Recurrent RNA motifs as scaffolds for genetically encodable small-molecule biosensors

Porter, Ely; Polaski, Jacob T.; Morck, Makenna M.; Batey, Robert T.

doi:10.1038/nchembio.2278

Cited by 109 publications

(138 citation statements)

References 59 publications

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“…The role of kinetic control mechanisms in creating biological activities that are both sensitive to, and selective for, specific molecular interactions has long been recognized 10 . Next-generation RNA aptamer biosensors have been successfully created through in vitro selection 40 , directed evolution 7 , activity-based screening 41,42 , two-state RNA folding design 8 , and thermodynamic optimization 43 . However, none of these state-of-the-art methods routinely generate RNA devices operating under kinetic control 7,8 , and an entirely different strategy was required to access that class of mechanisms.…”

Section: Discussionmentioning

confidence: 99%

“…4). Because the sensitivity of thermodynamically-controlled aptamer devices, including biosensors commonly engineered with the fluorogenic Spinach-family of aptamers, are fundamentally constrained by the equilibrium competition between the ON and OFF states 40,41,43 , they will always require concentrations significantly higher than the aptamer-ligand dissociation constant (K d ) for a response 13,36 . In this regard, it is very promising that the EC 50 s of the three kinetically-controlled p-AF ribosensors are both consistent with values predicted from the underlying design parameters ( Supplementary Fig.…”

Section: Discussionmentioning

confidence: 99%

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Multi-state design of kinetically-controlled RNA aptamer ribosensors

Burke

Sparkman-Yager

Carothers

2017

Preprint

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Metabolite-responsive RNA regulators with kinetically-controlled responses are widespread in nature. By comparison, very limited success has been achieved creating kinetic control mechanisms for synthetic RNA aptamer devices. Here, we show that kinetically-controlled RNA aptamer ribosensors can be engineered using a novel approach for multi-state, cotranscriptional folding design. The design approach was developed through investigation of 29 candidate p-aminophenylalanine-responsive ribosensors. We show that ribosensors can be transcribed in situ and used to analyze metabolic production directly from engineered microbial cultures, establishing a new class of cell-free biosensors. We found that kinetically-controlled ribosensors exhibited 5-10 fold greater ligand sensitivity than a thermodynamically-controlled device. And, we further demonstrated that a second aptamer, promiscuous for aromatic amino acid binding, could be assembled into kinetic ribosensors with 45-fold improvements in ligand selectivity. These results have broad implications for engineering RNA aptamer devices and overcoming thermodynamic constraints on molecular recognition through the design of kinetically-controlled responses.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Multi-state design of kinetically-controlled RNA aptamer ribosensors

Burke

Sparkman-Yager

Carothers

2017

Preprint

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“…Aptamers of natural riboswitches were utilized as scaffolds to select aptamers for new ligands. Nucleotides in the binding pockets of natural aptamers were randomized to produce potential aptamer libraries for in vitro selection (SELEX) [8 ] (Figure 1b). Selected aptamers for 5-hydroxytryptophan and 3,4-dihydroxyphenylalanine were successfully coupled to the readout domain, producing fluorescence upon binding of their cognate ligand in vitro and in vivo.…”

Section: Re-engineering Of Natural Riboswitchesmentioning

confidence: 99%

RNA-based dynamic genetic controllers: development strategies and applications

Jang

Yang

et al. 2018

Current Opinion in Biotechnology

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Dynamic regulation of gene expression in response to various molecules is crucial for both basic science and practical applications. RNA is considered an attractive material for creating dynamic genetic controllers because of its specific binding to ligands, structural flexibility, programmability, and small size. Here, we review recent advances in strategies for developing RNA-based dynamic controllers and applications. First, we describe studies that re-engineered natural riboswitches to generate new dynamic controllers. Next, we summarize RNA-based regulatory mechanisms that have been exploited to build novel artificial dynamic controllers. We also discuss computational methods and high-throughput selection approaches for de novo design of dynamic RNA controllers. Finally, we explain applications of dynamic RNA controllers for metabolic engineering and synthetic biology.

