Abstract
In RNA interference, a guide strand derived from a short dsRNA such as a microRNA (miRNA) is loaded into Argonaute, the central protein in the RNA Induced Silencing Complex (RISC) that silences messenger RNAs on a sequence-specific basis. The positions of any mismatched base pairs in an miRNA determine which Argonaute subtype is used. Subsequently, the Argonaute-guide complex binds and silences complementary target mRNAs; certain Argonautes cleave the target. Mismatches between guide strand and the target mRNA decrease cleavage efficiency. Thus, loading and silencing both require that signals about the presence of a mismatched base pair are communicated from the mismatch site to effector sites. These effector sites include the active site, to prevent target cleavage; the binding groove, to modify nucleic acid binding affinity; and surface allosteric sites, to control recruitment of additional proteins to form the RISC. To examine how such signals may be propagated, we analyzed the network of internal allosteric pathways in Argonaute exhibited through correlations of residue-residue interactions. The emerging network can be described as a set of pathways emanating from the core of the protein near the active site, distributed into the bulk of the protein, and converging upon a distributed cluster of surface residues. Nucleotides in the guide strand “seed region” have a stronger relationship with the protein than other nucleotides, concordant with their importance in sequence selectivity. Finally, any of several seed region guide-target mismatches cause certain Argonaute residues to have modified correlations with the rest of the protein. This arises from the aggregation of relatively small interaction correlation changes distributed across a large subset of residues. These residues are in effector sites: the active site, binding groove, and surface, implying that direct functional consequences of guide-target mismatches are mediated through the cumulative effects of a large number of internal allosteric pathways.
Highlights
RNA interference (RNAi) is a fundamental mechanism for regulating the expression of genes in a variety of contexts
Cells use the process of RNA interference (RNAi) to help orchestrate the production of the specific set of proteins needed at a given time
An messenger RNA (mRNA) is chosen for silencing based on its sequence, through binding to a complementary ‘‘guide strand’’ which is itself bound to an Argonaute protein
Summary
RNA interference (RNAi) is a fundamental mechanism for regulating the expression of genes in a variety of contexts It is a process by which a short dsRNA, such as a short interfering RNA (siRNA) or microRNA (miRNA), can induce sequence-specific silencing of genes at the mRNA stage, preventing their translation into proteins. The resulting complex forms the central component in the multimeric RNA Induced Silencing Complex (RISC), which hybridizes to complementary mRNAs and silences them [2] This is a sequence-specific process, guide and target need not be fully complementary, expanding the set of sequences that may be targeted by a single guide sequence [3]. The identity and position of any mismatched base pair variably affects the specific set of target genes and the extent to which they are silenced This allows a single guide strand to potentially inactivate multiple proteins involved in multiple pathways, yielding wide-ranging effects. Discrimination of targets is accomplished partly through decreased binding affinity of the mismatched target; the inhibition of catalysis from the bound state may play a significant role [4]
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