Deposition of newly synthesized histones: misinterpretations due to cross-linking density-labeled proteins with Lomant's reagent

We have reinvestigated studies using Lomant's reagent to cross-link newly synthesized density-labeled histones into octameric complexes to determine the nature of histone deposition. The analysis has additionally included procedures for reversal of the cross-link in order to analyze the individual histones in these complexes. These studies indicate that density-labeled, newly synthesized histones form hybrid octameric structures composed of both new and old histones. These studies also suggest that previous interpretations by other investigators for the production of homogeneous complexes (100% dense octamer containing 100% new histones) are misinterpretations due to the presence of non-histone protein that contaminates the preparation, even under conditions where much of this non-histone protein is removed by use of ion-exchange resins. These non-histone proteins can be fractionated on density gradients as un-cross-linked proteins with molecular weights that mimic those of cross-linked histone complexes.     

Isopycnic centrifugation of mammalian metaphase chromosomes in Nycodenz

Separation of chromosomes on the basis of buoyant density has proved difficult due to their high density and sensitivity to high ionic strength. Nycodenz is a new non-ionic gradient medium which offers significant advantages over previously described media for separation of chromosomes. The purpose of this study was to examine the banding characteristics of isolated mammalian metaphase chromosomes in Nycodenz gradients. The results indicate that chromosomes can be efficiently concentrated and separated from nuclei using Nycodenz gradients. Furthermore, chromosomes density-labeled with bromodeoxyuridine (BrdU) can be separated from unlabeled chromosomes in Nycodenz gradients. Nycodenz does not appear to alter chromosome morphology or protein complement. The introduction of Nycodenz represents a significant new tool for use in chromosome separation and purification.     

Buoyant densities of macromolecules, macromolecular complexes, and cell organelles in Nycodenz gradients

Nycodenz is a new nonionic iodinated density gradient medium which has several advantages over metrizamide. Although, overall, biological samples band at similar densities in Nycodenz and metrizamide gradients, a number of significant differences were found. As compared with metrizamide, not only does Nycodenz appear to interact less with proteins but also the buoyant density of chromatin is less affected by the amount loaded onto the gradient. A high degree of resolution is obtainable using Nycodenz gradients; thus, it is possible to separate density-labeled DNA and to subfractionate subcellular membrane fractions.     

Sedimentation equilibrium of proteins in density gradients.

The technique of sedimentation equilibrium in density gradients in the analytical ultracentrifuge has been applied to the study of proteins. A variety of effects and procedures including the use of density marker beads, the effects of pressure on buoyant density and pH, and the calculation of compositional density gradient proportionality constants and density--refractive index relations have been developed. The buoyant densities of twenty-four proteins have been measured and hydration values computed. The buoyant titrations of six proteins have been measured. These data have been interpreted in terms of the buoyant titrations which have been obtained for six ionizable homopolypeptides, five copolypeptides, two non-ionizable homopolypeptides and three chemically modified proteins. Spectropolarimetry and potentiometric titrations were employed to further interpret these data. Approximate values for dissociation constants, numbers of ionizable residues, and the nature of ions bound or dissociated upon ionization have been obtained. The relation between potentiometric and buoyant titrations and the use of density gradient centrifugation as a probe for protein structure have been explored.     

Vibrational analysis of the structure of gramicidin A. II. Vibrational spectra.

Raman and infrared spectra have been obtained of gramicidin A (GA) in the crystalline state both in the native form and complexed with CsSCN and KSCN, in solution in dioxane, and incorporated into lipid vesicles. Based on predictions from normal mode calculations of a number of relevant single- and double-stranded beta-helix conformations (Naik and Krimm, 1986), it has been possible to assign the structures of GA that are present under the above conditions. In the crystalline state, native GA has a double-stranded increases decreases beta 5.6 structure, whereas complexes with CsSCN or KSCN adopt a increases decreases beta 7.2 structure. In dioxane solution, the increases decreases beta 5.6 structure predominates. In lipid vesicles, the single-stranded beta 6.3-helix is found, which converts to a double-stranded helix on drying the sample. These results support our previous studies in showing that normal mode analysis can be a powerful technique in obtaining three-dimensional structural information from vibrational spectra.     

