Your search keyword '"Edward H. Snell"' showing total 25 results

1. Structural consequences of transforming growth factor beta-1 activation from near-therapeutic X-ray doses

Author

Thomas D. Grant, Timothy R. Stachowski, and Edward H. Snell

Subjects

Nuclear and High Energy Physics, Protein Conformation, Peptide, Biochemistry, Transforming Growth Factor beta1, Inorganic Chemistry, 03 medical and health sciences, 0302 clinical medicine, X-Ray Diffraction, Transforming Growth Factor beta, Structural Biology, Scattering, Small Angle, Radiation damage, Humans, General Materials Science, Irradiation, Protein Precursors, Physical and Theoretical Chemistry, Radiation Damage, Instrumentation, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Potential impact, Radiation, biology, Small-angle X-ray scattering, X-Rays, X-ray, Dose-Response Relationship, Radiation, Transforming growth factor beta, Condensed Matter Physics, chemistry, 030220 oncology & carcinogenesis, Biophysics, biology.protein, Peptides, Transforming growth factor

Abstract

Dissociation of transforming growth factor beta-1 (TGFβ-1) from the inhibitory protein latency-associated peptide (LAP) can occur from low doses of X-ray irradiation of the LAP–TGFβ-1 complex, resulting in the activation of TGFβ-1, and can have health-related consequences. Using the tools and knowledge developed in the study of radiation damage in the crystallographic setting, small-angle X-ray scattering (SAXS) and complementary techniques suggest an activation process that is initiated but not driven by the initial X-ray exposure. LAP is revealed to be extended when not bound to TGFβ-1 and has a different structural conformation compared to the bound state. These studies pave the way for the structural understanding of systems impacted at therapeutic X-ray doses and show the potential impact of radiation damage studies beyond their original intent.

Published

2019

2. Near-physiological-temperature serial crystallography reveals conformations of SARS-CoV-2 main protease active site for improved drug repurposing

Author

Gunseli Yildirim, Alaleh Shafiei, Oleksandr Yefanov, Hasan DeMirci, Frédéric Poitevin, Timucin Avsar, Chun Hong Yoon, Muge Didem Orhan, Merve Yigin, Lalehan Oktay, Fulya Aksit, Çağdaş Dağ, Serdar Durdagi, Christopher Kupitz, Omur Guven, Valerio Mariani, Ece Erdemoglu, Ebru Destan, Edward H. Snell, Ismail Erol, Mark S. Hunter, Esra Ayan, Berna Dogan, Mengning Liang, Busecan Aksoydan, A. Batyuk, Ozgur Can, Cengizhan Buyukdag, Sabri O. Besler, Seyma Calis, Brandon Hayes, Matthew Seaberg, Serena Ozabrahamyan, Ilayda Tolu, Gihan K. Ketawala, Anton Barty, Raymond G. Sierra, Kader Sahin, Gokhan Tanisali, Oktay Gocenler, Ali D. Yucel, E. Han Dao, Alpsu Olkan, Ayse B. Peksen, Zhen Su, A. Tolstikova, Sabine Botha, Busra Yuksel, Fatma Betul Ertem, Demirci, Hasan (ORCID 0000-0002-9135-5397 & YÖK ID 307350), Dağ, Çağdaş, Yığın, Merve, Büyükdağ, Cengizhan, Ertem, Fatma Betül, Yıldırım, Günseli, Destan, Ebru, Güven, Ömür, Ayan, Esra, Yüksel, Büşra, Pekşen, Ayşe Buket, Göçenler, Oktay, Yücel, Ali Doğa, Can, Özgür, Ozabrahamyan, Serena, Shafiei, Alaleh, Akşit, Fulya, Tanısalı, Gökhan, Besler, Sabri Özkan, Durdağı, Serdar, Doğan, Berna, Avşar, Timuçin, Erol, İsmail, Çalış, Şeyma, Orhan, Müge D., Aksoydan, Busecan, Şahin, Kader, Oktay, Lalehan, Tolu, İlayda, Olkan, Alpsu, Erdemoğlu, Ece, Yefanov, Oleksandr M., Dao, E. Han, Hayes, Brandon, Liang, Mengning, Seaberg, Matthew H., Hunter, Mark S., Batyuk, Alex, Mariani, Valerio, Su, Zhen, Poitevin, Frederic, Yoon, Chun Hong, Kupitz, Christopher, Sierra, Raymond G., Snell, Edward H., Koç Üniversitesi İş Bankası Enfeksiyon Hastalıkları Uygulama ve Araştırma Merkezi (EHAM) / Koç University İşbank Center for Infectious Diseases (KU-IS CID), College of Sciences, Graduate School of Sciences and Engineering, School of Nursing, Department of Molecular Biology and Genetics, Department of Chemical and Biological Engineering, and Department of Materials Science and Engineering

Subjects

Drug, Molecular model, Protein Conformation, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), media_common.quotation_subject, medicine.medical_treatment, ambient temperature, Molecular Conformation, Crystallography, X-Ray, Article, Structural Biology, Catalytic Domain, medicine, SFX, Computer Simulation, Molecular Biology, Coronavirus 3C Proteases, media_common, Principal Component Analysis, Protease, Biochemistry and molecular biology, Biophysics, Cell biology, biology, drug repurposing, Drug discovery, SARS-CoV-2, Drug Repositioning, Temperature, Active site, Small molecule, Recombinant Proteins, COVID-19 Drug Treatment, Molecular Docking Simulation, Drug repositioning, Crystallography, main protease, Drug Design, ddc:540, biology.protein, Dimerization, Ambient temperature, Drug repurposing, Main protease

