Determining protein-protein interactions by oxidative cross-linking of a glycine-glycine-histidine fusion protein

The Ni(II) complex of the tripeptide NH2-glycine-glycine-histidine-COOH (GGH) mediates efficient protein-protein cross-linking in the presence of oxidants such as oxone and monoperoxyphthalic acid (MMPP). Here we demonstrate that GGH fused to the amino terminus of a protein can still support cross-linking. The tripeptide was expressed at the amino terminus of ecotin, a dimeric macromolecular serine protease inhibitor found in the periplasm of Escherichia coli. In the presence of Ni(OAc)2 and MMPP, GGH-ecotin is cross-linked to give a species that has an apparent molecular mass of a GGH-ecotin dimer with no observable protein degradation. The cross-linking reaction occurs between two ecotin proteins in a dimer complex. Furthermore, GGH-ecotin can be cross-linked to a serine protease target, trypsin, and the reaction is specific for proteins that interact with ecotin. The cross-linking reaction has been carried out on small peptides, and the reaction products have been analyzed by matrix-assisted laser desorption/ionization mass spectrometry. The target of the reaction is tyrosine, and the product is bityrosyl cross-links. The yield of the cross-linking is on the order of 15%. However, the reaction efficiency can be increased 4-fold by a single amino acid substitution in the carboxy terminus of ecotin that places an engineered tyrosine within 5 A of a naturally occurring tyrosine. This cross-linking methodology allows for the protein cross-linking reagent to be encoded for at the DNA level, thus circumventing the need for posttranslational modification.     

Evaluation of integrin molecules involved in substrate adhesion

Integrins were cross-linked to their extracellular matrix ligands using non-penetrating chemical cross-linkers. This procedure did not disturb the distribution of integrin in the adhesion structure and adhesion plaque integrin staining remained even when the cultures were extracted with ionic detergents. 80-90% of the beta 1 integrin in the cross-linked culture was extracted with RIPA buffer and the remaining 10-20% was recovered following reversal of the cross-linking. This separated two distinct integrin pools, one which can be cross-linked to substrate bound extracellular matrix and one which is not. The specificity of this procedure for cross-linking of integrins involved in substrate adhesion was demonstrated using NIH 3T3 cells which express both alpha 5 beta 1 and alpha 6 beta 1 integrins. alpha 6 was cross-linked only in cells plated on laminin whereas alpha 5 was cross-linked when fibronectin was present. Using antisera directed to the cytoplasmic domains of either alpha 5 or beta 1 integrin, it was demonstrated that these domains can be blocked in the intact cell but the blocking can be removed using ionic detergent extraction after chemical cross-linking. The extracellular matrix associated with the substrate surface but not that associated with the media exposed surface is both cross-linked and retained on the plastic dish following cross-linking.     

Role of nucleosome remodeling factor NURF in transcriptional activation of chromatin

In the previous paper (D.Y. Lando, J. Biomol. Struct. Dynam, 15, 129-140 (1997)) the melting of cross-linked DNA with N base pairs and omega interstrand cross-links has been considered theoretically. In the present study on the basis of these results, two simple schemes are developed for the computation of melting curves of cross-linked DNA. The investigation of influence of interstrand linking on DNA stability has been carried out by computer simulation. It is shown that the relative concentration of cross-links, CCT = omega/N, their distribution along a DNA molecule, and particular values of the entropy factors of small loops formed by cross-links in melted regions strongly affect the DNA melting temperature, Tm. On the contrary, for DNA without cross-links, a ten-fold increase or decrease in the entropy factors of small loops does not cause the Tm variation. The comparison of the results of calculation with experimental data suggests that the majority of types of cross-link neither maintain ordered parallel orientation of bases in melted regions nor increase considerably the thermostability of cross-linked base pairs. Four different ways of influence of interstrand cross-linking on the DNA double helix stability are considered. It is shown that cross-linking significantly enhances the influence of single strand stiffness in melted regions on DNA melting behavior.     

Protein-rRNA binding features and their structural and functional implications in ribosomes as determined by cross-linking studies

We have investigated protein-rRNA cross-links formed in 30S and 50S ribosomal subunits of Escherichia coli and Bacillus stearothermophilus at the molecular level using UV and 2-iminothiolane as cross-linking agents. We identified amino acids cross-linked to rRNA for 13 ribosomal proteins from these organisms, namely derived from S3, S4, S7, S14, S17, L2, L4, L6, L14, L27, L28, L29 and L36. Several other peptide stretches cross-linked to rRNA have been sequenced in which no direct cross-linked amino acid could be detected. The cross-linked amino acids are positioned within loop domains carrying RNA binding features such as conserved basic and aromatic residues. One of the cross-linked peptides in ribosomal protein S3 shows a common primary sequence motif--the KH motif--directly involved in interaction with rRNA, and the cross-linked amino acid in ribosomal protein L36 lies within the zinc finger-like motif of this protein. The cross-linked amino acids in ribosomal proteins S17 and L6 prove the proposed RNA interacting site derived from three-dimensional models. A comparison of our structural data with mutations in ribosomal proteins that lead to antibiotic resistance, and with those from protein-antibiotic cross-linking experiments, reveals functional implications for ribosomal proteins that interact with rRNA.     

