@article {49117, title = {Atomic-level evidence for packing and positional amyloid polymorphism by segment from TDP-43 RRM2.}, journal = {Nature Structural \& Molecular Biology}, year = {2018}, month = {2018 Mar 12}, abstract = {

Proteins in the fibrous amyloid state are a major hallmark of neurodegenerative disease. Understanding the multiple conformations, or polymorphs, of amyloid proteins at the molecular level is a challenge of amyloid research. Here, we detail the wide range of polymorphs formed by a segment of human TAR DNA-binding protein 43 (TDP-43) as a model for the polymorphic capabilities of pathological amyloid aggregation. Using X-ray diffraction, microelectron diffraction (MicroED) and single-particle cryo-EM, we show that theDLIIKGISVHIsegment from the second RNA-recognition motif (RRM2) forms an array of amyloid polymorphs. These associations include seven distinct interfaces displaying five different symmetry classes of steric zippers. Additionally, we find that this segment can adopt three different backbone conformations that contribute to its polymorphic capabilities. The polymorphic nature of this segment illustrates at the molecular level how amyloid proteins can form diverse fibril structures.

}, issn = {1545-9985}, doi = {10.1038/s41594-018-0045-5}, author = {Guenther, Elizabeth L and Ge, Peng and Trinh, Hamilton and Sawaya, Michael R and Cascio, Duilio and Boyer, David R and Gonen, Tamir and Zhou, Z Hong and Eisenberg, David S} } @article {49006, title = {Sub-{\r a}ngstr{\"o}m cryo-EM structure of a prion protofibril reveals a polar clasp.}, journal = {Nature Structural \& Molecular Biology}, year = {2018}, month = {2018 Jan 15}, abstract = {

The atomic structure of the infectious, protease-resistant, β-sheet-rich and fibrillar mammalian prion remains unknown. Through the cryo-EM method MicroED, we reveal the sub-{\r a}ngstr{\"o}m-resolution structure of a protofibril formed by a wild-type segment from the β2-α2 loop of the bank vole prion protein. The structure of this protofibril reveals a stabilizing network of hydrogen bonds that link polar zippers within a sheet, producing motifs we have named {\textquoteright}polar clasps{\textquoteright}.

}, issn = {1545-9985}, doi = {10.1038/s41594-017-0018-0}, author = {Gallagher-Jones, Marcus and Glynn, Calina and Boyer, David R and Martynowycz, Michael W and Hernandez, Evelyn and Miao, Jennifer and Zee, Chih-Te and Novikova, Irina V and Goldschmidt, Lukasz and McFarlane, Heather T and Helguera, Gustavo F and Evans, James E and Sawaya, Michael R and Cascio, Duilio and Eisenberg, David S and Gonen, Tamir and Rodriguez, Jose A} } @article {48156, title = {Atomic structures of fibrillar segments of hIAPP suggest tightly mated β-sheets are important for cytotoxicity.}, journal = {eLife}, volume = {6}, year = {2017}, month = {2017 Jan 03}, abstract = {

hIAPP fibrils are associated with Type-II Diabetes, but the link of hIAPP structure to islet cell death remains elusive. Here we observe that hIAPP fibrils are cytotoxic to cultured pancreatic β-cells, leading us to determine the structure and cytotoxicity of protein segments composing the amyloid spine of hIAPP. Using the cryoEM method MicroED, we discover that one segment, 19-29 S20G, forms pairs of β-sheets mated by a dry interface that share structural features with and are similarly cytotoxic to full-length hIAPP fibrils. In contrast, a second segment, 15-25 WT, forms non-toxic labile β-sheets. These segments possess different structures and cytotoxic effects, however, both can seed full-length hIAPP, and cause hIAPP to take on the cytotoxic and structural features of that segment. These results suggest that protein segment structures represent polymorphs of their parent protein and that segment 19-29 S20G may serve as a model for the toxic spine of hIAPP.

