In Situ Localization of N and C Termini of Subunits of the Flagellar Nexin-Dynein Regulatory Complex (N-DRC) Using SNAP Tag and Cryo-electron Tomography*

Background: Techniques to localize proteins in situ at high resolution are important but limited. Results: Combining SNAP tag technology with cryo-electron tomography, we precisely localized proteins within the N-DRC that are important for ciliary motility. Conclusion: The developed method was applied to localize proteins with ∼3 nm resolution without interfering with the complex function. Significance: The method is a powerful tool for studies of proteins in situ. Cryo-electron tomography (cryo-ET) has reached nanoscale resolution for in situ three-dimensional imaging of macromolecular complexes and organelles. Yet its current resolution is not sufficient to precisely localize or identify most proteins in situ; for example, the location and arrangement of components of the nexin-dynein regulatory complex (N-DRC), a key regulator of ciliary/flagellar motility that is conserved from algae to humans, have remained elusive despite many cryo-ET studies of cilia and flagella. Here, we developed an in situ localization method that combines cryo-ET/subtomogram averaging with the clonable SNAP tag, a widely used cell biological probe to visualize fusion proteins by fluorescence microscopy. Using this hybrid approach, we precisely determined the locations of the N and C termini of DRC3 and the C terminus of DRC4 within the three-dimensional structure of the N-DRC in Chlamydomonas flagella. Our data demonstrate that fusion of SNAP with target proteins allowed for protein localization with high efficiency and fidelity using SNAP-linked gold nanoparticles, without disrupting the native assembly, structure, or function of the flagella. After cryo-ET and subtomogram averaging, we localized DRC3 to the L1 projection of the nexin linker, which interacts directly with a dynein motor, whereas DRC4 was observed to stretch along the N-DRC base plate to the nexin linker. Application of the technique developed here to the N-DRC revealed new insights into the organization and regulatory mechanism of this complex, and provides a valuable tool for the structural dissection of macromolecular complexes in situ.

[1]  R. Levine,et al.  Cytochrome f and plastocyanin: their sequence in the photosynthetic electron transport chain of Chlamydomonas reinhardi. , 1965, Proceedings of the National Academy of Sciences of the United States of America.

[2]  D. Luck,et al.  Suppressor mutations in chlamydomonas reveal a regulatory mechanism for flagellar function , 1982, Cell.

[3]  G. Witman Isolation of Chlamydomonas flagella and flagellar axonemes. , 1986, Methods in enzymology.

[4]  M. Heel,et al.  Exact filters for general geometry three dimensional reconstruction , 1986 .

[5]  E. O'Toole,et al.  Components of a "dynein regulatory complex" are located at the junction between the radial spokes and the dynein arms in Chlamydomonas flagella , 1994, The Journal of cell biology.

[6]  L. Jarett,et al.  Electron microscopic visualization of insulin translocation into the cytoplasm and nuclei of intact H35 hepatoma cells using covalently linked Nanogold-insulin. , 1995, Endocrinology.

[7]  J R Kremer,et al.  Computer visualization of three-dimensional image data using IMOD. , 1996, Journal of structural biology.

[8]  P. Hegemann,et al.  A Streptomyces rimosus aphVIII gene coding for a new type phosphotransferase provides stable antibiotic resistance to Chlamydomonas reinhardtii. , 2001, Gene.

[9]  Peter Berthold,et al.  An engineered Streptomyces hygroscopicus aph 7" gene mediates dominant resistance against hygromycin B in Chlamydomonas reinhardtii. , 2002, Protist.

[10]  H. Vogel,et al.  A general method for the covalent labeling of fusion proteins with small molecules in vivo , 2003, Nature Biotechnology.

[11]  M. Porter,et al.  A subunit of the dynein regulatory complex in Chlamydomonas is a homologue of a growth arrest–specific gene product , 2003, The Journal of cell biology.

[12]  Conrad C. Huang,et al.  UCSF Chimera—A visualization system for exploratory research and analysis , 2004, J. Comput. Chem..

[13]  D. Mastronarde,et al.  New views of cells in 3D: an introduction to electron tomography. , 2005, Trends in cell biology.

[14]  David N Mastronarde,et al.  Automated electron microscope tomography using robust prediction of specimen movements. , 2005, Journal of structural biology.

[15]  Pinfen Yang,et al.  Dimeric novel HSP40 is incorporated into the radial spoke complex during the assembly process in flagella. , 2004, Molecular biology of the cell.

[16]  J. McIntosh,et al.  The Molecular Architecture of Axonemes Revealed by Cryoelectron Tomography , 2006, Science.

