Publications

P II proteins control key processes of nitrogen metabolism in bacteria, archaea, and plants in response to the central metabolites ATP, ADP, and 2-oxoglutarate (2-OG), signaling cellular energy and carbon and nitrogen abundance. This metabolic information is integrated by P II and transmitted to regulatory targets (key enzymes, transporters, and transcription factors), modulating their activity. In oxygenic phototrophs, the controlling enzyme of arginine synthesis, N-acetyl-glutamate kinase (NAGK), is a major P II target, whose activity responds to 2-OG via P II . Here we show structures of the Synechococcus elongatus P II protein in complex with ATP, Mg??, and 2-OG, which clarify how 2-OG affects P II -NAGK interaction. P II trimers with all three sites fully occupied were obtained as well as structures with one or two 2-OG molecules per P II trimer. These structures identify the site of 2-OG located in the vicinity between the subunit clefts and the base of the T loop. The 2-OG is bound to a Mg?? ion, which is coordinated by three phosphates of ATP, and by ionic interactions with the highly conserved residues K58 and Q39 together with B- and T-loop backbone interactions. These interactions impose a unique T-loop conformation that affects the interactions with the P II target. Structures of P II trimers with one or two bound 2-OG molecules reveal the basis for anticooperative 2-OG binding and shed light on the intersubunit signaling mechanism by which P II senses effectors in a wide range of concentrations. Less |Related Solutions: Rock Imager^®

Fungal human pathogens such as Cryptococcus neoformans are becoming an increasingly prevalent cause of human morbidity and mortality owing to the increasing numbers of susceptible individuals. The few antimycotics available to combat these pathogens usually target fungal-specific cell-wall or membrane-related components; however, the number of these targets is limited. In the search for new targets and lead compounds, C. neoformans has been found to be susceptible to mycophenolic acid through its target inosine monophosphate dehydrogenase (IMPDH); in contrast, a rare subtype of the related C. gattii is naturally resistant. Here, the expression, purification, crystallization and preliminary crystallographic analysis of IMPDH complexed with IMP and NAD+ is reported for both of these Cryptococcus species. The crystals of IMPDH from both sources had the symmetry of the tetragonal space group I422 and diffracted to a resolution of 2.5 Å for C. neoformans and 2.6 Å for C. gattii. Less |Related Solutions: Rock Imager^®

PII signal transduction proteins are highly conserved in bacteria, archaea and plants and have key functions in coordination of central metabolism by integrating signals from the carbon, nitrogen and energy status of the cell. In the cyanobacterium Synechococcus elongatus PCC 7942, PII binds ATP and 2-oxoglutarate (2-OG) in a synergistic manner, with the ATP binding sites also accepting ADP. Depending on its effector molecule binding status, PII (from this cyanobacterium and other oxygenic phototrophs) complexes and regulates the arginine-controlled enzyme of the cyclic ornithine pathway, N-acetyl-l-glutamate kinase (NAGK), to control arginine biosynthesis. To gain deeper insights into the process of PII binding to NAGK, we searched for PII variants with altered binding characteristics and found PII variants I86N and I86T to be able to bind to an NAGK variant (R233A) that was previously shown to be unable to bind wild-type PII protein. Analysis of interactions between these PII variants and wild-type NAGK as well as with the NAGK R233A variant suggested that the PII I86N variant was a superactive NAGK binder. To reveal the structural basis of this property, we solved the crystal structure of the PII I86N variant at atomic resolution. The large T-loop, which prevails in most receptor interactions of PII proteins, is present in a tightly bended conformation that mimics the T-loop of S. elongatus PII after having latched onto NAGK. Moreover, both PII I86 variants display a specific defect in 2-OG binding, implying a role of residue I86 in 2-OG binding. We propose a two-step model for the mechanism of PII–NAGK complex formation: in an initiating step, a contact between R233 of NAGK and E85 of PII initiates the bending of the extended T-loop of PII, followed by a second step, where a bended T-loop deeply inserts into the NAGK clefts to form the tight complex. Less |Related Solutions: Rock Imager^®