Analysis of structural proteins of purified murine cytomegalovirus.

Murine cytomegalovirus propagated in mouse embryo fibroblasts was purified by the following procedures. (i) Extracellular virus was concentrated by centrifugation at 100,000 x g for 90 min. (ii) The concentrated virus was passed through a Bio-Rad Bio-Gel A-15m column to eliminate contaminating materials smaller than 15 x 10(6) daltons. Most of the virus was recovered in the void volume of the column. (iii) Two consecutive centrifugations through 20 to 50% potassium tartrate gradients were performed. After the second tartrate gradient centrifugation, symmetrical, coinciding peaks of plaque titer, protein, and radioactivity were found at a density between 1.20 g/cm3 and 1.21 g/cm3. To establish purification criteria, virus was purified from two different mixtures: [35S]methionine-labeled extracellular virus, mixed with an equal volume of unlabeled normal culture fluid, and unlabeled extracellular virus mixed with an equal volume of [35S]methionine-labeled normal culture fluid. At the end of the procedure, the extent of purification, as judged by the ratio of cellular to viral radioactivity was at least 70-fold. Virus proteins were analyzed by electrophoresis on a 5 to 20% gradient polyacrylamide gel slab. After gel electrophoresis,, Coomassie brilliant blue staining profiles and autoradiograms of the purified virus preparations were compared. At least 33 virus structural protein bands were present. The molecular weights of these proteins ranged from 11,500 to 255,000. The sum of the molecular weights of the virus structural proteins was 2,462,000. Autoradiograms obtained from electrophoresis of purified [14C]glucosamine-labeled virus showed that at lease 6 of the 33 viral structural proteins were glycoproteins.     

Metrizamide in D2O — A novel solute for the separation of labeled and unlabeled proteins by equilibrium density gradient centrifugation

Metrizamide(2-(3-acetamido-5-N-methylacetamido-2,4,6-triiodobenzamido)-2-deoxy-d-glucose) dissolved in D₂O was found to be a very suitable medium for the separation of labeled and unlabeled proteins by equilibrium gradient sedimentation. It is nontoxic, and has little influence on the activity of enzymes. Solutions in the density range of 1.3–1.45 g cm^?3 have low viscosities. Since the spontaneous equilibrium gradient, which is dependent on the angular velocity, occurs only after a long time of centrifugation in metrizamide solutions, the equilibrium density gradient sedimentation of proteins can be performed at the highest available speed with any preformed shallow gradient. Examples for the separation of proteins of different densities are given.     

Plant Disease and the Regulation of Enzymes Involved in Lignification: Increased Rate of De Novo Synthesis of the Three Tobacco O-Methyltransferases during the Hypersensitive Response to Infection by Tobacco Mosaic Virus

The mechanism underlying the increase of activity of the three O-methyltransferases of tobacco (Nicotiana tabacum) after infection by tobacco mosaic virus (TMV) has been investigated with a density-labeling method. The three O-methyltransferases from healthy or TMV-infected leaves fed with H₂O or ²H₂O were purified by ion-exchange chromatography and their mean buoyant densities were calculated from their respective distribution profiles after centrifugation to equilibrium on RbCl gradients. Densities were corrected with respect to the mean buoyant density of a radioactive density marker prepared from tobacco leaves floated on a solution containing l-[³H]leucine and selected on a preparative gradient for its density close to those of the O-methyltransferases. The introduction of ²H into the pool of amino acids from which the enzymic proteins were synthesized was monitored. By measurement of the labeling of β-galactosidase synthesized by bacteria from the plant amino acids, it was shown that infection did not alter the rate of labeling of the pool of amino acids. The buoyant-density values of the three O-methyltransferases were determined, and density-labeled enzymes from healthy and infected materials were compared. The largest density shifts from the native enzyme were measured for O-methyltransferases from infected leaves. These results show that the increase in activity of the three enzymes after infection is due to the stimulation of the rate of de novo synthesis of enzyme proteins.     