Abstract

The COVID-19 pandemic has resulted in 198 million reported infections and more than 4 million deaths as of July 2021 (covid19.who.int). Research to identify effective therapies for COVID-19 includes: (1) designing a vaccine as future protection; (2) de novo drug discovery; and (3) identifying existing drugs to repurpose them as effective and immediate treatments. To assist in drug repurposing and design, we determine two apo structures of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) main protease at ambient temperature by serial femtosecond X-ray crystallography. We employ detailed molecular simulations of selected known main protease inhibitors with the structures and compare binding modes and energies. The combined structural and molecular modeling studies not only reveal the dynamics of small molecules targeting the main protease but also provide invaluable opportunities for drug repurposing and structure-based drug design strategies against SARS-CoV-2., Graphical abstract, Durdağı et al. represent radiation damage-free high-resolution SARS-CoV-2 main protease SFX structures obtained at near-physiological temperature and performed MD simulation of apo-form proteins and three known main protease inhibitors. The structures reveal alternate conformation, while MD simulation indicates asymmetric behavior of the protein, which is invaluable information for immediate drug-repurposing studies.

Published

2021

3. Structural insights into conformational switching in latency-associated peptide between transforming growth factor β-1 bound and unbound states

Author

Mary E. Snell, Timothy R. Stachowski, and Edward H. Snell

Subjects

Steric effects, Conformational change, Glycan, TGFβ-1, Peptide, Biochemistry, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, growth factors, structural biology, General Materials Science, lcsh:Science, TGF beta 1, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, Chemistry, digestive, oral, and skin physiology, General Chemistry, Condensed Matter Physics, Research Papers, Structural biology, transforming growth factor β-1, biology.protein, Biophysics, Recombinant DNA, lcsh:Q, latency-associated peptide, 030217 neurology & neurosurgery, Transforming growth factor

Abstract

Analysis of crystallographic, solution scattering and biochemical experiments suggests a mechanism for the sequestration of transforming growth factor β-1 by latency-associated peptide (LAP) that includes a structural change in LAP from an open to a closed conformation. This mechanism contains several potential regulatory features that are exploitable for therapeutic development., Transforming growth factor β-1 (TGFβ-1) is a secreted signalling protein that directs many cellular processes and is an attractive target for the treatment of several diseases. The primary endogenous activity regulatory mechanism for TGFβ-1 is sequestration by its pro-peptide, latency-associated peptide (LAP), which sterically prohibits receptor binding by caging TGFβ-1. As such, recombinant LAP is promising as a protein-based therapeutic for modulating TGFβ-1 activity; however, the mechanism of binding is incompletely understood. Comparison of the crystal structure of unbound LAP (solved here to 3.5 Å resolution) with that of the bound complex shows that LAP is in a more open and extended conformation when unbound to TGFβ-1. Analysis suggests a mechanism of binding TGFβ-1 through a large-scale conformational change that includes contraction of the inter-monomer interface and caging by the ‘straight-jacket’ domain that may occur in partnership through a loop-to-helix transition in the core jelly-roll fold. This conformational change does not appear to include a repositioning of the integrin-binding motif as previously proposed. X-ray scattering-based modelling supports this mechanism and reveals possible orientations and ensembles in solution. Although native LAP is heavily glycosylated, solution scattering experiments show that the overall folding and flexibility of unbound LAP are not influenced by glycan modification. The combination of crystallography, solution scattering and biochemical experiments reported here provide insight into the mechanism of LAP sequestration of TGFβ-1 that is of fundamental importance for therapeutic development.

Published

2019

4. SAXS studies of X-ray induced disulfide bond damage: Engineering high-resolution insight from a low-resolution technique

Author

Edward H. Snell, Timothy R. Stachowski, and Mary E. Snell

Subjects

Models, Molecular, Protein Conformation, Dimer, Crystallography, X-Ray, Protein Engineering, Biochemistry, Small-Angle Scattering, Scattering, chemistry.chemical_compound, Protein structure, Disulfides, Post-Translational Modification, Materials, Crystallography, Multidisciplinary, Small-angle X-ray scattering, Physics, Monomers, Condensed Matter Physics, Chemistry, Monomer, Physical Sciences, X-ray crystallography, Crystal Structure, Crystallographic Techniques, Medicine, Disulfide Bonds, Small-angle scattering, Research Article, Materials science, Free Radicals, Macromolecular Substances, Science, Materials Science, X-Ray Crystallography, Structural Characterization, Singular Value Decomposition, Research and Analysis Methods, Crystals, Scattering, Small Angle, Radiation damage, Solid State Physics, Dimers, X-Rays, Biology and Life Sciences, Proteins, Protein engineering, Polymer Chemistry, Algebra, Linear Algebra, chemistry, Oligomers, Biophysics, Mathematics

Abstract

A significant problem in biological X-ray crystallography is the radiation chemistry caused by the incident X-ray beam. This produces both global and site-specific damage. Site specific damage can misdirect the biological interpretation of the structural models produced. Cryo-cooling crystals has been successful in mitigating damage but not eliminating it altogether; however, cryo-cooling can be difficult in some cases and has also been shown to limit functionally relevant protein conformations. The doses used for X-ray crystallography are typically in the kilo-gray to mega-gray range. While disulfide bonds are among the most significantly affected species in proteins in the crystalline state at both cryogenic and higher temperatures, there is limited information on their response to low X-ray doses in solution, the details of which might inform biomedical applications of X-rays. In this work we engineered a protein that dimerizes through a susceptible disulfide bond to relate the radiation damage processes seen in cryo-cooled crystals to those closer to physiologic conditions. This approach enables a low-resolution technique, small angle X-ray scattering (SAXS), to detect and monitor a residue specific process. A dose dependent fragmentation of the engineered protein was seen that can be explained by a dimer to monomer transition through disulfide bond cleavage. This supports the crystallographically derived mechanism and demonstrates that results obtained crystallographically can be usefully extrapolated to physiologic conditions. Fragmentation was influenced by pH and the conformation of the dimer, providing information on mechanism and pointing to future routes for investigation and potential mitigation. The novel engineered protein approach to generate a large-scale change through a site-specific interaction represents a promising tool for advancing radiation damage studies under solution conditions.

