of catDE transcription. DNA-binding assays and promoter mutagenesis studies showed that CatR protects two inverted repeats with the consensus sequence TTAC-N5-GTAA overlapping the -35 promoter region (BS1) and the transcriptional start site (BS2). The BS1 operator was required for binding of YodB in vitro. CatR and YodB share the conserved N-terminal Cys residue that is essential for redox-sensing of CatR in vivo as shown by Cys-to-Ser mutagenesis. Our data suggest that CatR is modified by intermolecular disulfide formation in response to diamide and quinones in vitro and in vivo. Redox-regulation of CatR occurs independently of YodB and no protein interaction was detected between CatR and YodB in vivo using protein-crosslinking and mass spectrometry. Control of Bacillus subtilis 168 wild type (Ko_WT) vs. DyvaP mutant (Ko_DyvaP). The experiment was conducted in duplicates using two independent total RNA preparations. For all datasets used for final analysis, wild-type samples were labeled with Cy3 and DyvaP mutant samples were labeled with Cy5.

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>

Project description:The redox-sensing MarR/DUF24-type repressor YodB controls expression of the azoreductase AzoR1 and the nitroreductase YodC that are involved in detoxification of quinones and diamide in Bacillus subtilis. In the present paper, we identified YodB and its paralog YvaP (CatR) as repressors of the yfiDE (catDE) operon encoding a catechol-2,3-dioxygenase that also contributes to quinone resistance. Inactivation of both paralogs, CatR and YodB, results in full derepression of catDE transcription. DNA-binding assays and promoter mutagenesis studies showed that CatR protects two inverted repeats with the consensus sequence TTAC-N5-GTAA overlapping the -35 promoter region (BS1) and the transcriptional start site (BS2). The BS1 operator was required for binding of YodB in vitro. CatR and YodB share the conserved N-terminal Cys residue that is essential for redox-sensing of CatR in vivo as shown by Cys-to-Ser mutagenesis. Our data suggest that CatR is modified by intermolecular disulfide formation in response to diamide and quinones in vitro and in vivo. Redox-regulation of CatR occurs independently of YodB and no protein interaction was detected between CatR and YodB in vivo using protein-crosslinking and mass spectrometry.

Project description:Genome engineering offers the possibility to create completely novel cell factories with enhanced properties for biotechnological application. In recent years, the possibilities for genome engineering have been extensively explored in the Gram-positive bacterial cell factory Bacillus subtilis, where up to 42% of the genome, encoding dispensable functions has been removed. Such studies have shown that some strains with minimized genomes gained beneficial features, for instance in protein production. However, strains with the most minimal genomes also showed particular growth defects. This has focused our attention on strains with less extensive genome deletions that show close-to-wild-type growth properties, while retaining the acquired beneficial traits in secretory protein production of strains lacking larger genomic segments. A strain of the latter category is B. subtilis IIG-Bs27-47-24, here referred to as midiBacillus II, which lacks 30.95% of the parental genome. To date, it was unknown how the altered genomic configuration of midiBacillus II impacts on cell physiology at large, and protein secretion in particular. Therefore, the present study was aimed at bridging this knowledge gap through an in-depth proteomics analysis with special focus on protein secretion stress responses. Interestingly, the results show that the secretion stress response of midiBacillus II as elicited by high-level expression of a staphylococcal antigen is completely different from the secretion stress responses that occur in the parental strain 168. This implies that high-level protein secretion has different implications for wild-type and genome-engineered Bacillus strains, dictated by the altered genomic and proteomic configurations.

Project description:Interaction of microbes affects the growth, metabolism and differentiation of members of the community. While direct and indirect competitions, like spite and nutrient consumption have negative effect on each other, microbes also evolved in nature not only to fight, but in some cases to adapt or support each other while increasing the fitness of the community. Presence of bacteria and fungi in the soil results in interactions and various examples were described, including mutualism. Bacilli attach to the plant root and form complex communities in the rhizosphere. Bacillus subtilis, when grown in the presence of Aspergillus niger interacts with the fungal partner, attaches and grows on the hyphae. Using dual transcriptome experiment, we show that both fungi and bacteria alter their metabolisms during the interaction. Interestingly, the transcription of genes related to the antifungal and antibacterial defense mechanism of B. subtilis and A. niger, respectively, are decreased upon attachment of bacteria to the mycelia. Our microarray experiments provide a novel insight into the mutual interaction of a bacterium and a fungus. Aspergillus niger were grown with and without Bacillus subtilis. Biological triplicates were made for both conditions, Affymetrix microarray experiments were performed on these samples.

Project description:We aimed to explore the application of the Target-AID base editor in genomic in situ protein engineering by generating nonsynonymous mutations. A general transcription factor Spt15 (TATA-box binding protein) gene of Saccharomyces cerevisiae was selected as a target. Based on computational and experimental scanning mutagenesis of the Spt15 gene as well as flask-fermentation screening, three stress-tolerant Spt15 mutant strains (A140G, P169A and R238K) and two stress-sensitive Spt15 mutant strains (S118L and L214V) were obtained. To validate the regulatory mechanisms underlying these different Spt15 mutants, genome-wide transcriptome analysis by RNA sequencing was carried out to quantify global transcription changes in the Spt15 mutant strains compared to the wild type strain at the same culture conditions including the unstressed normal condition as well as hyperosmotic and thermal stress conditions. Results uncover the impacts of the Spt15 point mutations on global transcriptional regulation in response to hyperosmotic and thermal stresses, and provide insight into the applicability of the Target-AID base editor in genomic in situ protein engineering to alter yeast stress tolerance.

Project description:Engineering microbes with novel metabolic properties is a critical step for production of biofuels and biochemicals. Synthetic biology enables identification and engineering of metabolic pathways into microbes; however, knowledge of how to reroute cellular regulatory signals and metabolic flux remains lacking. Here we used network analysis of multi-omic data to dissect the mechanism of anaerobic xylose fermentation, a trait important for biochemical production from plant lignocellulose. We compared transcriptomic, proteomic, and phosphoproteomic differences across a series of strains evolved to ferment xylose under various conditions.

Project description:Engineering microbes with novel metabolic properties is a critical step for production of biofuels and biochemicals. Synthetic biology enables identification and engineering of metabolic pathways into microbes; however, knowledge of how to reroute cellular regulatory signals and metabolic flux remains lacking. Here we used network analysis of multi-omic data to dissect the mechanism of anaerobic xylose fermentation, a trait important for biochemical production from plant lignocellulose. We compared transcriptomic, proteomic, and phosphoproteomic differences across a series of strains evolved to ferment xylose under various conditions.

Project description:Interaction of microbes affects the growth, metabolism and differentiation of members of the community. While direct and indirect competitions, like spite and nutrient consumption have negative effect on each other, microbes also evolved in nature not only to fight, but in some cases to adapt or support each other while increasing the fitness of the community. Presence of bacteria and fungi in the soil results in interactions and various examples were described, including mutualism. Bacilli attach to the plant root and form complex communities in the rhizosphere. Bacillus subtilis, when grown in the presence of Aspergillus niger interacts with the fungal partner, attaches and grows on the hyphae. Using dual transcriptome experiment, we show that both fungi and bacteria alter their metabolisms during the interaction. Interestingly, the transcription of genes related to the antifungal and antibacterial defense mechanism of B. subtilis and A. niger, respectively, are decreased upon attachment of bacteria to the mycelia. Our microarray experiments provide a novel insight into the mutual interaction of a bacterium and a fungus.