Synchrotron X-radiation protein crystallography and its use in the crystal structure determination of purine nucleoside phosphorylase

Rule, S. A. R.

January 1987

No description available.

530.41

Macromolecular crystallography

Investigation of X-ray induced radiation damage in proteins, nucleic acids and their complexes

Bury, Charles S.

January 2017

Macromolecular X-ray crystallography (MX) is currently the dominant technique for the structural eluci- dation of macromolecules at near atomic resolution. However, the progression and deleterious effects of radiation damage remains a major limiting factor in the success of diffraction data collection and subsequent structural solution at modern third generation synchrotron facilities. For experiments conducted at 100 K, protein specific damage to particular amino acids has been widely reported at doses of just several MGy, before any observable decay in average diffraction intensities. When undetected, such artefacts of X-ray irradiation can lead to significant modelling errors in protein structures, and ultimately the failure to derive the correct biological function from a model. It is thus vital to develop tools to help MX experimenters to detect and correct for such damage events. This thesis presents the development of an automated program, RIDL, which is designed to objectively quantify radiation-induced changes to electron density at individual atoms, based on F_obs,n − F_obs,1 Fourier difference maps between different dose states for a single crystal. The high-throughput RIDL program developed in this work provides the ability to systematically investigate a wide range of macromolecular systems. To date, damage to the broad class of nucleic acids and nucleoprotein complexes has remained largely uncharacterised, and it is unclear how radiation damage will disrupt the validity of such models derived from MX experiments. This thesis presents the first systematic investigations on a range of nucleic acid, protein-RNA and protein-DNA complex case studies. In general, it is concluded that nucleic acids are highly robust to radiation damage effects at 100K, relative to control protein counterparts across the tested systems. For protein crystals at 100K, cleavage of the phenolic C-O bond in tyrosine has disseminated through the MX radiation damage literature as a dominant specific damage event at 100K, despite the absence of any energetically favourable cleavage mechanism. To clarify the radiation susceptibility of tyrosine, this thesis presents a systematic investigation on radiation damage to tyrosine in a wide range of MX protein radiation damage series retrieved from the Protein Data Bank. It is concluded that the tyrosine C-O bond remains intact following X-ray irradiation, however the aromatic side-group can undergo radiation-induced displacement. This thesis also presents further applications of the RIDL program. A protocol is introduced to calculate explicit half-dose values for the electron density at individual atoms to decay to half of their initial value at zero absorbed dose. In addition, a methodology is developed to detect radiation-induced changes to electron density occurring over the course of the collection of a single MX dataset of diffraction images, all of which are required for structural solution. These protocols aim to advise experimenters of when previously-undetected site-specific damage effects may have corrupted the quality of their macromolecular model. Overall, the work in this thesis is highly applicable to both the future understanding of radiation damage in macromolecular structures, as well as of interest to the wider crystallographic community.

Structural characterization of the type II secretion system of Aeromonas hydrophila

2012 April 1900

The exeC gene, found in the gram-negative bacteria Aeromonas hydrophila codes for a 31 kDa, three domain, bitopic inner membrane protein. The components of the ExeC protein include an amino-terminal cytoplasmic domain, a trans-membrane helix and two periplasmic domains. The two periplasmic domains are involved in recognition and selection of protein substrates which are subsequently transported across the outer membrane and free of the cell. This study focuses exclusively on the two periplasmic domains referred to hereafter as the HR and the PDZ domains. Three constructs were used throughout the course of this study. Two of them were designed, cloned and expressed for this study. The third is a result of previous work. Two constructs contained both the HR and PDZ domains while the other consists of the amino-terminal periplasmic HR domain. Only one construct was used to grow single crystals for analysis by X-ray crystallography. Crystals comprised of the PDZ domain from a degraded construct grew in a hexagonal space group with a hexagonal bi-pyramidal morphology. Crystals diffracted anisotropically to a maximum resolutions of 2 Å along the c axis and 3 Å in the a/b plane. Anisotropy in combination with twinning drastically complicated structure solution. Efforts toward elucidating the crystal structure will be discussed.