Published

2020

5. Identifying, studying and making good use of macromolecular crystals

Author

Edward H. Snell, Joseph R. Luft, Guillermo Calero, Janet Newman, and Aina E. Cohen

Subjects

business.industry, Computer science, Macromolecular Substances, Scale (chemistry), crystal growth, Biophysics, Visible radiation, computer.file_format, Condensed Matter Physics, Protein Data Bank, crystal positioning, Crystallography, X-Ray, Biochemistry, Data science, Crystal, Optics, IYCr crystallization series, Structural biology, Structural Biology, Genetics, crystal detection, business, Crystallization, computer

Abstract

As technology advances, the crystal volume that can be used to collect useful X-ray diffraction data decreases. The technologies available to detect and study growing crystals beyond the optical resolution limit and methods to successfully place the crystal into the X-ray beam are discussed., Structural biology has contributed tremendous knowledge to the understanding of life on the molecular scale. The Protein Data Bank, a depository of this structural knowledge, currently contains over 100 000 protein structures, with the majority stemming from X-ray crystallography. As the name might suggest, crystallography requires crystals. As detectors become more sensitive and X-ray sources more intense, the notion of a crystal is gradually changing from one large enough to embellish expensive jewellery to objects that have external dimensions of the order of the wavelength of visible light. Identifying these crystals is a prerequisite to their study. This paper discusses developments in identifying these crystals during crystallization screening and distinguishing them from other potential outcomes. The practical aspects of ensuring that once a crystal is identified it can then be positioned in the X-ray beam for data collection are also addressed.

Published

2014

6. Structural studies on low-dose X-ray radiation induced transforming growth factor beta-1 (TGFβ-1) activation

Author

Timothy R. Stachowski, Thomas D. Grant, and Edward H. Snell

Subjects

biology, Chemistry, Low dose, X-ray, Radiation induced, Transforming growth factor beta, Condensed Matter Physics, Biochemistry, Inorganic Chemistry, Structural Biology, Biophysics, biology.protein, General Materials Science, Physical and Theoretical Chemistry

Published

2019

7. Structural knowledge or X-ray damage? Dose-dependent case studies on xylose isomerase revealing structural perturbations

Author

Helena Taberman, Edward H. Snell, M. van der Woerd, Charles S. Bury, and Elspeth F. Garman

Subjects

Inorganic Chemistry, Xylose isomerase, Structural Biology, Chemistry, X-ray, Dose dependence, Biophysics, General Materials Science, Physical and Theoretical Chemistry, Condensed Matter Physics, Biochemistry

Published

2019

8. Moving in the Right Direction: Protein Vibrational Steering Function

Author

Katherine A. Niessen, Mengyang Xu, Andrea Markelz, Edward H. Snell, Alessandro Paciaroni, and Andrea Orecchini

Subjects

0301 basic medicine, Terahertz radiation, Protein Conformation, Entropy, Movement, Biophysics, 02 engineering and technology, Inelastic scattering, Molecular Dynamics Simulation, Molecular physics, Vibration, 03 medical and health sciences, Molecular dynamics, Protein structure, chemistry entropy metabolism molecular dynamics movement (physiology) protein conformation vibration, Directionality, Physics::Chemical Physics, Anisotropy, Quantitative Biology::Biomolecules, Chemistry, Protein dynamics, Correction, 021001 nanoscience & nanotechnology, Crystallography, 030104 developmental biology, Muramidase, 0210 nano-technology

Abstract

Nearly all protein functions require structural change, such as enzymes clamping onto substrates, and ion channels opening and closing. These motions are a target for possible new therapies; however, the control mechanisms are under debate. Calculations have indicated protein vibrations enable structural change. However, previous measurements found these vibrations only weakly depend on the functional state. By using the novel technique of anisotropic terahertz microscopy, we find that there is a dramatic change to the vibrational directionality with inhibitor binding to lysozyme, whereas the vibrational energy distribution, as measured by neutron inelastic scattering, is only slightly altered. The anisotropic terahertz measurements provide unique access to the directionality of the intramolecular vibrations, and immediately resolve the inconsistency between calculations and previous measurements, which were only sensitive to the energy distribution. The biological importance of the vibrational directions versus the energy distribution is revealed by our calculations comparing wild-type lysozyme with a higher catalytic rate double deletion mutant. The vibrational energy distribution is identical, but the more efficient mutant shows an obvious reorientation of motions. These results show that it is essential to characterize the directionality of motion to understand and control protein dynamics to optimize or inhibit function.