}, issn = {2050-084X}, doi = {10.7554/eLife.19273}, author = {Krotee, Pascal and Rodriguez, Jose A and Sawaya, Michael R and Cascio, Duilio and Reyes, Francis E and Shi, Dan and Hattne, Johan and Nannenga, Brent L and Oskarsson, Marie E and Philipp, Stephan and Griner, Sarah and Jiang, Lin and Glabe, Charles G and Westermark, Gunilla T and Gonen, Tamir and Eisenberg, David S} } @article {48265, title = {Atomic-resolution structures from fragmented protein crystals with the cryoEM method MicroED.}, journal = {Nature Methods}, volume = {14}, year = {2017}, month = {2017 Feb 13}, pages = {399-402}, abstract = {

Traditionally, crystallographic analysis of macromolecules has depended on large, well-ordered crystals, which often require significant effort to obtain. Even sizable crystals sometimes suffer from pathologies that render them inappropriate for high-resolution structure determination. Here we show that fragmentation of large, imperfect crystals into microcrystals or nanocrystals can provide a simple path for high-resolution structure determination by the cryoEM method MicroED and potentially by serial femtosecond crystallography.

}, issn = {1548-7105}, doi = {10.1038/nmeth.4178}, author = {de la Cruz, M Jason and Hattne, Johan and Shi, Dan and Seidler, Paul and Rodriguez, Jose and Reyes, Francis E and Sawaya, Michael R and Cascio, Duilio and Weiss, Simon C and Kim, Sun Kyung and Hinck, Cynthia S and Hinck, Andrew P and Calero, Guillermo and Eisenberg, David and Gonen, Tamir} } @article {48991, title = {Common fibrillar spines of amyloid-β and human Islet Amyloid Polypeptide revealed by Micro Electron Diffraction and inhibitors developed using structure-based design.}, journal = {The Journal of Biological Chemistry}, volume = {293}, year = {2017}, month = {2017 Dec 27}, pages = {2888-902}, abstract = {

Amyloid-β (Aβ) and human islet amyloid polypeptide (hIAPP) aggregate to form amyloid fibrils that deposit in tissues, and are associated with Alzheimer{\textquoteright}s disease (AD) and Type-II Diabetes (T2D), respectively. Individuals with T2D have an increased risk of developing AD, and conversely, AD patients have an increased risk of developing T2D. Evidence suggests that this link between AD and T2D might originate from a structural similarity between aggregates of Aβ and hIAPP. Using the cryoEM method Micro-Electron Diffraction (MicroED) we determined the atomic structures of 11-residue segments from both Aβ and hIAPP, termed Aβ 24-34 WT and hIAPP 19-29 S20G, with 64\% sequence similarity. We observe a high degree of structural similarity between their backbone atoms (0.96 {\r A} RMSD). Moreover, fibrils of these segments induce amyloid formation through self- and cross-seeding. Furthermore, inhibitors designed for one segment show cross-efficacy for full-length Aβ and hIAPP and reduce cytotoxicity of both proteins, though by apparently blocking different cytotoxic mechanisms. The similarity of the atomic structures of Aβ 24-34 WT and hIAPP 19-29 S20G offers a molecular model for cross-seeding between Aβ and hIAPP.

}, issn = {1083-351X}, doi = {10.1074/jbc.M117.806109}, author = {Krotee, Pascal and Griner, Sarah L and Sawaya, Michael R and Cascio, Duilio and Rodriguez, Jose A and Shi, Dan and Philipp, Stephan and Murray, Kevin and Saelices, Lorena and Lee, Ji and Seidler, Paul and Glabe, Charles G and Jiang, Lin and Gonen, Tamir and Eisenberg, David S} } @article {48605, title = {Low-complexity domains adhere by reversible amyloid-like interactions between kinked β-sheets.}, journal = {bioRxiv}, year = {2017}, month = {2017 Jun 22}, abstract = {

Control of metabolism by compartmentation is a widespread feature of higher cells. Recent studies have focused on dynamic intracellular bodies such as stress granules, P-bodies, nucleoli, and metabolic puncta. These bodies appear as separate phases, some containing reversible, amyloid-like fibrils formed by interactions of low-complexity protein domains. Here we report five atomic structures of segments of low-complexity domains from granule-forming proteins, one determined to 1.1 {\r A} resolution by micro-electron diffraction. Four of these interacting protein segments show common characteristics, all in contrast to pathogenic amyloid: kinked peptide backbones, small surface areas of interaction, and predominate attractions between aromatic side-chains. By computationally threading the human proteome on three of our kinked structures, we identified hundreds of low-complexity segments potentially capable of forming such reversible interactions. These segments are found in proteins as diverse as RNA binders, nuclear pore proteins, keratins, and cornified envelope proteins, consistent with the capacity of cells to form a wide variety of dynamic intracellular bodies.

