Crystal Structures of the Mango-II RNA Aptamer Reveal Heterogeneous Fluorophore Binding and Guide Engineering of Variants with Improved Selectivity and Brightness

Trachman, Robert J.; Abdolahzadeh, Amir; Andreoni, Alessio; Cojocaru, Razvan; Knutson, Jay R.; Ryckelynck, Michaël; Unrau, Peter J.; Ferré-D′Amaré, A.R.

doi:10.1021/acs.biochem.8b00399

Cited by 55 publications

(64 citation statements)

References 12 publications

(29 reference statements)

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“…We chose the Mango II aptamer (Fig. 1a) because of its resistance to formaldehyde fixation, enhanced thermal stability and high affinity for TO1-Biotin (TO1-B) 28,29 . As Mango II requires a closing stem to efficiently fold, we engineered modified stem sequences by altering the Watson-Crick base pairs of three adjacent aptamers to avoid potential misfolding between the aptamer modules ( Fig.…”

Section: Resultsmentioning

confidence: 99%

Live cell imaging of single RNA molecules with fluorogenic Mango II arrays

2020

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RNA molecules play vital roles in many cellular processes. Visualising their dynamics in live cells at single-molecule resolution is essential to elucidate their role in RNA metabolism. RNA aptamers, such as Spinach and Mango, have recently emerged as a powerful background-free technology for live-cell RNA imaging due to their fluorogenic properties upon ligand binding. Here, we report a novel array of Mango II aptamers for RNA imaging in live and fixed cells with high contrast and single-molecule sensitivity. Direct comparison of Mango II and MS2-tdMCP-mCherry dual-labelled mRNAs show marked improvements in signal to noise ratio using the fluorogenic Mango aptamers. Using both coding (β-actin mRNA) and long non-coding (NEAT1) RNAs, we show that the Mango array does not affect cellular localisation. Additionally, we can track single mRNAs for extended time periods, likely due to bleached fluorophore replacement. This property makes the arrays readily compatible with structured illumination super-resolution microscopy.

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Section: Resultsmentioning

confidence: 99%

Live cell imaging of single RNA molecules with fluorogenic Mango II arrays

2020

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“…The open pocket also accommodates the TO3 headgroup, explaining the similar affinity of both fluorophores, 1.1 and 1.3 n M ). Biotin is not present in the ligand binding pocket, and while most of the PEG linker appeared to be excluded from the pocket, it was shown that its interactions with the RNA contribute to affinity and selectivity …”

Section: High Fluorophore Affinity Of Compact Mango Aptamersmentioning

confidence: 98%

From fluorescent proteins to fluorogenic RNAs: Tools for imaging cellular macromolecules

Truong

Ferré-D′Amaré

2019

Protein Science

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The explosion in genome-wide sequencing has revealed that noncoding RNAs are ubiquitous and highly conserved in biology. New molecular tools are needed for their study in live cells. Fluorescent RNA-small molecule complexes have emerged as powerful counterparts to fluorescent proteins, which are well established, universal tools in the study of proteins in cell biology. No naturally fluorescent RNAs are known; all current fluorescent RNA tags are in vitro evolved or engineered molecules that bind a conditionally fluorescent small molecule and turn on its fluorescence by up to 5000-fold. Structural analyses of several such fluorescence turn-on aptamers show that these compact (30-100 nucleotides) RNAs have diverse molecular architectures that can restrain their photoexcited fluorophores in their maximally fluorescent states, typically by stacking between planar nucleotide arrangements, such as G-quadruplexes, base triples, or base pairs. The diversity of fluorogenic RNAs as well as fluorophores that are cell permeable and bind weakly to endogenous cellular macromolecules has already produced RNA-fluorophore complexes that span the visual spectrum and are useful for tagging and visualizing RNAs in cells. Because the ligand binding sites of fluorogenic RNAs are not constrained by the need to autocatalytically generate fluorophores as are fluorescent proteins, they may offer more flexibility in molecular engineering to generate photophysical properties that are tailored to experimental needs.

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“…47,57,58 The structures of Mango variants from generations I-IV are known, and have recently been discussed in detail. 3,[58][59][60][61] The core of all Mango aptamers contains a G-quadruplex, primarily responsible for stacking and rigidification of the bound ligand. While the first generation included the PEG linker and the biotin in packing onto the G-quartet next to TO1, 61 later generations exhibited improved fluorophore planarity resulting in higher brightness.…”

Section: To-binding Aptamers -Mangomentioning

confidence: 99%