Tritium planigraphy: A tool for studying the spatial structure of proteins and their complexes

The review is devoted to tritium planigraphy and its applications in solving a broad scope of problems in modern molecular and physicochemical biology. The method is based on nonselective substitution of tritium for hydrogen in the hydrocarbon parts of target molecules. It furnishes information on the steric accessibility of the components of a system under study (macromolecule within a complex amino acid residues, and even separate atomic groupings in a macromolecule) that characterizes the structure of the entire object. The technique is applicable to specimens in different phase states and has no limitations in respect of the target molecular mass. Tritium planigraphy is especially important in the cases when the biological macromolecules cannot be examined by the conventional methods (X-ray analysis and NMR spectroscopy). The review summarizes the studies of protein accessible surface and spatial arrangement, and outlines the approaches to modeling the protein 3D structure and probing into the spatial organization of theEscherichia coli ribosome and virus particles.     

Differences in spatial structures of the influenza virus M1 protein in crystal, solution and virion

Spatial structure of the influenza virus A/Puerto Rico/8/34 (PR8, subtype H1N1) M1 protein in a solution and composition of the virion was studied by tritium planigraphy technique. The special algorithm for modeling of the spatial structure is used to simulate the experiment, as well as a set of algorithms predicting secondary structure and disordered regions in proteins. Tertiary structures were refined using the program Rosetta. To compare the structures in solution and in virion, also used the X-ray diffraction data for NM-domain. The main difference between protein structure in solution and crystal is observed in the contact region of N- and M-domains, which are more densely packed in the crystalline state. Locations include the maximum label is almost identical to the unstructured regions of proteins predicted by bioinformatics analysis. These areas are concentrated in the C-domain and in the loop regions between the M-, N-, and C-domains. Analytical centrifugation and dynamic laser light scattering confirm data of tritium planigraphy. Anomalous hydrodynamic size, and low structuring of the M1 protein in solution were found. The multifunctionality of protein in the cell appears to be associated with its plastic tertiary structure, which provides at the expense of unstructured regions of contact with various molecules-partners.     

Spatial structure peculiarities of influenza A virus matrix M1 protein in an acidic solution that simulates the internal lysosomal medium

The structure of the C-terminal domain of the influenza virus A matrix M1 protein, for which X-ray diffraction data were still missing, was studied in acidic solution. Matrix M1 protein was bombarded with thermally-activated tritium atoms, and the resulting intramolecular distribution of the tritium label was analyzed to assess the steric accessibility of the amino acid residues in this protein. This technique revealed that interdomain loops and the C-terminal domain of the protein are the most accessible to labeling with tritium atoms. A model of the spatial arrangement of the C-terminal domain of matrix M1 protein was generated using rosetta software adjusted to the data obtained by tritium planigraphy experiments. This model suggests that the C-terminal domain is an almost flat layer with a three-α-helical structure. To explain the high level of tritium label incorporation into the C-terminal domain of the M1 protein in an acidic solution, we also used independent experimental approaches (CD spectroscopy, limited proteolysis and MALDI-TOF MS analysis of the proteolysis products, dynamic light scattering and analytical ultracentrifugation), as well as multiple computational algorithms, to analyse the intrinsic protein disorder. Taken together, the results obtained in the present study indicate that the C-terminal domain is weakly structured. We hypothesize that the specific 3D structural peculiarities of the M1 protein revealed in acidic pH solution allow the protein greater structural flexibility and enable it to interact effectively with the components of the host cell.     

Modelling protein three-dimensional structure using tritium planigraphy

We propose the use of data on the topography of the label-accessible surface of a protein molecule obtained by the method of tritium planigraphy as a criterion for choosing the optimal intermediate arrangements of alpha-helices in globular proteins so as to model their three-dimensional structures. This approach has been used for modelling the three-dimensional structure of parvalbumin III from pike. The proposed model has been compared with high-resolution X-ray structural data for a related protein, paryvalbumin from carp. The possibilities and limitations of this approach are discussed.     

