easyCLIP analysis of RNA-protein interactions incorporating absolute quantification

AbstractQuantitative criteria to identify proteins as RNA-binding proteins (RBPs) are presently lacking, as are criteria to define RBP target RNAs. Here, we develop an ultraviolet (UV) cross-linking immunoprecipitation (CLIP)-sequencing method, easyCLIP. easyCLIP provides absolute cross-link rates, as well as increased simplicity, efficiency, and capacity to visualize RNA libraries during sequencing library preparation. Measurement of >200 independent cross-link experiments across >35 proteins identifies an RNA cross-link rate threshold that distinguishes RBPs from non-RBPs and defines target RNAs as those with a complex frequency unlikely for a random protein. We apply easyCLIP to the 33 most recurrent cancer mutations across 28 RBPs, finding increased RNA binding per RBP molecule for KHDRBS2 R168C, A1CF E34K and PCBP1 L100P/Q cancer mutations. Quantitating RBP-RNA interactions can thus nominate proteins as RBPs and define the impact of specific disease-associated RBP mutations on RNA association.

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The kinetic landscape of an RNA binding protein in cells

10.1101/2020.05.11.089102 ◽

2020 ◽

Author(s):

Deepak Sharma ◽

Leah L. Zagore ◽

Matthew M. Brister ◽

Xuan Ye ◽

Carlos E. Crespo-Hernández ◽

...

Keyword(s):

Protein Interactions ◽

Binding Sites ◽

High Throughput Sequencing ◽

Rna Binding ◽

Rna Binding Proteins ◽

Cumulative Probability ◽

Mrna Levels ◽

Dissociation Kinetics ◽

The Impact ◽

In Cells

ABSTRACTGene expression in higher eukaryotic cells orchestrates interactions between thousands of RNA binding proteins (RBPs) and tens of thousands of RNAs 1. The kinetics by which RBPs bind to and dissociate from their RNA sites are critical for the coordination of cellular RNA-protein interactions 2. However, these kinetics were experimentally inaccessible in cells. Here we show that time-resolved RNA-protein crosslinking with a pulsed femtosecond UV laser, followed by immunoprecipitation and high throughput sequencing allows the determination of binding and dissociation kinetics of the RBP Dazl for thousands of individual RNA binding sites in cells. This kinetic crosslinking and immunoprecipitation (KIN-CLIP) approach reveals that Dazl resides at individual binding sites only seconds or shorter, while the sites remain Dazl-free markedly longer. The data further indicate that Dazl binds to many RNAs in clusters of multiple proximal sites. The impact of Dazl on mRNA levels and ribosome association correlates with the cumulative probability of Dazl binding in these clusters. Integrating kinetic data with mRNA features quantitatively connects Dazl-RNA binding to Dazl function. Our results show how previously inaccessible, kinetic parameters for RNA-protein interactions in cells can be measured and how these data quantitatively link RBP-RNA binding to cellular RBP function.

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FLASH: ultra-fast protocol to identify RNA–protein interactions in cells

Nucleic Acids Research ◽

10.1093/nar/gkz1141 ◽

2019 ◽

Vol 48 (3) ◽

pp. e15-e15 ◽

Cited By ~ 1

Author(s):

Ibrahim Avsar Ilik ◽

Tugce Aktas ◽

Daniel Maticzka ◽

Rolf Backofen ◽

Asifa Akhtar

Keyword(s):

High Throughput ◽

Protein Interactions ◽

Binding Sites ◽

Binding Proteins ◽

High Throughput Sequencing ◽

Rna Binding ◽

Rna Binding Proteins ◽

Affinity Purification ◽

Sequencing Library

Abstract Determination of the in vivo binding sites of RNA-binding proteins (RBPs) is paramount to understanding their function and how they affect different aspects of gene regulation. With hundreds of RNA-binding proteins identified in human cells, a flexible, high-resolution, high-throughput, highly multiplexible and radioactivity-free method to determine their binding sites has not been described to date. Here we report FLASH (Fast Ligation of RNA after some sort of Affinity Purification for High-throughput Sequencing), which uses a special adapter design and an optimized protocol to determine protein–RNA interactions in living cells. The entire FLASH protocol, starting from cells on plates to a sequencing library, takes 1.5 days. We demonstrate the flexibility, speed and versatility of FLASH by using it to determine RNA targets of both tagged and endogenously expressed proteins under diverse conditions in vivo.

