Imaging mRNA and protein interactions within neurons

Carolina Eliscovich; Shailesh M. Shenoy; Robert H. Singer

doi:10.1073/pnas.1621440114

Imaging mRNA and protein interactions within neurons

Carolina Eliscovich, Shailesh M. Shenoy, Robert H. Singer

Research output: Contribution to journal › Article › peer-review

65 Scopus citations

Abstract

RNA-protein interactions are essential for proper gene expression regulation, particularly in neurons with unique spatial constraints. Currently, these interactions are defined biochemically, but a method is needed to evaluate them quantitatively within morphological context. Colocalization of two-color labels using wide-field microscopy is a method to infer these interactions. However, because of chromatic aberrations in the objective lens, this approach lacks the resolution to determine whether two molecules are physically in contact or simply nearby by chance. Here, we developed a robust super registration methodology that corrected the chromatic aberration across the entire image field to within 10 nm, which is capable of determining whether two molecules are physically interacting or simply in proximity by random chance. We applied this approach to image single-molecule FISH in combination with immunofluorescence (smFISH-IF) and determined whether the association between an mRNA and binding protein(s) within a neuron was significant or accidental. We evaluated several mRNA-binding proteins identified from RNA pulldown assays to determine which of these exhibit bona fide interactions. Surprisingly, many known mRNA-binding proteins did not bind the mRNA in situ, indicating that adventitious interactions are significant using existing technology. This method provides an ability to evaluate two-color registration compatible with the scale of molecular interactions.

Original language	English (US)
Pages (from-to)	E1875-E1884
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	114
Issue number	10
DOIs	https://doi.org/10.1073/pnas.1621440114
State	Published - Mar 7 2017

Keywords

Chromatic aberration correction
SmFISH-IF
Super registration

ASJC Scopus subject areas

General

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10.1073/pnas.1621440114

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title = "Imaging mRNA and protein interactions within neurons",

abstract = "RNA-protein interactions are essential for proper gene expression regulation, particularly in neurons with unique spatial constraints. Currently, these interactions are defined biochemically, but a method is needed to evaluate them quantitatively within morphological context. Colocalization of two-color labels using wide-field microscopy is a method to infer these interactions. However, because of chromatic aberrations in the objective lens, this approach lacks the resolution to determine whether two molecules are physically in contact or simply nearby by chance. Here, we developed a robust super registration methodology that corrected the chromatic aberration across the entire image field to within 10 nm, which is capable of determining whether two molecules are physically interacting or simply in proximity by random chance. We applied this approach to image single-molecule FISH in combination with immunofluorescence (smFISH-IF) and determined whether the association between an mRNA and binding protein(s) within a neuron was significant or accidental. We evaluated several mRNA-binding proteins identified from RNA pulldown assays to determine which of these exhibit bona fide interactions. Surprisingly, many known mRNA-binding proteins did not bind the mRNA in situ, indicating that adventitious interactions are significant using existing technology. This method provides an ability to evaluate two-color registration compatible with the scale of molecular interactions.",

keywords = "Chromatic aberration correction, SmFISH-IF, Super registration",

author = "Carolina Eliscovich and Shenoy, {Shailesh M.} and Singer, {Robert H.}",

note = "Funding Information: We thank Jeff A. Chao for the MBP-PP7 recombinant protein and 3′-UTR β-actin-PP7 construct; Xiuhua Meng for GFP-ZBP1 cloning; Jeetayu Biswas for the molecular model in PyMOL; Young Yoon for hippocampal neuron cultures and discussion; Bin Wu for tdMCP-GFP lentivirus and discussion; Chiso Nwokafor and Melissa Lopez-Jones for mice; Aviv Bergman for mathematical modeling; Stefan H{\"u}ttelmaier for anti-zbp1, anti-hnRNPU, and anti-hnRNPE2 antibodies; Maria Vera and members of the R.H.S. laboratory for critical reading of the manuscript; Joe Fernandez and Milica Tesic Mark for proteomics (Rockefeller University); and Andrew Gerson (Olympus) and Thomas Geer (BioVision) for help with instrumentation. This work was supported by a Human Frontier Science Program Fellowship (to C.E.), NIH Grant NS083085 (to R.H.S.), and the Integrated Imaging Program of the Gruss Lipper Biophotonics Center. Publisher Copyright: {\textcopyright} 2017, National Academy of Sciences. All rights reserved.",

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doi = "10.1073/pnas.1621440114",

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AU - Shenoy, Shailesh M.

AU - Singer, Robert H.

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N2 - RNA-protein interactions are essential for proper gene expression regulation, particularly in neurons with unique spatial constraints. Currently, these interactions are defined biochemically, but a method is needed to evaluate them quantitatively within morphological context. Colocalization of two-color labels using wide-field microscopy is a method to infer these interactions. However, because of chromatic aberrations in the objective lens, this approach lacks the resolution to determine whether two molecules are physically in contact or simply nearby by chance. Here, we developed a robust super registration methodology that corrected the chromatic aberration across the entire image field to within 10 nm, which is capable of determining whether two molecules are physically interacting or simply in proximity by random chance. We applied this approach to image single-molecule FISH in combination with immunofluorescence (smFISH-IF) and determined whether the association between an mRNA and binding protein(s) within a neuron was significant or accidental. We evaluated several mRNA-binding proteins identified from RNA pulldown assays to determine which of these exhibit bona fide interactions. Surprisingly, many known mRNA-binding proteins did not bind the mRNA in situ, indicating that adventitious interactions are significant using existing technology. This method provides an ability to evaluate two-color registration compatible with the scale of molecular interactions.

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KW - Super registration

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Imaging mRNA and protein interactions within neurons

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Keywords

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