Spatially encoded strategies in the execution of biomolecular-oriented 3D NMR experiments

Three-dimensional nuclear magnetic resonance (3D NMR) provides one of the foremost analytical tools available for the elucidation of biomolecular structure, function and dynamics. Executing a 3D NMR experiment generally involves scanning a series of time-domain signals S(t ₃), as a function of two time variables (t ₁, t ₂) which need to undergo parametric incrementations throughout independent experiments. Recent years have witnessed extensive efforts towards the acceleration of this kind of experiments. Among the different approaches that have been proposed counts an “ultrafast” scheme, which distinguishes itself from other propositions by enabling—at least in principle—the acquisition of the complete multidimensional NMR data set within a single transient. 2D protein NMR implementations of this single-scan method have been demonstrated, yet its potential for 3D acquisitions has only been exemplified on model organic compounds. This publication discusses a number of strategies that could make these spatial encoding protocols compatible with 3D biomolecular NMR applications. These include a merging of 2D ultrafast NMR principles with temporal 2D encoding schemes, which can yield 3D HNCO spectra from peptides and proteins within ≈100 s timescales. New processing issues that facilitate the collection of 3D NMR spectra by relying fully on spatial encoding principles are also assessed, and shown capable of delivering HNCO spectra within 1 s timescales. Limitations and prospects of these various schemes are briefly addressed.     

Probing the structural determinants of yellow fluorescence of a protein from Phialidium sp

Fluorescent proteins homologous to green fluorescent protein (avGFP) display pronounced spectral variability due to different chromophore structures and variable chromophore interactions with the surrounding amino acids. To gain insight into the structural basis for yellow emission, the 3D structure of phiYFP (λ_em = 537 nm), a protein from the sea medusa Phialidium sp., was built by a combined homology modeling – mass spectrometry approach. Mass spectrometry of the isolated chromophore-bearing peptide reveals that the chromophore of phiYFP is chemically identical to that of avGFP (λ_em = 508 nm). The experimentally acquired chromophore structure was combined with the homology-based model of phiYFP, and the proposed 3D structure was used as a starting point for identification of the structural features responsible for yellow fluorescence. Mutagenesis of residues in the local chromophore environment of phiYFP suggests that multiple factors cooperate to establish the longest-wavelength emission maximum among fluorescent proteins with an unmodified GFP-like chromophore.     

Structures of Helical Plant Virus Ribonucleoproteins as Assessed by Tritium Planigraphy and Theoretical Modeling

This review considers the results of probing the structure of ribonucleoprotein particles of helical plant viruses by tritium planigraphy (TP). This method works by exposing macromolecular targets to a beam of tritium atoms and analyzing the tritium label distribution along the macromolecule length. The TP data combined with theoretical predictions made it possible to propose a structural model of the coat protein for the virions of potato viruses X (the type representative of potexviruses) and A (a potyvirus), which eluded X-ray diffraction analysis so far. TP revealed fine structural differences between the wild-type tobacco mosaic virus (strain U1) and its temperature-sensitive mutant with an altered coat protein and host specificity. The possibilities of using TP for studying the RNA–protein interactions in helical virus particles are discussed.     

Remote sensing of forest gas exchange: Considerations derived from a tomographic perspective

The global exchange of gas (CO₂, H₂O) and energy (sensible and latent heat) between forest ecosystems and the atmosphere is often assessed using remote sensing (RS) products. Although these products are essential in quantifying the spatial variability of forest–atmosphere exchanges, large uncertainties remain from a measurement bias towards top of canopy fluxes since optical RS data are not sensitive for the vertically integrated forest canopy. We hypothesize that a tomographic perspective opens new pathways to advance upscaling gas exchange processes from leaf to forest stands and larger scales. We suggest a 3D modelling environment comprising principles of ecohydrology and radiative transfer modelling with measurements of micrometeorological variables, leaf optical properties and forest structure, and assess 3D fields of net CO₂ assimilation (A_n) and transpiration (T) in a Swiss temperate forest canopy. 3D simulations were used to quantify uncertainties in gas exchange estimates inherent to RS approaches and model assumptions (i.e. a big‐leaf approximation in modelling approaches). Our results reveal substantial 3D heterogeneity of forest gas exchange with top of canopy A_n and T being reduced by up to 98% at the bottom of the canopy. We show that a simplified use of RS causes uncertainties in estimated vertical gas exchange of up to 300% and that the spatial variation of gas exchange in the footprint of flux towers can exceed diurnal dynamics. We also demonstrate that big‐leaf assumptions can cause uncertainties up to a factor of 10 for estimates of A_n and T. Concluding, we acknowledge the large potential of 3D assessments of gas exchange to unravelling the role of vertical variability and canopy structure in regulating forest–atmosphere gas and energy exchange. Such information allows to systematically link canopy with global scale controls on forest functioning and eventually enables advanced understanding of forest responses to environmental change.     