Published

2017

9. The Effect of the Protein Dynamical Transition on Intramolecular Vibrations

Author

Mengyang Xu, Katherine A. Niessen, Yanting Deng, Nigel S. Michki, Andrea Markelz, and Edward H. Snell

Subjects

Crystallography, Range (particle radiation), Terahertz radiation, Chemistry, Intramolecular force, Anharmonicity, Biophysics, Molecule, Neutron scattering, Spectroscopy, Absorption (electromagnetic radiation), Molecular physics

Abstract

Protein structural motion is necessary for function. A typical measure of protein flexibility is the average mean squared atomic displacement (MSD). Both X-ray and neutron scattering have found a strong increase in the MSD at 200-220 K for a number of proteins. This increase is often referred to as the dynamical transition (DT) [1]. Function ceases for many proteins below the DT. It was suggested that the DT indicated the temperature at which the motions necessary for function are frozen out. A question has been raised as to how long-range motions are affected by the transition. Specifically, would the long-range intramolecular vibrations associated with conformational changes be present at low frequencies, and then at higher temperatures red shift due to anharmonicity, as is seen in conventional solids? The different DT measurement techniques do not distinguish between local particle excitations and coherent long-range motions. Direct optical measurement of the long-range intramolecular vibrations requires spectroscopy within the energy range of 1-100 cm−1 (ν = 0.03-3 THz). Our recently developed technique, CATM (Crystal Anisotropy Terahertz Microscopy) [2], uses polarization dependent absorption on aligned molecules to isolate the long-range intramolecular vibrations from the local excitations. Temperature dependent CATM from 180K to 295K is used to investigate how the DT effects long-range vibrations. We find that a sharp 70 cm-1 band grows in as the temperature increases. We suggest that this new band above DT demonstrates that in fact the surrounding solvent acts as a frozen cage preventing long-range correlated motions, and as the surrounding solvent becomes more mobile, the large-scale motions necessary for function can occur.1.Doster, W., et al. Physical Review Letters, 2010. 104(9): p. 098101.2.Acbas, G., et al. Nature Communications, 2014. 5, 3076 http://dx.doi.org/10.1038/ncomms4076.

Published

2016

10. On the need for an international effort to capture, share and use crystallization screening data

Author

Edward H. Snell, David Ratcliffe, Joseph R. Luft, Kerry Taylor, D. Travis Gallagher, Pascal Vallotton, Thomas S. Peat, Janet Newman, Frank von Delft, Jochen Müller-Dieckmann, Evan E Bolton, Roger A. Sayle, David Lovell, Sameer Velanker, and Vincent J. Fazio

Subjects

Process (engineering), Computer science, Biophysics, Ontology (information science), Crystallography, X-Ray, 010402 general chemistry, Bioinformatics, 01 natural sciences, Biochemistry, law.invention, 03 medical and health sciences, Structural Biology, law, Genetics, Crystallization, 030304 developmental biology, crystallization screening data, 0303 health sciences, Condensed Matter Physics, Data science, Scientific Comment, 0104 chemical sciences, ComputingMilieux_GENERAL, crystallization ontology, Disparate system, Data exchange

Abstract

Development of an ontology for the description of crystallization experiments and results is proposed., When crystallization screening is conducted many outcomes are observed but typically the only trial recorded in the literature is the condition that yielded the crystal(s) used for subsequent diffraction studies. The initial hit that was optimized and the results of all the other trials are lost. These missing results contain information that would be useful for an improved general understanding of crystallization. This paper provides a report of a crystallization data exchange (XDX) workshop organized by several international large-scale crystallization screening laboratories to discuss how this information may be captured and utilized. A group that administers a significant fraction of the world’s crystallization screening results was convened, together with chemical and structural data informaticians and computational scientists who specialize in creating and analysing large disparate data sets. The development of a crystallization ontology for the crystallization community was proposed. This paper (by the attendees of the workshop) provides the thoughts and rationale leading to this conclusion. This is brought to the attention of the wider audience of crystallographers so that they are aware of these early efforts and can contribute to the process going forward.

Published

2012

11. Computational Crystallization

Author

Edward H. Snell, Irem Altan, and Patrick Charbonneau

Subjects

Models, Molecular, 0301 basic medicine, Protein Conformation, Computer science, Biophysics, Binary number, 02 engineering and technology, Biochemistry, Article, Field (computer science), law.invention, Crystal (programming language), 03 medical and health sciences, law, Computer Simulation, Crystallization, Molecular Biology, Structure (mathematical logic), Crystallography, Proteins, Biomolecules (q-bio.BM), 021001 nanoscience & nanotechnology, Trial and error, 030104 developmental biology, Quantitative Biology - Biomolecules, Scientific method, FOS: Biological sciences, Key (cryptography), 0210 nano-technology, Algorithm

Abstract

Crystallization is a key step in macromolecular structure determination by crystallography. While a robust theoretical treatment of the process is available, due to the complexity of the system, the experimental process is still largely one of trial and error. In this article, efforts in the field are discussed together with a theoretical underpinning using a solubility phase diagram. Prior knowledge has been used to develop tools that computationally predict the crystallization outcome and define mutational approaches that enhance the likelihood of crystallization. For the most part these tools are based on binary outcomes (crystal or no crystal), and the full information contained in an assembly of crystallization screening experiments is lost. The potential of this additional information is illustrated by examples where new biological knowledge can be obtained and where a target can be sub-categorized to predict which class of reagents provides the crystallization driving force. Computational analysis of crystallization requires complete and correctly formatted data. While massive crystallization screening efforts are under way, the data available from many of these studies are sparse. The potential for this data and the steps needed to realize this potential are discussed., Comment: 9 pages, 3 figures

Published

2015

12. FRET, SAXS and Molecular Simulations Resolve the Solution Structures of Three Coexisting Conformers of Flexible RNA Four-Way Junction

Author

Danilo Springstubbe, Tomasz Soltynski, Claus A. M. Seidel, Simon Sindbert, Stanislav Kalinin, Thomas D. Grant, Bettina Apel, Jan Lipfert, Grzegorz Lach, Christian A. Hanke, Edward H. Snell, Sabine Müller, Janusz M. Bujnicki, Holger Gohlke, and Hayk Vardanyan

Subjects

Crystallography, Förster resonance energy transfer, Chemistry, Small-angle X-ray scattering, Biophysics, RNA, Solution structure, Conformational isomerism

Published

2017

13. Importance of Protein Vibration Directionality on Function

Author

Katherine A. Niessen, Edward H. Snell, Andrea Markelz, Yanting Deng, and Mengyang Xu

