生物化学

The importance of studying the mechanistic aspects of long non-coding RNAs is being increasingly emphasized as more and more regulatory RNAs are being discovered. Non-coding RNA sequences directly associate with generic RNA-binding proteins as well as specific proteins, which cooperate in the downstream functions of the RNA and can also be dysregulated in various physiologic states and/or diseases. While current methods exist for identifying RNA–protein interactions, these methods require high quantities of input cells or use pooled capture reagents that may increase non-specific binding. We have developed a method to efficiently capture specific RNAs using less than one million input cells. One single oligonucleotide is used to pull down the target RNA of choice and oligonucleotide selection is driven by sequence accessibility. We perform thermal elution to specifically elute the target RNA and its associated proteins, which are identified by mass spectrometry. Ultimately, two target and control oligonucleotides are used to create an enrichment map of interacting proteins of interest.

RNA is a vital component of the cell and is involved in a diverse range of cellular processes through a variety of functions. However, many of these functions cannot be performed without interactions with proteins. There are currently several techniques used to study protein–RNA interactions, such as electrophoretic mobility shift assay, fluorescence anisotropy, and filter binding. RNA-pulldown is a technique that uses biotinylated RNA probes to capture protein–RNA complexes of interest. First, the RNA probe and a recombinant protein are incubated to allow the in vitro interaction to occur. The fraction of bound protein is then captured by a biotin pull-down using streptavidin-agarose beads, followed by elution and immunoblotting for the recombinant protein with a His-tag–reactive probe. Overall, this method does not require specialized equipment outside what is typically found in a modern molecular laboratory and easily facilitates the maintenance of an RNase-free environment.

Graphical abstract

In Arabidopsis, DICER-LIKE PROTEIN 3 (DCL3) cuts the substrate pre-siRNA into a product siRNA duplex, encompassing one 23-nt strand and one 24-nt strand. To monitor the separation of the siRNA duplex with only 1-nt difference, we developed this protocol to evaluate the in vitro dicing activity of DCL3. The method can be applied for measuring the lengths of single-stranded RNA separated through denaturing urea polyacrylamide gel electrophoresis (urea PAGE), which are visualized by a label-free fluorescence SYBR Gold, and quantified in a multi-function imager. This label-free method is easy to conduct, has low cost, and lacks the hazard of the traditional radio-labeled method. This method can also be adapted to the other Dicers and small RNAs.

During development, cells must quickly switch from one cell state to the next to execute precise and timely differentiation. One method to ensure fast transitions in cell states is by controlling gene expression at the post-transcriptional level through action of RNA-binding proteins on mRNAs. The ability to accurately identify the RNA targets of RNA-binding proteins at specific stages is key to understanding the functional role of RNA-binding proteins during development. Here we describe an adapted formaldehyde RNA immunoprecipitation (fRIP) protocol to identify the in vivo RNA targets of a cytoplasmic RNA-binding protein, YTHDC2, from testis, during the first wave of spermatogenesis, at the stage when germ cells are shutting off the proliferative program and initiating terminal differentiation (Bailey et al., 2017). This protocol enables quick and efficient identification of endogenous RNAs bound to an RNA-binding protein, and facilitates the monitoring of stage-specific changes during development.

To determine the molecular and functional interactions between RNA-binding proteins (RBPs) and their targets RNAs, is of fundamental importance to understand the dynamic organization of the nervous system in health and disease. Nevertheless, this task has remained elusive due to the lack of specific protocols and experimental systems that would allow the combination of biochemical analysis with in vivo functional genetics. In this manuscript, we describe a trustworthy and detailed methodology to establish the molecular organization and intracellular function of RBPs/RNA multimeric complexes in a cell type-defined manner by using the powerful GAL4/UAS system for gene expression in Drosophila melanogaster.

Graphic abstract:

Immunoprecipitation for protein-RNA interaction in Drosophila.

RNA-protein interactions are often mediated by dedicated canonical RNA binding domains. However, interactions through non-canonical domains with unknown specificity are increasingly observed, raising the question how RNA targets are recognized. Knowledge of the intrinsic RNA binding specificity contributes to the understanding of target selectivity and function of an individual protein.

The presented in vitro RNA immunoprecipitation assay (vitRIP) uncovers intrinsic RNA binding specificities of isolated proteins using the total cellular RNA pool as a library. Total RNA extracted from cells or tissues is incubated with purified recombinant proteins, RNA-protein complexes are immunoprecipitated and bound transcripts are identified by deep sequencing or quantitative RT-PCR. Enriched RNA classes and the nucleotide frequency in these RNAs inform on the intrinsic specificity of the recombinant protein. The simple and versatile protocol can be adapted to other RNA binding proteins and total RNA libraries from any cell type or tissue.

