Your search keyword '"McSweeney MA"' showing total 5 results

1. A modular cell-free protein biosensor platform using split T7 RNA polymerase.

Author

McSweeney MA, Patterson AT, Loeffler K, Cuellar Lelo de Larrea R, McNerney MP, Kane RS, and Styczynski MP

Subjects

Humans, Biomarkers, Saliva metabolism, DNA-Directed RNA Polymerases metabolism, Biosensing Techniques methods, Viral Proteins metabolism, Cell-Free System

Abstract

Conventional laboratory protein detection techniques are not suitable for point-of-care (POC) use because they require expensive equipment and laborious protocols, and existing POC assays suffer from long development timescales. Here, we describe a modular cell-free biosensing platform for generalizable protein detection that we call TLISA (T7 RNA polymerase-linked immunosensing assay), designed for extreme flexibility and equipment-free use. TLISA uses a split T7 RNA polymerase fused to affinity domains against a protein. The target antigen drives polymerase reassembly, inducing reporter expression. We characterize the platform and then demonstrate its modularity by using 16 affinity domains against four different antigens with minimal protocol optimization. We show that TLISA is suitable for POC use by sensing human biomarkers in serum and saliva with a colorimetric readout within 1 hour and by demonstrating functionality after lyophilization. Altogether, this technology has the potential to enable truly rapid, reconfigurable, modular, and equipment-free detection of diverse classes of proteins.

Published

2025

2. A modular cell-free protein biosensor platform using split T7 RNA polymerase.

Author

McSweeney MA, Patterson AT, Loeffler K, de Larrea RCL, McNerney MP, Kane RS, and Styczynski MP

Abstract

Conventional laboratory protein detection techniques are not suitable for point-of-care (POC) use because they require expensive equipment and laborious protocols, and existing POC assays suffer from long development timescales. Here, we describe a modular cell-free biosensing platform for generalizable protein detection that we call TLISA ( T 7 RNA polymerase- L inked I mmuno S ensing A ssay), designed for extreme flexibility and equipment-free use. TLISA uses a split T7 RNA polymerase fused to affinity domains against a protein. The target antigen drives polymerase reassembly, inducing reporter expression. We characterize the platform, then demonstrate its modularity by using 16 affinity domains against four different antigens with minimal protocol optimization. We show TLISA is suitable for POC use by sensing human biomarkers in serum and saliva with a colorimetric readout within one hour and by demonstrating functionality after lyophilization. Altogether, this technology could have potentially revolutionary impacts, enabling truly rapid, reconfigurable, equipment-free detection of virtually any protein., Competing Interests: Competing interests: MPS, MAM, and MPM have filed a patent with the USPTO that is related to this work (Application no. 63/622,682, filed on 19 January 2024). The authors declare no other competing interests.

Published

2024

3. Short Activators and Repressors of RNA Toehold Switches.

Author

McSweeney MA, Zhang Y, and Styczynski MP

Subjects

Nucleosides chemistry, Nucleosides genetics, Nucleosides metabolism, Transcription Factors chemistry, Transcription Factors genetics, RNA genetics, MicroRNAs chemistry, MicroRNAs genetics, MicroRNAs metabolism

Abstract

RNA toehold switches are a widely used class of molecule to detect specific RNA "trigger" sequences, but their design, intended function, and characterization to date leave it unclear whether they can function properly with triggers shorter than 36 nucleotides. Here, we explore the feasibility of using standard toehold switches with 23-nucleotide truncated triggers. We assess the crosstalk of different triggers with significant homology and identify a highly sensitive trigger region where just one mutation from the consensus trigger sequence can reduce switch activation by 98.6%. However, we also find that triggers with as many as seven mutations outside of this region can still lead to 5-fold induction of the switch. We also present a new approach using 18- to 22-nucleotide triggers as translational repressors for toehold switches and assess the off-target regulation for this strategy as well. The development and characterization of these strategies could help enable applications like microRNA sensors, where well-characterized crosstalk between sensors and detection of short target sequences are critical.

Published

2023

4. Corrigendum: Effective use of linear DNA in cell-free expression systems.

Author

McSweeney MA and Styczynski MP

Abstract

[This corrects the article DOI: 10.3389/fbioe.2021.715328.]., (Copyright © 2022 McSweeney and Styczynski.)

Published

2022

5. Effective Use of Linear DNA in Cell-Free Expression Systems.

Author

McSweeney MA and Styczynski MP

Abstract

Cell-free expression systems (CFEs) are cutting-edge research tools used in the investigation of biological phenomena and the engineering of novel biotechnologies. While CFEs have many benefits over in vivo protein synthesis, one particularly significant advantage is that CFEs allow for gene expression from both plasmid DNA and linear expression templates (LETs). This is an important and impactful advantage because functional LETs can be efficiently synthesized in vitro in a few hours without transformation and cloning, thus expediting genetic circuit prototyping and allowing expression of toxic genes that would be difficult to clone through standard approaches. However, native nucleases present in the crude bacterial lysate (the basis for the most affordable form of CFEs) quickly degrade LETs and limit expression yield. Motivated by the significant benefits of using LETs in lieu of plasmid templates, numerous methods to enhance their stability in lysate-based CFEs have been developed. This review describes approaches to LET stabilization used in CFEs, summarizes the advancements that have come from using LETs with these methods, and identifies future applications and development goals that are likely to be impactful to the field. Collectively, continued improvement of LET-based expression and other linear DNA tools in CFEs will help drive scientific discovery and enable a wide range of applications, from diagnostics to synthetic biology research tools., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 McSweeney and Styczynski.)

Published

2021