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“…The identification of riboswitch ligands has consistently revealed diverse roles for RNA molecules in cellular physiology and illustrated the capacity of RNA for precise chemical recognition (McCown, Corbino, Stav, Sherlock, & Breaker, 2017;Nelson & Breaker, 2017). In addition, riboswitches have found diverse utility as antibiotic targets (Howe et al, 2015), diagnostic biosensors (Kellenberger, Wilson, Sales-Lee, & Hammond, 2013;Porter, Polaski, Morck, & Batey, 2017), and as imaging tools (Braselmann et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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

Strobel¹,

Cheng²,

Berman³

et al. 2019

Preprint

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Cotranscriptional RNA folding forms structural intermediates that can be critically important for RNA biogenesis. This is especially true for transcriptional riboswitches that must undergo ligand-dependent structural changes during transcription to regulate the synthesis of downstream genes. Here, we systematically map the folding states traversed by the Clostridium beijerinckii pfl riboswitch as it controls transcription termination in response to the purine biosynthetic intermediate ZMP. We find that after rearrangement of a non-native hairpin to form the ZTP aptamer, cotranscriptional ZMP binding stabilizes two structural elements that lead to antitermination by tuning the efficiency of terminator hairpin nucleation and strand displacement. We also uncover biases within natural ZTP riboswitch sequences that could avoid misfolded intermediates that disrupt function. Our findings establish a mechanism for ZTP riboswitch control of transcription that has similarities to the mechanisms of diverse riboswitches and provide evidence of selective pressure at the level of cotranscriptional RNA folding pathways.superfolder GFP (SFGFP) coding sequence, listed as 'trailing sequence' below. Promoter sequences are blue. Mutation positions are highlighted with red. Deletion positions are shown as "-". Description Sequence Promoter GCTTGATTCTAAAGATCTTTGACAGCTAGCTCAGTCCTAGGTATAATACTAGT C. beijericnckii ZTP pfl riboswitch ATATTAGATATTAGTCATATGACTGACGGAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAAGCCGACCGTCTGGGCAAAAAAAGCCTGGATTGCGTCGGCTTTTTTAT Cbe ZTP riboswitch PK4 ATATTAGATATTAGTCATATGACTGACGGAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAAGCCGATCGCCTGGGCAAAAAAAGCCTGGGTTGCATCGGCTTTTTTAT Cbe ZTP riboswitch PK5 ATATTAGATATTAGTCATATGACTGGCGAAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAAGCCGATCGCCTGGGCAAAAAAAGCCTGGGTTGCATCGGCTTTTTTAT Cbe ZTP riboswitch PKAT ATATTAGATATTAGTCATATGACTGACGAAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAAGCCGATCGTCTGGGCAAAAAAAGCCTGGATTGCATCGGCTTTTTTAT Cbe ZTP riboswitch PKGC ATATTAGATATTAGTCATATGACTGGCGGAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAAGCCGACCGCCTGGGCAAAAAAAGCCTGGGTTGCGTCGGCTTTTTTAT Cbe ZTP riboswitch PKMM ATATTAGATATTAGTCATATGACTGACGAAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAAGCCGACCGCCTGGGCAAAAAAAGCCTGGGTTGCGTCGGCTTTTTTAT Cbe ZTP riboswitch T1 ATATTAGATATTAGTCATATGACTGACGGAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAAGCCGACCGTCTGGGCAAAAAAAGCCCGGATTGCGTCGGCTTTTTTAT Cbe ZTP riboswitch T2 ATATTAGATATTAGTCATATGACTGACGGAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAAGCCGACCGTCTGGGCAAAAAAAGCCTGGA-TG-GTCGGCTTTTTTAT Cbe ZTP riboswitch T3 ATATTAGATATTAGTCATATGACTGACGGAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAAGCCGACCGTCTGGGCAAAAAAAGCCTGGA-CG-GTCGGCTTTTTTAT Cbe ZTP riboswitch H1 ATATTAGATATTAGTCATATGACTGACGGAAGTGGAGTTACCACATGAAGTATGACTAGGCATATTATCTTATATG CCACAAAAATCGCCGACCGTCTGGGCGCAAAAAAAGCGCCTGGATTGCGTCGGCTTTTTTAT Cbe ZTP riboswitch H2 ATATTAGATATTAGTCATATGACTGACGGAAGTGGAGTTACCACATGAAGTATGACTAGGCAT...

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Recurrent RNA motifs as scaffolds for genetically encodable small-molecule biosensors

Cited by 109 publications

References 59 publications

Multi-state design of kinetically-controlled RNA aptamer ribosensors

Multi-state design of kinetically-controlled RNA aptamer ribosensors

RNA-based dynamic genetic controllers: development strategies and applications

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

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