Direct and tunable modulation of protein levels in rice and wheat with a synthetic small molecule

A Rapid and Reversible Molecular "Switch" Regulating Protein Expression in Chlamydomonas reinhardtii

Chlamydomonas reinhardtii, a prominent chassis in synthetic biology, faces limitations in regulating the expression of exogenous genes. A destabilization domain (DD)/Shield-1 system, originally derived from mammals, offers a ligand-dependent control of stability, making it a valuable tool. This system utilises the destabilization domain to induce rapid degradation of target protein unless stabilised by Shield-1, a synthetic ligand. Upon the addition of Shield-1,the degradation is halted, leading to the accumulation and stabilisation of the target protein. This system has demonstrated successful regulation of foreign protein expression in mammals, parasites, and plants. In this study, the DD/Shield-1 system was harnessed to regulate the expression of the paromomycin resistance gene and luciferase encoding gene in Chlamydomonas, revealing its capability for rapid, stable, and reversible protein expression regulation in microalgae, serving as a molecular switch. Furthermore, this regulation exhibits reagent dependency, enhancing its applicability in practical production. A strain with induced expression of the gene-editing protein, LbCas12a, was successfully constructed and then tested for gene editing. The findings not only enrich the toolkit for Chlamydomonas molecular studies but offer a promising technique for regulating the expression and validating the functionality of exogenous proteins in microalgae.

Exploring plant protein functions through structure-based clustering

The upsurge in new plant protein sequences has far outpaced experimental functional characterization efforts. Prediction of protein function based on sequence homology often falls short when dealing with proteins that have low sequence similarity. Artificial intelligence (AI) programs, such as AlphaFold, have transformed computational protein structure prediction with remarkable accuracy. By leveraging the availability of predicted structures for nearly all protein sequences, clustering proteins based on their similarity in structural features has become a powerful tool for function annotation and discovery. Structure-based protein clustering enables the identification of distant evolutionary relationships and novel protein families, and offers an effective strategy for exploring plant protein functions, bridging the gap between sequence data and function annotation while also assisting in protein design.

Manipulation of targeted protein degradation in plant biology

Inducible protein degradation systems are an important but untapped resource for the study of protein function in plant cells. Unlike mutagenesis or transcriptional control, regulated degradation of proteins of interest allows the study of the biological mechanisms of highly dynamic cellular processes involving essential proteins. While systems for targeted protein degradation are available for research and therapeutics in animals, there are currently limited options in plant biology. Targeted protein degradation systems rely on target ubiquitination by E3 ubiquitin ligases. Systems that are available or being developed in plants can be distinguished primarily by the type of E3 ubiquitin ligase involved, including those that utilize Cullin-RING ligases, bacterial novel E3 ligases, and N-end rule pathway E3 ligases, or they can be controlled by proteolysis targeting chimeras. Target protein ubiquitination leads to degradation by the proteasome or targeting to the vacuole, with both pathways being ubiquitous and important for the endogenous control of protein abundance in plants. Targeted proteolysis approaches for plants will likely be an important tool for basic research and to yield novel traits for crop biotechnology.

Synthetic Biology Approaches to Posttranslational Regulation in Plants

To date synthetic biology approaches involving creation of functional genetic modules are used in a wide range of organisms. In plants, such approaches are used both for research in the field of functional genomics and to increase the yield of agricultural crops. Of particular interest are methods that allow controlling genetic apparatus of the plants at post-translational level, which allow reducing non-targeted effects from interference with the plant genome. This review discusses recent advances in the plant synthetic biology for regulation of the plant metabolism at posttranslational level and highlights their future directions.

Design and Combinatorial Development of Shield-1 Peptide Mimetics Binding to Destabilized FKBP12

On the basis of computational design, a focused one-bead one-compound library has been prepared on microparticle-encoded PEGA₁₉₀₀ beads consisting of small tripeptides with a triazole-capped N-terminal. The library was screened towards a double point-mutated version of the human FKBP12 protein, known as the destabilizing domain (DD). Inspired by the decoded library hits, unnatural peptide structures were screened in a novel on-bead assay, which was useful for a rapid structure evaluation prior to off-bead resynthesis. Subsequently, a series of 19 compounds were prepared and tested using a competitive fluorescence polarization assay, which led to the discovery of peptide ligands with low micromolar binding affinity towards the DD. The methodology represents a rapid approach for identification of a novel structure scaffold, where the screening and initial structure refinement was accomplished using small quantities of library building blocks.