Phasing macromolecular structures with UV-induced structural changes

Experimental phasing of macromolecular crystal structures relies on the accurate measurement of two or more sets of reflections from isomorphous crystals, where the scattering power of a few atoms is different for each set. Recently, it was demonstrated that X-ray-induced intensity differences can also contain phasing information, exploiting specific structural changes characteristic of X-ray damage. This method (radiation damage-induced phasing; RIP) has the advantage that it can be performed on a single crystal of the native macromolecule. However, a drawback is that X-rays introduce many small changes to both solvent and macromolecule. In this study, ultraviolet (UV) radiation has been used to induce specific changes in the macromolecule alone, leading to a larger contrast between radiation-susceptible and nonsusceptible sites. Unlike X-ray RIP, UV RIP does not require the use of a synchrotron. The method has been demonstrated for a series of macromolecules.     

Specific radiation damage can be used to solve macromolecular crystal structures

The use of third generation synchrotron sources has led to renewed concern about the effect of ionizing radiation on crystalline biological samples. In general, the problem is seen as one to be avoided. However, in this paper, it is shown that, far from being a hindrance to successful structure determination, radiation damage provides an opportunity for phasing macromolecular structures. This is successfully demonstrated for both a protein and an oligonucleotide, by way of which complete models were built automatically. The possibility that, through the exploitation of radiation damage, the phase problem could become less of a barrier to macromolecular crystal structure determination is discussed.     

How to avoid premature decay of your macromolecular crystal: a quick soak for long life

Radiation damage to biological samples is currently one of the major limiting factors in macromolecular X-ray crystallography, since it severely and irreversibly affects the quality of the data that can be obtained from a diffraction experiment. However, radiation damage can effectively be reduced by utilizing the electron and radical scavenging potential of certain small-molecule compounds. We propose an approach to protect macromolecular crystals prior to data collection by quick soaking with scavengers. This, in favorable cases, can more than double crystal lifetime in the X-ray beam. The approach has the potential to yield diffraction data of superior quality and hence to increase the amount of high-quality diffraction data and of structural information attainable from a single crystal.     

Doses for experiments with microbeams and microcrystals: Monte Carlo simulations in RADDOSE‐3D

Increasingly, microbeams and microcrystals are being used for macromolecular crystallography (MX) experiments at synchrotrons. However, radiation damage remains a major concern since it is a fundamental limiting factor affecting the success of macromolecular structure determination. The rate of radiation damage at cryotemperatures is known to be proportional to the absorbed dose, so to optimize experimental outcomes, accurate dose calculations are required which take into account the physics of the interactions of the crystal constituents. The program RADDOSE‐3D estimates the dose absorbed by samples during MX data collection at synchrotron sources, allowing direct comparison of radiation damage between experiments carried out with different samples and beam parameters. This has aided the study of MX radiation damage and enabled prediction of approximately when it will manifest in diffraction patterns so it can potentially be avoided. However, the probability of photoelectron escape from the sample and entry from the surrounding material has not previously been included in RADDOSE‐3D, leading to potentially inaccurate does estimates for experiments using microbeams or microcrystals. We present an extension to RADDOSE‐3D which performs Monte Carlo simulations of a rotating crystal during MX data collection, taking into account the redistribution of photoelectrons produced both in the sample and the material surrounding the crystal. As well as providing more accurate dose estimates, the Monte Carlo simulations highlight the importance of the size and composition of the surrounding material on the dose and thus the rate of radiation damage to the sample. Minimizing irradiation of the surrounding material or removing it almost completely will be key to extending the lifetime of microcrystals and enhancing the potential benefits of using higher incident X‐ray energies.     

In-house UV radiation-damage-induced phasing of selenomethionine-labeled protein structures

Selenomethionine labeling is the most common technique used in protein crystallography to derivatize recombinant proteins for experimental phasing using anomalous scattering at tunable synchrotron beamlines. Recently, it has been shown that UV radiation depletes electron density of selenium atoms of selenomethionine residues and that UV radiation-damage-induced phasing (equivalent to single isomorphous replacement) protocol can be applied to calculate experimental phases. Here we present the straightforward integration of a UV source with an in-house diffractometer. We show how this setup can extend the capabilities of a sealed tube X-ray generator and be used for experimental phasing of selenium-labeled proteins.     

