Short Arginine Motifs Drive Protein Stickiness in the Escherichia coli Cytoplasm.

Although essential to numerous biotech applications, knowledge of molecular recognition by arginine-rich motifs in live cells remains limited. 1H,15N HSQC and 19F NMR spectroscopies were used to investigate the effects of C-terminal -GRn (n = 1-5) motifs on GB1 interactions in Escherichia coli cells and cell extracts. While the "biologically inert" GB1 yields high-quality in-cell spectra, the -GRn fusions with n = 4 or 5 were undetectable. This result suggests that a tetra-arginine motif is sufficient to drive interactions between a test protein and macromolecules in the E. coli cytoplasm. The inclusion of a 12 residue flexible linker between GB1 and the -GR5 motif did not improve detection of the "inert" domain. In contrast, all of the constructs were detectable in cell lysates and extracts, suggesting that the arginine-mediated complexes were weak. Together these data reveal the significance of weak interactions between short arginine-rich motifs and the E. coli cytoplasm and demonstrate the potential of such motifs to modify protein interactions in living cells. These interactions must be considered in the design of (in vivo) nanoscale assemblies that rely on arginine-rich sequences.

[1]  N. Dokholyan,et al.  Physicochemical code for quinary protein interactions in Escherichia coli , 2017, Proceedings of the National Academy of Sciences.

[2]  P. B. Crowley,et al.  Protein Dimerization on a Phosphonated Calix[6]arene Disc. , 2017, Angewandte Chemie.

[3]  Ciara Kyne,et al.  Protein charge determination and implications for interactions in cell extracts , 2017, Protein science : a publication of the Protein Society.

[4]  Diana M. Mitrea,et al.  C9orf72 Dipeptide Repeats Impair the Assembly, Dynamics, and Function of Membrane-Less Organelles , 2016, Cell.

[5]  Ciara Kyne,et al.  Grasping the nature of the cell interior: from Physiological Chemistry to Chemical Biology , 2016, The FEBS journal.

[6]  D. Liang,et al.  Assembly and Reassembly of Polyelectrolyte Complex Formed by Poly(ethylene glycol)-block-poly(glutamate sodium) and S5R4 Peptide , 2016 .

[7]  Vikas Nanda,et al.  Dissecting Electrostatic Contributions to Folding and Self-Assembly Using Designed Multicomponent Peptide Systems. , 2016, Journal of the American Chemical Society.

[8]  Christopher B. Stanley,et al.  Nucleophosmin integrates within the nucleolus via multi-modal interactions with proteins displaying R-rich linear motifs and rRNA , 2016, eLife.

[9]  C. Keating,et al.  Phosphorylation-mediated RNA/peptide complex coacervation as a model for intracellular liquid organelles. , 2016, Nature chemistry.

[10]  Philipp Selenko,et al.  Structural disorder of monomeric α-synuclein persists in mammalian cells , 2016, Nature.

[11]  G. Pielak,et al.  In-cell thermodynamics and a new role for protein surfaces , 2016, Proceedings of the National Academy of Sciences.

[12]  G. Pielak,et al.  Intracellular pH modulates quinary structure , 2015, Protein science : a publication of the Protein Society.

[13]  Peter Tompa,et al.  Polymer physics of intracellular phase transitions , 2015, Nature Physics.

[14]  David R. Liu,et al.  Discovery and characterization of a peptide that enhances endosomal escape of delivered proteins in vitro and in vivo. , 2015, Journal of the American Chemical Society.

[15]  A. Kanagaraj,et al.  Phase Separation by Low Complexity Domains Promotes Stress Granule Assembly and Drives Pathological Fibrillization , 2015, Cell.

[16]  J. Danielsson,et al.  Thermodynamics of protein destabilization in live cells , 2015, Proceedings of the National Academy of Sciences.

[17]  J. Szostak,et al.  Electrostatic Localization of RNA to Protocell Membranes by Cationic Hydrophobic Peptides , 2015, Angewandte Chemie.

[18]  L. Regan,et al.  Design of Protein-Peptide Interaction Modules for Assembling Supramolecular Structures in Vivo and in Vitro. , 2015, ACS chemical biology.

[19]  M. Kibbe,et al.  Shape-Dependent Targeting of Injured Blood Vessels by Peptide Amphiphile Supramolecular Nanostructures. , 2015, Small.

[20]  D. Woolfson,et al.  Functionalized α-Helical Peptide Hydrogels for Neural Tissue Engineering , 2015, ACS biomaterials science & engineering.

[21]  D. Burz,et al.  Probing protein quinary interactions by in-cell nuclear magnetic resonance spectroscopy. , 2015, Biochemistry.

