Zero-length Cross-linker Research Articles

Synaptotagmin C2A Loop 2 Mediates Ca2+-dependent SNARE Interactions Essential for Ca2+-triggered Vesicle Exocytosis

Synaptotagmins contain tandem C2 domains and function as Ca(2+) sensors for vesicle exocytosis but the mechanism for coupling Ca(2+) rises to membrane fusion remains undefined. Synaptotagmins bind SNAREs, essential components of the membrane fusion machinery, but the role of these interactions in Ca(2+)-triggered vesicle exocytosis has not been directly assessed. We identified sites on synaptotagmin-1 that mediate Ca(2+)-dependent SNAP25 binding by zero-length cross-linking. Mutation of these sites in C2A and C2B eliminated Ca(2+)-dependent synaptotagmin-1 binding to SNAREs without affecting Ca(2+)-dependent membrane binding. The mutants failed to confer Ca(2+) regulation on SNARE-dependent liposome fusion and failed to restore Ca(2+)-triggered vesicle exocytosis in synaptotagmin-deficient PC12 cells. The results provide direct evidence that Ca(2+)-dependent SNARE binding by synaptotagmin is essential for Ca(2+)-triggered vesicle exocytosis and that Ca(2+)-dependent membrane binding by itself is insufficient to trigger fusion. A structure-based model of the SNARE-binding surface of C2A provided a new view of how Ca(2+)-dependent SNARE and membrane binding occur simultaneously.

Dimerization and Actin-bundling Properties of Villin and Its Role in the Assembly of Epithelial Cell Brush Borders

Villin is a major actin-bundling protein in the brush border of epithelial cells. In this study we demonstrate for the first time that villin can bundle actin filaments using a single F-actin binding site, because it has the ability to self-associate. Using fluorescence resonance energy transfer, we demonstrate villin self-association in living cells in microvilli and in growth factor-stimulated cells in membrane ruffles and lamellipodia. Using sucrose density gradient, size-exclusion chromatography, and matrix-assisted laser desorption ionization time-of-flight, the majority of villin was identified as a monomer or dimer. Villin dimers were also identified in Caco-2 cells, which endogenously express villin and Madin-Darby canine kidney cells that ectopically express villin. Using truncation mutants of villin, site-directed mutagenesis, and fluorescence resonance energy transfer, an amino-terminal dimerization site was identified that regulated villin self-association in parallel conformation as well as actin bundling by villin. This detailed analysis describes for the first time microvillus assembly by villin, redefines the actin-bundling function of villin, and provides a molecular mechanism for actin bundling by villin, which could have wider implications for other actin cross-linking proteins that share a villin-like headpiece domain. Our study also provides a molecular basis to separate the morphologically distinct actin-severing and actin-bundling properties of villin.

Application of zero-length cross-linking to form lysozyme, horseradish peroxidase and lysozyme–peroxidase dimers: Activity and stability

A facile method for the formation of covalent bonds between protein molecules is zero-length cross-linking. This method enables the formation of cross-links without use of any chemical reagents. Here, the cross-linking is performed for lysozyme, peroxidase (a glycoprotein) and between lysozyme–peroxidase by the method of Simons et al. [B.L. Simons, M.C. King, T. Cyr, M.A. Hefford, H. Kaplan, Covalent cross-linking of protein without chemical reagents, Protein Sci. 2002, 11, 1558–1564]. Approximately one-third of the total lysozyme becomes cross-linked and the dimer form was the major product for both enzymes. This modification induced some changes in the kinetic properties of the dimer peroxidase, as evident by two-fold increasing of V max compared to the monomer but the enzymatic activity of cross-linked lysozyme dimer was the same as monomer. The activity of lysozyme dimer remained constant up to 10 min at 80 °C, while peroxidase activity of both monomer and dimer began to decrease after heating. The structural changes of the enzymes were investigated by circular dichroism and intrinsic fluorescence techniques. Near UV result showed lysozyme possess a compact structure in the dimer form but disruption of tertiary structure of peroxidase dimer was observed. Also conformational changes were detected and discussed by intrinsic fluorescence experiments. Effect of several metals in the formation of lysozyme dimer showed that Co 2+ is the most effective one but its effect was marginal. At the end formation of heterogeneous dimer, peroxidase–lysozyme, was achieved using this method.