}, doi = {10.1101/153817}, author = {Hughes, Michael P and Sawaya, Michael R and Goldschmidt, Lukasz and Rodriguez, Jose A and Cascio, Duilio and Gonen, Tamir and Eisenberg, David S} } @article {48603, title = {MicroED structures from micrometer thick protein crystals.}, journal = {bioRxiv}, year = {2017}, month = {2017 Jun 20}, abstract = {

Theoretical calculations suggest that crystals exceeding 100 nm thickness are excluded by dynamical scattering from successful structure determination using microcrystal electron diffraction (MicroED). These calculations are at odds with experimental results where MicroED structures have been determined from significantly thicker crystals. Here we systematically evaluate the influence of thickness on the accuracy of MicroED intensities and the ability to determine structures from protein crystals one micrometer thick. To do so, we compare ab initio structures of a human prion protein segment determined from thin crystals to those determined from crystals up to one micrometer thick. We also compare molecular replacement solutions from crystals of varying thickness for a larger globular protein, proteinase K. Our results indicate that structures can be reliably determined from crystals at least an order of magnitude thicker than previously suggested by simulation, opening the possibility for an even broader range of MicroED experiments.

}, doi = {10.1101/152504}, author = {Martynowycz, Michael and Glynn, Calina and Miao, Jennifer and de la Cruz, Michael Jason and Hattne, Johan and Shi, Dan and Cascio, Duilio and Rodriguez, Jose and Gonen, Tamir} } @article {48958, title = {Structure-based inhibitors of tau aggregation.}, journal = {Nature Chemistry}, year = {2017}, month = {2017 Nov 20}, abstract = {

Aggregated tau protein is associated with over 20 neurological disorders, which include Alzheimer{\textquoteright}s disease. Previous work has shown that tau{\textquoteright}s sequence segments VQIINK and VQIVYK drive its aggregation, but inhibitors based on the structure of the VQIVYK segment only partially inhibit full-length tau aggregation and are ineffective at inhibiting seeding by full-length fibrils. Here we show that the VQIINK segment is the more powerful driver of tau aggregation. Two structures of this segment determined by the cryo-electron microscopy method micro-electron diffraction explain its dominant influence on tau aggregation. Of practical significance, the structures lead to the design of inhibitors that not only inhibit tau aggregation but also inhibit the ability of exogenous full-length tau fibrils to seed intracellular tau in HEK293 biosensor cells into amyloid. We also raise the possibility that the two VQIINK structures represent amyloid polymorphs of tau that may account for a subset of prion-like strains of tau.

}, doi = {10.1038/nchem.2889}, author = {Seidler, P M and Boyer, D R and Rodriguez, J A and Sawaya, Michael R and Cascio, Duilio and Murray, K and Gonen, Tamir and Eisenberg, David S} } @article {47875, title = {Ab initio structure determination from prion nanocrystals at atomic resolution by MicroED.}, journal = {Proceedings of the National Academy of Sciences of the United States of America}, volume = {113}, year = {2016}, month = {2016 Oct 04}, pages = {11232-6}, abstract = {

Electrons, because of their strong interaction with matter, produce high-resolution diffraction patterns from tiny 3D crystals only a few hundred nanometers thick in a frozen-hydrated state. This discovery offers the prospect of facile structure determination of complex biological macromolecules, which cannot be coaxed to form crystals large enough for conventional crystallography or cannot easily be produced in sufficient quantities. Two potential obstacles stand in the way. The first is a phenomenon known as dynamical scattering, in which multiple scattering events scramble the recorded electron diffraction intensities so that they are no longer informative of the crystallized molecule. The second obstacle is the lack of a proven means of de novo phase determination, as is required if the molecule crystallized is insufficiently similar to one that has been previously determined. We show with four structures of the amyloid core of the Sup35 prion protein that, if the diffraction resolution is high enough, sufficiently accurate phases can be obtained by direct methods with the cryo-EM method microelectron diffraction (MicroED), just as in X-ray diffraction. The success of these four experiments dispels the concern that dynamical scattering is an obstacle to ab initio phasing by MicroED and suggests that structures of novel macromolecules can also be determined by direct methods.