Type II secretion system

Macromolecular crystallography

PDZ domain

Iterative projection algorithms and applications in x-ray crystallography

Lo, Victor Lai-Xin

January 2011

X-ray crystallography is a technique for determining the structure (positions of atoms in space) of molecules. It is a well developed technique, and is applied routinely to both small inorganic and large organic molecules. However, the determination of the structures of large biological molecules by x-ray crystallography can still be an experimentally and computationally expensive task. The data in an x-ray experiment are the amplitudes of the Fourier transform of the electron density in the crystalline specimen. The structure determination problem in x-ray crystallography is therefore identical to a phase retrieval problem in image reconstruction, for which iterative transform algorithms are a common solution method. This thesis is concerned with iterative projection algorithms, a generalized and more powerful version of iterative transform algorithms, and their application to macromolecular x-ray crystallography. A detailed study is made of iterative projection algorithms, including their properties, convergence, and implementations. Two applications to macromolecular crystallography are then investigated. The first concerns reconstruction of binary image and the application of iterative projection algorithms to determining molecular envelopes from x-ray solvent contrast variation data. An effective method for determining molecular envelopes is developed. The second concerns the use of symmetry constraints and the application of iterative projection algorithms to ab initio determination of macromolecular structures from crystal diffraction data. The algorithm is tested on an icosahedral virus and a protein tetramer. The results indicate that ab initio phasing is feasible for structures containing 4-fold or 5-fold non-crystallographic symmetry using these algorithms if an estimate of the molecular envelope is available.

iterative projection algorithms

inverse problems

image reconstruction

phase retrieval

macromolecular crystallography

Estudos funcionais e estruturais de uma endoglucanase de Phanerochaete chrysosporium da família 45 das hidrolases de glicosídeos / Structural and functional studies of an endoglucanase from Phanerochaete chrysorporium belonging to the glycoside hydrolase family 45

Ramia, Marina Paglione

07 December 2015

A importância do estudo das celulases não se limita à aquisição de conhecimento científico, mas também ao grande potencial biotecnológico que elas representam. Isso se deve ao fato da celulose ser a molécula mais abundante presente na natureza e prover uma vasta gama de produtos e processos sustentáveis. Muitas famílias de celulases já foram bem caracterizadas, enquanto outras permanecem ainda desconhecidas. Dentre estas últimas, a família 45 das hidrolases de glicosídeos é a família de celulases fúngicas menos caracterizada tanto estruturalmente quanto funcionalmente. Recentemente foi proposta a divisão dessa família em três subfamílias e, até agora, apenas membros da subfamília A tiveram enzimas estruturalmente elucidadas. Nesse trabalho reportamos a estrutura cristalográfica da proteína recombinante endoglucanase de Phanerochaete chrysosporium (PcCel45A), a primeira das hidrolases de glicosídeos da subfamília C, e seu complexo com celobiose a 1,4 Å e 1,7 Å de resolução, respectivamente. A PcCel45A é uma enzima de domínio único, com uma estrutura em β-barril e seu empacotamento geral remete ao formato de âncora. O sítio ativo da enzima forma um longo sulco na superfície da estrutura, sendo que o seu centro catalítico é diferente das outras enzimas publicadas dessa família e o aspartato catalítico, que atua como aceptor de próton na reação de inversão, (Asp10) não é conservado. Adicionalmente, a estrutura cristalográfica dessa enzima apresenta mais similaridades com as β-expansinas (proteínas de plantas) e transglicosilases líticas (proteínas que clivam o peptidoglicano de bactérias) do que com as outras representantes da família 45, o que a torna ainda mais singular. Para entendermos melhor seu funcionamento foram realizadas mutações sítio-dirigidas nos principais resíduos do sítio ativo. O Asp121, conhecido por participar da reação de inversão das outras enzimas da família como doador de próton, mostrou-se essencial para a atividade da enzima, enquanto que outros resíduos conservados como a Tyr25, o Trp161 e o Asp92 afetaram, mas não aniquilaram a atividade da enzima, apresentando aproximadamente 20%, 50% e 10% da atividade da enzima nativa, respectivamente. / The importance of the study of the cellulases is not limited to generating significant scientific knowledge, since these enzymes represents an enormous potential in biotechnology. This is partly because cellulose is the most abundant molecule in nature and provides a wide range of products and sustainable process. Many cellulases families have been well characterized, while others still remain unknown. Among them, the glycoside hydrolase family 45 is the least well characterized both structurally and functionally, between fungal cellulases. It was recently proposed the subdivision of this family into three subfamilies, with structural information available only for subfamily A. In this work, we report the chrystallographic structure of the recombinant endoglucanase from Phanerochaete chrysosporium (PcCel45A), the first GH45 subfamily C and its complex with cellobiose at 1.4 Å and 1.7 Å respectively. The PcCel45A is a single domain enzyme, which has a β-barrel structure with the overall shape resembling an anchor. The active site of the enzyme has a long cleft on the surface, being remarkably different from those members of subfamily A, and the catalytic aspartate responsible for acting as proton acceptor (Asp10) is not present. Additionally, the chrystallographic structure of this enzyme has shown more similarity with β -expansins (plant proteins) and lytic transglycosylase (proteins that cleave the peptidoglycan of bacteria) than others representants of family 45, which makes it more singular. For a better understanding of its function, we perform pontual mutations in the main residues from active site. The Asp121, known for acting as proton acceptor in the inversion reaction of others enzymes, proved to be essential for the enzyme activity, while others conserved residues as Tyr25, Trp161 and Asp92 affected but not annihilated the enzyme activity, leaving approximately 20%, 50% and 10% of the native enzyme activity.