Subjects

biology, Chemistry, Biophysics, Active site, Neutron scattering, Molecular physics, Spectral line, Crystallography, Normal mode, Intramolecular force, biology.protein, Directionality, Absorption (electromagnetic radiation), Anisotropy

Abstract

Global protein vibrations have long been associated with protein functionality. Long-range intramolecular vibrations have been measured in proteins using anisotropic absorption in the terahertz frequency range [1,2]. These measurements directly correspond to the directionality of vibrations and show large changes in the directionality of the vibrational displacements for free chicken egg white lysozyme (CEWL) and inhibitor bound CEWL. Normal mode ensemble analysis (NMEA) and quasiharmonic analysis (QHA) calculations of the free and tri-acetylglucosamine (3NAG) bound CEWL dynamics were performed and also show large changes in vibration directionality with binding. This in spite of the calculated energy distribution showing very little change, in agreement with neutron scattering measurements. We investigate the importance of the protein directionality by extending the calculations to a double deletion mutant (DD CEWL) with an activity rate 1.4 times that of WT [3]. The deletions are far from the active site, indicating that the increased activity arises from changes in the dynamics. The calculated anisotropic spectra show large changes with mutation, whereas the energy distribution show practically no change from the WT. Similarities in the bound WT, free DD, and bound DD CEWL NMEA spectra indicate the mutation may be changing the directionality of the vibrations toward more efficient motions. Projections of the low frequency vibrations, from QHA, on the functional displacement show higher overlap of residues around Glu35 and Asp52 in the mutant system. These residues are known to be critical in CEWL functionality. The results reveal that the mutation may be steering the protein toward more functional dynamics without significantly affecting the energy distribution. [1] K.A. Niessen, et al. (2015) DOI: 10.1007/s12551-015-0168-4[2] G. Acbas, et al. (2014) DOI: 10.1038/ncomms4076[3] S. Mine, et al. (1999) DOI: 10.1006/jmbi.1999.2572. Supported by NSF (DBI 1556359, MCB 1616529) and DOE (DE-SC0016317).

Published

2017

14. Crystallization screening: the influence of history on current practice

Author

Janet Newman, Joseph R. Luft, and Edward H. Snell

Subjects

Materials science, Biophysics, Nanotechnology, Crystallography, X-Ray, Biochemistry, History, 21st Century, Phase Transition, law.invention, Diffusion, Structural Biology, law, Genetics, Animals, Humans, Crystallization, Bacteria, Proteins, crystallization screening, History, 20th Century, Condensed Matter Physics, Crystallography, IYCr crystallization series, Current practice, Scientific method, Volatilization

Abstract

The rich history of crystallization and how that history influences current practices is described. The tremendous impact of crystallization screens on the field is discussed., While crystallization historically predates crystallography, it is a critical step for the crystallographic process. The rich history of crystallization and how that history influences current practices is described. The tremendous impact of crystallization screens on the field is discussed.

Published

2014

15. Long-Range Correlated Motion Changes with Protein-Ligand Binding

Author

Andrea Markelz, Mengyang Xu, Katherine A. Niessen, and Edward H. Snell

Subjects

Crystallography, Tetragonal crystal system, Molecular dynamics, Chemistry, Phonon, Molecular vibration, Intramolecular force, Biophysics, Protein crystallization, Molecular physics, Spectral line, Protein ligand

Abstract

Molecular dynamics calculations have long predicted large scale protein structural vibrations lie in the terahertz (THz) frequency range (5-100 cm−1), and these vibrations are related to protein function. Measuring these vibrational modes has been challenged by the large glass-like contribution from solvent and side chain librational motions. We remove this isotropic background, using anisotropic THz near field microscopy measurements of protein crystals. The technique reveals for the first time narrow band protein excitations in this frequency range. To determine if these features arise from the internal molecular motions, we measured ligand binding dependence using a faster data acquisition technique. The measurements performed on tetragonal chicken-egg white lysozyme (CEWL) single crystals and tetragonal CEWL tri-N-acetylglucosamine inhibitor bound crystals (CEWL+3NAG) show reproducible spectra that change dramatically with inhibitor binding. The large shifts observed indicate the features arise from the protein intramolecular motions and not from crystal phonons, which would have frequency shifts of only ≤ 2% with binding. The results validate that the technique can be used to determine ligand binding for inhibitor screening and to understand the role of intramolecular motions in protein function. This work supported by NSF MRI∧2 grant DBI295998.View Large Image | View Hi-Res Image | Download PowerPoint Slide

Published

2014

16. Statistical analysis of crystallization database links protein physico-chemical features with crystallization mechanisms

Author

Patrick Charbonneau, Edward H. Snell, Andrew E. Bruno, Sayan Mukherjee, Joseph R. Luft, Diana Fusco, Timothy J. Barnum, Massachusetts Institute of Technology. Department of Chemistry, and Barnum, Timothy James

Subjects

Proteomics, Biophysics, lcsh:Medicine, Bioinformatics, Crystallography, X-Ray, Biochemistry, Physical Chemistry, Structural genomics, law.invention, Computational Chemistry, X ray methods, law, Statistical analysis, Crystallization, lcsh:Science, Databases, Protein, Multidisciplinary, Chemical Physics, Chemistry, Extramural, lcsh:R, Biology and Life Sciences, Computational Biology, Proteins, Statistical model, Biomolecules (q-bio.BM), 3. Good health, Models, Chemical, Quantitative Biology - Biomolecules, FOS: Biological sciences, Physical Sciences, lcsh:Q, Biological system, Research Article