Molecular Structure,Conformation and Interactions of Antitumor Antibiotic Cyanonaphthridinomycin,a Covalent Binder of DNA

Abstract

X-ray, NMR and molecular modeling studies on cyanonaphthridinomycin (C₂₂ H₂₆N₄O₅), a DNA binding antibiotic, have been carried out to study the structure, conformation and interactions with DNA. The crystals belong to the space group P₂₁ with the cell dimensions of a = 5.934(1), b = 20.684(4), c = 16.866(3)A γ = 90.9° and Z = 4(two molecules/asymmetric unit). The structure was solved by direct methods and difference Fourier methods and refined to an R value of 0.087 for 4061 reflections. The conformation of the molecule is compared with that of naphthridinomycin. There are differences in the orientation of the methoxyl group and the saturated oxazole ring. 1 and 2D NMR studies have been carried out and the dihedral angles obtained from coupling constants have been compared with those obtained from the crystal structure. Molecular mechanics studies were carried out to obtain the energy minimized structure and its comparison with X-ray and NMR results. Molecular modelling studies were performed to propose models for drug-DNA interactions. Both partial intercalation and groove-binding models have been proposed.     

Studying Liposomes by Tritium Bombardment

Bilayer liposomes from a mixture of dipalmitoylphosphatidylcholine (DPPC) and dipalmitoylphosphatidylethanolamine (DPPC:DPPE=8:2, molar ratio) or DPPC labeled with ¹⁴C-DPPC (DPPC:¹⁴C-DPPC) were bombarded with thermally activated tritium atoms. The tritiated liposomes were hydrolyzed by phospholipase C, and the tritium incorporation into different parts of the bilayer along its thickness was determined. The tritium flux attenuation coefficients were calculated for the headgroup (k₁=0.176±0.032 Å^–1) and acylglycerol residue (k₂=0.046±0.004 Å^–1) layers indicating a preferential attenuation of the tritium flux in the headgroup region and relative transparence of the membrane hydrophobic part. The finding is potentially important to apply tritium bombardment for investigation of spatial organization of transmembrane proteins in their native lipid environment.     

Possibility to study cell membrane topography using tritium planigraphy

The method of tritium planigraphy was adopted for the investigation of intact cells. Conditions for the incorporation of thermally activated tritium atoms in the erythrocytes are described. The accessibility of erythrocytes hemoglobin for tritium was compared to that of free hemoglobin. By comparing specific radioactivities of amino acids it was shown that the incorporation of the label into free hemoglobin was over 100 times higher than into that in erythrocytes. The cell membrane was highly tritiated. Thus the plasma membrane protects the cell inner regions from penetration of the hot tritium atoms. Tritium planigraphy can be used for studying the cell surface topography.     

The characterization of pc-polylines representing protein backbones

The backbone of a protein is typically represented as either a C _α-polyline, a three-dimensional (3D) polyline that passes through the C _α atoms, or a tuple of ϕ,ψ pairs while its fold is usually assigned using the 3D topological arrangement of the secondary structure elements (SSEs). It is tricky to obtain the SSE composition for a protein from the C _α-polyline representation while its 3D SSE arrangement is not apparent in the two-dimensional (2D) ϕ,ψ representation. In this article, we first represent the backbone of a protein as a pc-polyline that passes through the centers of its peptide planes. We then analyze the pc-polylines for six different sets of proteins with high quality crystal structures. The results show that SSE composition becomes recognizable in pc-polyline presentation and consequently the geometrical property of the pc-polyline of a protein could be used to assign its secondary structure. Furthermore, our analysis finds that for each of the six sets the total length of a pc-polyline increases linearly with the number of the peptide planes. Interestingly a comparison of the six regression lines shows that they have almost identical slopes but different intercepts. Most interestingly there exist decent linear correlations between the intercepts of the six lines and either the average helix contents or the average sheet contents and between the intercepts and the average backbone hydrogen bonding energetics. Finally, we discuss the implications of the identified correlations for structure classification and protein folding, and the potential applications of pc-polyline representation to structure prediction and protein design.     