[22]  A. Pastore,et al.  Selective observation of the disordered import signal of a globular protein by in-cell NMR: The example of frataxins , 2015, Protein science : a publication of the Protein Society.

[23]  Ciara Kyne,et al.  Specific ion effects on macromolecular interactions in Escherichia coli extracts , 2015, Protein science : a publication of the Protein Society.

[24]  Alanna Schepartz,et al.  Fluorescence correlation spectroscopy reveals highly efficient cytosolic delivery of certain penta-arg proteins and stapled peptides. , 2015, Journal of the American Chemical Society.

[25]  G. Pielak,et al.  Quinary structure modulates protein stability in cells , 2015, Proceedings of the National Academy of Sciences.

[26]  P. Uchil,et al.  Attachment of cell-binding ligands to arginine-rich cell-penetrating peptides enables cytosolic translocation of complexed siRNA. , 2015, Chemistry & biology.

[27]  Conggang Li,et al.  Strategies for protein NMR in Escherichia coli. , 2014, Biochemistry.

[28]  C. Luchinat,et al.  SSNMR of biosilica-entrapped enzymes permits an easy assessment of preservation of native conformation in atomic detail. , 2014, Chemical communications.

[29]  Gary J. Pielak,et al.  Impact of reconstituted cytosol on protein stability , 2013, Proceedings of the National Academy of Sciences.

[30]  Donata K. Kirchner,et al.  Molecular crowding drives active Pin1 into nonspecific complexes with endogenous proteins prior to substrate recognition. , 2013, Journal of the American Chemical Society.

[31]  L. Banci,et al.  Visualization of redox-controlled protein fold in living cells. , 2013, Chemistry & biology.

[32]  Ciara Kyne,et al.  Simple and inexpensive incorporation of 19F-tryptophan for protein NMR spectroscopy. , 2012, Chemical communications.

[33]  A. Schepartz,et al.  Arginine topology controls escape of minimally cationic proteins from early endosomes to the cytoplasm. , 2012, Chemistry & biology.

[34]  Lila M Gierasch,et al.  Exploring weak, transient protein--protein interactions in crowded in vivo environments by in-cell nuclear magnetic resonance spectroscopy. , 2011, Biochemistry.

[35]  Stephen Mann,et al.  Peptide-nucleotide microdroplets as a step towards a membrane-free protocell model. , 2011, Nature chemistry.

[36]  Borries Demeler,et al.  A postreductionist framework for protein biochemistry. , 2011, Nature chemical biology.

[37]  P. B. Crowley,et al.  Protein Interactions in the Escherichia coli Cytosol: An Impediment to In‐Cell NMR Spectroscopy , 2011, Chembiochem : a European journal of chemical biology.

[38]  Hidekazu Hiroaki,et al.  High-resolution multi-dimensional NMR spectroscopy of proteins in human cells , 2009, Nature.

[39]  D. Ehrnhoefer,et al.  EGCG redirects amyloidogenic polypeptides into unstructured, off-pathway oligomers , 2008, Nature Structural &Molecular Biology.

[40]  J. Janin,et al.  Protein–protein interaction and quaternary structure , 2008, Quarterly Reviews of Biophysics.

[41]  J. Ferrell,et al.  Investigating macromolecules inside cultured and injected cells by in-cell NMR spectroscopy , 2006, Nature Protocols.

[42]  Sara Linse,et al.  Salting the charged surface: pH and salt dependence of protein G B1 stability. , 2006, Biophysical journal.

[43]  D. Hilvert,et al.  A simple tagging system for protein encapsulation. , 2006, Journal of the American Chemical Society.

[44]  B. Poolman,et al.  Electrochemical structure of the crowded cytoplasm. , 2005, TIBS -Trends in Biochemical Sciences. Regular ed.

[45]  Wayne Boucher,et al.  The CCPN data model for NMR spectroscopy: Development of a software pipeline , 2005, Proteins.

[46]  Adel Golovin,et al.  Cation–π interactions in protein–protein interfaces , 2005 .

[47]  A. Gronenborn,et al.  Placement of 19F into the center of GB1: effects on structure and stability , 2002, FEBS letters.

[48]  P. V. van Zijl,et al.  Improved sensitivity of HSQC spectra of exchanging protons at short interscan delays using a new fast HSQC (FHSQC) detection scheme that avoids water saturation. , 1995, Journal of magnetic resonance. Series B.

[49]  A. Gronenborn,et al.  A novel, highly stable fold of the immunoglobulin binding domain of streptococcal protein G. , 1993, Science.

[50]  George M. Church,et al.  Comparing the predicted and observed properties of proteins encoded in the genome of Escherichia coli K‐12 , 1997, Electrophoresis.