Determination of refractive index increment ratios for protein-nucleic acid complexes by surface plasmon resonance

Three nucleic acid-protein complexes of 1:1 stoichiometry were analyzed by surface plasmon resonance on a Biacore biosensor to test whether or not proteins and nucleic acids yielded similar refractive index increments on binding. The expected maximum response in resonance units, (RU(exp))(max), and the observed one, (RU(obs))(max), on saturation of immobilized targets by interacting partners were compared to determine the ratio of (deltan/deltaC)(protein) to (deltan/deltaC)(nucleic acid), where n is the refractive index at the surface and C is the concentration of one partner. Our results suggest that proteins and nucleic acids behave similarly and that the discrepancy between the expected and observed maximum responses for such complexes reflects inaccurate evaluation of the binding responses. Therefore, no correction of the instrument response is required for protein and nucleic acid interaction studies on a Biacore biosensor.     

Phenomenological theory of gel electrophoresis of protein-nucleic acid complexes

A phenomenological theory of gel electrophoresis is elaborated for protein-DNA complexes involving one, two, or three binding sites on the DNA molecule. The computed electrophoretic patterns simulate experimental patterns shown by both prokaryotic and eukaryotic systems. The mechanism whereby the electrophoretic protein-DNA ladder is generated upon titration of the operator with repressor is embodied in theory of mass transport coupled to reversible interactions under chemical kinetic control. In contrast to strong interactions (association constant greater than 10(12) M-1), patterns observed with weak complexes (K less than 10(10) M-1) could be simulated only by applying the cage effect, a model of which is formulated. Theoretical underpinning is provided for the electrophoretic estimation of equilibrium association constants, and requisite chemical kinetic conditions are elucidated for direct estimation of the rate constant for dissociation of the protein-DNA complex from gel patterns. The theory thus affords an experimenter with a means for determining the conditions required to render the gel retardation method a valid procedure for evaluating equilibrium constants and/or kinetic parameters for the particular protein-nucleic acid system under investigation. These several considerations apply not only to interactions of proteins with nucleic acids (DNA or RNA) but also to a wide range of macromolecular interactions involving peptides, drugs, and other ligands as well as large assemblies such as multienzyme complexes.     

A new electron microscopic method for studying protein-nucleic acid interactions.

A new method for preparation of nucleic acid specimens for electron microscopy has been adapted to study the interaction of proteins with DNA. Both a detergent and a basic protein are added to the DNA-protein solution before spreading on a hypophase containing 0.2 m ammonium acetate. This method has been tested using T7 DNA and Escherichia coli RNA polymerase. Specifically bound enzyme molecules were clearly visible on the well extended DNA molecules; the binding sites were located at 0.59, 1.24, 1.57, and 1.86% of the total length of T7 DNA. Under carefully controlled conditions, 40–85% of the DNA molecules specifically bound at least one enzyme molecule.     

A simple assay procedure for beta-D-mannanase.

A simple assay procedure for beta-D-mannanase enzyme has been developed which employs carob D-galacto-D-mannan dyed with Remazolbrilliant Blue. Additionally, the procedure is quantitative, relatively sensitive, and highly specific for beta-D-mannanase enzyme. It can be readily used for the determination of beta-D-mannanase activity in crude enzyme preparations and column-chromatography eluates.     

A simple procedure for tenascin purification.

Here we describe a two-step procedure for purification of human tenascin from conditioned medium of the SK-MEL-28 human melanoma cell line. The first step consists in passing the conditioned media through two chromatography columns connected in sequence. The first is a large capacity gelatin--Sepharose affinity chromatography column (to remove fibronectin), the second, over which the unbound material from the first column flows directly, is a hydroxyapatite chromatography column. Under these conditions, all tenascin present in the conditioned medium binds to the hydroxyapatite chromatography column from which it is then eluted by a 5-300 mM sodium phosphate gradient. With this step, we obtain a crude tenascin preparation, concentrated about 20 times with respect to the starting conditioned medium, and in which tenascin represents more than 50% of the total protein. The second step consists of two sequential precipitations with 6% and 12.8% poly(ethylene glycol). After this step, tenascin is more than 95% pure and does not show any contamination of chondroitin-sulfate-containing proteoglycans that are known to bind to it. From 21 medium we obtain about 3-4 mg tenascin which corresponds to a yield of about 40-50%. This procedure gives a higher yield, is simpler with respect to procedures previously described, avoids the exposure of the protein to denaturing agents or harsh conditions and could be used for purification of tenascin from the conditioned media of other cell lines. Thus, this procedure may represent a simple and useful tool for the preparation of tenascin to study its biological functions.     

Specific labeling of threonine methyl groups for NMR studies of protein-nucleic acid complexes

Specific (13)C labeling of Thr methyl groups has been accomplished via the growth of a standard laboratory strain of Escherichia coli on [2-(13)C]glycerol in the presence of deuterated isoketovalerate, Ile, and Ala. Diversion of the label from the Thr biosynthetic pathway is suppressed by including Lys, Met, and Ile in the growth medium. This method complements the repertoire of methyl labeling schemes for NMR structural and dynamic studies of proteins and is particularly useful for the study of nucleic acid binding proteins because of the high propensity of Thr residues at protein-DNA and -RNA interfaces.     

A simple purification procedure for monomeric nucleosomes.

The soluble chromatin fragments from nuclei of avian erythrocytes digested with micrococcal nuclease were fractionated by the addition of sodium phosphate to 0.1 m. The supernatant consisted predominantly of monomeric nucleosomes, while most dimeric and larger nucleosomes precipitated. A variable percentage of monomers also precipitated, the exact amount depending upon the extent of digestion. The solubility properties can be used for the simple preparation of fractions that are highly enriched for monomers either containing, or deplete in, lysine-rich histone.     