New approaches to high-throughput phasing

Recent progress in macromolecular phasing, in part stimulated by the high-throughput structural biology initiatives, has made this crucial stage of the elucidation of crystal structures easier and more automatic. A quick soak in various salts leads to the rapid incorporation of the anomalously scattering ions, suitable for phasing by MAD (multiwavelength anomalous dispersion), SAD (single-wavelength anomalous dispersion) or MIR (multiple isomorphous replacement) methods. The availability of stable synchrotron beam lines equipped with elaborate hardware control and sophisticated data processing programs makes it possible to collect very accurate diffraction data and to solve structures from the very weak anomalous signal of such atoms as sulfur or phosphorus, inherently present in macromolecules. The current progress in phasing, coupled with the parallel advances in protein crystallization, diffraction data collection and so on, suggests that, in the near future, the process of macromolecular crystal structure elucidation may become fully automatic.     

Advances in multiple wavelength anomalous diffraction crystallography

In only a few years, multiple wavelength anomalous diffraction (MAD) phasing has advanced from an esoteric technique used in only a few favorable cases to the method of choice for solving new macromolecular structures. Before 1994, MAD phasing had been used for fewer than a dozen new structure determinations. In 1999 alone, well over 100 new structures were determined by MAD phasing. The meteoric rise in MAD applications resulted from the availability of new synchrotron beamlines, equipped with low bandpass optics, fast readout detectors, cryogenic cooling and user-friendly interfaces. The power of MAD phasing has been amplified by the availability of new computer programs for locating the positions of the anomalous scattering atoms and for calculating phases from the experimental data. Phasing by anomalous scattering techniques has been applied to structures as large as 640 kDa and 120 selenium atoms in the asymmetric unit. The practical size limitation for application of MAD phasing techniques has not yet been encountered.     

CRANK: new methods for automated macromolecular crystal structure solution

CRANK is a novel suite for automated macromolecular structure solution and uses recently developed programs for substructure detection, refinement, and phasing. CRANK utilizes methods for substructure detection and phasing and combines them with existing crystallographic programs for density modification and automated model building in a convenient and easy-to-use CCP4i graphical interface. The data model used conforms to the XML eXtensible Markup Language specification and works as a common language to communicate data between many different applications inside and outside of the suite. The application of CRANK on various test cases has yielded promising results: with minimal user input, CRANK can produce better quality solutions over currently available programs.     

High-resolution electron cryomicroscopy of macromolecular assemblies

Electron cryomicroscopy is a high-resolution imaging technique that is particularly appropriate for the structural determination of large macromolecular assemblies, which are difficult to study by X-ray crystallography or NMR spectroscopy. For some biological molecules that form two-dimensional crystals, the application of electron cryomicroscopy and image reconstruction can help elucidate structures at atomic resolution. In instances where crystals cannot be formed, atomic-resolution information can be obtained by combining high-resolution structures of individual components determined by X-ray crystallography or NMR with image-derived reconstructions at moderate resolution. This can provide unique and crucial information on the mechanisms of these complexes. Finally, image reconstructions can be used to augment X-ray studies by providing initial models that facilitate phasing of crystals of large macromolecular machines such as ribosomes and viruses.     

The 'fingerprint' that X-rays can leave on structures

BACKGROUND: Exposure of biomacromolecules to ionising radiation results in damage that is initiated by free radicals and progresses through a variety of mechanisms. A widely used technique to study the three-dimensional structures of biomacromolecules is crystallography, which makes use of ionising X-rays. It is crucial to know to what extent structures determined using this technique might be biased by the inherent radiation damage. RESULTS: The consequences of radiation damage have been investigated for three dissimilar proteins. Similar results were obtained for each protein, atomic B factors increase, unit-cell volumes increase, protein molecules undergo slight rotations and translations, disulphide bonds break and decarboxylation of acidic residues occurs. All of these effects introduce non-isomorphism. The absorbed dose in these experiments can be reached during routine data collection at undulator beamlines of third generation synchrotron sources. CONCLUSIONS: X-rays can leave a 'fingerprint' on structures, even at cryogenic temperatures. Serious non-isomorphism can be introduced, thus hampering multiple isomorphous replacement (MIR) and multiwavelength anomalous dispersion (MAD) phasing methods. Specific structural changes can occur before the traditional measures of radiation damage have signalled it. Care must be taken when assigning structural significance to features that might easily be radiation-damage-induced changes. It is proposed that the electron-affinic disulphide bond traps electrons that migrate over the backbone of the protein, and that the sidechains of glutamic acid and aspartic acid donate electrons to nearby electron holes and become decarboxylated successively. The different disulphide bonds in each protein show a clear order of susceptibility, which might well relate to their intrinsic stability.     