The environment of individual tryptophans in known protein structures and the effectiveness of four commercial robotic UV microscopes to illuminate tryptophan-containing protein crystals by either tryptophan fluorescence (epi-illumination) or absorbance (transmission) are evaluated. In agreement with other studies, tryptophan residues are found on average to be largely buried in protein structures (with ~84% of their surface area buried) and to be surrounded by partially polar microenvironments (with ~43% of their surface area covered by polar residues), which suggests an inherent degree of fluorescence signal quenching. In bacterial genomes, up to one-third (~18.5% on average) of open reading frames are deficient in tryptophan. In the laboratory, because of the attenuation of UV light by the media commonly used in sitting-drop and hanging-drop crystallization trials, it was often necessary to simplify the light path by manually removing or inverting the supporting media. Prolonged exposure (minutes) to UV light precipitates some protein samples. The absorbance spectra of many commercially available media in crystallization trials are presented. The advantages of using tryptophan absorbance over fluorescence for characterizing crystals are discussed. Less |Related Solutions: Rock Imager^®

Second order nonlinear optical imaging of chiral crystals (SONICC) is explored for selective detection of integral membrane protein crystals grown in opaque and turbid environments. High turbidity is a hallmark of membrane protein crystallization due to the extensive use of detergent and/or lipids that often form various mesophases. Detection of crystals in such media by conventional optical methods (e.g., intrinsic UV fluorescence, birefringence, bright-field image analysis, etc.) is often complicated by optical scattering and by the small sizes of the crystals that routinely form. SONICC is shown to be well-suited for this application, by nature of its compatibility with imaging in scattering media and its high selectivity for protein crystals. Bright second harmonic generation (SHG) (up to 18 million counts/s) was observed from even relatively small crystals (5 micron) with a minimal background due to the surrounding lipid mesophase (~1 thousand counts/s). The low background nature of the resulting protein crystal images permitted the use of a relatively simple, particle counting analysis for preliminary scoring. Comparisons between a particle counting analysis of SONICC images and protocols based on the human expert analysis of conventional bright-field and birefringence images were performed. Less |Related Solutions: Rock Imager^®

Background Protein crystallization screening involves the parallel testing of large numbers of candidate conditions with the aim of identifying conditions suitable as a starting point for the production of diffraction quality crystals. Generally, condition screening is performed in 96-well plates. While previous studies have examined the effects of protein construct, protein purity, or crystallisation condition ingredients on protein crystallisation, few have examined the effect of the crystallisation plate. Methodology/Principal Findings We performed a statistically rigorous examination of protein crystallisation, and evaluated interactions between crystallisation success and plate row/column, different plates of same make, different plate makes and different proteins. From our analysis of protein crystallisation, we found a significant interaction between plate make and the specific protein being crystallised. Conclusions/Significance Protein crystal structure determination is the principal method for determining protein structure but is limited by the need to produce crystals of the protein under study. Many important proteins are difficult to crystallise, so that identification of factors that assist crystallisation could open up the structure determination of these more challenging targets. Our findings suggest that protein crystallisation success may be improved by matching a protein with its optimal plate make. Less |Related Solutions: Rock Imager^®

T-cell receptors (TCRs) are membrane proteins which recognize antigens with high specificity forming the basis of the cellular immune response. The study of these receptors has been limited by the challenges in expressing sufficient quantities of stable soluble protein. Here we report our systematic approach for generating soluble, αβ-TCRs, for X-ray crystallographic studies. By using small-scale expression screens, novel standardized quality control mechanisms and crystallization and imaging robots we were able to add significantly to the current TCR structural database. Our success in crystallizing both isolated TCRs and Major histocompatibility complex (MHC):TCR complexes has provided us with sufficient data to develop focused crystallization screens, which have proved generically useful for the crystallization of this family of proteins and complexes. Less |Related Solutions: Rock Imager^®

