Ribonucleoprotein Networks Analyzed by Mutational Profiling

Ribonucleoprotein Networks Analyzed by Mutational Profiling (RNP-MaP) is a strategy for probing RNA-protein networks and protein binding sites at a nucleotide resolution. Information about RNP assembly and function can facilitate a better understanding of biological mechanisms. RNP-MaP uses NHS-diazirine (SDA), a hetero-bifunctional crosslinker, to freeze RNA-bound proteins in place. Once the RNA-protein crosslinks are formed, MaP reverse transcription[1] is then conducted to reversely transcribe the protein-bound RNAs as well as introduce mutations at the site of RNA-protein crosslinks. Sequencing results of the cDNAs reveal information about both protein-RNA interaction networks and protein binding sites.[2]

RNP-MaP workflow overview

Strategy

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Components

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RNA-MaP involves three major components:[2]

  • Ribonucleoproteins (RNPs): complexes made up of RNAs and RNA-binding proteins (RBPs)[3]
  • NHS-diazirine (SDA): a cell permeable crosslinking reagent. SDA contains two reactive groups - a diazirine and a succinimidyl ester. The reaction between succinimidyl esters and amine groups (e.g. lysine side chains) results in peptide bonds (or amide bonds). When exposed to UV light with a wavelength of 365 nm, an intermediate broadly reactive toward nucleotide riboses and bases is formed. As a result, proteins are crosslinked with RNA by the SDA linker.[2]
  • Mutational profiling (MaP): a method using reverse transcriptase with relaxed fidelity to incorporate modified residues at protein-RNA binding sites.[1][3]

Workflow

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Long-wavelength UV and SDA reagents are first supplied to living cells to crosslink protein residues with RNA by forming amide bonds between amine groups of lysine (or arginine) residues and succinimidyl esters. Next, cells containing crosslinked RNPs are lysed and the RNA-bound proteins are digested into peptide adducts. MaP reverse transcription is then performed to label the protein-RNA binding sites through peptide adduct-induced mutations. Sequencing of the mutation-containing cDNA product will reveal the mutation sites (or RNP-MaP sites) and the correlations between the RNP-MaP sites are computationally determined using 3-nucleotide windows.[2][4]

Analysis

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RNP-MaP site identification

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RNP-MaP sites are defined as protein bound nucleotides. SDA and UV treated and UV only treated sample sequence reads are aligned and mutations are counted using ShapeMapper2 software.[5] The SDA or RNP-MaP reactivity for a nucleotide is the ratio of the crosslinked (SDA and UV treated) mutational frequency to the un-crosslinked (UV only) mutation frequency. Using differential mutational signatures, RNP-MaP sites are identified based on universal normalization factors and thresholds on each RNA nucleotide (U, A, C, and G) derived from analysis of ribonucleoproteins of known structure.[2]

A nucleotide is identified as a RNP-MaP site if it passes three filters:

  1. The number of mutation events in the SDA + UV-treated sample is at least 50 greater than the UV-treated sample.
  2. Site reactivities must exceed the nucleotide-dependent thresholds ( ) that are empirically defined as:
    •  , where
      •   is the nucleotide U, A, C, or G
      •   is the background threshold defined by the 90% reactivity values of nucleotides in a >10Å group
      •   is the median of all reactivities for all nucleotides
      •   is the standard deviation of reactivities for all nucleotides
  3. The calculated Z-factor is greater than zero
    • The calculated Z-factor is defined as
      •  , where
        •   is the mutation rate of a nucleotide treated with SDA and UV and   is the mutation rate of a nucleotide treated with UV only
        •  , where   is treatment (SDA + UV or UV only)

Protein-RNA interaction network identification

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Protein-RNA interactions networks are identified using RNP-MaP correlations since multiple crosslink sites can be detected for a single RNA molecule. RNP-MaP correlations provide a complementary measure of protein binding to RNA independent of RNP-MaP sites.[2] They are identified using a G-test framework known as RingMapper.[4]

RNP-MaP correlations require a single RNA molecule to form at least two crosslinks and arise from any of three scenarios:

  1. A single protein binds to two locations of one RNA
  2. Two proteins that interact and bind to two locations on one RNA
  3. Two proteins are deposited on two locations on one RNA by a coordinated assembly process

Using RNP-MaP correlations, a network of protein-RNA interaction sites is found and can then be used for functional analysis.