Interactions between globular proteins and F-actin in isotonic saline solution.

Solutions of each of three different globular proteins (cytochrome c, chromophorically labeled serum albumin, and chromophorically labeled aldolase), mixed with another unlabeled globular protein or with fibrous actin, were prepared in pH 8.0 Tris-HCl buffer containing 0.15 M NaCl. Each solution was centrifuged at low speed, at 5 degrees C, until unassociated globular protein in solution achieved sedimentation equilibrium. Individual absorbance gradients of both macrosolutes in the mixtures subsequent to centrifugation were obtained via optical scans of the centrifuge tubes at two wavelengths. The gradients of each macrosolute in mixtures of two globular proteins revealed no association of globular proteins under the conditions of these experiments, but perturbation of the gradients of serum albumin, aldolase, and cytochrome c in the presence of F-actin indicated association of all three globular proteins with F-actin. Perturbation of actin gradients in the presence of serum albumin and aldolase suggested partial depolymerization of the F-actin by the globular protein. Analysis of the data with a simple phenomenological model relating free globular protein, bound globular protein, and total actin concentration provided estimates of the respective equilibrium constants for association of serum albumin and aldolase with F-actin, under the conditions of these experiments, of the order of 0.1 microM-1.     

Isotope labeling strategies for the study of high-molecular-weight proteins by solution NMR spectroscopy

The development of isotope labeling methodology has had a significant impact on NMR studies of high-molecular-weight proteins and macromolecular complexes. Here we review some of this methodology that has been developed and used in our laboratory. In particular, experimental protocols are described for the production of highly deuterated, uniformly 15N- and 13C-labeled samples of large proteins, with optional incorporation of selective isotope labels into methyl groups of isoleucine, leucine and valine residues. Various types of methyl labeling schemes are assessed, and the utility of different methyl labeling strategies is highlighted for studies ranging from protein structure determination to the investigation of side-chain dynamics. In the case of malate synthase G (MSG), the time frame of the whole preparation, including the protein refolding step, is about 70 h.     

Intein-based biosynthetic incorporation of unlabeled protein tags into isotopically labeled proteins for NMR studies

Segmental isotopic labeling of proteins using protein ligation is a recently established in vitro method for incorporating isotopes into one domain or region of a protein to reduce the complexity of NMR spectra, thereby facilitating the NMR analysis of larger proteins. Here we demonstrate that segmental isotopic labeling of proteins can be conveniently achieved in Escherichia coli using intein-based protein ligation. Our method is based on a dual expression system that allows sequential expression of two precursor fragments in media enriched with different isotopes. Using this in vivo approach, unlabeled protein tags can be incorporated into isotopically labeled target proteins to improve protein stability and solubility for study by solution NMR spectroscopy.     

Classification of subcellular location by comparative proteomic analysis of native and density-shifted lysosomes

One approach to the functional characterization of the lysosome lies in the use of proteomic methods to identify proteins in subcellular fractions enriched for this organelle. However, distinguishing between true lysosomal residents and proteins from other cofractionating organelles is challenging. To this end, we implemented a quantitative mass spectrometry approach based on the selective decrease in the buoyant density of liver lysosomes that occurs when animals are treated with Triton-WR1339. Liver lysosome-enriched preparations from control and treated rats were fractionated by isopycnic sucrose density gradient centrifugation. Tryptic peptides derived from gradient fractions were reacted with isobaric tag for relative and absolute quantitation eight-plex labeling reagents and analyzed by two-dimensional liquid chromatography matrix-assisted laser desorption ionization time-of-flight MS. Reporter ion intensities were used to generate relative protein distribution profiles across both types of gradients. A distribution index was calculated for each identified protein and used to determine a probability of lysosomal residence by quadratic discriminant analysis. This analysis suggests that several proteins assigned to the lysosome in other proteomics studies are not true lysosomal residents. Conversely, results support lysosomal residency for other proteins that are either not or only tentatively assigned to this location. The density shift for two proteins, Cu/Zn superoxide dismutase and ATP-binding cassette subfamily B (MDR/TAP) member 6, was corroborated by quantitative Western blotting. Additional balance sheet analyses on differential centrifugation fractions revealed that Cu/Zn superoxide dismutase is predominantly cytosolic with a secondary lysosomal localization whereas ATP-binding cassette subfamily B (MDR/TAP) member 6 is predominantly lysosomal. These results establish a quantitative mass spectrometric/subcellular fractionation approach for identification of lysosomal proteins and underscore the necessity of balance sheet analysis for localization studies.     