Crystallization of human membrane proteins in lipidic cubic phase often results in very small but highly ordered crystals. Advent of the sub-10 �m minibeam at the APS GM/CA CAT has enabled the collection of high quality diffraction data from such microcrystals. Herein we describe the challenges and solutions related to growing, manipulating and collecting data from optically invisible microcrystals embedded in an opaque frozen in meso material. Of critical importance is the use of the intense and small synchrotron beam to raster through and locate the crystal sample in an efficient and reliable manner. The resulting diffraction patterns have a significant reduction in background, with strong intensity and improvement in diffraction resolution compared with larger beam sizes. Three high-resolution structures of human G protein-coupled receptors serve as evidence of the utility of these techniques that will likely be useful for future structural determination efforts. We anticipate that further innovations of the technologies applied to microcrystallography will enable the solving of structures of ever more challenging targets. Less |Related Solutions: Rock Imager^®

A detailed protocol for crystallizing membrane proteins that makes use of lipidic mesophases is described. This has variously been referred to as the lipid cubic phase or in meso method. The method has been shown to be quite general in that it has been used to solve X-ray crystallographic structures of prokaryotic and eukaryotic proteins, proteins that are monomeric, homo- and hetero-multimeric, chromophore-containing and chromophore-free, and a-helical and �-barrel proteins. Its most recent successes are the human engineered �2-adrenergic and adenosine A2A G protein-coupled receptors. Protocols are provided for preparing and characterizing the lipidic mesophase, for reconstituting the protein into the monoolein-based mesophase, for functional assay of the protein in the mesophase, and for setting up crystallizations in manual mode. Methods for harvesting micro-crystals are also described. The time required to prepare the protein-loaded mesophase and to set up a crystallization plate manually is about one hour. Less |Related Solutions: Rock Imager^®

VERNALIZATION1 (VRN1) is required in the model plant Arabidopsis thaliana for the epigenetic suppression of the floral repressor FLC by prolonged cold treatment. Stable suppression of FLC accelerates flowering, a physiological process known as vernalization. VRN1 is a 341-residue DNA-binding protein that contains two plant-specific B3 domains (B3a and B3b), a putative nuclear localization sequence (NLS) and two putative PEST domains. VRN1208�341 includes the second B3 domain and a region upstream that is highly conserved in the VRN1 orthologues of other dicotyledonous plants. VRN1208�341 was crystallized by the hanging-drop method in 0.05 M sodium acetate pH 6.0 containing 1.0 M NaCl and 18%(w/v) PEG 3350. Preliminary X-ray diffraction data analysis revealed that the VRN1208�341 crystal diffracted to 2.1 � and belonged to space group C2, with unit-cell parameters a = 105.2, b = 47.9, c = 61.2 �, a = 90.0, � = 115.4, ? = 90.0�. Assuming that two molecules occupy the asymmetric unit, a Matthews coefficient of 2.05 �3 Da-1 and a solvent content of 40.1% were calculated. Less |Related Solutions: Rock Imager^®

The stimulatory RNA of the Visna-Maedi virus (VMV) -1 ribosomal frameshifting signal has not previously been characterized but can be modeled either as a two-stem helix, reminiscent of the HIV-1 frameshift-stimulatory RNA, or as an RNA pseudoknot. The pseudoknot is unusual in that it would include a 7 nucleotide loop (termed here an interstem element [ISE]) between the two stems. In almost all frameshift-promoting pseudoknots, ISEs are absent or comprise a single adenosine residue. Using a combination of RNA structure probing, site directed mutagenesis, NMR, and phylogenetic sequence comparisons, we show here that the VMV stimulatory RNA is indeed a pseudoknot, conforming closely to the modeled structure, and that the ISE is essential for frameshifting. Pseudoknot function was predictably sensitive to changes in the length of the ISE, yet altering its sequence to alternate pyrimidine/purine bases was also detrimental to frameshifting, perhaps through modulation of local tertiary interactions. How the ISE is placed in the context of an appropriate helical junction conformation is not known, but its presence impacts on other elements of the pseudoknot, for example, the necessity for a longer than expected loop 1. This may be required to accommodate an increased flexibility of the pseudoknot brought about by the ISE. In support of this, 1H NMR analysis at increasing temperatures revealed that stem 2 of the VMV pseudoknot is more labile than stem 1, perhaps as a consequence of its connection to stem 1 solely via flexible single-stranded loops. Less |Related Solutions: Rock Imager^®