Surface modification of protein nanocontainers and their self-directing character in polymer blends

Tailoring the surfaces of a nanocontainer with polymer brushes that have different affinities to the components of a phase-separating polymer blend should impart self-directing properties to the nanocontainers. Such nanocontainers could then be used to deliver a variety of functional species in tunable amounts and in a site-specific manner to polymer systems. This paper describes the surface modification, subsequent characterization of nanocontainers derived from ferritin, and the effects of surface modification on their self-directing properties in a binary phase-separating homopolymer blend. Wild ferritin was either PEGylated or alkylated by zero-length cross-linking to its surface carboxylate groups that were activated by carbodiimide. Modification was confirmed by ion-exchange chromatography, ζ-potential measurement, and electrospray ionization mass spectrometry. FT-IR spectrometry was used to quantify the extent of PEGylation by ratioing the intensity of the C–O–C asymmetric stretching vibration from the grafted PEG to that of the carbonyl stretching vibration (amide I band) from the protein. Importantly, modified ferritin was soluble in the organic solvent dichloromethane (DCM). Modified ferritin was introduced into a polymer blend of hydrophobic and hydrophilic polymers made up of poly(desaminotyrosyl tyrosine dodecyl ester carbonate) (PDTD) and PEG by solvent casting from solution in the common solvent DCM. Polymer thin films with an average thickness of ∼200 μm were obtained upon evaporation of the solvent. Transmission electron micrographs of microtomed polymer films demonstrated remarkable selectivity of PEGylated ferritin to PEG domains, while alkylated ferritin self-directs to the PDTD matrix.

Protein Interactions Captured by Chemical Cross-linking: One-Step Cross-linking with Formaldehyde: Figure 1.

INTRODUCTIONThis protocol describes a method for chemical cross-linking of proteins using formaldehyde. With the exception of zero-length cross-linkers, formaldehyde has the shortest cross-linking span (~2-3 Å) of any cross-linking reagent, thus making it an ideal tool for detecting specific protein-protein interactions with great confidence. Despite its simple chemical structure (CH(2)O), formaldehyde's single carbonyl group functions essentially as a homobifunctional reagent and is capable of conjugating targets through two different chemical pathways. In Mannich-type reactions, which typically require elevated temperatures (37°C or above) for a period of 2-24 hours for acceptable yields, formaldehyde condenses with amines (1°, 2°, or salts of ammonia) and compounds with active hydrogens to form stable cross-links. Formaldehyde also reacts with amines to form highly reactive immonium cations that are reactive toward protein-containing nucleophiles, including sulfhydryls, amines, phenols, and imidazoles. The latter reaction is more rapid than the former and is generally the more predominant in typical protein cross-linking reactions at ambient temperatures.

Gelatin microspheres cross-linked with EDC as a drug delivery system for doxycyline: Development and characterization

Chronic wounds express elevated levels of proteases, in particular matrix metalloproteinases (MMPs), which degrades de novo granulation tissue and endogenous biologically active proteins. An effective therapeutic approach for chronic wounds would be to modify this hostile environment and reduce the proteolytic imbalance. Doxycycline has been proved recently to inhibit MMPs and used topically for chronic wound ulcers, beyond their antimicrobial profile. To this end, a carrier system for controlled release of doxycycline, suitable for incorporation into various wound dressings like membranes and sponges was developed. In the present study gelatin microspheres, cross-linked with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide (EDC) was proposed. The cross-linking was carried out with different concentrations of EDC (10 mM, 50 mM and 100 mM) and for different time periods (3–24 h). The cross-linked microspheres were characterized by evaluating the extent of cross-linking, the morphology, swelling behaviour and drug loading and in vitro studies of drug release, enzymatic degradation and biocompatibility. The extent of cross-linking increased as a function of both EDC concentration and the cross-linking time periods. It is found that the extent of cross-linking greatly influences the swelling and drug release behaviour of the microspheres. The cross-linked microspheres were found to be biocompatible to NIH 3T3 mouse embryonic fibroblast. The overall study indicates that the zero length cross-linker EDC can be considered as a potential alternative for cross-linking the gelatin microspheres.