Abstract

X-ray crystallography is the predominant method for obtaining atomic-scale information about biological macromolecules. Despite the success of the technique, obtaining well diffracting crystals still critically limits going from protein to structure. In practice, the crystallization process proceeds through knowledge-informed empiricism. Better physico-chemical understanding remains elusive because of the large number of variables involved, hence little guidance is available to systematically identify solution conditions that promote crystallization. To help determine relationships between macromolecular properties and their crystallization propensity, we have trained statistical models on samples for 182 proteins supplied by the Northeast Structural Genomics consortium. Gaussian processes, which capture trends beyond the reach of linear statistical models, distinguish between two main physico-chemical mechanisms driving crystallization. One is characterized by low levels of side chain entropy and has been extensively reported in the literature. The other identifies specific electrostatic interactions not previously described in the crystallization context. Because evidence for two distinct mechanisms can be gleaned both from crystal contacts and from solution conditions leading to successful crystallization, the model offers future avenues for optimizing crystallization screens based on partial structural information. The availability of crystallization data coupled with structural outcomes analyzed through state-of-the-art statistical models may thus guide macromolecular crystallization toward a more rational basis., National Institutes of Health (U.S.) (Protein Structure Initiative, NIGMS grant U54 GM094597), National Institutes of Health (U.S.) (grant NIH R01GM088396), National Science Foundation (U.S.) (Grant NSF CHE-1062607), National Science Foundation (U.S.) (Grant No. NSF DMR-1055586)

Published

2013

17. Optical Absorbance Sensitivity to Rugged Energy Landscape

Author

Edward H. Snell, Katherine A. Niessen, and Andrea Markelz

Subjects

Range (particle radiation), Dipole, Molecular dynamics, Normal mode, Chemistry, Biophysics, Analytical chemistry, Energy landscape, Absorption (electromagnetic radiation), Anisotropy, Molecular physics, Spectral line

Abstract

Previously we have shown that underdamped long-range intramolecular vibrations exist in proteins using anisotropic absorption in the terahertz frequency range [1,2]. Measurements on free chicken egg white lysozyme (CEWL) and CEWL bound to the inhibitor tri-acetylglucosamine (3NAG) found the anisotropic absorption dramatically changes with inhibitor binding. To associate the spectral features with specific motions that are enhanced or diminished by the binding, we compare the measured spectra to calculations using normal mode analysis (NMA). Starting structures were randomly chosen frames from a molecular dynamics trajectory of a fully hydrated CEWL molecule. For each starting structure, we minimize the energy with small structural perturbations, and then perform NMA using CHARMM. These calculations find that the vibrational density of states (VDOS) is largely unchanged for a given starting structure, whereas the optical absorbance is different for each minimized structure. This variation arises from the sensitivity of the optical absorption to the strength and direction of the transition dipole, which is strongly dependent on the actual displacements for a given mode energy. This suggests that to properly model optical absorbance, one must perform an ensemble average of the calculated spectra, whereas for comparisons with the VDOS measurements, a single minimized structure is sufficient. The VDOS does not appear to be strongly affected by the ruggedness of the energy landscape, whereas the optical absorbance is. Given that strong bands are measured experimentally, the results suggest that in spite of the variation in the optical spectra, there are vibrations that are more prevalent than others, and possibly this biasing towards these motions enhances function. [1] Niessen, K.A., Xu, M., Markelz, A.G. (2015). Biophysical Reviews 7(2): 201-216. http://dx.doi.org/10.1007/s12551-015-0168-4. [2] Acbas, G., Niessen, K.A., Snell, E.H., Markelz, A.G. (2014) Nature Communications 5, 3076 http://dx.doi.org/10.1038/ncomms4076.

Published

2016

18. Purification and SAXS analysis of the integrin linked kinase, PINCH, parvin (IPP) heterotrimeric complex

Author

Titus J. Boggon, David A. Calderwood, Joseph R. Luft, Edward H. Snell, Amy L. Stiegler, and Thomas D. Grant

Subjects

Models, Molecular, Macromolecular Assemblies, Integrins, Protein Conformation, lcsh:Medicine, Plasma protein binding, Biochemistry, Protein structure, X-Ray Diffraction, Heterotrimeric G protein, Molecular Cell Biology, lcsh:Science, Cytoskeleton, 0303 health sciences, Multidisciplinary, biology, Chemistry, 030302 biochemistry & molecular biology, LIM Domain Proteins, Cellular Structures, Enzymes, Extracellular Matrix, Structural Proteins, Protein Binding, Research Article, Protein Structure, Integrin, Biophysics, Protein Serine-Threonine Kinases, Focal adhesion, 03 medical and health sciences, Scattering, Small Angle, Cell Adhesion, Humans, Integrin-linked kinase, Protein Interaction Domains and Motifs, Biology, 030304 developmental biology, Adaptor Proteins, Signal Transducing, lcsh:R, Membrane Proteins, Proteins, Cytoskeletal Proteins, Membrane protein, Multiprotein Complexes, biology.protein, lcsh:Q, Globular Proteins, Linker

Abstract

The heterotrimeric protein complex containing the integrin linked kinase (ILK), parvin, and PINCH proteins, termed the IPP complex, is an essential component of focal adhesions, where it interacts with many proteins to mediate signaling from integrin adhesion receptors. Here we conduct a biochemical and structural analysis of the minimal IPP complex, comprising full-length human ILK, the LIM1 domain of PINCH1, and the CH2 domain of α-parvin. We provide a detailed purification protocol for IPP and show that the purified IPP complex is stable and monodisperse in solution. Using small-angle X-ray scattering (SAXS), we also conduct the first structural characterization of IPP, which reveals an elongated shape with dimensions 120×60×40 Å. Flexibility analysis using the ensemble optimization method (EOM) is consistent with an IPP complex structure with limited flexibility, raising the possibility that inter-domain interactions exist. However, our studies suggest that the inter-domain linker in ILK is accessible and we detect no inter-domain contacts by gel filtration analysis. This study provides a structural foundation to understand the conformational restraints that govern the IPP complex.

