Highly Parallelized Screening of Functionally Enhanced XNA Aptamers in Uniform Hydrogel Particles

A colorimetric biosensor composed of split aptamers and mannan oligosaccharide nanozyme to monitor synthetic His-tagged food biomolecules

Food synthetic biology is garnering increasing attention for its potential to generate bioactive components. His-tag is one of the most popular tags used in food synthetic biology. Herein, His-tag, His-tagged proteins, and His-tagged peptides were adopted as the model targets, and a commonly used biosensor was developed to monitor His-tagged food biomolecules, using split aptamers as specific recognition probes and nanozyme as the transduction element. A strategy to generate high-affinity split aptamers was proposed, obtaining a pair of split aptamers for His-tag (Kd = 132 nM). AuNPs-mannan oligosaccharide nanozyme was fabricated and combined with the split aptamers to develop the biosensor. The functional mechanism of the probes and the nanozyme was revealed. The biosensor demonstrated good sensitivity, selectivity, and practicability when analyzing synthetic His-tagged proteins and peptides in real-world samples, with a limit of detection of 12.44 nM. The strategies provide robust reference for developing analytical methods for synthetic biomolecules.

Sequence-defined phosphoestamers for selective inhibition of the KRASG12D/RAF1 interaction

RAS proteins are the most frequently mutated in cancer, yet they have proved extremely difficult to target in drug discovery, largely because interfering with the interaction of RAS with its downstream effectors comes up against the challenge of protein-protein interactions (PPIs). Sequence-defined synthetic oligomers could combine the precision and customisability of synthetic molecules with the size required to address entire PPI surfaces. We have adapted the phosphoramidite chemistry of oligonucleotide synthesis to produce a library of nearly one million non-nucleosidic oligophosphoester sequences (phosphoestamers) composed of units taken from synthetic supramolecular chemistry, and used a fluorescent-activated bead sorting (FABS) process to select those that inhibit the interaction between KRASG12D (the most prevalent, and undrugged, RAS mutant) and RAF, a downstream effector of RAS that drives cell proliferation. Hits were identified using tandem mass spectrometry, and orthogonal validation showed effective inhibition of KRASG12D with IC50 values as low as 25 nM, and excellent selectivity over the wild type form. These findings have the potential to lead to new drugs that target mutant RAS-driven cancers, and provide proof-of-principle for the phosphoestamer chemical platform against PPIs in general - opening up new possibilities in neurodegenerative disease, viral infection, and many more conditions.

Versatility of threose nucleic acids: synthesis, properties, and applications in chemical biology and biomedical advancements

This feature article delves into the realm of α-L-threose nucleic acid (TNA), an artificial nucleic acid analog characterized by a backbone comprising an unconventional four-carbon sugar, α-L-threose, with phosphodiester linkages connecting at the 2' and 3' vicinal positions of the sugar ring. Within this article, we encapsulate the potential, progress, current state of the art, and persisting challenges within TNA research. Kicking off with a historical overview of xeno nucleic acids (XNAs), the discussion transitions to the compelling attributes and structure-property relationships of TNAs as advanced tools when contrasted with natural nucleic acids. Noteworthy aspects such as their advantageous spatial arrangements of functional groups around the sugar ring, stable Watson-Crick base pairing, high binding affinity, biostability, biocompatibility, and in vivo bio-safety are highlighted. Moreover, the narrative unfolds the latest advancements in chemical and biological methodologies for TNA synthesis, spanning from monomer and oligomer synthesis to polymerization, alongside cutting-edge developments in enzyme engineering aimed at bolstering large-scale TNA synthesis for in vitro selection initiatives. The article sheds light on the evolution of TNA aptamers over time, expounding on the tools and selection techniques engineered to unearth superior binding aptamers and TNA catalysts. Furthermore, the article accentuates the recent applications of TNAs across diverse domains such as molecular detection, immunotherapy, gene therapy, synthetic biology, and molecular computing. In conclusion, we summarize the key aspects of recent TNA research, address persisting gaps and challenges, and provide crucial insights and future perspectives in the dynamic domain of TNA research.

