We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Site-directed Conjugation of Single-Stranded DNA to Affinity Proteins: Quantifying the Importance of Conjugation Strategy
Summary
This study developed a new site-selective method for conjugating single-stranded DNA to affinity proteins for diagnostic and therapeutic applications. This is a biotechnology paper with no direct relevance to microplastics or environmental health.
Affinity protein–oligonucleotide conjugates are increasingly being explored as diagnostic and therapeutic tools. Despite growing interest, these probes are typically constructed using outdated, non-selective chemistries, and little has been done to investigate how conjugation to oligonucleotides influences the function of affinity proteins. Herein, we report a novel site-selective conjugation method for furnishing affinity protein–oligonucleotide conjugates in a 93% yield within fifteen minutes. Using SPR, we explore how the choice of affinity protein, conjugation strategy, and DNA length impact target binding and reveal the deleterious effects of non-specific conjugation methods. Furthermore, we show that these adverse effects can be minimised by employing our site-selective conjugation strategy, leading to improved performance in an immuno-PCR assay. Finally, we investigate the interactions between affinity protein–oligonucleotide conjugates and live cells, demonstrating the benefits of site-selective conjugation. This work provides critical insight into the importance of conjugation strategy when constructing affinity protein–oligonucleotide conjugates.
Sign in to start a discussion.
More Papers Like This
Site-directed Conjugation of Single-Stranded DNA to Affinity Proteins: Quantifying the Importance of Conjugation Strategy
This study developed a new site-selective method for conjugating single-stranded DNA to affinity proteins for diagnostic and therapeutic applications. This is a biotechnology paper with no direct relevance to microplastics or environmental health.
Adsorption of Linear and Spherical DNA Oligonucleotides onto Microplastics
Researchers investigated DNA adsorption onto common microplastics and found that DNA oligonucleotides bind to polyethylene, polypropylene, polystyrene, and PVC surfaces, suggesting microplastics could serve as carriers for environmental DNA in aquatic ecosystems.
Selection of Plastic‐Binding DNA Aptamers for Microplastics Detection
Researchers isolated DNA aptamers that selectively bind to PVC and polystyrene plastics, detecting microplastic particles as small as 1 milligram using fluorescent labeling. The aptamers showed strong selectivity for plastics over other environmental materials like silica, and molecular simulations revealed how they maximize surface contact with plastic for adsorption. This aptamer-based approach could offer a new, targeted tool for environmental microplastic monitoring.
eDNA Adsorption onto Microplastics: Impacts of Water Chemistry and Polymer Physiochemical Properties
Researchers studied how environmental DNA, genetic material shed by organisms, attaches to different types of microplastics under varying water conditions. They found that DNA adsorption depends on the type of plastic polymer, water chemistry factors like pH and salt concentration, and the presence of natural organic matter. The findings suggest that microplastics could serve as carriers of genetic material in the environment, with implications for tracking both pollution sources and the spread of antibiotic resistance genes.
DNA Nano‐Biomaterials Based Futuristic Technologies for Tissue Engineering and Regenerative Therapeutics
This review covers advances in DNA-based nanomaterials for tissue engineering and regenerative medicine, including drug delivery and wound healing. While not directly about microplastics, DNA nanotechnology could potentially be applied to detect or remediate nanoplastic contamination in biological tissues. The research represents a broader trend in nanoscale biomaterials that may intersect with microplastics research in the future.