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easyCLIP Analysis of RNA-Protein Interactions Incorporating Absolute Quantification

10.21203/rs.3.pex-1333/v1 ◽

2021 ◽

Author(s):

Douglas Porter ◽

Paul Khavari

Keyword(s):

Protein Interactions ◽

Rna Binding ◽

Absolute Quantification ◽

Specific Protein ◽

Sequencing Analysis ◽

Sequencing Data ◽

Cross Link ◽

Cross Links ◽

Methodological Problems ◽

Target Rna

Abstract In general, an RNA-binding protein (RBP) may be considered a protein with an abnormally frequent interaction with RNA, and a "target RNA" for a specific protein may be considered an RNA with an abnormally frequent interaction with that protein. Traditional ultraviolet (UV) cross-linking immunoprecipitation (CLIP)-sequencing analysis methods generally define interactions by methods that are indirectly assessing the latter. However, there has been limited direct assessment of these metrics by determining RNA cross-link rates or the RNA-binding profiles of non-RBPs.Here, we describe a method to determine RNA cross-link rates and create sequencing libraries for a protein of interest, either of which may be performed on their own. easyCLIP is a relatively short, reliable, and efficient CLIP method, with the capacity to directly visualize RNA libraries and diagnose methodological problems. By combining the sequencing data and cross-link rates, the absolute frequency of given cross-links may be compared between control and experimental proteins, to nominate potential RBPs and distinctive RNA-protein interactions.

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The search for RNA-binding proteins: a technical and interdisciplinary challenge

Biochemical Society Transactions ◽

10.1042/bst20200688 ◽

2021 ◽

Author(s):

Jeffrey M. Smith ◽

Jarrod J. Sandow ◽

Andrew I. Webb

Keyword(s):

Gene Expression ◽

Protein Interactions ◽

Binding Proteins ◽

Rna Binding ◽

Rna Binding Proteins ◽

Target Validation ◽

Binding Function ◽

Technical Features ◽

Post Transcriptional Regulation ◽

The Impact

RNA-binding proteins are customarily regarded as important facilitators of gene expression. In recent years, RNA–protein interactions have also emerged as a pervasive force in the regulation of homeostasis. The compendium of proteins with provable RNA-binding function has swelled from the hundreds to the thousands astride the partnership of mass spectrometry-based proteomics and RNA sequencing. At the foundation of these advances is the adaptation of RNA-centric capture methods that can extract bound protein that has been cross-linked in its native environment. These methods reveal snapshots in time displaying an extensive network of regulation and a wealth of data that can be used for both the discovery of RNA-binding function and the molecular interfaces at which these interactions occur. This review will focus on the impact of these developments on our broader perception of post-transcriptional regulation, and how the technical features of current capture methods, as applied in mammalian systems, create a challenging medium for interpretation by systems biologists and target validation by experimental researchers.

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PlncRNADB: A Repository of Plant lncRNAs and lncRNA-RBP Protein Interactions

Current Bioinformatics ◽

10.2174/1574893614666190131161002 ◽

2019 ◽

Vol 14 (7) ◽

pp. 621-627 ◽

Cited By ~ 3

Author(s):

Youhuang Bai ◽

Xiaozhuan Dai ◽

Tiantian Ye ◽

Peijing Zhang ◽

Xu Yan ◽

...

Keyword(s):

Protein Interactions ◽

Binding Proteins ◽

Rna Binding ◽

Rna Binding Proteins ◽

Populus Trichocarpa ◽

Noncoding Rnas ◽

Reference Database ◽

Protein Coding ◽

Arabidopsis Lyrata ◽

User Friendly

Background: Long noncoding RNAs (lncRNAs) are endogenous noncoding RNAs, arbitrarily longer than 200 nucleotides, that play critical roles in diverse biological processes. LncRNAs exist in different genomes ranging from animals to plants. Objective: PlncRNADB is a searchable database of lncRNA sequences and annotation in plants. Methods: We built a pipeline for lncRNA prediction in plants, providing a convenient utility for users to quickly distinguish potential noncoding RNAs from protein-coding transcripts. Results: More than five thousand lncRNAs are collected from four plant species (Arabidopsis thaliana, Arabidopsis lyrata, Populus trichocarpa and Zea mays) in PlncRNADB. Moreover, our database provides the relationship between lncRNAs and various RNA-binding proteins (RBPs), which can be displayed through a user-friendly web interface. Conclusion: PlncRNADB can serve as a reference database to investigate the lncRNAs and their interaction with RNA-binding proteins in plants. The PlncRNADB is freely available at http://bis.zju.edu.cn/PlncRNADB/.

