Abstract
Graph representations have been widely used to analyze and design various economic, social, military, political, and biological networks. In systems biology, networks of cells and organs are useful for understanding disease and medical treatments and, in structural biology, structures of molecules can be described, including RNA structures. In our RNA-As-Graphs (RAG) framework, we represent RNA structures as tree graphs by translating unpaired regions into vertices and helices into edges. Here we explore the modularity of RNA structures by applying graph partitioning known in graph theory to divide an RNA graph into subgraphs. To our knowledge, this is the first application of graph partitioning to biology, and the results suggest a systematic approach for modular design in general. The graph partitioning algorithms utilize mathematical properties of the Laplacian eigenvector (µ2) corresponding to the second eigenvalues (λ2) associated with the topology matrix defining the graph: λ2 describes the overall topology, and the sum of µ2′s components is zero. The three types of algorithms, termed median, sign, and gap cuts, divide a graph by determining nodes of cut by median, zero, and largest gap of µ2′s components, respectively. We apply these algorithms to 45 graphs corresponding to all solved RNA structures up through 11 vertices (∼220 nucleotides). While we observe that the median cut divides a graph into two similar-sized subgraphs, the sign and gap cuts partition a graph into two topologically-distinct subgraphs. We find that the gap cut produces the best biologically-relevant partitioning for RNA because it divides RNAs at less stable connections while maintaining junctions intact. The iterative gap cuts suggest basic modules and assembly protocols to design large RNA structures. Our graph substructuring thus suggests a systematic approach to explore the modularity of biological networks. In our applications to RNA structures, subgraphs also suggest design strategies for novel RNA motifs.
Highlights
Ribonucleotide Acid (RNA) has become a prominent subject in modern biology, due to recent discoveries of RNA’s vital roles in regulating gene expression, which come in addition to well-known roles in protein synthesis [1,2,3]
We present results for the topological aspects described by the second Laplacian eigenvector, partitioning results for RNA graphs, and iterative partitioning results
Before describing results of our RNA partitioning, it is useful to understand the overall topologies of RNA graphs
Summary
Ribonucleotide Acid (RNA) has become a prominent subject in modern biology, due to recent discoveries of RNA’s vital roles in regulating gene expression, which come in addition to well-known roles in protein synthesis [1,2,3] Based on these new discoveries, new applications are being pursued in areas such as therapeutic biotechnology, by using RNA’s editing, silencing, and other regulatory capabilities to activate and deactivate genes, deliver drugs, and design new nanomaterials [4,5]. All of these functions of RNA are closely tied to the threedimensional structures that RNAs adopt To explore these new potential functions of RNA, it is essential to understand the principles of RNA’s architecture. Several 3D modules called motifs (e.g., coaxial helix, A-minor, ribose zipper, kissing hairpin, right-angles, twist-joint and double twist-joints motifs) have been identified by manual and computational inspection from experimentally resolved structures
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