A mechanism for ligand gated strand displacement in ZTP riboswitch transcription regulation

Strobel, Eric J.; Cheng, Luyi; Berman, Katherine E.; Carlson, Paul D.; Lucks, Julius B.

doi:10.1101/521930

Cited by 2 publications

(3 citation statements)

References 62 publications

(125 reference statements)

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“…SSIV RT reactions produced similar levels of full length product with library 1 and library 3A (Figure 2B) resulting in similar yield and processivity values between the two templates indicating less template related bias as compared to ImProm-II reactions. Although increasing the SSIV reaction temperature from 55°C to 65°C reduced template bias, the higher temperatures also negatively impacted the yield and processivity, consistent with previous reports of activity loss at higher temperatures (Strobel et al, 2019). Even under optimized conditions, SSIV reactions produced no significant improvement in yield or processivity compared to reactions using ImProm-II.…”

Section: Assessing Reverse Transcriptase Bias Processivity and Yield ...supporting

confidence: 84%

“…ImProm-II originates from Avian Myeloblastosis Virus (AMV) RT and has been used frequently in successful aptamer and ribozyme selections by our group (Alam et al, 2018;Gruenke et al, 2020Gruenke et al, , 2022 and others (Dua et al, 2018;Kang et al, 2009;Rahimi & Bitan, 2010). SSIV (and its predecessor SSIII) originated from Moloney murine leukemia virus (M-MLV) and is also commonly used in aptamer and ribozyme selections (Akoopie et al, 2021;Moretti & Müller, 2014;Ning et al, 2019;Pressman et al, 2019;Saha et al, 2018;Strobel et al, 2019). TGIRT-III, originating from a mobile type II intron, is reported to have higher processivity, fidelity, and thermostability than some retroviral RTs (Mohr et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Minimizing amplification bias during reverse transcription for in vitro selections

Lucas

Gruenke

Burke

2023

RNA

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Systematic Evolution of Ligands through EXponential enrichment (SELEX) is widely used to identify functional nucleic acids, such as aptamers and ribozymes. Ideally, selective pressure drives enrichment of sequences that display the function of interest (binding, catalysis, etc). However, amplification biases from reverse transcription can overwhelm this enrichment and leave some functional sequences at a disadvantage, with cumulative effects across multiple rounds of selection. Libraries that are designed to include structural scaffolds can improve selection outcomes by sampling sequence space more strategically, but they are also susceptible to such amplification biases, particularly during reverse transcription. Therefore, we tested five reverse transcriptases (RTs) – ImProm-II, Marathon RT (MaRT), TGIRT-III, SuperScript IV (SSIV), and BST 3.0 DNA polymerase (BST) – to determine which enzymes introduced the least bias. We directly compared cDNA yield and processivity for these enzymes on RNA templates with varying degrees of structure under various reaction conditions. In these analyses, BST exhibited excellent processivity, generated large quantities of full length cDNA product, displayed little bias among templates with varying structure and sequence, and performed well on long, highly structured viral RNAs. Additionally, six RNA libraries containing either strong, moderate, or no incorporated structural elements were pooled and competed head-to-head in six rounds of an amplification-only selection without external selective pressure using either SSIV, ImProm-II, or BST during reverse transcription. High-throughput sequencing established that BST maintained the most neutral enrichment values, indicating low inter-library bias over the course of six rounds, relative to SSIV and ImProm-II, and it introduced minimal mutational bias.

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Section: Assessing Reverse Transcriptase Bias Processivity and Yield ...supporting

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Minimizing amplification bias during reverse transcription for in vitro selections

Lucas

Gruenke

Burke

2023

RNA

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“…We imagine that these strategies could even be used to reengineer riboswitches to have novel function (27)(28)(29). As the rules of riboswitch mechanisms are deciphered at deeper levels (11,(30)(31)(32), we hope to reach a sufficient understanding to design their functional properties to meet the global needs for field-deployable environmental and health diagnostics.…”

Section: Discussionmentioning

confidence: 99%

Point-of-Use Detection of Environmental Fluoride via a Cell-Free Riboswitch-Based Biosensor

Thavarajah

Silverman

Verosloff

et al. 2019

Preprint

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Advances in biosensor engineering have enabled the design of programmable molecular systems to detect a range of pathogens, nucleic acids, and chemicals. Here, we engineer and field-test a biosensor for fluoride, a major groundwater contaminant of global concern. The sensor consists of a cell-free system containing a DNA template that encodes a fluoride-responsive riboswitch regulating genes that produce a fluorescent or colorimetric output. Individual reactions can be lyophilized for long-term storage and detect fluoride at levels above 2 parts per million, the EPA's most stringent regulatory standard, in both laboratory and field conditions. Through onsite detection of fluoride in a real-world water source, this work provides a critical proof-of-principle for the future engineering of riboswitches and other biosensors to address challenges for global health and the environment.

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A mechanism for ligand gated strand displacement in ZTP riboswitch transcription regulation

Cited by 2 publications

References 62 publications

Minimizing amplification bias during reverse transcription for in vitro selections

Minimizing amplification bias during reverse transcription for in vitro selections

Point-of-Use Detection of Environmental Fluoride via a Cell-Free Riboswitch-Based Biosensor

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