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Eukaryotes use multiple RNA biogenesis regulatory pathways to maintain cellular biological processes. Among the known types of RNA, mRNA is very diverse and carries the coding capacity of proteins and their isoforms1.The PTGR pathway directs the fates of pre-mRNAs2,3. RBPs from different gene families control the regulation of RNA, and in PTGR, specific mRBPs guide mRNAs through direct physical interactions, forming functional mRNPs. Therefore, identifying and characterizing mRBPs and their mRNPs is critical to understanding the regulation of cellular mRNA metabolism2.Over the past three decades, various in vitro methods – including RNA electrophoretic mobility shift (REMSA) assays, systematic evolution of ligands by exponential enrichment assays (SELEX) based on library-derived constructs, RNA Bind-n-Seq (RBNS), radiolabeled or quantitative fluorescence RNA binding assays, X-ray crystallography, and NMR spectroscopy4,5,6,7,8,9 – have been widely applied to studies of RBPs, mainly from mammalian cells. The results of these studies of mammalian RBPs can be searched via the RNA-binding Protein DataBase (RBPDB), which collects the published observations10.
Although these in vitro approaches are powerful tools, they determine the bound RNA motifs from a given RNA pool of sequences and therefore are limited in their ability to discover new target RNAs. The same is true for computational strategies to predict genome-wide RBPs, which are based on the conservation of protein sequence and structure15. To overcome this, a new experimental method has been established that allows for the identification of the RNA motifs that an RBP of interest interacts with, as well as for the determination of the precise location of binding. This method, called "crosslinking and immunoprecipitation" (CLIP), is composed of in vivo UV crosslinking followed by immunoprecipitation11. Early studies have shown that photoactivation of DNA and RNA nucleotides can occur at excitation UV wavelengths greater than 245 nm. The reaction through thymidine seems to be favored (rank in order of decreased photoreactivity: dT ≥ dC > rU > rC, dA, dG)12. Using UV light with a wavelength of 254 nm (UV-C), it was observed that covalent bonds between RNA nucleotides and protein residues are created when in the range of only a few Angstroms (Å). The phenomenon is therefore called the "zero-length" crosslinking of RNA and RBP. This can be followed by a stringent purification procedure with little background13,14.
A strategy complementary to CLIP is to combine in vivo UV crosslinking with protein identification to describe the landscape of RBPs. A number of such genome-wide mRNA-bound proteomes have been isolated from yeast cells, embryonic stem cells (ESCs), and human cell lines (i.e., HEK293 and HeLa) using this novel experimental approach, called "mRNA interactome capture"18,19,20,21. The method is composed of in vivo UV crosslinking followed by mRNP purification and MS-based proteomics. By applying this strategy, many novel "moonlighting" RBPs containing non-canonical RBDs have been discovered, and it has become clear that more proteins have RNA-binding capacities than previously supposed15,16,17. The use of this method allows for new applications and for the ability to answer new biological questions when investigating RBPs. For example, a recent study has investigated the conservation of the mRNA-bound proteome (the core RBP proteome) between yeast and human cells22.
Plant RBPs have already been found to be involved in growth and development (e.g., in the post-transcriptional regulation of flowering time, the circadian clock, and gene expression in mitochondria and chloroplasts)24,25,26,27,28,29. Furthermore, they are thought to perform functions in the cellular processes responding to abiotic stresses (e.g., cold, drought, salinity, and abscisic acid (ABA))31,32,33,34. There are more than 200 predicted RBP genes in the Arabidopsis thaliana genome, based on RNA recognition motif (RRM) and K homology (KH) domain sequence motifs; in rice, approximately 250 have been noted35,36. It is notable that many predicted RBPs seem to be unique to plants (e.g., no metazoan orthologs to approximately 50% of predicted Arabidopsis RBPs containing an RRM domain)35, suggesting that many may serve new functions. The functions of most predicted RBPs remain uncharacterized23.
The isolation of mRNA-bound proteomes from Arabidopsis etiolated seedlings, leaf tissue, cultured root cells, and leaf mesophyll protoplasts through the use of mRNA interactome capture has recently been reported38,39. These studies demonstrate the strong potential of systematically cataloging functional RBPs in plants in the near future. Here, we present a protocol for mRNA interactome capture from plant protoplasts (i.e., cells without cell walls). Arabidopsis thaliana leaf mesophyll protoplasts are the major type of leaf cell. The isolated protoplasts allow optimal access of UV light to the cells. This cell type can be used in assays that transiently express proteins for functional characterization40,41. Furthermore, protoplasting has been applied to several other plant cell types and species42,43,44 (e.g., Petersson et al., 2009; Bargmann and Birnbaum, 2010; and Hong et al., 2012).
The method encompasses a total of 11 steps (Figure 1A). Arabidopsis leaf mesophyll protoplasts are first isolated (step 1) and are subsequently UV irradiated to form crosslinked mRNPs (step 2). When protoplasts are lysed under denaturing conditions (step 3), the crosslinked mRNPs are released in lysis/binding buffer and pulled down by oligo-d(T)25 beads (step 4). After several rounds of stringent washes, the mRNPs are purified and further analyzed. The denatured peptides of mRBPs are digested by proteinase K before the crosslinked mRNAs are purified and the RNA quality is verified by qRT-PCR (steps 5 and 6). After RNase treatment and protein concentration (step 7), the protein quality is controlled by SDS polyacrylamide gel electrophoresis (SDS-PAGE) and silver staining (step 8). The difference in protein band patterns can easily be visualized between a crosslinked sample (CL) and a non-crosslinked sample (non-CL; the negative control sample from protoplasts that is not subjected to UV irradiation). The identification of proteins is achieved through MS-based proteomics. The proteins from the CL sample are separated by one-dimensional polyacrylamide gel electrophoresis (1D-PAGE) to remove possible background contamination, are "in-gel digested" into short peptides using trypsin, and are purified (step 9). Nano reverse-phase liquid chromatography coupled to mass spectrometry (nano-LC-MS) allows for the determination of the amount of definitive proteins in the mRNA-bound proteome (step 10). Finally, the identified mRBPs are characterized and cataloged using bioinformatic analysis (step 11).