A simple, two-component buffer enhances use of chromatofocusing for processing of therapeutic proteins

To extend the feasibility of chromatofocusing to industrial use, we have developed a simple chromatofocusing buffer system capable of generating a smooth pH gradient without the use of an external gradient maker. Using two cationic buffering components, an internal pH gradient is produced on appropriate chromatography media over a broad pH range (9.5 to 5.0). The utility of this buffer system is demonstrated with PBE94 and DEAE Sepharose fast flow ion-exchangers, as well as with experimental fast flow chromatofocusing gels. Using a rapid flow rate, we evaluated this buffer system for recovery of a therapeutic protein from a bacterial cell extract. The simplicity of the buffer system requiring no external gradient maker, coupled with the use of fast flow chromatographic media to produce broad-range pH gradients, improves the scalability of chromatofocusing for processing of therapeutic proteins.     

Structural determination of biomolecular interfaces by nuclear magnetic resonance of proteins with reduced proton density

Protein interactions are important for understanding many molecular mechanisms underlying cellular processes. So far, interfaces between interacting proteins have been characterized by NMR spectroscopy mostly by using chemical shift perturbations and cross-saturation via intermolecular cross-relaxation. Although powerful, these techniques cannot provide unambiguous estimates of intermolecular distances between interacting proteins. Here, we present an alternative approach, called REDSPRINT (REDduced/Standard PRoton density INTerface identification), to map protein interfaces with greater accuracy by using multiple NMR probes. Our approach is based on monitoring the cross-relaxation from a source protein (or from an arbitrary ligand that need not be a protein) with high proton density to a target protein (or other biomolecule) with low proton density by using isotope-filtered nuclear Overhauser spectroscopy (NOESY). This methodology uses different isotropic labeling for the source and target proteins to identify the source-target interface and also determine the proton density of the source protein at the interface for protein-protein or protein-ligand docking. Simulation indicates significant gains in sensitivity because of the resultant relaxation properties, and the utility of this technique, including a method for direct determination of the protein interface, is demonstrated for two different protein–protein complexes.     

Phalloidin shift on velocity sedimentation sucrose gradient centrifugation for identification of microfilament-associated proteins

Velocity sedimentation by sucrose density gradient centrifugation has been used to characterize ascites microvillar microfilament cores and to identify microfilament-associated proteins. Fluoride, calcium, phalloidin and chemical cross-linking treatments of microvilli during Triton X-100 extractions increase the sedimentation rate of the microfilament core, compared with untreated control samples. Electrophoretic analyses of the distributions of actin, alpha-actinin and other microfilament-associated proteins across the gradients indicate that the primary mechanism for stabilization of the microfilament core is the reduction of fragmentation of the microfilaments. Significantly, alpha-actinin could be completely removed from the microfilaments by calcium treatment without causing a decrease in the size of the microfilament core. Because of the specificity of phalloidin in the stabilization of microfilaments, the shift on the gradients of microfilaments and their associated proteins in the presence of phalloidin provides a diagnostic tool for the identification of microfilament-associated proteins. This phalloidin shift technique should have widespread utility in the analysis of actin forms and microfilament-associated proteins from complex cell fractions.     

