The VMH integrates the metabolic reconstructions of human (Recon3D) and gut microbes (AGORA) representing a vast and unique knowledge base for metabolic pathways. Both resources have a shared nomenclature which allows exploring potential interactions between gut microbes and host metabolism. These reconstructions can also be used for metabolic modeling experiments. The VMH functions as a knowledge hub. It interlinks “Human metabolism”, “Gut microbiome”, “Disease”, “Nutrition”, and “ReconMaps”, allowing for cross-linked analysis. Emphasis has been placed on connecting VMH’s entities with external resources facilitating access to further metabolic, genetic, clinical, nutritional, and toxicological information. The VMH enables the visualization of simulation and experimental data in the context of the human metabolic network. Seven comprehensive Google-like maps of human metabolism are available in the “ReconMaps” resource.

Understanding anatomical structures and biological functions based on gene expression is critical in a systemic approach to address the complexity of the mammalian brain. Co-expressed genes are thought to regulate cell type- or region-specific brain functions. Thus, well-designed data acquisition and visualization systems for profiling combinatorial gene expression in relation to anatomical structures are crucial. The authors have mapped spatial expression densities of genome-wide transcripts to the 3D coordinates of mouse brains at four post-natal stages, and built a database, ViBrism DB. With the DB platform, users can access a total of 172 022 expression maps of transcripts in the whole context of 3D magnetic resonance (MR) images. Co-expression of transcripts is represented in the image space and in topological network graphs. In situ hybridization images and anatomical area maps are browsable in the same space of 3D expression maps using a new browser-based 2D/3D viewer.

Adenosine to inosine RNA editing (A-to-I editing) is among the most prevalent epitranscriptomic changes found in metazoa. It is commonly believed that inosine is interpreted as guanosine by cellular machineries, most importantly during translation. In this study, investigators systematically examined ribosomal decoding using an unbiased mass spectrometry approach. They demonstrated that, while inosine is indeed primarily interpreted as guanosine, it can also be decoded as adenosine, and rarely even as uracil. In addition, the authors show that inosine causes ribosome stalling, especially when multiple inosines are present in the codon. The study demonstrates previously unappreciated functions for inosines in mRNAs, expanding the coding potential of edited mRNAs and affecting translational efficiency.