}, issn = {1091-6490}, doi = {10.1073/pnas.1606287113}, author = {Sawaya, Michael R and Rodriguez, Jose and Cascio, Duilio and Collazo, Michael J and Shi, Dan and Reyes, Francis E and Hattne, Johan and Gonen, Tamir and Eisenberg, David S} } @article {47711, title = {Accurate design of megadalton-scale two-component icosahedral protein complexes.}, journal = {Science (New York, N.Y.)}, volume = {353}, year = {2016}, month = {2016 Jul 22}, pages = {389-94}, abstract = {

Nature provides many examples of self- and co-assembling protein-based molecular machines, including icosahedral protein cages that serve as scaffolds, enzymes, and compartments for essential biochemical reactions and icosahedral virus capsids, which encapsidate and protect viral genomes and mediate entry into host cells. Inspired by these natural materials, we report the computational design and experimental characterization of co-assembling, two-component, 120-subunit icosahedral protein nanostructures with molecular weights (1.8 to 2.8 megadaltons) and dimensions (24 to 40 nanometers in diameter) comparable to those of small viral capsids. Electron microscopy, small-angle x-ray scattering, and x-ray crystallography show that 10 designs spanning three distinct icosahedral architectures form materials closely matching the design models. In vitro assembly of icosahedral complexes from independently purified components occurs rapidly, at rates comparable to those of viral capsids, and enables controlled packaging of molecular cargo through charge complementarity. The ability to design megadalton-scale materials with atomic-level accuracy and controllable assembly opens the door to a new generation of genetically programmable protein-based molecular machines.

}, issn = {1095-9203}, doi = {10.1126/science.aaf8818}, author = {Bale, Jacob B and Gonen, Shane and Liu, Yuxi and Sheffler, William and Ellis, Daniel and Thomas, Chantz and Cascio, Duilio and Yeates, Todd O and Gonen, Tamir and King, Neil P and Baker, David} } @article {46923, title = {Structure of a designed tetrahedral protein assembly variant engineered to have improved soluble expression.}, journal = {Protein Science}, volume = {24}, year = {2015}, month = {2015 Jul 15}, pages = {1695-701}, abstract = {

We recently reported the development of a computational method for the design of co-assembling, multi-component protein nanomaterials. While four such materials were validated at high-resolution by X-ray crystallography, low yield of soluble protein prevented X-ray structure determination of a fifth designed material, T33-09. Here we report the design and crystal structure of T33-31, a variant of T33-09 with improved soluble yield resulting from redesign efforts focused on mutating solvent-exposed side chains to charged amino acids. The structure is found to match the computational design model with atomic-level accuracy, providing further validation of the design approach and demonstrating a simple and potentially general means of improving the yield of designed protein nanomaterials. This article is protected by copyright. All rights reserved.

}, issn = {1469-896X}, doi = {10.1002/pro.2748}, author = {Bale, Jacob B and Park, Rachel U and Liu, Yuxi and Gonen, Shane and Gonen, Tamir and Cascio, Duilio and King, Neil P and Yeates, Todd O and Baker, David} } @article {47031, title = {Structure of the toxic core of α-synuclein from invisible crystals.}, journal = {Nature}, volume = {525}, year = {2015}, month = {2015 Sep 9}, pages = {486-90}, abstract = {

The protein α-synuclein is the main component of Lewy bodies, the neuron-associated aggregates seen in Parkinson disease and other neurodegenerative pathologies. An 11-residue segment, which we term NACore, appears to be responsible for amyloid formation and cytotoxicity of human α-synuclein. Here we describe crystals of NACore that have dimensions smaller than the wavelength of visible light and thus are invisible by optical microscopy. As the crystals are thousands of times too small for structure determination by synchrotron X-ray diffraction, we use micro-electron diffraction to determine the structure at atomic resolution. The 1.4 {\r A} resolution structure demonstrates that this method can determine previously unknown protein structures and here yields, to our knowledge, the highest resolution achieved by any cryo-electron microscopy method to date. The structure exhibits protofibrils built of pairs of face-to-face β-sheets. X-ray fibre diffraction patterns show the similarity of NACore to toxic fibrils of full-length α-synuclein. The NACore structure, together with that of a second segment, inspires a model for most of the ordered portion of the toxic, full-length α-synuclein fibril, presenting opportunities for the design of inhibitors of α-synuclein fibrils.

}, issn = {1476-4687}, doi = {10.1038/nature15368}, author = {Rodriguez, Jose A and Ivanova, Magdalena I and Sawaya, Michael R and Cascio, Duilio and Reyes, Francis E and Shi, Dan and Sangwan, Smriti and Guenther, Elizabeth L and Johnson, Lisa M and Zhang, Meng and Jiang, Lin and Arbing, Mark A and Nannenga, Brent L and Hattne, Johan and Whitelegge, Julian and Brewster, Aaron S and Messerschmidt, Marc and Boutet, S{\'e}bastien and Sauter, Nicholas K and Gonen, Tamir and Eisenberg, David S} }