Identification of Precise Electrostatic Recognition Sites between Cytochrome c6 and the Photosystem I Subunit PsaF Using Mass Spectrometry

The reduction of the photo-oxidized special chlorophyll pair P700 of photosystem I (PSI) in the photosynthetic electron transport chain of eukaryotic organisms is facilitated by the soluble copper-containing protein plastocyanin (pc). In the absence of copper, pc is functionally replaced by the heme-containing protein cytochrome c6 (cyt c6) in the green alga Chlamydomonas reinhardtii. Binding and electron transfer between both donors and PSI follows a two-step mechanism that depends on electrostatic and hydrophobic recognition between the partners. Although the electrostatic and hydrophobic recognition sites on pc and PSI are well known, the precise electrostatic recognition site on cyt c6 is unknown. To specify the interaction sites on a molecular level, we cross-linked cyt c6 and PSI using a zero-length cross-linker and obtained a cross-linked complex competent in fast and efficient electron transfer. As shown previously, cyt c6 cross-links specifically with the PsaF subunit of PSI. Mass spectrometric analysis of tryptic peptides from the cross-linked product revealed specific interaction sites between residues Lys27 of PsaF and Glu69 of cyt c6 and between Lys23 of PsaF and Glu69/Glu70 of cyt c6. Using these new data, we present a molecular model of the intermolecular electron transfer complex between eukaryotic cyt c6 and PSI.

Different roles of P1 and P2 Saccharomyces cerevisiae ribosomal stalk proteins revealed by cross‐linking

The stalk is an essential domain of the large ribosomal subunit formed by a complex of a set of very acidic proteins bound to a core rRNA binding component. While in prokaryotes there is only one type acidic protein, L7/12, two protein families are found in eukaryotes, phosphoproteins P1 and P2, which presumably have different roles. To search for differences zero-length cross-linking by S-S bridge formation was applied using Saccharomyces cerevisiae mutant P1 and P2 proteins carrying single cysteine residues at various positions. The results show a more exposed location of the N-terminal domain of the P2 proteins, which in contrast to P1, can be found as dimers when the Cys is introduced in this domain. Similarly, the Cys containing C-terminal domain of mutant P2 proteins shows a notable capacity to form cross-links with other proteins, which is considerably lower in the P1 type. On the other hand, mutation at the conserved C-domain of protein P0, the eukaryotic stalk rRNA binding component, results in removal of about 14 terminal amino acids. Protein P2, but not P1, protects mutant P0 from this truncation. These results support a eukaryotic stalk structure in which P1 proteins are internally located with their C-terminals having a restricted reactivity while P2 proteins are more external and accessible to interact with other cellular components.

Molecular Contacts for Chlorosome Envelope Proteins Revealed by Cross-Linking Studies with Chlorosomes fromChlorobium tepidum

Chlorosomes are unique light-harvesting antennae found in two phyla of green bacteria: Chlorobi and Chloroflexi. In the green sulfur bacterium Chlorobium tepidum, 10 proteins (CsmA, CsmB, CsmC, CsmD, CsmE, CsmF, CsmH, CsmI, CsmJ, and CsmX) exist in the chlorosome envelope. Chlorosomes from the wild type and mutants lacking a single chlorosome protein were cross-linked with the zero-length cross-linker 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC) and analyzed by gel electrophoresis. Similar cross-linking products were observed when the time and temperature were varied or when EDC was replaced with glutaraldehyde. Specific interactions between chlorosome proteins in cross-linked products were identified by immunoblotting with polyclonal antibodies raised against recombinant chlorosome proteins. We confirmed these interactions by demonstrating that these products were missing in appropriate mutants. Confirming the location of CsmA in the paracrystalline baseplate, cross-linking showed that CsmA forms dimers, trimers, and homomultimers as large as dodecamers and that CsmA directly interacts with the Fenna-Matthews-Olson protein. Cross-linking further suggests that the precursor form of CsmA is inserted near the edges of the baseplate, where CsmA and pre-CsmA interact with CsmB and CsmF. Several chlorosome proteins, including CsmA, CsmC, CsmD, CsmH, CsmI, CsmJ, and CsmX, were shown to exist as homomultimers in the chlorosome envelope. On the basis of the structural information obtained from these cross-linking experiments, a model for the locations and interactions of the proteins of the chlorosome envelope is proposed.

