CovidShiny: An Integrated Web Tool for SARS-CoV-2 Mutation Profiling and Molecular Diagnosis Assay Evaluation In Silico.

The coronavirus disease 2019 (COVID-19) pandemic is still ongoing, with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) continuing to evolve and accumulate mutations. While various bioinformatics tools have been developed for SARS-CoV-2, a well-curated mutation-tracking database integrated with in silico evaluation for molecular diagnostic assays is currently unavailable. To address this, we introduce CovidShiny, a web tool that integrates mutation profiling, in silico evaluation, and data download capabilities for genomic sequence-based SARS-CoV-2 assays and data download.

Degradation strategies of pesticide residue: From chemicals to synthetic biology.

The past 50 years have witnessed a massive expansion in the demand and application of pesticides. However, pesticides are difficult to be completely degraded without intervention hence the pesticide residue could pose a persistent threat to non-target organisms in many aspects. To aim at the problem of the abuse of pesticide products and excessive pesticide residues in the environment, chemical and biological degradation methods are widely developed but are scaled and insufficient to solve such a pollution.

One-Pot Bioconversion of Lignin-Derived Substrates into Gallic Acid.

Lignin is regarded as the most abundant renewable aromatic compound on earth. In this study, we established -based whole-cell biocatalytic systems to efficiently convert two lignin-derived substrates (ferulic acid and -coumaric acid) to gallic acid. For the synthesis of gallic acid from ferulic acid, we used the recombinant expressing feruloyl-CoA synthetase and enoyl-CoA hydratase/aldolase from , aldehyde dehydrogenase (HFD1) from , vanillic acid -demethylase (VanAB) from and a mutant version of -hydroxybenzoate hydroxylase (PobA) from .

Engineering an Optogenetic CRISPRi Platform for Improved Chemical Production.

Microbial synthesis of chemicals typically requires the redistribution of metabolic flux toward the synthesis of targeted products. Dynamic control is emerging as an effective approach for solving the hurdles mentioned above. As light could control the cell behavior in a spatial and temporal manner, the optogenetic-CRISPR interference (opto-CRISPRi) technique that allocates the metabolic resources according to different optical signal frequencies will enable bacteria to be controlled between the growth phase and the production stage.