Theoretical Model of the Three-dimensional Structure of a Disease Resistance Gene Homolog Encoding Resistance Protein in Vigna mungo

Abstract

Plant disease resistance (R) genes, the key players of innate immunity system in plants encode ‘R’ proteins. ‘R’ protein recognizes product of avirulance gene from the pathogen and activate downstream signaling responses leading to disease resistance. No three dimensional (3D) structural information of any ‘R’ proteins is available as yet. We have reported a ‘R’ gene homolog, the 'VMYR1′, encoding ‘R’ protein in Vigna mungo. Here, we describe the homology modeling of the 'VMYR1′ protein. The model was created by using the 3D structure of an ATP-binding cassette transporter protein from Vibrio cholerae as a template. The strategy for homology modeling was based on the high structural conservation in the superfamily of P-loop containing nucleoside triphosphate hydrolase in which target and template proteins belong. This is the first report of theoretical model structure of any ‘R’ proteins.     

Tritium planigraphy: Differences in the spatial structures of the influenza virus M1 protein in crystal,solution, and virion

The structure of the M1 protein of the influenza virus A/Puerto Rico/8/34 (PR8, subtype H1N1) in solution at acidic pH and in the composition of the virion has been studied by the tritium planigraphy method. A model of the spatial structure was constructed using a special algorithm simulating the experiment and a set of algorithms for predicting the secondary structure and disordered regions in proteins. The tertiary structure was refined using the Rosetta program. For a comparison of the structures in solution and inside the virion, the data of X-ray diffraction analysis for the NM domain were also used. The main difference in the structures of the protein in solution and the crystalline state is observed in the region of contact of N and M domains, which in the crystalline state is packed more densely. The regions of the maximum label incorporation almost completely coincide with unstructured regions in the protein that were predicted by the bioinformatics analysis. These regions are concentrated in the C domain and in loop regions between M, N, and C domains. The data were confirmed by analytical centrifugation and dynamic light scattering. Anomalous hydrodynamic dimensions and a low structuration of the M1 protein in solution were found. The polyfunctionality of the protein in the cell is probably related to its flexible tertiary structure, which, owing to unstructured regions, provides contact with various partner molecules.     

Application of three-dimensional molecular hydrophobicity potential to the analysis of spatial organization of membrane domains in proteins: I. Hydrophobic properties of transmembrane segments of Na+, K+-ATPase

A new computer-aided molecular modeling approach based on the concept of three-dimensional (3D) molecular hydrophobicity potential has been developed to calculate the spatial organization of intramembrane domains in proteins. The method has been tested by calculating the arrangement of membrane-spanning segments in the photoreaction center ofRhodopseudomonas viridis and comparing the results obtained with those derived from the X-ray data. We have applied this computational procedure to the analysis of interhelical packing in membrane moiety of Na⁺, K⁺-ATPase. The work consists of three parts. In Part I, 3D distributions of electrostatic and molecular hydrophobicity potentials on the surfaces of transmembrane helical peptides were computed and visualized. The hydrophobic and electrostatic properties of helices are discussed from the point of view of their possible arrangement within the protein molecule. Interlocation of helical segments connected with short extramembrane loops found by means of optimization of their hydrophobic/hydrophilic contacts is considered in Part II. The most probable 3D model of packing of helical peptides in the membrane domain of Na⁺, K⁺-ATPase is discussed in the final part of the work.     

Investigation of helical plant virus ribonucleoprotein structures with the help of tritium planigraphy and theoretical modeling

The results of the studies of helical plant virus structures by tritium planigraphy (TP) method are discussed. TP method is based on bombardment of macromolecular objects with a stream of tritium atoms, followed by analysis of tritium label distribution along the macromolecule. By combining the TP data with the results of theoretical predictions of the protein structure, it turned out to be possible to propose a model of the coat protein structure in the virions of potato virus X (the type member of potexvirus group) and potato virus A (one of the members of potyvirus group). With the help of TP it also managed to find subtle differences in the coat protein structure between wildtype tobacco mosaic virus (strain U1) and its mutant with two amino acid substitutions in the coat protein and alter host specificity.     

