Graph, pseudoknot, and SARS-CoV-2 genomic RNA: A biophysical synthesis

“…In our prior work 22 (see also commentary 39 ), we defined target residues for drug binding and gene editing of the FSE from designed minimal mutants that dramatically transform the FSE conformation. Our RAG (RNA-As-Graphs) machinery represents RNA 2D structure as coarse-grained dual graphs, where double-stranded RNA helices are represented as vertices, and loop strands are edges.…”

“…However, depending on the modeling software and experimental technique, alternative secondary structures have been offered for SARS-CoV-2, both pseudoknotted and unknotted (see below). 20,23−25,28−34 In our prior work 22 (see also commentary 39 ), we defined target residues for drug binding and gene editing of the FSE from designed minimal mutants that dramatically transform the FSE conformation. Our RAG (RNA-As-Graphs) machinery represents RNA 2D structure as coarse-grained dual graphs, where double-stranded RNA helices are represented as vertices, and loop strands are edges.…”

To Knot or Not to Knot: Multiple Conformations of the SARS-CoV-2 Frameshifting RNA Element

“…In our prior work 22 (see also commentary 39 ), we defined target residues for drug binding and gene editing of the FSE from designed minimal mutants that dramatically transform the FSE conformation. Our RAG (RNA-As-Graphs) machinery represents RNA 2D structure as coarse-grained dual graphs, where double-stranded RNA helices are represented as vertices, and loop strands are edges.…”

“…However, depending on the modeling software and experimental technique, alternative secondary structures have been offered for SARS-CoV-2, both pseudoknotted and unknotted (see below). 20,23−25,28−34 In our prior work 22 (see also commentary 39 ), we defined target residues for drug binding and gene editing of the FSE from designed minimal mutants that dramatically transform the FSE conformation. Our RAG (RNA-As-Graphs) machinery represents RNA 2D structure as coarse-grained dual graphs, where double-stranded RNA helices are represented as vertices, and loop strands are edges.…”

To Knot or Not to Knot: Multiple Conformations of the SARS-CoV-2 Frameshifting RNA Element

“…However, depending on the modeling software and experimental technique, alternative secondary structures have been offered for SARS-CoV-2, both pseudoknotted and unknotted (see below). 20,[23][24][25][28][29][30][31][32][33][34] In our prior work 22 (see also commentary 39 ), we defined target residues for drug binding and gene editing of the FSE from designed minimal mutants that dramatically transform the FSE conformation. Our RAG (RNA-As-Graphs) machinery represents RNA 2D structure as coarse-grained dual graphs, where doublestranded RNA helices are represented as vertices, and loop strands are edges.…”

“…In our prior work 20 (see also commentary 25 ), we defined target residues for drug binding and gene editing of the FSE from designed minimal mutants that dramatically transform the conformation of the FSE. Our RAG (RNA-As-Graphs) machinery represents RNA 2D structure as coarse-grained dual graphs, where doublestranded RNA helices are represented as vertices, and loop strands are edges.…”

To knot or not to knot: Multiple conformations of the SARS-CoV-2 frameshifting RNA element

“…Developing further and applying the RNA-As-Graphs (RAG) graph-theory tools for handling pseudoknots [90] , [91] , [92] , [93] , [94] to the SARS-CoV-2 FSE, the Schlick group has designed double mutants, shown in Fig. 5 B, that dramatically alter the FSE conformation (see [84] and accompanying New & Notable commentary [95] ). These mutations define target residues for drug binding and gene editing.…”

Biomotors, viral assembly, and RNA nanobiotechnology: Current achievements and future directions