New applications of maximum likelihood and Bayesian statistics in macromolecular crystallography

Maximum likelihood methods are well known to macromolecular crystallographers as the methods of choice for isomorphous phasing and structure refinement. Recently, the use of maximum likelihood and Bayesian statistics has extended to the areas of molecular replacement and density modification, placing these methods on a stronger statistical foundation and making them more accurate and effective.     

Iterative ACORN as a high throughput tool in structural genomics

High throughput macromolecular structure determination is very essential in structural genomics as the available number of sequence information far exceeds the number of available 3D structures. ACORN, a freely available resource in the CCP4 suite of programs is a comprehensive and efficient program for phasing in the determination of protein structures, when atomic resolution data are available. ACORN with the automatic model-building program ARP/wARP and refinement program REFMAC is a suitable combination for the high throughput structural genomics. ACORN can also be run with secondary structural elements like helices and sheets as inputs with high resolution data. In situations, where ACORN phasing is not sufficient for building the protein model, the fragments (incomplete model/dummy atoms) can again be used as a starting input. Iterative ACORN is proved to work efficiently in the subsequent model building stages in congerin (PDB-ID: lis3) and catalase (PDB-ID: 1gwe) for which models are available.     

Cryo-cooling in macromolecular crystallography: advantages, disadvantages and optimization

The flash-cooling of crystals in macromolecular crystallography has become commonplace. The procedure makes it possible to collect data from much smaller specimens than was the case in the past Also, flash-cooled crystals are much less prone to radiation damage than their room-temperature counterparts, allowing data to be accumulated over extended periods of time. Notwithstanding the attractiveness of the technique, it does have potential disadvantages. First, better methods need to be developed to prevent damage to crystals on freezing. There is also a risk that structures determined at low temperature may suggest conclusions based on aspects of the structure that are not necessarily relevant at room temperature.     

Macromolecular cryocrystallography--methods for cooling and mounting protein crystals at cryogenic temperatures

Cryocrystallography is routinely used in macromolecular crystallography laboratories. The main advantage of X-ray diffraction data collection near 100K is that crystals display much less radiation damage than seen at room temperature. Techniques and tools are described to facilitate cryoprotecting and flash-cooling crystals for data collection.     

Proceedings: Characteristics of freeze-dried cells

Microorganisms have been found to be more sensitive to selective media after freeze-drying. This increased sensitivity can be measured and thus the degree of sublethal injury can be determined as a function of various processing variables. In light of this, the use of selective media for the enrichment and detection of pathogens in freeze-dried products has to be reevaluated; indeed, the literature is now becoming abundant with such evaluations. In addition, the response of freeze-dried microorganisms has been found to be dependent on the medium in which they were grown; the phenomena of “metabolic injury” and “minimal medium recovery” are observed when microorganisms are grown in a complete and minimal medium, respectively. The expression of these two phenomena also can be used to assay for injury.Observations on the effects of freeze-drying on cell viability lead to the conclusion that freeze-drying is a complex stress. Damage to the cellular membrane structure and function, RNA integrity, and, possibly, DNA have been cited. The extrapolation of these macromolecular changes to specific viability responses for the purpose of elucidating the principal site of damage is still difficult. It is our opinion that the pre- and post-freeze-drying conditions to which the microorganisms are exposed can lead to a situation in which a particular macromolecular damage can become dominant over others, depending on the physiology of the cell.This knowledge can not only be applied for the purpose of improving detection of undesirable microbes but also for the preservation of desirable cultures, such as starter cultures in the dairy industry. Finally, the finding that microorganisms leak or release nucleic acids after freeze-drying, as they do after freezing and heating, can be applied to the problem of elimination of undesirable cytoplasmic components of organisms to be used as protein sources (4, 8).     

