5 research outputs found
Cooperative folding of intrinsically disordered domains drives assembly of a strong elongated protein.
Bacteria exploit surface proteins to adhere to other bacteria, surfaces and host cells. Such proteins need to project away from the bacterial surface and resist significant mechanical forces. SasG is a protein that forms extended fibrils on the surface of Staphylococcus aureus and promotes host adherence and biofilm formation. Here we show that although monomeric and lacking covalent cross-links, SasG maintains a highly extended conformation in solution. This extension is mediated through obligate folding cooperativity of the intrinsically disordered E domains that couple non-adjacent G5 domains thermodynamically, forming interfaces that are more stable than the domains themselves. Thus, counterintuitively, the elongation of the protein appears to be dependent on the inherent instability of its domains. The remarkable mechanical strength of SasG arises from tandemly arrayed 'clamp' motifs within the folded domains. Our findings reveal an elegant minimal solution for the assembly of monomeric mechano-resistant tethers of variable length.This research was supported by Biotechnology and Biological Research Council Grants BB/J006459/1 (D.T.G. and J.C.), BB/J005029/1 (F.W. and J.R.P), BB/G019452/1 (O.E.F and D.J.B) and BB/G020671/1 (C.G.B. and J.R.P.). H.K.H.F. is supported by a studentship from a Wellcome Trust 4-year PhD programme (WT095024MA). C.M.J. is supported by the German Federal Ministry of Education and Research (BMBF), grant BIOSCAT (contract N° 05K12YE1). J.C. is a Wellcome Trust Senior Research
Fellow (WT/095195). J.R.P holds a British Heart Foundation Senior Basic Science Fellowship (FS/12/36/29588). The authors acknowledge the use of EMBL SAXS beamline P12 at Petra-3 (DESY, Hamburg, Germany) and Maxim Petoukhov (EMBL) for providing a modified version of SASR EF. The research leading to these results has received funding from the European Community's Seventh Framework Programme (FP7/2007-2013) under BioStruct-X (grant agreement N°283570). The authors would like to thank Diamond Light Source for beamtime (proposal mx-7864) and Johan Turkenburg and Sam Hart for assistance with crystal testing and data collection.This is the final version of the article. It first appeared from NPG via http://dx.doi.org/10.1038/ncomms827
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Insights into a viral motor: the structure of the HK97 packaging termination assembly.
Acknowledgements: The authors would like to thank J. Turkenburg, S. Hart and J.N. Blaza for assistance in cryo-electron microscopy at York and K.L. Morris for data collection assistance at eBIC, M. Chechik for assistance in protein production and Hesketh E.L., Thompson R.F. and Maskell D.P. for collection of additional data sets and help with processing. Bacterial strains and HK97 mutant strains used in procapsid production were provided by R.L. Duda. We thank R.L. Duda and P.J. Jardine for helpful discussion and assistance in setting up the HK97 packaging system. We are grateful for computational support from the University of York High Performance Computing service, Viking, and the Research Computing team. This work was supported by Diamond Light Source, access to eBIC under proposal EM19832 funded by the Wellcome Trust, MRC and BBRSC. Molecular graphics and analyses were performed with UCSF ChimeraX, developed by the Resource for Biocomputing, Visualization, and Informatics at the University of California, San Francisco, with support from National Institutes of Health R01-GM129325 and the Office of Cyber Infrastructure and Computational Biology, National Institute of Allergy and Infectious Diseases.Double-stranded DNA viruses utilise machinery, made of terminase proteins, to package viral DNA into the capsid. For cos bacteriophage, a defined signal, recognised by small terminase, flanks each genome unit. Here we present the first structural data for a cos virus DNA packaging motor, assembled from the bacteriophage HK97 terminase proteins, procapsids encompassing the portal protein, and DNA containing a cos site. The cryo-EM structure is consistent with the packaging termination state adopted after DNA cleavage, with DNA density within the large terminase assembly ending abruptly at the portal protein entrance. Retention of the large terminase complex after cleavage of the short DNA substrate suggests that motor dissociation from the capsid requires headful pressure, in common with pac viruses. Interestingly, the clip domain of the 12-subunit portal protein does not adhere to C12 symmetry, indicating asymmetry induced by binding of the large terminase/DNA. The motor assembly is also highly asymmetric, showing a ring of 5 large terminase monomers, tilted against the portal. Variable degrees of extension between N- and C-terminal domains of individual subunits suggest a mechanism of DNA translocation driven by inter-domain contraction and relaxation