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Compendium of Methods to Uncover RNA-Protein Interactions In Vivo

Methods and Protocols ◽

10.3390/mps4010022 ◽

2021 ◽

Vol 4 (1) ◽

pp. 22

Author(s):

Mrinmoyee Majumder ◽

Viswanathan Palanisamy

Keyword(s):

Gene Expression ◽

Protein Interactions ◽

Rna Binding ◽

Rna Binding Proteins ◽

Expression Patterns ◽

Control Of Gene Expression ◽

Regulatory Pathways ◽

Advantages And Disadvantages ◽

Protein Nucleic Acid

Control of gene expression is critical in shaping the pro-and eukaryotic organisms’ genotype and phenotype. The gene expression regulatory pathways solely rely on protein–protein and protein–nucleic acid interactions, which determine the fate of the nucleic acids. RNA–protein interactions play a significant role in co- and post-transcriptional regulation to control gene expression. RNA-binding proteins (RBPs) are a diverse group of macromolecules that bind to RNA and play an essential role in RNA biology by regulating pre-mRNA processing, maturation, nuclear transport, stability, and translation. Hence, the studies aimed at investigating RNA–protein interactions are essential to advance our knowledge in gene expression patterns associated with health and disease. Here we discuss the long-established and current technologies that are widely used to study RNA–protein interactions in vivo. We also present the advantages and disadvantages of each method discussed in the review.

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RNA-Centric Approaches to Profile the RNA–Protein Interaction Landscape on Selected RNAs

Non-Coding RNA ◽

10.3390/ncrna7010011 ◽

2021 ◽

Vol 7 (1) ◽

pp. 11 ◽

Cited By ~ 1

Author(s):

André P. Gerber

Keyword(s):

Mass Spectrometry ◽

Protein Interactions ◽

Regulatory Networks ◽

Rna Binding ◽

Rna Binding Proteins ◽

Protein Complexes ◽

Cell Protein ◽

Transcriptional Regulatory Networks ◽

Technological Advances

RNA–protein interactions frame post-transcriptional regulatory networks and modulate transcription and epigenetics. While the technological advances in RNA sequencing have significantly expanded the repertoire of RNAs, recently developed biochemical approaches combined with sensitive mass-spectrometry have revealed hundreds of previously unrecognized and potentially novel RNA-binding proteins. Nevertheless, a major challenge remains to understand how the thousands of RNA molecules and their interacting proteins assemble and control the fate of each individual RNA in a cell. Here, I review recent methodological advances to approach this problem through systematic identification of proteins that interact with particular RNAs in living cells. Thereby, a specific focus is given to in vivo approaches that involve crosslinking of RNA–protein interactions through ultraviolet irradiation or treatment of cells with chemicals, followed by capture of the RNA under study with antisense-oligonucleotides and identification of bound proteins with mass-spectrometry. Several recent studies defining interactomes of long non-coding RNAs, viral RNAs, as well as mRNAs are highlighted, and short reference is given to recent in-cell protein labeling techniques. These recent experimental improvements could open the door for broader applications and to study the remodeling of RNA–protein complexes upon different environmental cues and in disease.

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Current insights into the implications of m6A RNA methylation and autophagy interaction in human diseases

Cell & Bioscience ◽

10.1186/s13578-021-00661-x ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Xuechai Chen ◽

Jianan Wang ◽

Muhammad Tahir ◽

Fangfang Zhang ◽

Yuanyuan Ran ◽

...

Keyword(s):

Intervertebral Disc Degeneration ◽

Rna Binding ◽

Rna Binding Proteins ◽

Degradation Process ◽

Human Diseases ◽

Rna Modification ◽

Rna Methylation ◽

M6a Rna Methylation ◽

The Impact

AbstractAutophagy is a conserved degradation process crucial to maintaining the primary function of cellular and organismal metabolism. Impaired autophagy could develop numerous diseases, including cancer, cardiomyopathy, neurodegenerative disorders, and aging. N6-methyladenosine (m6A) is the most common RNA modification in eukaryotic cells, and the fate of m6A modified transcripts is controlled by m6A RNA binding proteins. m6A modification influences mRNA alternative splicing, stability, translation, and subcellular localization. Intriguingly, recent studies show that m6A RNA methylation could alter the expression of essential autophagy-related (ATG) genes and influence the autophagy function. Thus, both m6A modification and autophagy could play a crucial role in the onset and progression of various human diseases. In this review, we summarize the latest studies describing the impact of m6A modification in autophagy regulation and discuss the role of m6A modification-autophagy axis in different human diseases, including obesity, heart disease, azoospermatism or oligospermatism, intervertebral disc degeneration, and cancer. The comprehensive understanding of the m6A modification and autophagy interplay may help in interpreting their impact on human diseases and may aid in devising future therapeutic strategies.