Published

2012

19. Small Angle X-ray Scattering as a Complementary Tool for High-throughput Structural Studies

Author

Jennifer R. Wolfley, Gaetano T. Montelione, Thomas D. Grant, Anne Martel, Hiro Tsuruta, Edward H. Snell, and Joseph R. Luft

Subjects

Magnetic Resonance Spectroscopy, Small-angle X-ray scattering, Scattering, Chemistry, Organic Chemistry, fungi, Biophysics, Ab initio, Proteins, General Medicine, Nuclear magnetic resonance crystallography, Nuclear magnetic resonance spectroscopy, Crystallography, X-Ray, Biochemistry, Article, High-Throughput Screening Assays, Biomaterials, Solutions, Crystallography, Structural biology, X-Ray Diffraction, X-ray crystallography, Scattering, Small Angle, Humans, Spectroscopy

Abstract

Structural crystallography and nuclear magnetic resonance (NMR) spectroscopy are the predominant techniques for understanding the biological world on a molecular level. Crystallography is constrained by the ability to form a crystal that diffracts well and NMR is constrained to smaller proteins. Although powerful techniques, they leave many soluble, purified structurally uncharacterized protein samples. Small angle X-ray scattering (SAXS) is a solution technique that provides data on the size and multiple conformations of a sample, and can be used to reconstruct a low-resolution molecular envelope of a macromolecule. In this study, SAXS has been used in a high-throughput manner on a subset of 28 proteins, where structural information is available from crystallographic and/or NMR techniques. These crystallographic and NMR structures were used to validate the accuracy of molecular envelopes reconstructed from SAXS data on a statistical level, to compare and highlight complementary structural information that SAXS provides, and to leverage biological information derived by crystallographers and spectroscopists from their structures. All the ab initio molecular envelopes calculated from the SAXS data agree well with the available structural information. SAXS is a powerful albeit low-resolution technique that can provide additional structural information in a high-throughput and complementary manner to improve the functional interpretation of high-resolution structures.

Published

2011

20. Optimizing crystal volume for neutron diffraction: D-xylose isomerase

Author

Mark J. van der Woerd, Flora Meilleur, Michael Damon, Russell A. Judge, Edward H. Snell, and Dean A. A. Myles

Subjects

Diffraction, Materials science, Neutron diffraction, Biophysics, Physics::Optics, Context (language use), Molecular physics, Catalysis, Crystal, Optics, Neutron, Aldose-Ketose Isomerases, Neutrons, Binding Sites, Xylose, business.industry, General Medicine, Small-angle neutron scattering, Streptomyces, Neutron Diffraction, Models, Chemical, Neutron reflectometry, business, Crystallization, Powder diffraction, Hydrogen, Protein Binding

Abstract

Neutron diffraction is uniquely sensitive to hydrogen positions and protonation state. In that context structural information from neutron data is complementary to that provided through X-ray diffraction. However, there are practical obstacles to overcome in fully exploiting the potential of neutron diffraction, i.e. low flux and weak scattering. Several approaches are available to overcome these obstacles and we have investigated the simplest: increasing the diffracting volume of the crystals. Volume is a quantifiable metric that is well suited for experimental design and optimization techniques. By using response surface methods we have optimized the xylose isomerase crystal volume, enabling neutron diffraction while we determined the crystallization parameters with a minimum of experiments. Our results suggest a systematic means of enabling neutron diffraction studies for a larger number of samples that require information on hydrogen position and/or protonation state.

Published

2006

21. A quasi-Laue neutron crystallographic study of D-xylose isomerase

Author

Russell A. Judge, Flora Meilleur, Edward H. Snell, Mark J. van der Woerd, and Dean A. A. Myles

Subjects

Xylose isomerase, Neutrons, Binding Sites, Xylose, biology, Chemistry, Biophysics, Active site, Protonation, General Medicine, Isomerase, Ring (chemistry), Crystallography, X-Ray, Catalysis, Streptomyces, Crystallography, Neutron Diffraction, Deuterium, Models, Chemical, biology.protein, Neutron, Isomerization, Aldose-Ketose Isomerases, Hydrogen, Protein Binding

Abstract

The location of hydrogen atoms in enzyme structures can bring critical understanding of catalytic mechanism. However, whilst it is often difficult to determine the position of hydrogen atoms using X-ray crystallography even with subatomic (

Published

2006

22. Correlated Motions in Protein Crystals Measured by THz Microscopy

Author

Katherine A. Niessen, Edward H. Snell, G. Acbas, and Andrea Markelz

Subjects

Crystal, Crystallography, Absorption spectroscopy, Chemical physics, Chemistry, Terahertz radiation, Microscopy, Biophysics, Protein crystallization, Anisotropy, Polarization (waves), Absorption (electromagnetic radiation)

Abstract

We introduce a new technique, Crystal Anisotropy Terahertz Microscopy (CATM) which directly measures correlated intra-molecular protein vibrations. The terahertz (THz) frequency range (5-100 cm−1) corresponds to global correlated protein motions proposed to be essential to functional conformational changes [1, 2]. CATM accesses these motions above the relaxational background of the solvent and residue side chain librational motions. We demonstrate narrowband features in the anisotropic absorbance for hen egg-white lysozyme (HEWL) single crystals as well as HEWL with triacetylglucosamine (HEWL-3NAG) inhibitor single crystals. By self-referencing to a single orientation, the absorption spectra were obtained and are free from absorption due to librational motions from biological water and artifacts due to multiple reflections within the crystal. The most prominent features for the HEWL crystals appear at 45 cm−1, 69 cm−1, and 78 cm−1 and the strength of the absorption varies with crystal orientation relative to the THz polarization. Similar anisotropic features appear in molecular mechanics calculations suggesting specific correlated mode identification is possible, giving us direct insight to the role of correlated motions in conformational changes necessary for ligand binding and catalysis. This work supported by NSF MRI∧2 grant DBI295998.View Large Image | View Hi-Res Image | Download PowerPoint Slide