When X-rays modify the protein structure: radiation damage at work

The majority of 3D structures of macromolecules are currently determined by macromolecular crystallography, which employs the diffraction of X-rays on single crystals. However, during diffraction experiments, the X-rays can damage the protein crystals by ionization processes, especially when powerful X-ray sources at synchrotron facilities are used. This process of radiation damage generates photo-electrons that can get trapped in protein moieties. The 3D structure derived from such experiments can differ remarkably from the structure of the native molecule. Recently, the crystal structures of different oxidation states of horseradish peroxidase and nickel-containing superoxide dismutase were determined using crystallographic redox titration performed during the exposure of the crystals to the incident X-ray beam. Previous crystallographic analyses have not shown the distinct structures of the active sites associated with the redox state of the structural features of these enzymes. These new studies show that, for protein moieties that are susceptible to radiation damage and prone to reduction by photo-electrons, care is required in both the design of the diffraction experiment and the analysis and interpretation.     

Selenium Derivatization of Nucleic Acids for X‐Ray Crystal‐Structure and Function Studies

It is estimated that over two thirds of all new crystal structures of proteins are determined via the protein selenium derivatization (selenomethionine (Se‐Met) strategy). This selenium derivatization strategy via MAD (multi‐wavelength anomalous dispersion) phasing has revolutionized protein X‐ray crystallography. Through our pioneer research, similarly, Se has also been successfully incorporated into nucleic acids to facilitate the X‐ray crystal‐structure and function studies of nucleic acids. Currently, Se has been stably introduced into nucleic acids by replacing nucleotide O‐atom at the positions 2′, 4′, 5′, and in nucleobases and non‐bridging phosphates. The Se derivatization of nucleic acids can be achieved through solid‐phase chemical synthesis and enzymatic methods, and the Se‐derivatized nucleic acids (SeNA) can be easily purified by HPLC, FPLC, and gel electrophoresis to obtain high purity. It has also been demonstrated that the Se derivatization of nucleic acids facilitates the phase determination via MAD phasing without significant perturbation. A growing number of structures of DNAs, RNAs, and protein–nucleic acid complexes have been determined by the Se derivatization and MAD phasing. Furthermore, it was observed that the Se derivatization can facilitate crystallization, especially when it is introduced to the 2′‐position. In addition, this novel derivatization strategy has many advantages over the conventional halogen derivatization, such as more choices of the modification sites via the atom‐specific substitution of the nucleotide O‐atom, better stability under X‐ray radiation, and structure isomorphism. Therefore, our Se‐derivatization strategy has great potentials to provide rational solutions for both phase determination and high‐quality crystal growth in nucleic‐acid crystallography. Moreover, the Se derivatization generates the nucleic acids with many new properties and creates a new paradigm of nucleic acids. This review summarizes the recent developments of the atomic site‐specific Se derivatization of nucleic acids for structure determination and function study. Several applications of this Se‐derivatization strategy in nucleic acid and protein research are also described in this review.     

Current aspects on the radiation induced base damage in DNA

In this short review, some current aspects of our knowledge about base damage in DNA induced by ionizing radiation will be summarized. It is not intended, to describe all the literature in this field; a very extensive review has been given in the book of Hüttermann et al. (1978) and also in later by Cadet and Berger (1985), Hutchinson (1985) and v. Sonntag and Schuchmann (1986). However, in this review, current ideas and unsolved problems concerning DNA base damage will be discussed, which may outline possible future research in this field. The understanding of DNA base damage requires the analysis of radicals formed in irradiated single DNA moieties as well as in whole DNA. Chemical studies about can be used for the molecular alterations of bases and biochemical methods for DNA-sequencing. In addition enzymes recognizing DNA damage and immunological methods with specific antibodies can be employed. However special emphasis should be given to the analysis of DNA base damage in irradiated cells and it will be shown, that a distinct gap in knowledge exists in this field in contrast to the radiation chemistry in aqueous solutions of DNA.