Intrastrand cross-linked actin between Gln-41 and Cys-374. III. Inhibition of motion and force generation with myosin

Structural and functional properties of intrastrand, ANP (N-(4-azido-2-nitrophenyl)-putrescine) cross-linked actin filaments, between Gln-41 and Cys-374 on adjacent monomers, were examined for several preparations of such actin. Extensively cross-linked F-actin (with 12% un-cross-linked monomers) lost at 60 degrees C the ability to activate myosin ATPase at a 100-fold slower rate and unfolded in CD melting experiments at a temperature higher by 11 degrees C than the un-cross-linked actin. Electron microscopy and image reconstruction of these filaments did not reveal any gross changes in F-actin structure but showed a change in the orientation of subdomain 2 and a decrease in interstrand connectivity. Rigor and weak (in the presence of ATP) myosin subfragment (S1) binding and acto-S1 ATPase did not show major changes upon 50% and 90% ANP cross-linking of F-actin; the Kd and Km values were little affected by the cross-linking, and the Vmax decreased by 50% for the extensively cross-linked actin. The cross-linking of actin (50%) decreased the mean speed and the number of sliding filaments in the in vitro motility assays by approximately 35% while the relative force, as measured by using external load in these assays, was inhibited by approximately 25%. The mean speed of actin filaments decreased with the increase in their cross-linking and approached 0 for the 90% cross-linked actin. Also examined were actin filaments reassembled from cross-linked and purified ANP cross-linked dimers, trimers, and oligomers. All of these filaments had the same acto-S1 ATPase and rigor S1 binding properties but different behavior in the in vitro motility assays. Filaments made of cross-linked dimers moved at approximately 50% of the speed of the un-cross-linked actin. The movement of filaments made of cross-linked trimers was inhibited more severely, and the oligomer-made filaments did not move at all. These results show the uncoupling between force generation and other events in actomyosin interactions and emphasize the role of actin filament structure and dynamics in the contractile process.     

Formation of a cleavasome: enhancer DNA-2 stabilizes an active conformation of NaeI dimer

Cleavage of DNA by NaeI-type restriction enzymes is stimulated by a DNA element with affinity for the activator site of the enzyme: a cleavage-enhancer DNA element. Measurements of the mobility of NaeI activity in comparison with protein standards on gel permeation columns and glycerol gradients demonstrated that NaeI, without enhancer, can form a 70,000 MW dimer. The dimer, however, is inactive: it could not cleave the "resistant" NaeI site in M13mp18 DNA in the absence of enhancer. In cleavage assays, enhancer stimulated either DNA nicking or DNA cleavage, depending upon NaeI concentration, and reduced the NaeI concentration required for the transition from nicking to cleavage activity. A gel mobility-shift assay of the interaction of NaeI with enhancer showed the formation of two complexes. Results using different sized DNAs and different percentage acrylamide gels for gel mobility-shift analysis implied that the two complexes were caused by NaeI monomer and dimer structures rather than one and two DNA binding. Dimer formation increased with the affinity of enhancer for NaeI. UV cross-linking "captured" the NaeI-enhancer complex; electrophoretic analysis of the cross-linked products showed NaeI dimer bound to enhancer. These results imply a model for cleavage enhancement in which enhancer binding stabilizes an active NaeI dimer conformation ("cleavasome") that cleaves both DNA strands before dissociating.     

Structural and transglutaminase substrate properties of the small proline-rich 2 family of cornified cell envelope proteins

The small proline-rich (SPR) proteins are components of the cornified cell envelope of stratified squamous epithelia and become cross-linked to other proteins by transglutaminases (TGases). The SPR2 family is the most complex, as it consists of several differentially expressed members of the same size. To explore their physical and cross-linking properties, we have expressed in bacteria a human SPR2 family member, and purified it to homogeneity. By circular dichroism, it possesses no alpha or beta structure but has some organized structure associated with the central peptide repeat domain. The TGase 1, 2, and 3 enzymes expressed in epithelia use the recombinant SPR2 protein as a complete substrate in vitro, but with widely differing kinetic efficiencies, and in different ways. With TGase 1, only one glutamine on the head domain and one lysine on the tail domain were used for limited interchain cross-linking. With TGase 3, multiple head and tail domain residues were used for extensive interchain cross-linking. The total usage of glutamine and lysine residues in vitro by TGase 3 was similar to that seen in earlier in vivo studies. We conclude that SPR2 proteins are cross-linked in epithelia primarily by the TGase 3 enzyme, a minor extent by TGase 1, and probably not by TGase 2.     