Aptamer Screening: Current Methods and Future Trend towards Non-SELEX Approach

Aptamers are nucleic acid sequences that specifically bind with target molecules and are vital to applications such as biosensing, drug development, disease diagnostics, etc. The traditional selection procedure of aptamers is based on the Systematic Evolution of Ligands by an Exponential Enrichment (SELEX) process, which relies on repeating cycles of screening and amplification. With the rapid development of aptamer applications, RNA and XNA aptamers draw more attention than before. But their selection is troublesome due to the necessary reverse transcription and transcription process (RNA) or low efficiency and accuracy of enzymes for amplification (XNA). In light of this, we review the recent advances in aptamer selection methods and give an outlook on future development in a non-SELEX approach, which simplifies the procedure and reduces the experimental costs. We first provide an overview of the traditional SELEX methods mostly designed for screening DNA aptamers to introduce the common tools and methods. Then a section on the current screening methods for RNA and XNA is prepared to demonstrate the efforts put into screening these aptamers and the current difficulties. We further predict that the future trend of aptamer selection lies in non-SELEX methods that do not require nucleic acid amplification. We divide non-SELEX methods into an immobilized format and non-immobilized format and discuss how high-resolution partitioning methods could facilitate the further improvement of selection efficiency and accuracy.

Biopolymer based nanoparticles and their therapeutic potential in wound healing - A review

Nanoparticles (NPs) have been extensively investigated for their potential in nanomedicine. There is a significant level of enthusiasm about the potential of NPs to bring out a transformative impact on modern healthcare. NPs can serve as effective wound dressings or delivery vehicles due to their antibacterial and pro-wound-healing properties. Biopolymer-based NPs can be manufactured using various food-grade biopolymers, such as proteins, polysaccharides, and synthetic polymers, each offering distinct properties suitable for different applications which include collagen, polycaprolactone, chitosan, alginate, and polylactic acid, etc. Their biodegradable and biocompatible nature renders them ideal nanomaterials for applications in wound healing. Additionally, the nanofibers containing biopolymer-based NPs have shown excellent anti-bacterial and wound healing activity like silver NPs. These NPs represent a paradigm shift in wound healing therapies, offering targeted and personalized solutions for enhanced tissue regeneration and accelerated wound closure. The current review focuses on biopolymer NPs with their applications in wound healing.

Threose nucleic acid as a primitive genetic polymer and a contemporary molecular tool

Nucleic acids serve a dual role as both genetic materials in living organisms and versatile molecular tools for various applications. Threose nuclei acid (TNA) stands out as a synthetic genetic polymer, holding potential as a primitive genetic material and as a contemporary molecular tool. In this review, we aim to provide an extensive overview of TNA research progress in these two key aspects. We begin with a retrospect of the initial discovery of TNA, followed by an in-depth look at the structural features of TNA duplex and experimental assessment of TNA as a possible RNA progenitor during early evolution of life on Earth. In the subsequent section, we delve into the recent development of TNA molecular tools such as aptamers, catalysts and antisense oligonucleotides. We emphasize the practical application of functional TNA molecules in the realms of targeted protein degradation and selective gene silencing. Our review culminates with a discussion of future research directions and the technical challenges that remain to be addressed in the field of TNA research.

Interrogating Aptamer Chemical Space Through Modified Nucleotide Substitution Facilitated by Enzymatic DNA Synthesis

Chemical modification of aptamers is an important step to improve their performance and stability in biological media. This can be performed either during their identification (mod-SELEX) or after the in vitro selection process (post-SELEX). In order to reduce the complexity and workload of the post-SELEX modification of aptamers, we have evaluated the possibility of improving a previously reported, chemically modified aptamer by combining enzymatic synthesis and nucleotides bearing bioisosteres of the parent cubane side-chains or substituted cubane moieties. This method lowers the synthetic burden often associated with post-SELEX approaches and allowed to identify one additional sequence that maintains binding to the PvLDH target protein, albeit with reduced specificity. In addition, while bioisosteres often improve the potency of small molecule drugs, this does not extend to chemically modified aptamers. Overall, this versatile method can be applied for the post-SELEX modification of other aptamers and functional nucleic acids.

Functionally Enhanced XNA Aptamers Discovered by Parallelized Library Screening

In vitro evolution strategies have been used for >30 years to generate nucleic acid aptamers against therapeutic targets of interest, including disease-associated proteins. However, this process requires many iterative cycles of selection and amplification, which severely restricts the number of target and library design combinations that can be explored in parallel. Here, we describe a single-round screening approach to aptamer discovery that relies on function-enhancing chemotypes to increase the distribution of high-affinity sequences in a random-sequence library. We demonstrate the success of de novo discovery by affinity selection of threomers against the receptor binding domain of the S1 protein from SARS-CoV-2. Detailed biochemical characterization of the enriched population identified threomers with binding affinity values that are comparable to aptamers produced by conventional SELEX. This work establishes a highly parallelizable path for querying diverse chemical repertoires and may offer a viable route for accelerating the discovery of therapeutic aptamers.