The Morphogenic Properties of Oligomeric Endostatin Are Dependent on Cell Surface Heparan Sulfate

Endostatin has attracted considerable attention because of its ability to inhibit angiogenesis. This property of monomeric endostatin contrasts with that of the trimeric endostatin moiety generated from the intact C-terminal domain of collagen XVIII that induces a promigratory phenotype in endothelial cells. This activity is inhibited by monomeric endostatin. In this study we demonstrate that the effect of oligomeric endostatin can also be inhibited by exogenous glycosaminoglycans in a size-dependent manner, with heparin oligosaccharides containing more than 20 monosaccharide residues having optimal inhibitory activity. Oligomeric endostatin was also found to induce morphological changes in Chinese hamster ovary cells, an epithelial cell line. This novel observation allowed the utilization of a panel of Chinese hamster ovary cell mutants with defined glycosaminoglycan biosynthetic defects. The action of oligomeric endostatin on these cells was shown to be dependent on cell surface glycosaminoglycans, principally heparan sulfate with N- and 6-O-sulfation of glucosamine residues rather than iduronate 2-O-sulfation being important for bioactivity. The responsiveness of a cell line (pgsE-606) with globally reduced heparan sulfate sulfation and shortened S domains, however, indicates that overall heparan sulfate domain patterning is the key determinant of the bioactivity of oligomeric endostatin. Purified heparin-monomeric endostatin constructs generated by zero-length cross-linking techniques were found to be unable to inhibit the action of oligomeric endostatin. This indicates a mechanism for the perturbation of oligomeric endostatin action by its monomeric counterpart via competition for glycosaminoglycan attachment sites at the cell surface.

Fluorophore-Assisted Light Inactivation of Calmodulin Involves Singlet-Oxygen Mediated Cross-Linking and Methionine Oxidation

Fluorophore-assisted light inactivation (FALI) permits the targeted inactivation of tagged proteins and, when used with cell-permeable multiuse affinity probes (MAPs), offers important advantages in identifying physiological function, because targeted protein inactivation is possible with spatial and temporal control. However, reliable applications of FALI, also known as chromophore-assisted light inactivation (CALI) with fluorescein derivatives, have been limited by lack of mechanistic information regarding target protein sensitivity. To permit the rational inactivation of targeted proteins, we have identified the oxidizing species and the susceptibility of specific amino acids to modification using the calcium regulatory protein calmodulin (CaM) that, like many essential proteins, regulates signal transduction through the reversible association with a large number of target proteins. Following the covalent and rigid attachment of 4',5'-bis(1,3,2-dithioarsolan-2-yl)fluorescein (FlAsH) to helix A, we have identified light-dependent oxidative modifications of endogenous methionines to their corresponding methionine sulfoxides. Initial rates of methionine oxidation correlate with surface accessibility and are insensitive to the distance between the bound fluorophore and individual methionines, which vary between approximately 7 and 40 A. In addition, we observed a loss of histidines, as well as zero-length cross-linking with binding partners corresponding to the CaM-binding sites of smooth myosin light chain kinase and ryanodine receptor. Our results provide a rationale for proteomic screens using FALI to inhibit the function of many signaling proteins, which, like CaM, commonly present methionines at binding interfaces.

Mapping Factor VIIIa Inter-Subunit Interactions Using Chemical Modification and Zero-Length Cross-Linking.