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Cross-linking immunoprecipitation (CLIP)

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CLIP analyzes protein interactions with RNA by combining UV cross-linking and immunoprecipitation. CLIP-based techniques are able to map RNA binding protein binding sites of interest on a genome-wide scale.[6]

There are many CLIP-based methods including:

  • HITS-CLIP (High-throughput sequencing of RNA isolated by crosslinking immunoprecipitation or CLIP-seq)[7]
  • PAR-CLIP (Photoactivatable ribonucleoside-enhanced cross-linking and immunoprecipitation)[8]
  • iCLIP (Individual nucleotide-resolution cross-linking and immunoprecipitation)[9]
  • eCLIP (Enhanced cross-linking and immunoprecipitation followed by high-throughput sequencing)[10]
  • sCLIP (Simple cross-linking and immunoprecipitation)[11]

Mass spectrometry

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Quantitative mass spectrometry (MS) (or quantitative proteomics) can be used to discover RNA-binding proteins (RBPs) bound to RNA. Labeling MS methods involve the differential use of stable isotope labels or chemical tagging of proteins in samples and controls. This is used to obtain enrichment scores and true binding partners through the ratio of labeled peptides.[12] Label-free MS methods are able to identify proteins in samples and controls. In order to distinguish true binding partners for nonspecific proteins, analytical tools used alongside spectral count data from non-quantitative MS are used to score the probability of a true RBP-RNA interaction[13]

Advantages and Limitations

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Advantages

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RNP-MaP can help reveal functionally important RNA-protein binding networks through binding site density and interconnectivity independent of previous knowledge of interacting proteins. Because of the unbiased nature of the analysis, RNP-MaP is able to detect conserved RNA-protein interactions between species.[2]

RNP-MaP is also able to facilitate the characterization of functionally critical elements in large non-coding RNAs or even viral RNAs.[2]

Limitations

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As a standalone technique, RNP-MaP cannot be used to determine protein-RNA binding mechanisms or protein identities. In order to do so, RNP-MaP must be used in conjunction with other techniques such as CLIP and mass spectrometry.[2]

RNP-MaP requires extremely high read-depths for analysis. To identify RNP-MaP sites, 1000x sequencing coverage is required, while RNP-MaP correlation sites require 10,000x sequencing coverage.[2]

There are severe limitations on the ability to characterize RNP-MaP correlations between distant (>500 nucleotides) RNP-MaP sites. This is due to limitations of MaP reverse transcription processivity (500-600 nucleotides) and sequencing instrument clustering (<1,000 nucleotides).[2]

