Douglas F. Porter scite author profile

Noncoding RNA sequences, including long noncoding RNAs, small nucleolar RNAs, and untranslated mRNA regions, accomplish many of their diverse functions through direct interactions with RNA-binding proteins (RBPs). Recent efforts have identified hundreds of new RBPs that lack known RNA-binding domains, thus underscoring the complexity and diversity of RNA-protein complexes. Recent progress has expanded the number of methods for studying RNAprotein interactions in two general categories: approaches that characterize proteins bound to an RNA of interest (RNA-centric), and those that examine RNAs bound to a protein of interest (protein-centric). Each method has unique strengths and limitations, which makes it important to select optimal approaches for the biological question being addressed. Here we review methods for the study of RNA-protein interactions, with a focus on their suitability for specific applications. RNA and proteins are interconnected biomolecules that can promote each other's life cycles and functions through physical interactions 1. The coding sequence of mRNA carries the instructions for protein synthesis and some regulatory sequences, and the untranslated regions of mRNA influence the fate of the encoded protein by regulating its protein translation, localization, and interactions with other proteins 2. Proteins, in turn, can bind and modulate RNA expression and function from RNA synthesis to degradation 3. RNA-protein interactions are key to cellular homeostasis, and perturbations of RNA-RBP interactions can lead to cellular dysfunction and disease 4,5. Recent work has substantially expanded the number of putative RNA-protein associations in eukaryotes, underscoring the need for a versatile array of methods to identify and characterize their interactions 6,7. Methods for studying the physical interactions between RNA and protein can be classified by the type of molecule they start with. RNA-centric methods start with an RNA of interest

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The PUF binding landscape in metazoan germ cells

Prasad

Porter

Kroll-Conner

et al. 2016

RNA

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PUF (Pumilio/FBF) proteins are RNA-binding proteins and conserved stem cell regulators. The Caenorhabditis elegans PUF proteins FBF-1 and FBF-2 (collectively FBF) regulate mRNAs in germ cells. Without FBF, adult germlines lose all stem cells. A major gap in our understanding of PUF proteins, including FBF, is a global view of their binding sites in their native context (i.e., their "binding landscape"). To understand the interactions underlying FBF function, we used iCLIP (individual-nucleotide resolution UV crosslinking and immunoprecipitation) to determine binding landscapes of C. elegans FBF-1 and FBF-2 in the germline tissue of intact animals. Multiple iCLIP peak-calling methods were compared to maximize identification of both established FBF binding sites and positive control target mRNAs in our iCLIP data. We discovered that FBF-1 and FBF-2 bind to RNAs through canonical as well as alternate motifs. We also analyzed crosslinking-induced mutations to map binding sites precisely and to identify key nucleotides that may be critical for FBF-RNA interactions. FBF-1 and FBF-2 can bind sites in the 5 ′ UTR, coding region, or 3 ′ UTR, but have a strong bias for the 3 ′ end of transcripts. FBF-1 and FBF-2 have strongly overlapping target profiles, including mRNAs and noncoding RNAs. From a statistically robust list of 1404 common FBF targets, 847 were previously unknown, 154 were related to cell cycle regulation, three were lincRNAs, and 335 were shared with the human PUF protein PUM2.

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Unbiased screen of RNA tailing activities reveals a poly(UG) polymerase

et al. 2019

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Ribonucleotidyl transferases (rNTases) add non-templated ribonucleotides to diverse RNAs. We developed TRAID-Seq, a screening strategy in S. cerevisiae to identify sequences added to a reporter RNA at single-nucleotide resolution by overexpressing candidate enzymes from different organisms. The rNTase activities of 22 previously unexplored enzymes were determined. In addition to poly(A)- and poly(U)-adding enzymes, we identified a C-adding enzyme that is likely part of a two-enzyme system that adds CCA to tRNAs in a eukaryote; a nucleotidyl transferase that adds nucleotides to RNA without apparent nucleotide preference; and a poly(UG) polymerase, C. elegans MUT-2, which adds alternating U and G nucleotides to form poly(UG) tails. MUT-2 is known to be required for certain forms of RNA silencing, and mutations in the enzyme that are defective in silencing fail to add poly(UG) tails in our assay. We propose that MUT-2 poly(UG) polymerase activity is required to promote genome integrity and RNA silencing.

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Douglas F. Porter

Methods to study RNA–protein interactions

The PUF binding landscape in metazoan germ cells

Unbiased screen of RNA tailing activities reveals a poly(UG) polymerase

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