Cross-linked high amylose starch for controlled release of drugs: recent advances

Cross-linked high amylose starches have been developed as excipients for the formulation of controlled-release solid dosage forms for the oral delivery of drugs. Advantages of this new class of excipients include cost-effectiveness, readily accessible industrial manufacturing technology, high active ingredient core loading and the possibility of achieving a quasi zero-order release for most drugs. In addition to the latter, other features distinguish cross-linked high amylose starches from other excipients used to prepare hydrophilic matrices. Among these are the absence of erosion, the limited swelling and the fact that increasing cross-linking degrees results in increased water uptake rate, drug release rate and equilibrium swelling. Thus the goal of the present study was to gain some insights into the mechanism of drug release control by matrices of cross-linked high amylose starch. Water transport kinetics and dimensional changes were studied in matrices placed in water at 37 degrees C by an image analysis technique. The results show that in the first 5 min, a gel layer is formed at the surface of the tablet, after which the gel front seems to halt its progression toward the center of the tablet. Water continues to diffuse through the front and to invade the core. As a consequence, this latter swells, with a predominance for radial swelling. Equilibrium swelling is reached over 3 days, when the water concentration in the tablet becomes homogeneous and the whole tablet gelifies. Solid-state 13C-NMR were acquired on cross-linked high amylose starch powders, tablets and hydrated tablets with varying cross-linking degrees. They show a predominance of the V-type single helix arrangement of amylose in the dry state irrespective of the cross-linking degree. Upon hydration, the homologues with a low cross-linking degrees show a transition from the V to the B-type double helix arrangement. It is therefore hypothesized that the capacity of amylose to undergo the V to B transition is an important factor in controlling water transport and drug release rate. Finally applications to different drugs are reviewed briefly. They illustrate the versatility of this technology as generic versions of zero order OROS drug (Efidac) and Fickian release conventional matrices (Voltaren SR) were developed and successfully tested in pilot clinical studies to be bioequivalent to the references. These studies further showed that cross-linked high amylose starch matrices have the lowest inter-subject variability among the systems tested and show a total absence of food effect.     

Intradimerically tethered DNA topoisomerase II is catalytically active in DNA transport

A covalently cross-linked dimer of yeast DNA topoisomerase II was created by fusing the enzyme with the GCN4 leucine zipper followed by two glycines and a cysteine. Upon oxidation of the chimeric protein, a disulfide bond forms between the two carboxyl termini, covalently and intradimerically cross-linking the two protomers. In addition, all nine of the cysteines naturally occurring in topoisomerase II have been changed to alanines in this construct. This cross-linked, cysteine-less topoisomerase II is catalytically active in DNA duplex passage as indicated by ATP-dependent DNA supercoil relaxation and kinetoplast DNA decatenation assays. However, these experiments do not directly distinguish between a "one-gate" and a "two-gate" mechanism for the enzyme.     

Differential proximity probing of two DNA binding sites in the Escherichia coli recA protein using photo-cross-linking methods

The DNA strand-exchange reaction catalyzed by the Escherichia coli RecA protein occurs between the two DNA binding sites that are functionally distinct. Site I is the site to which a DNA molecule (normally single-stranded DNA) binds first; this first binding makes site II available for additional DNA-binding (normally double- stranded DNA). Photo-cross linking was employed to identify the amino acid residues located close to the bound DNA molecule(s). A ssDNA oligo containing multiple 5-iodouracil residues (IdU) was cross-linked to RecA by irradiation with a XeC1 pulse laser (308 nm), and the cross-linked peptides were purified and sequenced. To differentiate the two DNA binding sites, we used two protocols for making RecA-ssDNA complexes: (1) IdU-containing oligo was mixed with a stoichiometric excess of RecA, a condition which favors the binding of the oligo to site I, and (2) RecA was first allowed to bind to a nonphotoreactive oligo and then chased with the IdU-containing oligo, a condition which favors the binding of the IdU-oligo to site II. We observed that when RecA was in excess (site I probing), cross-linking occurred to Met-164 which is located in the disordered loop 1 of the RecA crystal structure [Story, R.M., Weber, I.T., & Steitz, T.A. (1992) Nature 355, 318-325]. When site II was probed, the majority of cross-linking occurred to Met-202 or Phe-203, located in loop 2. These results support the idea that, as predicted by Story and co-workers (1992), the disordered loops are involved in DNA binding. The results also suggest that the two sites are not only functionally but also physically distinct.     

