Project description:Non-targeted metabolomics analysis of cell and medium extract obtained by bacterial co-cultures.

Project description:Non-targeted microbial metabolomics (DDA) of extracts from methanotroph cocultures

Project description:Non-targeted metabolomics analysis of cell and medium extract obtained by bacterial co-cultures.

Project description:HoloFood Chicken Caecum+Ileum Metagenome – non-targeted metabolomics batch

Project description:Positive Mode. Non-targeted analysis of sourdough crude extract and isolated bacterial cultures.

Project description:Liquid-Liquid Extraction an d Non-targeted Metabolomics of Xenobiotic Biotransformations from gut microbiome strains

Project description:Non-targeted LC-MS/MS based Metabolomics of Plant Microbiome strain for natural product Screening

Project description:Metagenome sequencing enables discovery and genetic characterization of complex microbial communities from diverse ecosystems. However, determining the activity of isolates within a community using transcriptomics presents several challenges including the wide dynamic range of organismal and gene expression abundances, the presence of host RNA, and low microbial biomass at many body sites. To address these limitations, we developed “Targeted Expression Analysis Sequencing” or TEAL-seq. Targeting strategies enabled sensitive species-specific analyses of gene expression using highly multiplexed custom probe pools targeting about 1700 core and accessory genes of Staphylococcus aureus (S.a.) and S. epidermidis (S.e.), two key species of the skin microbiome. Two targeting methods were applied to mixed cultures and nasal swab specimens from human research participants. Both methods showed a high degree of specificity, with >90% reads on target, even in the presence of complex microbial or human background DNA/RNA. Targeting using molecular inversion probes demonstrated excellent correlation in inferred expression levels with bulk RNA-seq. Further, we show that a linear pre-amplification step to increase the amount of input nucleic acids for analysis was quite reproducible . While pre-amplification introduced some noise compared to non-amplified samples, it also enabled profiling of expression from as little as 1 ng of total RNA. TEAL-seq is much less expensive than bulk metatranscriptomic profiling and enables detection across a greater dynamic range. Custom probe pools are readily configurable and this strategy is broadly applicable for determining the transcriptional status of organisms in any microbial community.

Project description:Non-targeted microbial metabolomics (DDA) of extracts from methanotroph cocultures

Project description:mRNA sequencing in bacteria is challenging due to the abundance of ribosomal rRNA that cannot be easily removed prior to sequencing. While commercially available kits target specific rRNA sequences found in defined lists of common bacterial species, they are frequently inefficient when applied to other divergent species, including those from environmental isolates. Similar to the commercial kits, other common techniques for rRNA depletion typically employ large probe sets that tile full-length rRNA sequences; however, such approaches are both time consuming and expensive when applied to multiple species or complex consortia of non-model microbes. To overcome these limitations, we present EMBR-seq+, which employs less than twenty target oligonucleotides per rRNA molecule, and builds upon our previous rRNA depletion approach, EMBR-seq, through the addition of an RNase H depletion step, to achieve rRNA removal efficiencies of up to 99%. First, we applied EMBR-seq+ to monocultures of Escherichia coli, Geobacter metallireducens, and Fibrobacter succinogenes strain UWB7 to deplete rRNA to approximately 1-7% of the sequencing reads, demonstrating that the new method can be easily extended to diverse bacterial species. Further, in more complex co-cultures between F. succinogenes strain UWB7 and anerobic fungal species, we applied EMBR-seq+ to deplete both bacterial and fungal rRNA, with an approximately 4-fold improved bacterial rRNA depletion efficiency compared to a previous report using a commercial kit, thereby showing that the method can be effectively translated to non-model microbial mixtures. Notably, we also demonstrate that for microbial species with poorly annotated genomes and unknown rRNA sequences, the RNase H depletion component of EMBR-seq+ enables rapid iterations in probe design without requiring to start experiments from total RNA each time, and was key for depleting fungal rRNA to enrich the bacterial mRNA readout in co-cultures. Finally, efficient depletion of rRNA enabled systematic quantification of the reprogramming of the bacterial transcriptome when cultured in the presence of the anerobic fungi, Anaeromyces robustus and Caecomyces churrovis. We observed that F. succinogenes strain UWB7 transcribes nearly 200 carbohydrate-active enzyme (CAZyme) genes in both monoculture and co-culture conditions, with several lignocellulose-degrading CAZymes downregulated in the presence of an anerobic gut fungus. This finding is consistent with the premise that bacteria and fungi specialize in different aspects of biomass breakdown, such that the presence of one regulates the CAZyme production of the other. This also supports previous findings that the fungi release excess reducing sugars in the supernatant, which benefits other members of the microbial community. Thus EMBR-seq+ provides a new and detailed perspective of a rumen microbiome model system by dramatically improving the efficiency of mRNA sequencing, and more generally also enables high-throughput, cost-effective and rapid quantification of the transcriptome to gain functional insights into less-studied and non-model microbial systems.