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LPI-HyADBS: a hybrid framework for lncRNA-protein interaction prediction integrating feature selection and classification

BMC Bioinformatics ◽

10.1186/s12859-021-04485-x ◽

2021 ◽

Vol 22 (1) ◽

Author(s):

Liqian Zhou ◽

Qi Duan ◽

Xiongfei Tian ◽

He Xu ◽

Jianxin Tang ◽

...

Keyword(s):

Feature Selection ◽

Protein Interactions ◽

Cross Validation ◽

Rna Binding ◽

Rna Binding Proteins ◽

Biological Information ◽

Hybrid Framework ◽

Protein Interaction Prediction ◽

Single Dataset ◽

Feature Selection Approach

Abstract Background Long noncoding RNAs (lncRNAs) have dense linkages with a plethora of important cellular activities. lncRNAs exert functions by linking with corresponding RNA-binding proteins. Since experimental techniques to detect lncRNA-protein interactions (LPIs) are laborious and time-consuming, a few computational methods have been reported for LPI prediction. However, computation-based LPI identification methods have the following limitations: (1) Most methods were evaluated on a single dataset, and researchers may thus fail to measure their generalization ability. (2) The majority of methods were validated under cross validation on lncRNA-protein pairs, did not investigate the performance under other cross validations, especially for cross validation on independent lncRNAs and independent proteins. (3) lncRNAs and proteins have abundant biological information, how to select informative features need to further investigate. Results Under a hybrid framework (LPI-HyADBS) integrating feature selection based on AdaBoost, and classification models including deep neural network (DNN), extreme gradient Boost (XGBoost), and SVM with a penalty Coefficient of misclassification (C-SVM), this work focuses on finding new LPIs. First, five datasets are arranged. Each dataset contains lncRNA sequences, protein sequences, and an LPI network. Second, biological features of lncRNAs and proteins are acquired based on Pyfeat. Third, the obtained features of lncRNAs and proteins are selected based on AdaBoost and concatenated to depict each LPI sample. Fourth, DNN, XGBoost, and C-SVM are used to classify lncRNA-protein pairs based on the concatenated features. Finally, a hybrid framework is developed to integrate the classification results from the above three classifiers. LPI-HyADBS is compared to six classical LPI prediction approaches (LPI-SKF, LPI-NRLMF, Capsule-LPI, LPI-CNNCP, LPLNP, and LPBNI) on five datasets under 5-fold cross validations on lncRNAs, proteins, lncRNA-protein pairs, and independent lncRNAs and independent proteins. The results show LPI-HyADBS has the best LPI prediction performance under four different cross validations. In particular, LPI-HyADBS obtains better classification ability than other six approaches under the constructed independent dataset. Case analyses suggest that there is relevance between ZNF667-AS1 and Q15717. Conclusions Integrating feature selection approach based on AdaBoost, three classification techniques including DNN, XGBoost, and C-SVM, this work develops a hybrid framework to identify new linkages between lncRNAs and proteins.

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Development of an RNA-protein crosslinker to capture protein interactions with diverse RNA structures in cells

RNA ◽

10.1261/rna.078896.121 ◽

2021 ◽

pp. rna.078896.121

Author(s):

Yan Han ◽

Xuzhen Guo ◽

Tiancai Zhang ◽

Jiangyun Wang ◽

Keqiong Ye

Keyword(s):

Protein Interactions ◽

Rna Structure ◽

Rna Binding ◽

Rna Binding Proteins ◽

High Specificity ◽

Ester Group ◽

Yeast Cells ◽

Primary Amines ◽

Low Efficiency ◽

In Cells

Characterization of RNA-protein interaction is fundamental for understanding metabolism and function of RNA. UV crosslinking has been widely used to map the targets of RNA-binding proteins, but is limited by low efficiency, requirement for zero-distance contact and biases for single-stranded RNA structure and certain residues of RNA and protein. Here, we report the development of an RNA-protein crosslinker (AMT-NHS) composed of a psoralen derivative and an N-hydroxysuccinimide ester group, which react with RNA bases and primary amines of protein, respectively. We show that AMT-NHS can penetrate into living yeast cells and crosslink Cbf5 to H/ACA snoRNAs with high specificity. The crosslinker induced different crosslinking patterns than UV and targeted both single- and double-stranded regions of RNA. The crosslinker provides a new tool to capture diverse RNA-protein interactions in cells.

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