Cellulase

Celulase

Cristalografia de macromoléculas

Endoglucanase

Endoglucanase

Glycoside hydrolase

Hidrolases de glicosídeos

Macromolecular crystallography

An exploration of some aspects of molecular replacement in macromolecular crystallography

Mifsud, Richard William

January 2018

This thesis reports work in three areas of X-ray crystallography. An initial chapter describes the structure of a protein, the methods based on the use of X-rays and computer analysis of diffraction patterns to determine crystal structure, and the subsequent derivation of the structure of part or all of a protein molecule. Work to determine the structure of the protein cytokine receptor-like factor 3 (CRLF3) leading to the successful generation of a structural model of a significant part of this molecule is then described in Chapter 2. A variety of techniques had to be deployed to complete this work, and the steps undertaken are described. Analysis was performed principally using phaser, using maximum likelihood methods. Areas for improvement in generating non-crystallographic symmetry (NCS) operators in existing programmes were identified and new and modified algorithms implemented and tested. Searches based on improved single sphere algorithms, and a new two-sphere approach, are reported. These methods showed improvements in many cases and are available for future use. In Chapter 4, work on determining the relative importance of low resolution and high intensity data in molecular replacement solutions is described. This work has shown that high intensity data are more important than the low resolution data, dispelling a common perception and helping in experimental design.

Estudos funcionais e estruturais de uma endoglucanase de Phanerochaete chrysosporium da família 45 das hidrolases de glicosídeos / Structural and functional studies of an endoglucanase from Phanerochaete chrysorporium belonging to the glycoside hydrolase family 45

Marina Paglione Ramia

07 December 2015

A importância do estudo das celulases não se limita à aquisição de conhecimento científico, mas também ao grande potencial biotecnológico que elas representam. Isso se deve ao fato da celulose ser a molécula mais abundante presente na natureza e prover uma vasta gama de produtos e processos sustentáveis. Muitas famílias de celulases já foram bem caracterizadas, enquanto outras permanecem ainda desconhecidas. Dentre estas últimas, a família 45 das hidrolases de glicosídeos é a família de celulases fúngicas menos caracterizada tanto estruturalmente quanto funcionalmente. Recentemente foi proposta a divisão dessa família em três subfamílias e, até agora, apenas membros da subfamília A tiveram enzimas estruturalmente elucidadas. Nesse trabalho reportamos a estrutura cristalográfica da proteína recombinante endoglucanase de Phanerochaete chrysosporium (PcCel45A), a primeira das hidrolases de glicosídeos da subfamília C, e seu complexo com celobiose a 1,4 Å e 1,7 Å de resolução, respectivamente. A PcCel45A é uma enzima de domínio único, com uma estrutura em β-barril e seu empacotamento geral remete ao formato de âncora. O sítio ativo da enzima forma um longo sulco na superfície da estrutura, sendo que o seu centro catalítico é diferente das outras enzimas publicadas dessa família e o aspartato catalítico, que atua como aceptor de próton na reação de inversão, (Asp10) não é conservado. Adicionalmente, a estrutura cristalográfica dessa enzima apresenta mais similaridades com as β-expansinas (proteínas de plantas) e transglicosilases líticas (proteínas que clivam o peptidoglicano de bactérias) do que com as outras representantes da família 45, o que a torna ainda mais singular. Para entendermos melhor seu funcionamento foram realizadas mutações sítio-dirigidas nos principais resíduos do sítio ativo. O Asp121, conhecido por participar da reação de inversão das outras enzimas da família como doador de próton, mostrou-se essencial para a atividade da enzima, enquanto que outros resíduos conservados como a Tyr25, o Trp161 e o Asp92 afetaram, mas não aniquilaram a atividade da enzima, apresentando aproximadamente 20%, 50% e 10% da atividade da enzima nativa, respectivamente. / The importance of the study of the cellulases is not limited to generating significant scientific knowledge, since these enzymes represents an enormous potential in biotechnology. This is partly because cellulose is the most abundant molecule in nature and provides a wide range of products and sustainable process. Many cellulases families have been well characterized, while others still remain unknown. Among them, the glycoside hydrolase family 45 is the least well characterized both structurally and functionally, between fungal cellulases. It was recently proposed the subdivision of this family into three subfamilies, with structural information available only for subfamily A. In this work, we report the chrystallographic structure of the recombinant endoglucanase from Phanerochaete chrysosporium (PcCel45A), the first GH45 subfamily C and its complex with cellobiose at 1.4 Å and 1.7 Å respectively. The PcCel45A is a single domain enzyme, which has a β-barrel structure with the overall shape resembling an anchor. The active site of the enzyme has a long cleft on the surface, being remarkably different from those members of subfamily A, and the catalytic aspartate responsible for acting as proton acceptor (Asp10) is not present. Additionally, the chrystallographic structure of this enzyme has shown more similarity with β -expansins (plant proteins) and lytic transglycosylase (proteins that cleave the peptidoglycan of bacteria) than others representants of family 45, which makes it more singular. For a better understanding of its function, we perform pontual mutations in the main residues from active site. The Asp121, known for acting as proton acceptor in the inversion reaction of others enzymes, proved to be essential for the enzyme activity, while others conserved residues as Tyr25, Trp161 and Asp92 affected but not annihilated the enzyme activity, leaving approximately 20%, 50% and 10% of the native enzyme activity.