Activated factor VIII (FVIIIa) is a complex of three subunits, designated A1, A2, and A3C1C2, that serves as a cofactor for factor IXa in the proteolytic activation of factor X. The structure and surface interactions between factor VIIIa subunits have yet to be fully defined, but a homology-based model is available as a predictive tool (Stoylova-McPhie et al, Blood, 2002). To investigate FVIIIa inter-subunit interactions we used a chemical modification approach to determine surface-exposed and potentially interactive residues. The protein modification reagents acetic anhydride and diethylpyrocarbonate (DEPC), that modify lysine and histidine residues, respectively, were used to identify residues that are modified in the free subunits but protected in the bound complex. The modified samples were digested with various proteases and the resulting digests were analyzed by MALDI-TOF mass spectrometry to determine sites of peptide modification (Figure 1). The majority of data observed was in agreement with the A1/A3C1C2 interface in the predicted model. Protection was observed at Lys-89, Lys-142, and Lys-230 in the A1 subunit, all of which are near the A3C1C2 interface. While most His residues were completely modified by DEPC, partial protection was seen at His-1954, His-1957, and His-1961 in A3C1C2, which we have previously shown to be an A1-interactive region (Ansong and Fay, Biochemistry, 2005). In addition to this data, we attempted to define inter-subunit contacts by covalently cross-linking the FVIIIa complex. Using the zero-length cross-linker 1-ethyl-3-[3-dimethylaminopropyl] carbodiimide (EDC), which cross-links Glu/Asp residues to Lys, four distinct cross-linked bands were identified by SDS-PAGE (Figure 2). The composition of the cross-linked products was determined using proteolytic digestion and MALDI analysis. The four products correspond to each possible combination of the three subunits. Interestingly, there are no candidate cross-link sites between A1 and A2 in the model, yet this cross-link is the most predominant of the four. One alternative is that the A1–A2 cross-link may involve the A1 337–372 region that is not represented in the model. Taken together, the data are directed toward physically defining interactive regions between FVIIIa subunits and serve to test and supplement current structure models. [Display omitted]

Zero-length cross-linking of the LH receptor reveals tight interactions between extracellular and transmembrane domains during receptor activation

Luteinizing hormone (LH) secreted by the anterior pituitary is critical for normal sexual development and function. Activation of the LH receptor in target tissues involves LH binding to the extracellular domain (ECD), thereby modifying interactions between the ECD and transmembrane domain (TMD). To analyse these intramolecular changes we developed a recombinant LH/CG receptor (LHR) bearing an intramolecular cleavage site at position 316 recognized by the proprotein convertase furin (LHR-F316). Western blot studies indicated normal synthesis, glycosylation and expression of the recombinant LHR with complete cleavage into both domains, ECD-316 and 316-TMD. Affinity binding for hCG as well as basal and hormone induced cAMP production were identical to the wildtype LHR, indicating intact functional activity of the cleaved LHR. Physical interaction between the ECD and TMD was studied by zero-length cross-linking on HEK 293 cells expressing LHR-F316. No difference in cross-linking intensity between both domains was observed after ligand binding or in constitutively active receptors. Incubation of cells expressing LHR-F316 with dithiotreitol led to a shedding of the ECD-316 from the 316-TMD without increase of the basal adenylate cyclase activity. Our results show that activation of the LH receptor does not result from a switch of an inverse agonist effect of the ECD-316 to an agonist effect but is related to subtle modifications of intramolecular interactions between ECD and TMD.

Differential Light Chain Assembly Influences Outer Arm Dynein Motor Function

Tctex1 and Tctex2 were originally described as potential distorters/sterility factors in the non-Mendelian transmission of t-haplotypes in mice. These proteins have since been identified as subunits of cytoplasmic and/or axonemal dyneins. Within the Chlamydomonas flagellum, Tctex1 is a subunit of inner arm I1. We have now identified a second Tctex1-related protein (here termed LC9) in Chlamydomonas. LC9 copurifies with outer arm dynein in sucrose density gradients and is missing only in those strains completely lacking this motor. Zero-length cross-linking of purified outer arm dynein indicates that LC9 interacts directly with both the IC1 and IC2 intermediate chains. Immunoblot analysis revealed that LC2, LC6, and LC9 are missing in an IC2 mutant strain (oda6-r88) that can assemble outer arms but exhibits significantly reduced flagellar beat frequency. This defect is unlikely to be due to lack of LC6, because an LC6 null mutant (oda13) exhibits only a minor swimming abnormality. Using an LC2 null mutant (oda12-1), we find that although some outer arm dynein components assemble in the absence of LC2, they are nonfunctional. In contrast, dyneins from oda6-r88, which also lack LC2, retain some activity. Furthermore, we observed a synthetic assembly defect in an oda6-r88 oda12-1 double mutant. These data suggest that LC2, LC6, and LC9 have different roles in outer arm assembly and are required for wild-type motor function in the Chlamydomonas flagellum.