[17]  G. Murphy,et al.  Electron cryotomography sample preparation using the Vitrobot , 2006, Nature Protocols.

[18]  D. DeRosier,et al.  Concatenated metallothionein as a clonable gold label for electron microscopy. , 2007, Journal of structural biology.

[19]  A. Hoenger,et al.  Electron microscopy of microtubule-based cytoskeletal machinery. , 2007, Methods in cell biology.

[20]  E. Onelli,et al.  Clathrin-dependent and independent endocytic pathways in tobacco protoplasts revealed by labelling with charged nanogold , 2008, Journal of experimental botany.

[21]  D. Nicastro Cryo-electron microscope tomography to study axonemal organization. , 2009, Methods in cell biology.

[22]  S. Dutcher,et al.  Genetic and phenotypic analysis of flagellar assembly mutants in Chlamydomonas reinhardtii. , 2009, Methods in cell biology.

[23]  J. Fontana,et al.  Visualization of proteins in intact cells with a clonable tag for electron microscopy. , 2009, Journal of structural biology.

[24]  D. Nicastro,et al.  The dynein regulatory complex is the nexin link and a major regulatory node in cilia and flagella , 2009, The Journal of cell biology.

[25]  Ericka B. Ramko,et al.  A Genetically Encoded Tag for Correlated Light and Electron Microscopy of Intact Cells, Tissues, and Organisms , 2011, PLoS biology.

[26]  John M Heumann,et al.  Clustering and variance maps for cryo-electron tomography using wedge-masked differences. , 2011, Journal of structural biology.

[27]  G. Jensen,et al.  Electron tomography of cells , 2011, Quarterly Reviews of Biophysics.

[28]  D. Nicastro,et al.  Building Blocks of the Nexin-Dynein Regulatory Complex in Chlamydomonas Flagella* , 2011, The Journal of Biological Chemistry.

[29]  B. Engel,et al.  Structural Studies of Ciliary Components , 2012, Journal of molecular biology.

[30]  K. Bui,et al.  Polarity and asymmetry in the arrangement of dynein and related structures in the Chlamydomonas axoneme , 2012, Journal of Cell Biology.

[31]  W. Sale,et al.  The N-DRC forms a conserved biochemical complex that maintains outer doublet alignment and limits microtubule sliding in motile axonemes , 2013, Molecular biology of the cell.

[32]  S. Lindberg,et al.  The nexin-dynein regulatory complex subunit DRC1 is essential for motile cilia function in algae and humans , 2013, Nature Genetics.

[33]  M. Kikkawa,et al.  Novel structural labeling method using cryo-electron tomography and biotin-streptavidin system. , 2013, Journal of structural biology.

[34]  M. Rosenfeld,et al.  Zebrafish Ciliopathy Screen Plus Human Mutational Analysis Identifies C21orf59 and CCDC65 Defects as Causing Primary Ciliary Dyskinesia. , 2013, American journal of human genetics.

[35]  Kate S. Wilson,et al.  CCDC65 Mutation Causes Primary Ciliary Dyskinesia with Normal Ultrastructure and Hyperkinetic Cilia , 2013, PloS one.

[36]  Mason R. Mackey,et al.  Molecular Composition and Ultrastructure of the Caveolar Coat Complex , 2013, PLoS biology.

[37]  M. Kikkawa,et al.  Mechanosignaling between central apparatus and radial spokes controls axonemal dynein activity , 2014, The Journal of cell biology.

[38]  Ivan R. Corrêa Live-cell reporters for fluorescence imaging. , 2014, Current opinion in chemical biology.

[39]  M. Kikkawa,et al.  A molecular ruler determines the repeat length in eukaryotic cilia and flagella , 2014, Science.

[40]  K. Tan,et al.  A rapid SNAP-tag fluorogenic probe based on an environment-sensitive fluorophore for no-wash live cell imaging. , 2014, ACS chemical biology.

[41]  D. Nicastro,et al.  Insights into the Structure and Function of Ciliary and Flagellar Doublet Microtubules , 2014, The Journal of Biological Chemistry.

[42]  G. Pazour,et al.  NPHP4 controls ciliary trafficking of membrane proteins and large soluble proteins at the transition zone , 2014, Journal of Cell Science.

[43]  V. Subramaniam,et al.  Evaluation of fluorophores to label SNAP-tag fused proteins for multicolor single-molecule tracking microscopy in live cells. , 2014, Biophysical journal.

[44]  M. Kikkawa,et al.  Detailed structural and biochemical characterization of the nexin-dynein regulatory complex , 2015, Molecular biology of the cell.