In this article, we describe for the first time the high-resolution crystal structure of a phenylalanine tRNA synthetase from the pathogenic bacterium Staphylococcus haemolyticus. We demonstrate the subtle yet important structural differences between this enzyme and the previously described Thermus thermophilus ortholog. We also explain the structure-activity relationship of several recently reported inhibitors. The native enzyme crystals were of poor quality—they only diffracted X-rays to 3–5 Å resolution. Therefore, we have executed a rational surface mutagenesis strategy that has yielded crystals of this 2300-amino acid multidomain protein, diffracting to 2 Å or better. This methodology is discussed and contrasted with the more traditional domain truncation approach. Less |Related Solutions: Rock Imager^®

Plastic microchannel crystallization template designs made from inexpensive cyclic olefin copolymers have been shown to be low-birefringent, X-ray transmissive and compatible with microfluidic fabrication in restricted geometry. The model proteins thaumatin, lysozyme and bacteriorhodopsin demonstrated the feasibility of conducting counter-diffusion equilibration within the new plastic configuration. Crystals of each of these proteins were directly evaluated in situ using synchrotron radiation and their diffraction quality was evaluated without invasive manipulation or cryofreezing. Protein crystals able to produce complete X-ray data sets were used to calculate electron-density maps for structure determination. Fluidic crystallization in the plastic platform was also coupled with a commercialized automated imager and an in situ X-ray scanner that allowed optical and X-ray inspection of crystallization hits. The results demonstrate the feasibility of rapid nanovolume counter-diffusion crystallization experiments without the need for additional instrumentation. Less |Related Solutions: Rock Imager^®

"Protein disorder can plague protein crystallography where the first important goal is to identify conditions that grow stable, ordered, and well diffracting crystals. Initial crystal trials for protease X produced numerous crystals in a myriad of conditions; many of which did not produce well diffracting crystals. Optimizing all of the most obvious parameters: pH, temperature, salt and precipitant concentration continued to produce poor crystals. The fast growth rate and consistently poor diffraction gave an indication that the protein may have some stability issues that could stem from the choice of storage buffer. Recent studies have shown that incorporating thermal melting (Tm) assays into the crystallization screening experiments completely opens up a greater opportunity to explore the protein?s stability prior to crystal trials. This poster will look at the use of thermal shift and the use of automation to screen, characterize and optimize poorly diffracting crystals to well ordered crystals diffracting to beyond 2 angstrom resolution" Less |Related Solutions: Rock Imager^®

Proteins of the cradle-loop barrel metafold are formed by duplication of a conserved βαβ-element, suggesting a common evolutionary origin from an ancestral group of nucleic acid-binding proteins. The basal fold within this metafold, the RIFT barrel, is also found in a wide range of enzymes, whose homologous relationship with the nucleic acid-binding group is unclear. We have characterized a protein family that is intermediate in sequence and structure between the basal group of cradle-loop barrels and one family of RIFT-barrel enzymes, the riboflavin kinases. We report the structure, substrate-binding mode, and catalytic activity for one of these proteins, Methanocaldococcus jannaschii Mj0056, which is an archaeal riboflavin kinase. Mj0056 is unusual in utilizing CTP rather than ATP as the donor nucleotide, and sequence conservation in the relevant residues suggests that this is a general feature of archaeal riboflavin kinases. Less |Related Solutions: Rock Imager^®

A microfluidic device denoted the Phase Chip has been designed to measure and manipulate the phase diagram of multi-component fluid mixtures. The Phase Chip exploits the permeation of water through poly(dimethylsiloxane) (PDMS) in order to controllably vary the concentration of solutes in aqueous nanoliter volume microdrops stored in wells. The permeation of water in the Phase Chip is modeled using the diffusion equation and good agreement between experiment and theory is obtained. The Phase Chip operates by first creating drops of the water/solute mixture whose composition varies sequentially. Next, drops are transported down channels and guided into storage wells using surface tension forces. Finally, the solute concentration of each stored drop is simultaneously varied and measured. Two applications of the Phase Chip are presented. First, the phase diagram of a polymer/salt mixture is measured on-chip and validated off-chip and second, protein crystallization rates are enhanced through the manipulation of the kinetics of nucleation and growth. Less |Related Solutions: Rock Imager^®