Alpha-S-cysteinylthymine: a model for protein-nucleic acid cross-linking.

Crystals of alpha-S-cysteinylthymine, C8H12CIN3O4S, formula weight 281.72, are orthorhombic, space group P212121, with a=9.499 (1), b=24.072 (4), and c=5.012 (1) A, V=1146.1 (2) A3, and Z=4. The structure was determined by the direct method and refined by a full-matrix least-squares procedure to a final residual, R=0.043, using 1277 diffractometer data. From the structure, a three-dimensional model for the radiation-induced interaction of thymine residues and cysteine residues could be postulated.     

Recognition schemes for protein-nucleic acid interactions

The molecular forces involved in protein-nucleic acid interaction are electrostatic, stacking and hydrogen-bonding. These interactions have a certain amount of specificity due to the directional nature of such interactions and the spatial contributions of the steric effects of different substituent groups. Quantum chemical calculations on these interactions have been reported which clearly bring out such features. While the binding energies for electrostatic interactions are an order of magnitude higher, the differences in interaction energies for structures stabilised by hydrogen-bonding and stacking are relatively small. Thus, the molecular interactions alone cannot explain the highly specific nature of binding observed in certain segments of proteins and nucleic acids. It is therefore logical to assume that the sequence dependent three dimensional structures of these molecules help to place the functional groups in the correct geometry for a favourable interaction between the two molecules. We have carried out 2D-FT nuclear magnetic resonance studies on the oligonucleotide d-GGATCCGGATCC. This oligonucleotide sequence has two binding sites for the restriction enzyme Bam H1. Our studies indicate that the conformation of this DNA fragment is predominantly B-type except near the binding sites where the ribose ring prefers a³E conformation. This interesting finding raises the general question about the presence of specificity in the inherent backbone structures of proteins and nucleic acids as opposed to specific intermolecular interactions which may induce conformational changes to facilitate such binding.     

Zone-interference gel electrophoresis: a new method for studying weak protein-nucleic acid complexes under native equilibrium conditions.

A new and general electrophoresis method is described for the determination of dissociation constants of weak macromolecular complexes in the range of 10(-6) to 10(-4) M. The method is based on the measurement of the migration distance of a macromolecular complex in rapid dynamic equilibrium as a function of the interacting ligand concentration in a surrounding zone. Special advantages of the method are: its high sensitivity (dependent on the autoradiography, immunoblotting or staining technique used), its speed (electrophoresis time 20 min), and the independence of the Kd determination on the sample concentration of macromolecules. The latter is of great value for labile macromolecules: unknown partial inactivation does not influence the measurement. Studying the interactions between elongation factor EF-Tu and tRNA from E. coli we found for EF-Tu.GTP.aurodox.aminocyl-tRNA a Kd of 3 microM and for EF-Tu.GDP.aurodox.aminoacyl-tRNA a Kd of 11 microM at 9 degrees C.     

A protein-nucleic acid crosslink in 30S ribosomes

The data indicate that probably a single 30s ribosomal protein has been crosslinked to the 3′-ribosyl terminus of 16s RNA in intact 30s ribosomes. The crosslink was made by oxidizing the 3′-ribosyl moiety of 16s RNA to a dialdehyde with NaIO₄. One of the aldehyde groups generated in the oxidation reacted with an α- or ε-amino group of an adjacent protein to form a Schiff's base. The Schiff's base was reduced with NaBH₄ to a stable, specific covalent crosslink between the protein and the 16s RNA molecules. The crosslinked protein was tentatively identified as S1 according to the nomenclature of Wittmann et al. (1971), Mol. Gen. Genetics 111, 327.     

Methylphosphonates as probes of protein-nucleic acid interactions.

Deoxydinucleoside methylphosphonates were prepared by chemical synthesis and were introduced stereospecifically into the lac operator at two sites. These sites within d(ApApTpTpGpTpGpApGpCpGpGpApTpApApCpApApTpT), segment I, and d(ApApTpTpGpTpTpApTpCpCpGpCpTpCpApCpApApTpT), segment II, are indicated by p. Each segment containing a chiral methylphosphonate was annealed to the complementary unmodified segment. The interactions of these four modified lac operators with lac repressor were analyzed by the nitrocellulose filter binding assay. Introduction of either chiral phosphonate in segment II had little effect on the stability of the repressor-operator complex. When methylphosphonates were introduced into segment I, the affinity of lac repressor for the modified operators was shown to be dependent on the stereochemical configuration of the methylphosphonate.     

Sequence and structural features of binding site residues in protein-protein complexes: comparison with protein-nucleic acid complexes

Background

Protein-protein interactions are important for several cellular processes. Understanding the mechanism of protein-protein recognition and predicting the binding sites in protein-protein complexes are long standing goals in molecular and computational biology.

Methods

We have developed an energy based approach for identifying the binding site residues in protein–protein complexes. The binding site residues have been analyzed with sequence and structure based parameters such as binding propensity, neighboring residues in the vicinity of binding sites, conservation score and conformational switching.

Results

We observed that the binding propensities of amino acid residues are specific for protein-protein complexes. Further, typical dipeptides and tripeptides showed high preference for binding, which is unique to protein-protein complexes. Most of the binding site residues are highly conserved among homologous sequences. Our analysis showed that 7% of residues changed their conformations upon protein-protein complex formation and it is 9.2% and 6.6% in the binding and non-binding sites, respectively. Specifically, the residues Glu, Lys, Leu and Ser changed their conformation from coil to helix/strand and from helix to coil/strand. Leu, Ser, Thr and Val prefer to change their conformation from strand to coil/helix.

Conclusions

The results obtained in this study will be helpful for understanding and predicting the binding sites in protein-protein complexes.