Celulase

Cristalografia de macromoléculas

Endoglucanase

Hidrolases de glicosídeos

Cellulase

Endoglucanase

Glycoside hydrolase

Macromolecular crystallography

APPLICATIONS OF MOLECULAR DYNAMICS SIMULATIONS IN PROTEIN X-RAY CRYSTALLOGRAPHY

Oleg Mikhailovskii (8748906)

23 April 2020

<div>X-ray crystallography is a foundation of the modern structural biology. Thus, refinement of crystallographic structures remains an important and actively pursued area of research. We have built a software solution for refinement of crystallographic protein structures using X-ray diffraction data in conjunction with state-of-the-art MD modeling setup. This solution was implemented on the platform of Amber 16 biomolecular simulation package, making use of graphical processing unit (GPU) computing. The proposed refinement protocol consists of a short MD simulation, which represents an entire crystal unit cell containing multiple protein molecules and interstitial solvent. The simulation is guided by crystallographic restraints based on experimental structure factors, as well as conventional force-field terms. We assessed the performance of this new protocol against various refinement procedures based on the Phenix engine, which represents the current industry standard. The evaluation was conducted on a set of 84 protein structures with different realizations of initial models; the main criterion of success was free R-factor, R_free. Initially, we performed the re-refinement of the models deposited in the PDB bank. We found that in 58% of all cases our protocol achieved better R_free than Phenix. As a next step, we conducted the refinement on three different sets of lower-quality models that were manufactured specifically to test the competing algorithms (average C^α RMSD from the target structures 0.75, 0.89, and 1.02 Å). In these tests, our protocol outperformed the refinement procedures available in Phenix in up to 89% of all cases. Aside from R-factors, we also compared geometric qualities of the models as measured by MolProbity scores. It was found that our protocol led to consistently better geometries in all of the refinement comparisons.</div><div>Recently, a number of attempts have been made to fully utilize the information encoded in protein diffraction data, including diffuse scattering, which is dependent on molecular dynamics in the crystal. To understand the nature of this dependence, we have chosen three different crystalline forms of ubiquitin. By post-processing the MD data, we separated the effects from different types of motion on the diffuse scattering profiles. This analysis failed to identify any features of the diffuse scattering profiles that could be uniquely linked to certain specific motional modes (e.g. small-amplitude rocking motion of protein molecules in the crystal lattice). However, we were able to confirm the previous experimental observations, made in the combined X-ray diffraction and NMR study, suggesting that the amount of motion in the specific crystal is reflected in the amplitude of diffuse scattering.</div>

Biochemistry

Structural Biology

Macromolecular Crystallography

Protein Refinement

Diffuse Scattering

Comprehensive Model for X-Ray-Induced Damage in Protein Crystallography

Close, David M., Bernhard, William A.

01 July 2019

Acquisition of X-ray crystallographic data is always accompanied by structural degradation owing to the absorption of energy. The application of high-fluency X-ray sources to large biomolecules has increased the importance of finding ways to curtail the onset of X-ray-induced damage. A significant effort has been under way with the aim of identifying strategies for protecting protein structure. A comprehensive model is presented that has the potential to explain, both qualitatively and quantitatively, the structural changes induced in crystalline protein at 100 K. The first step is to consider the qualitative question: what are the radiation-induced intermediates and expected end products? The aim of this paper is to assist in optimizing these strategies through a fundamental understanding of radiation physics and chemistry, with additional insight provided by theoretical calculations performed on the many schemes presented.

amino-acid side chains

DFT calculations

free-radical radiation chemistry

macromolecular crystallography

x-ray radiation damage

Physics and Astronomy

Analysis of the Interactions between the 5' to 3' Exonuclease and the Single-Stranded DNA-Binding Protein from Bacteriophage T4 and Related Phages

Boutemy, Laurence S.

14 October 2008

No description available.

Biochemistry

DNA replication

protein-protein interactions

protein-DNA interactions

macromolecular crystallography

SAXS

RNase H

32 protein

bacteriophage T4