Cross-linked growth hormone dimers have enhanced biological activity

In this study we have investigated the effect on the bioactivity of pituitary-derived human growth hormone (hGH) and recombinant bovine (b) GH after the addition of various concentrations of the water soluble cross-linking agent 1-ethyl-3(3-dimethylaminopropyl) carbodiimide (EDC; 6.25-100 mg/ml). The biological activity of resulting cross-linked reactions were determined by its ability to promote incorporation of 35SO4(2-) into costal cartilage of hypopituitary Snell dwarf mice in vivo. Administration of EDC-treated hGH solutions resulted in a significant enhancement of hormone activity in vivo compared with non-cross-linked samples. A similar significant enhancement of bGH activity in vivo was also observed when solutions containing recombinant bGH were cross-linked using EDC. For both hGH and bGH the degree of enhancement appears to be dose-dependent for the concentration of EDC (6.25-100 mg/ml for hGH; 6.25-50 mg/ml for bGH) present in the cross-linking reactions. SDS-PAGE analysis of EDC cross-linked solutions containing hGH and bGH spiked with 125I-hGH and 125I-bGH respectively revealed that dimeric GH was the primary cross-linked component. Increasing the concentration of EDC in cross-linking reactions resulted in increased formation of dimeric hGH and bGH. There was a significant correlation between the amount of GH dimer present and the increase in biological activity, suggesting that GH dimers were responsible for the enhanced biological activity. This was confirmed by the enhanced biological activity of a purified preparation of EDC cross-linked dimeric hGH. In conclusion, covalently cross-linked GH dimers reported here have enhanced bioactivity in vivo. However, since naturally occurring GH dimers are known to have reduced biological activity, this work suggests that the structure of EDC cross-linked GH dimers differs fundamentally from that of native dimeric hGH.     

Mitochondrial NADH:ubiquinone oxidoreductase (complex I): proximity of the subunits of the flavoprotein and the iron-sulfur protein subcomplexes

The proximities of the three subunits (51, 24, and 9 kDa) of the flavoprotein subcomplex (FP) and five subunits (75, 49, 30, 18, and 13) of the iron-sulfur protein subcomplex (IP) of the bovine NADH: ubiquinone oxidoreductase (complex I) were investigated by cross-linking studies. The cross-linking reagents used were disuccinimidyl tartrate and ethylene glycol bis(succinimidyl succinate). The cross-linked products were identified by sodium dodecyl sulfate gel electrophoresis and immunoblotting with antibodies specific for each subunit. Results showed that the three FP subunits are juxtaposed to one another, and only the 51 kDa subunit of FP is in close proximity to only the 75-kDa subunit of IP. The 75-kDa subunit cross-linked to the 30- and the 13-kDa subunits, the 49-kDa subunit cross-linked to the 30-, 18-, and 13-kDa subunits, and the 30-kDa subunit cross-linked to the 18- and the 13-kDa subunits. No cross-linked products of 75+49-, 75+18-, or 18+13-kDa subunits were detected. These results are consistent with the occurrence of potential electron carriers in FP and IP subunits. These electron carriers are FMN and one iron-sulfur cluster in the 51-kDa subunit, one iron-sulfur cluster in the 24-kDa subunit, and apparently two iron-sulfur clusters in the 75-kDa subunit.     

Erythrocyte spectrin maintains its segmental motions on oxidation: a spin-label EPR study

The segmental motions of cross-linked erythrocyte skeletal protein (spectrin-actin-protein 4.1) samples, labeled with nitroxide spin labels, were monitored by conventional first-harmonic and saturation transfer second-harmonic electron paramagnetic resonance methods. Skeletal proteins were extracted from human red blood cells and treated with three oxidative reagents (diamide, hydrogen peroxide, and phenylhydrazine) to cross-link sulfhydryl groups and with one fixative reagent (glutaraldehyde) to cross-link lysine residues. The treatments provided extensive cross-linking between spectrin-actin-protein 4.1 molecules, as determined by gel electrophoresis, and surface charge modification, as determined by pl measurements. However, segmental motions of the cross-linked skeletal proteins remained generally similar to those in normal skeletal proteins. Both the weakly immobilized and the strongly immobilized motions were similar in cross-linked and control samples. Small differences in some motional components were detected. In some cases, faster mobilities were observed, with approximately 5% of the strongly immobilized motions converted to the weakly immobilized motions in the cross-linked samples. It is often believed that the consequence of membrane protein oxidation is restricted protein dynamics, giving membrane rigidity. However, our studies provide needed experimental evidence to indicate that segmental motions are maintained with very little modification even in the presence of extensive cross-linking. Thus cross-linking does not restrict the internal molecular flexibility that gives rise to segmental motions.     