Automated structure determination of proteins with the SAIL-FLYA NMR method

The labeling of proteins with stable isotopes enhances the NMR method for the determination of 3D protein structures in solution. Stereo-array isotope labeling (SAIL) provides an optimal stereospecific and regiospecific pattern of stable isotopes that yields sharpened lines, spectral simplification without loss of information, and the ability to collect rapidly and evaluate fully automatically the structural restraints required to solve a high-quality solution structure for proteins up to twice as large as those that can be analyzed using conventional methods. Here, we describe a protocol for the preparation of SAIL proteins by cell-free methods, including the preparation of S30 extract and their automated structure analysis using the FLYA algorithm and the program CYANA. Once efficient cell-free expression of the unlabeled or uniformly labeled target protein has been achieved, the NMR sample preparation of a SAIL protein can be accomplished in 3 d. A fully automated FLYA structure calculation can be completed in 1 d on a powerful computer system.     

Reverse-phase high-performance liquid chromatography of Escherichia coli ribosomal small subunit proteins

Reverse-phase high-performance liquid chromatography has been explored as an approach for the separation of the proteins of the 30 S subunit of Escherichia coli ribosomes. The majority of these proteins are of similar molecular weight and isoelectric point, making separation by size exclusion or ion exchange difficult. With the use of an octadecasilyl silica column and a trifluoroacetic acid-acetonitrile solvent system, the 21 proteins of the 30 S subunit have been separated into 15 peaks. The yield of total protein recovered from the column was ≥85%. The proteins present in each peak have been identified by polyacrylamide gel electrophoretic analysis of the peaks as well as by comparison with the relative retention volumes of known purified 30 S proteins on the column. The results clearly show that this method is a powerful and rapid technique for the identification and purification of 30 S proteins. Analysis of [³H]puromycin-labeled 30 S subunit protein provides an illustrative example of its utility for affinity labeling studies.     

Double labeling of chromatin proteins,in vivo and in vitro,and their two-dimensional electrophoretic resolution

A modification of the two-dimensional electrophoretic method that involves nonequilibrium pH gradients has been adapted for high resolution of chromatin proteins from sea urchin embryos. A simple method of labeling the protein, in vitro, by reductive methylation with boro[³H]hydride to a specific activity of 100,000 cpm/μg of protein is detailed. Chromatin protein may be labeled, in vivo with ¹⁴C-amino acids, and newly synthesized (³H and ¹⁴C-labeled) and preexistent proteins (only ³H labeled) may be distinguished. The method reveals that sea urchin embryo chromatin contains over 200 proteins.     

Interaction in vitro of nonepithelial intermediate filament proteins with total cellular lipids, individual phospholipids, and a phospholipid mixture

The interaction of nonepithelial intermediate filament (IF) proteins with vesicles produced from total Ehrlich ascites tumor cell lipids results in the formation of complexes which in sucrose density gradient centrifugation attain positions distinctly different from those of the original reactants. In KBr density gradient equilibrium centrifugation, the IF protein-lipid adducts accumulate as thin proteolipid films on top of the KBr gradients, whereas in the absence of lipids the proteins remain distributed within the density gradients. Similar results were obtained with vesicles derived from individual phospholipids and a mixture thereof. The affinity of IF proteins for negatively charged phospholipids is greater than that for vesicles derived from uncharged phospholipids. Limited digestion of IF proteins with various proteinases demonstrated that for optimal association of the reactants IF proteins must carry an intact N terminus and that the isolated N-terminal polypeptide itself shows strong reactivity with lipid vesicles. Arginine-phosphate interactions between the N terminus and phospholipids seem to be partly responsible for this association. However, as shown by hydrophobic interaction chromatography on phenyl- and octyl-Sepharose 4B, IF proteins and their proteolytic derivatives also appear to have high affinities for aromatic and aliphatic substructures of biologically important molecules. The results are discussed in terms of a possible functional role of IF protein-lipid interactions in the association of nonepithelial intermediate filaments with intracellular membrane systems.