The structure of human inosine triphosphate pyrophosphohydrolase (ITPA) has been determined using diffraction data to 1.6 � resolution. ITPA contributes to the accurate replication of DNA by cleansing cellular dNTP pools of mutagenic nucleotide purine analogs such as dITP or dXTP. A similar high-resolution unpublished structure has been deposited in the Protein Data Bank from a monoclinic and pseudo-merohedrally twinned crystal. Here, cocrystallization of ITPA with a molar ratio of XTP appears to have improved the crystals by eliminating twinning and resulted in an orthorhombic space group. However, there was no evidence for bound XTP in the structure. Comparison with substrate-bound NTPase from a thermophilic organism predicts the movement of residues within helix a1, the loop before a6 and helix a7 to cap off the active site when substrate is bound. Less |Related Solutions: Rock Imager^®

Crystals of the apo-form of the vitamin B12 and colicin transporter, BtuB, that diffract to 1.95 Å have been grown by the membrane-based in meso technique. The structure of the protein differs in several details from that of its counterpart grown by the more traditional, detergent-based (in surfo) method. Some of these differences include i) the five N-terminal residues are resolved in meso, ii) residues 57–62 in the hatch domain and residues 574–581 in loop 21–22 are disordered in meso and are ordered in surfo, iii) residues 278–287 in loop 7–8 are resolved in meso, iv) residues 324–331 in loop 9–10, 396–411 in loop 13–14, 442–458 in loop 15–16 and 526–541 in loop 19–20 have large differences in position between the two crystal forms, as have residues 86–96 in the hatch domain, and v) the conformation of residues 6 and 7 in the Ton box (considered critical to signal transduction and substrate transport) are entirely different in the two structures. Importantly, the in meso orientation of residues 6 and 7 is similar to that of the vitamin B12-charged state. These data suggest that the 'substrate-induced' 180-degree rotation of residues 6 and 7 reported in the literature may not be a unique signaling event. The extent to which these findings agree with structural, dynamic and functional insights gleaned from site-directed spin labeling and electron paramagnetic resonance measurements is evaluated. Packing in in meso-grown crystals is dense and layered, consistent with the current model for crystallogenesis of membrane proteins in lipidic mesophases. Layered packing has been used to locate the transmembrane hydrophobic surface of the protein. Generally, this is consistent with tryptophan, tyrosine, lipid and Cα-B-factor distributions in the protein, and with predictions based on transfer free energy calculations. Less |Related Solutions: Rock Imager^®

The cubic phase or in meso crystallization method is responsible for almost 40 solved integral membrane protein structures. Most of these are small and compact proteins. A model for how crystals form by the in meso method has been proposed that invokes a transition between mesophases. In light of this model, we speculated that a more hydrated and open mesophase, of reduced interfacial curvature, would support facile crystallization of bigger and bulkier proteins. The proposal was explored here by performing crystallization in the presence of additives that swell the cubic phase. The additive concentration inducing swelling, as quantified by small-angle X-ray diffraction, coincided with a "crystallization window" in which two, very different transmembranal proteins produced crystals. That the swollen mesophase can grow structure-grade crystals was proven with one of these, the light-harvesting II complex. In most regards, the structural details of the corresponding complex resembled those of crystals grown by the conventional vapour diffusion method, with some important differences. In particular, packing density in the in meso-grown crystals was dramatically higher, more akin to that seen with water-soluble proteins, which accounts for their enhanced diffracting power. The layered and close in-plane packing observed has been rationalized in a model for nucleation and crystal growth by the in meso method that involves swollen mesophases. These results present a rational case for including mesophase-swelling additives in screens for in meso crystallogenesis. Their use will contribute to broadening the range of membrane proteins that yield to structure determination. Less |Related Solutions: Rock Imager^®