Published

2013

23. The Effect of Temperature and Solution pH on the Nucleation of Tetragonal Lysozyme Crystals

Author

Edward H. Snell, Randolph S. Jacobs, Tyralynn Frazier, Russell A. Judge, and Marc L. Pusey

Subjects

Supersaturation, Microscopy, Video, Chemistry, Analytical chemistry, Nucleation, Temperature, Biophysics, Crystal growth, Hydrogen-Ion Concentration, Crystallography, X-Ray, law.invention, Crystal, Solutions, Tetragonal crystal system, chemistry.chemical_compound, Crystallography, law, Animals, Thermodynamics, Muramidase, Crystallization, Lysozyme, Chickens, Order of magnitude, Research Article

Abstract

Part of the challenge of macromolecular crystal growth for structure determination is obtaining crystals with a volume suitable for x-ray analysis. In this respect an understanding of the effect of solution conditions on macromolecule nucleation rates is advantageous. This study investigated the effects of supersaturation, temperature, and pH on the nucleation rate of tetragonal lysozyme crystals. Batch crystallization plates were prepared at given solution concentrations and incubated at set temperatures over 1 week. The number of crystals per well with their size and axial ratios were recorded and correlated with solution conditions. Crystal numbers were found to increase with increasing supersaturation and temperature. The most significant variable, however, was pH; crystal numbers changed by two orders of magnitude over the pH range 4.0–5.2. Crystal size also varied with solution conditions, with the largest crystals obtained at pH 5.2. Having optimized the crystallization conditions, we prepared a batch of crystals under the same initial conditions, and 50 of these crystals were analyzed by x-ray diffraction techniques. The results indicate that even under the same crystallization conditions, a marked variation in crystal properties exists.

24. Trends and challenges in experimental macromolecular crystallography

Author

A. Deacon, Naomi E. Chayen, Vivian Stojanoff, T. J. Boggon, S. J. Harrop, T. Ursby, Y.P. Nieh, J. Habash, A. Cassetta, James Raftery, D. P. Siddons, John R. Helliwell, M. R. Peterson, Edward H. Snell, T. Gleichmann, Alfons Hädener, Michael Wulff, Annette C. Niemann, and Andrew Thompson

Subjects

Light, Macromolecular Substances, Biophysics, Computational biology, Crystallography, X-Ray, Microscopy, Atomic Force, Concanavalin A, Electrochemistry, Scattering, Radiation, Neutrons, Primary (chemistry), Crystallography, Microscopy, Video, Drug discovery, Chemistry, Weightlessness, Macromolecular crystallography, Rational design, Proteins, Structural chemistry, Interferometry, Solubility, Nucleic acid, Human genome, Crystallization, Synchrotrons, Macromolecule

Abstract

Macromolecular X-ray crystallography underpins the vigorous field of structural molecular biology having yielded many protein, nucleic acid and virus structures in fine detail. The understanding of the recognition by these macromolecules, as receptors, of their cognate ligands involves the detailed study of the structural chemistry of their molecular interactions. Also these structural details underpin the rational design of novel inhibitors in modern drug discovery in the pharmaceutical industry. Moreover, from such structures the functional details can be inferred, such as the biological chemistry of enzyme reactivity. There is then a vast number and range of types of biological macromolecules that potentially could be studied. The completion of the protein primary sequencing of the yeast genome, and the human genome sequencing project comprising some 105proteins that is underway, raises expectations for equivalent three dimensional structural databases.

25. Long-Range Protein Vibrations Dependence on Ligand Binding: Rate Promoting Motions

Author

Katherine A. Niessen, Edward H. Snell, and Andrea Markelz

Subjects

Crystallography, Dipole, Normal mode, Phonon, Chemistry, Intramolecular force, Biophysics, Density of states, Resonance, Charge density, Anisotropy, Molecular physics

Abstract

It has been suggested that long-range intramolecular vibrations in enzymes may provide efficient access to intermediate state configurations, enhancing catalytic turnover rates. Recently we have successfully measured these long-range protein vibrations using an anisotropic THz near-field technique to measure protein crystals, called crystal anisotropy terahertz microscopy (CATM). The method isolates these motions from the isotropic librational background, revealing narrow band resonances. Recent measurements on free chicken-egg white lysozyme (CEWL) and tri-N-acetylglucosamine (3NAG) inhibitor bound CEWL reveal dramatic and reproducible changes in the intramolecular vibrational mode spectra with binding. A large resonance at ∼70 cm−1 for free CEWL, is somewhat suppressed with binding, whereas a new resonance is observed at ∼ 40 cm−1, with binding. This dramatic change in the spectra with binding confirms that the observed resonances arise from intramolecular vibrations, and not crystal phonons. Using normal mode analysis, our calculated CATM spectra find a consistent increase in the low frequency signal with binding. While the density of states does not change appreciably with binding, the overall direction of motion shifts for vibrations in the frequency range where there is a large change in the optical signal. The change in the direction of the vibrational motion results in a change in the motion of the charge distribution and therefore, the dipole derivative, leading to the sensitivity to the trajectories in the terahertz optical absorbance. The remaining question is if these specific motions participate in the structural preorganization of the binding site, and thus promote catalytic activity. We will discuss measurements to answer this long standing question. This work was supported by NSF MRI∧2 grant DBI295998.