Oxygen effect and influence of buffer on radiation-induced tritium cleavage from phage-T2-DNA-(methyl-3H) in aqueous solution

Summary The effect of gamma irradiation on tritium release into water (HTO) from phage T2-DNA-(methyl-³H) was studied in diluted aqueous solution. The influence of O₂ and of citrate and phosphate buffer was investigated. In oxygenated solutions an enhancement ratio of 3 was found. From the linear dose yield relationsG values were calculated. In the presence of N₂O tritium release was doubled, whereas tritium release decreased with increasing citrate concentration. It has been concluded that the major precursor of this tritium release is the OH radical. This was substantiated by experiments using thymine-(methyl-³H) and dimethylsulfoxide.     

Intrinsically unstructured regions in the C domain of the influenza virus M1 protein

The M1 matrix protein of the influenza virus is one of the main structural components of the virion that performs several different functions in the infected cell. X-ray analysis (with 2.08 Å resolution) has been performed for the N-terminal part of the M1 protein (residues 2–158) but not for its C-terminal domain (159–252). In the present study, we analyzed the structure of the M1 protein of the influenza virus A/Puerto Rico/8/34 (H1N1) strain in acidic solution using tritium planigraphy. The incorporation of tritium label into the domains of the M1 protein were studied; the C domain and the interdomain loops are preferentially accessible to tritium. Analytical centrifugation and dynamic laser light scattering demonstrated anomalous hydrodynamic parameters and low structuredness of the M1 protein, which has also been confirmed by circular dichroism data. Bioinformatic analysis of the M1 protein sequence revealed intrinsically unstructured segments that were concentrated in the C domain and interdomain loops between the N-, M-, and C domains. We suggest that the multifunctionality of the M1 protein in a cell is determined by the plasticity of its tertiary structure, which is caused by the presence of intrinsically unstructured segments.     

The conformational flexibility of the antibiotic virginiamycin M1

The antibiotic virginiamycin is a combination of two molecules, virginiamycin M₁ (VM1) and virginiamycin S₁ (VS1) or analogues, which function synergistically by binding to bacterial ribosomes and inhibiting bacterial protein synthesis. Both VM1 and VS1 dissolve poorly in water and are soluble in more hydrophobic solvents. We have recently reported that the 3D conformation of VM1 in CDCl₃ solution (Aust. J. Chem. 57:415, 2004; Org. Biomol. Chem. 2:2919, 2004) differs markedly from the conformation bound to a VM1 binding enzyme (Sugantino and Roderick in Biochemistry 41:2209, 2002) and to 50S ribosomes (Hansen et al. in J. Mol. Biol. 330:1061, 2003) as found by X-ray crystallographic studies. We now report the results of further NMR studies and subsequent molecular modeling of VM1 dissolved in CD₃CN/H₂O and compare the structure with that in CD₃OD and CDCl₃. The conformations of VM1 in CD₃CN/H₂O, CD₃OD and CDCl₃ differ substantially from one another and from the bound form, with the aqueous form most like the bound structure. We propose that the flexibility of the VM1 molecule in response to environmental conditions contributes to its effectiveness as an antibiotic.     

X-ray crystal structure and molecular dynamics simulation of bovine pancreas phospholipase A2–n-dodecylphosphorylcholine complex

The crystal structure of n-dodecylphosphorylcholine (n-C₁₂PC)–bovine pancreas phospholipase A₂ (PLA₂) complex provided the following structural.characteristics: (1) the dodecyl chain of n-C₁₂PC was located at the PLA₂ N -terminal helical region by hydrophobic interactions, which corresponds to the binding pocket of 2-acyl fatty acid chain (β-chain) of the substrate phospholipid, (2) the region from Lys-53 to Lys-56 creates a cholinereceiving pocket of n-C₁₂PC and (3) the N-termillal group of Ala-1 shifts significantly toward the Tyr-52 OH group by the binding of the n-C1₂PC inhibitor. Since the accuracy of the X-ray analysis (R = 0.275 at 2.3 Å resolution) was insufficient to establish these important X-ray insights, the complex structure was further investigated through the molecular dynamics (M D) simulation, assuming a system in aqueous solution at 310K. The M D simulation covering 176 ps showed that the structural characteristics observed by X-ray analysis are intrinsic and also stable in the dynamic state. Furthermore, the M D simulation made clear that the PLA₂ binding pocket is large enough to permit the conformational fluctuation of the n-C₁₂PC hydrocarbon chain. © 1994 Wiley-Liss, Inc. © 1994 Wiley-Liss, Inc.