Graphic abstract:


Figure 1. Schematic of the in vitro RNA immunoprecipitation (vitRIP) protocol

Over the last decade, it has been noticed that microbial pathogens and pests deliver small RNA (sRNA) effectors into their host plants to manipulate plant physiology and immunity for infection, known as cross kingdom RNA interference. In this process, fungal and oomycete parasite sRNAs hijack the plant ARGONAUTE (AGO)/RNA-induced silencing complex to post-transcriptionally silence host target genes. We hereby describe the methodological details of how we recovered cross kingdom sRNA effectors of the oomycete pathogen Hyaloperonospora arabidopsidis during infection of its host plant Arabidopsis thaliana. This Bio-protocol contains two parts: first, a detailed description on the procedure of plant AGO/sRNA co-immunopurification and sRNA recovery for Illumina high throughput sequencing analysis. Second, we explain how to perform bioinformatics analysis of sRNA sequence reads using a Galaxy server. In principle, this protocol is suitable to investigate AGO-bound sRNAs from diverse host plants and plant-interacting (micro)organisms.

An important but often overlooked aspect of gene regulation occurs at the level of protein translation. Many genes are regulated not only by transcription but by their propensity to be recruited to actively translating ribosomes (polysomes). Polysome profiling allows for the separation of unbound 40S and 60S subunits, 80S monosomes, and actively translating mRNA bound by two or more ribosomes. Thus, this technique allows for actively translated mRNA to be isolated. Transcript abundance can then be compared between actively translated mRNA and all mRNA present in a sample to identify instances of post-transcriptional regulation. Additionally, polysome profiling can be used as a readout of global translation rates by quantifying the proportion of actively translating ribosomes within a sample. Previously established protocols for polysome profiling rely on the absorbance of RNA to visualize the presence of polysomes within the fractions. However, with the advent of flow cells capable of detecting fluorescence, the association of fluorescently tagged proteins with polysomes can be detected and quantified in addition to the absorbance of RNA. This protocol provides detailed instructions on how to perform fluorescent polysome profiling in C. elegans to collect actively translated mRNA, to quantify changes in global translation, and to detect ribosomal binding partners.

RNA binding proteins (RBPs) interact with cellular mRNAs, controlling various steps throughout the lifetime of these transcripts, including transcription, cellular transport, subcellular localization, translation and degradation. In addition to binding mRNA transcripts, a growing number of RBPs are shown to bind long noncoding RNAs (lncRNAs), controlling key cellular processes, including gene expression and translation of proteins. Current methodologies aimed at identifying and characterizing protein binding partners of specific RNAs of interest typically rely on tagging of the RNA with affinity aptamers, using in vitro transcribed RNA or immobilized oligonucleotides to capture RNA-protein complexes under native conditions. These assays are coupled with mass spectrometry or Western Blot analysis to identify or/and confirm interacting proteins. Here, we describe an alternative approach to identify protein binding partners of mRNAs and large long noncoding RNAs. This approach relies on biochemical pulldown of specific target RNAs and interacting protein partners from cellular lysates coupled with mass spectrometry to identify novel interacting proteins. By using 24-48 ~20 mer biotinylated DNA probes that hybridize to the target RNA, the method ensures high specificity and minimal off target binding. This approach is reproducible and fast and serves as a base for discovery studies to identify proteins that bind to RNAs of interest.

Viruses need to open, i.e., uncoat, in order to release their genomes for efficient replication and translation. Especially for non-enveloped viruses, such as enteroviruses, the cues leading to uncoating are less well known. The status of the virus has previously been observed mainly by transmission electron microscopy using negative staining, cryo electron microscopy, X-ray crystallography or gradient separation (reviewed in Tuthill et al., 2010, Myllynen et al., 2016, Ruokolainen et al., 2019). However, monitoring of uncoating has been limited by the lack of methods detecting dynamic changes of the virions. Here, we present a real-time fluorescence based protocol, which detects the viral genome (RNA) during various stages of uncoating in vitro, while RNA is still inside the particle that has been expanded before the actual RNA release, and when the RNA has been totally released from the viral particle. Our method allows to explore how various molecular factors may promote or inhibit virus uncoating.