References

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  1. ^ a b Smola, Matthew J.; Rice, Greggory M.; Busan, Steven; Siegfried, Nathan A.; Weeks, Kevin M. (2015-10-01). "Selective 2′-hydroxyl acylation analyzed by primer extension and mutational profiling (SHAPE-MaP) for direct, versatile and accurate RNA structure analysis". Nature Protocols. 10 (11): 1643–1669. doi:10.1038/nprot.2015.103. ISSN 1750-2799. PMC 4900152. PMID 26426499.
  2. ^ a b c d e f g h i j k Weidmann, Chase A.; Mustoe, Anthony M.; Jariwala, Parth B.; Calabrese, J. Mauro; Weeks, Kevin M. (2020-10-19). "Analysis of RNA–protein networks with RNP-MaP defines functional hubs on RNA". Nature Biotechnology. 39 (3): 347–356. doi:10.1038/s41587-020-0709-7. ISSN 1546-1696. PMC 7956044. PMID 33077962.
  3. ^ a b Stefl, Richard; Skrisovska, Lenka; Allain, Frédéric H.-T. (January 2005). "RNA sequence- and shape-dependent recognition by proteins in the ribonucleoprotein particle". EMBO Reports. 6 (1): 33–38. doi:10.1038/sj.embor.7400325. PMC 1299235. PMID 15643449.
  4. ^ a b Mustoe, Anthony M.; Lama, Nicole N.; Irving, Patrick S.; Olson, Samuel W.; Weeks, Kevin M. (2019-11-19). "RNA base-pairing complexity in living cells visualized by correlated chemical probing". Proceedings of the National Academy of Sciences. 116 (49): 24574–24582. Bibcode:2019PNAS..11624574M. doi:10.1073/pnas.1905491116. ISSN 0027-8424. PMC 6900531. PMID 31744869.
  5. ^ Busan, Steven; Weeks, Kevin M. (2018-02-01). "Accurate detection of chemical modifications in RNA by mutational profiling (MaP) with ShapeMapper 2". RNA. 24 (2): 143–148. doi:10.1261/rna.061945.117. ISSN 1355-8382. PMC 5769742. PMID 29114018.
  6. ^ Hafner, Markus; Katsantoni, Maria; Köster, Tino; Marks, James; Mukherjee, Joyita; Staiger, Dorothee; Ule, Jernej; Zavolan, Mihaela (2021-03-04). "CLIP and complementary methods". Nature Reviews Methods Primers. 1 (1): 1–23. doi:10.1038/s43586-021-00018-1. ISSN 2662-8449. S2CID 233834798.
  7. ^ Darnell, Robert B. (2010-08-02). "HITS-CLIP: panoramic views of protein–RNA regulation in living cells". Wiley Interdisciplinary Reviews: RNA. 1 (2): 266–286. doi:10.1002/wrna.31. ISSN 1757-7004. PMC 3222227. PMID 21935890.
  8. ^ Hafner, Markus; Landthaler, Markus; Burger, Lukas; Khorshid, Mohsen; Hausser, Jean; Berninger, Philipp; Rothballer, Andrea; Ascano, Manuel; Jungkamp, Anna-Carina; Munschauer, Mathias; Ulrich, Alexander (2010-07-02). "PAR-CliP - A Method to Identify Transcriptome-wide the Binding Sites of RNA Binding Proteins". Journal of Visualized Experiments (41): 2034. doi:10.3791/2034. ISSN 1940-087X. PMC 3156069. PMID 20644507.
  9. ^ König, Julian; Zarnack, Kathi; Rot, Gregor; Curk, Tomaž; Kayikci, Melis; Zupan, Blaž; Turner, Daniel J.; Luscombe, Nicholas M.; Ule, Jernej (2010-07-04). "iCLIP reveals the function of hnRNP particles in splicing at individual nucleotide resolution". Nature Structural & Molecular Biology. 17 (7): 909–915. doi:10.1038/nsmb.1838. ISSN 1545-9985. PMC 3000544. PMID 20601959.
  10. ^ Van Nostrand, Eric L; Pratt, Gabriel A; Shishkin, Alexander A; Gelboin-Burkhart, Chelsea; Fang, Mark Y; Sundararaman, Balaji; Blue, Steven M; Nguyen, Thai B; Surka, Christine; Elkins, Keri; Stanton, Rebecca (2016-03-28). "Robust transcriptome-wide discovery of RNA-binding protein binding sites with enhanced CLIP (eCLIP)". Nature Methods. 13 (6): 508–514. doi:10.1038/nmeth.3810. ISSN 1548-7091. PMC 4887338. PMID 27018577.
  11. ^ Kargapolova, Yulia; Levin, Michal; Lackner, Karl; Danckwardt, Sven (2017-06-02). "sCLIP—an integrated platform to study RNA–protein interactomes in biomedical research: identification of CSTF2tau in alternative processing of small nuclear RNAs". Nucleic Acids Research. 45 (10): 6074–6086. doi:10.1093/nar/gkx152. ISSN 0305-1048. PMC 5449641. PMID 28334977.
  12. ^ Bantscheff, Marcus; Schirle, Markus; Sweetman, Gavain; Rick, Jens; Kuster, Bernhard (2007-10-01). "Quantitative mass spectrometry in proteomics: a critical review". Analytical and Bioanalytical Chemistry. 389 (4): 1017–1031. doi:10.1007/s00216-007-1486-6. ISSN 1618-2650. PMID 17668192. S2CID 14236144.
  13. ^ Mellacheruvu, Dattatreya; Wright, Zachary; Couzens, Amber L.; Lambert, Jean-Philippe; St-Denis, Nicole A.; Li, Tuo; Miteva, Yana V.; Hauri, Simon; Sardiu, Mihaela E.; Low, Teck Yew; Halim, Vincentius A. (2013-07-07). "The CRAPome: a contaminant repository for affinity purification–mass spectrometry data". Nature Methods. 10 (8): 730–736. doi:10.1038/nmeth.2557. ISSN 1548-7105. PMC 3773500. PMID 23921808.