Asymmetric linker histone association directs the asymmetric rearrangement of core histone interactions in a positioned nucleosome containing a thyroid hormone response element

We describe histone-DNA cross-linking in a positioned nucleosome containing a thyroid hormone response element (TRE) from the Xenopus laevis thyroid hormone receptor betaA gene (TRbetaA). Histones H3 and H4 are cross-linked to DNA in the nucleosome core within 30 base pairs to either side of the dyad axis. Histone H2A cross-links to DNA in the core at the dyad axis, and histones H2A and H2B have extensive interactions with DNA 40-80 bp away from the dyad axis. Linker histone H5 and the globular domain of Xenopus H1(0) associate asymmetrically with DNA at one edge of the TRbetaA nucleosome. Nevertheless, the asymmetric association of H5 leads to a significant rearrangement of core histone-DNA contacts at the dyad axis of the nucleosome. In the presence of linker histone, cross-linkings of H4 within 15 bp to one side of the dyad axis, of histone H2A at the dyad axis, and of H2A and H2B 40-80 bp to one side of the dyad axis are all reduced. This reduction in cross-linking occurs preferentially on the side of the nucleosome to which H5 is bound. Our results indicate that core histone contacts within mononucleosomes are conformationally dynamic and that linker histone incorporation at the edge of the nucleosome can influence core histone-DNA interactions in an asymmetric way including contacts at the dyad axis.     

Differential affinity cross-linking of phosphorylase kinase conformers by the geometric isomers of phenylenedimaleimide

Phosphorylase b kinase (PbK) from skeletal muscle is a highly regulated oligomer consisting of four copies of four distinct subunits (alphabetagamma)delta4. The gamma subunit is catalytic, and the remaining subunits are regulatory. To characterize effector-induced changes in the quaternary structure of the enzyme, we utilized the ortho-, meta, and para-isomers of phenylenedimaleimide (PDM), which in addition to having different geometries, also vary 2.5-fold in their cross-linking spans. Even at concentrations equivalent to the alphabetagammadelta protomers of PbK, all three isomers caused specific, rapid, and extensive cross-linking of the holoenzyme to form primarily alphabeta dimers, plus smaller amounts of betagammagamma and alphagammagamma trimers. The formation of these three conjugates was nearly totally inhibited by a 10-fold molar excess over PDM of N-(o- and p-tolyl)succinimide, which are chemically inert structural analogs of PDM. This inhibition suggests that PbK has binding sites for PDM and that PDM acts as an affinity cross-linker in binding to these sites prior to forming cross-linked conjugates. The largest effect on cross-linking in progressing from o- to p-PDM was on the alphagammagamma trimer, which is preferentially formed by the p-isomer. Activation of the enzyme by either phosphorylation or the allosteric activators ADP and GDP resulted in large increases in the amount of alphagammagamma formed, small increases in betagammagamma, and little change in alphabeta. When cross-linked in the presence of the reversibly activating nucleoside diphosphates, PbK remained activated after their removal, indicating that cross-linking had locked it in the active conformation. Our results provide direct evidence for perturbations in the interactions of the catalytic gamma subunit with the regulatory alpha and beta subunits upon activation of PbK.     

Archaeal nucleosomes

Archaea contain histones that have primary sequences in common with eukaryal nucleosome core histones and a three-dimensional structure that is essentially only the histone fold. Here we report the results of experiments that document that archaeal histones compact DNA in vivo into structures similar to the structure formed by the histone (H3+H4)2 tetramer at the center of the eukaryal nucleosome. After formaldehyde cross-linking in vivo, these archaeal nucleosomes have been isolated from Methanobacterium thermoautotrophicum and Methanothermus fervidus, visualized by electron microscopy on plasmid and genomic DNAs, and shown by immunogold labeling, SDS/PAGE, and immunoblotting to contain archaeal histones, cross-linked into tetramers. Archaeal nucleosomes protect approximately 60 bp of DNA and multiples of approximately 60 bp from micrococcal nuclease digestion, and immunoprecipitation has demonstrated that most, but not all, M. fervidus genomic DNA sequences are associated in vivo with archaeal histones.