Crosslinking of collagen with dendrimers

Polypropyleneimine octaamine dendrimers were studied as an alternative means of generating highly crosslinked collagen. Crosslinking was effected by using the water-soluble carbodiimide 1-ethyl-3-(3-dimethyl aminopropyl) carbodiimide hydrochloride (EDC). The multifunctional dendrimers were introduced as novel crosslinkers after the activation of the carboxylic acid groups of glutamic and aspartic acid residues in collagen. The conventional crosslinker glutaraldehyde was used as a control. EDC, itself an alternative crosslinker, which forms zero-length crosslinks by directly covalently binding collagen molecules, as well as a low molecular weight diamine and a low molecular weight triamine, were also studied. All of the resultant gels were freeze-dried to obtain sponges for characterization. Water uptake of the gels decreased from 90% to 60% after dendrimer crosslinking compared with EDC crosslinking. DSC results showed an increase of denaturation temperature of collagen after crosslinking with the various methods. The generation 2 and 3 dendrimer-crosslinked collagen samples had the highest denaturation temperature, at up to 90 degrees C compared with 50 degrees C in the uncrosslinked collagen control. The dendrimer-crosslinked collagen also showed unique thermal characteristics, with multiple denaturation temperature peaks in contrast to the single peak noted with the other crosslinked collagens. This is thought to be due to the heterogeneous nature of dendrimer crosslinking. Collagenase results revealed that the dendrimer-crosslinked collagen had a comparative resistance to proteolysis to glutaraldehyde-crosslinked collagen. Measurement of activated carboxylic acid groups before and after crosslinking indicated that 40-70% of the activated carboxylic acid was consumed during crosslinking with dendrimers. The results suggest that dendrimer crosslinking of collagen produces stable gels. The presence of a large number of excess amine groups in the dendrimers may also be useful for subsequent modification with biologically relevant groups.

Siderophore Transport through Escherichia coli Outer Membrane Receptor FhuA with Disulfide-tethered Cork and Barrel Domains

The hydroxamate siderophore receptor FhuA is a TonB-dependent outer membrane protein of Escherichia coli composed of a C-terminal 22-stranded beta-barrel occluded by an N-terminal globular cork domain. During siderophore transport into the periplasm, the FhuA cork domain has been proposed to undergo conformational changes that allow transport through the barrel lumen; alternatively, the cork may be completely displaced from the barrel. To probe such changes, site-directed cysteine mutants in the cork domain (L109C and Q112C) and in the barrel domain (S356C and M383C) were created within the putative siderophore transport pathway. Molecular modeling predicted that the double cysteine mutants L109C/S356C and Q112C/M383C would form disulfide bonds, thereby tethering the cork and barrel domains. The double cysteine FhuA mutants were denatured under nonreducing conditions and fluorescently labeled with thiol-specific Oregon Green maleimide. Subsequent SDS-PAGE analysis revealed two distinct species: FhuA containing a disulfide bond and FhuA with free sulfhydryl groups. To address the role of the putative siderophore transport pathway and to evaluate possible rearrangements of the cork domain during ferricrocin transport, disulfide bond formation was enhanced by an oxidative catalyst. Cells containing double cysteine FhuA mutants that were subjected to oxidation during ferricrocin transport exhibited disulfide bond formation to near completion. After disulfide tethering of the cork to the barrel, ferricrocin transport was equivalent to transport by untreated cells. These results demonstrate that blocking the putative siderophore transport pathway does not abrogate ferricrocin uptake. We propose that, during siderophore transport through FhuA, the cork domain remains within the barrel rather than being displaced.

Covalent protein immobilization on glass surfaces: Application to alkaline phosphatase

Lyophilized alkaline phosphatase (ALPase) was immobilized on aminated glass surfaces using the in vacuo cross-linking process [Simons, B.L., King, M.C., Cyr, T., Hefford, M.A., Kaplan, H., 2002. Zero-length cross-linking of lyophilized proteins. Protein Sci. 11, 1558–1564]. In this procedure, amide bonds were formed between carboxyl groups on the protein and amino groups on the glass surface. After the non-covalently attached enzyme was removed the immobilized ALPase not only retained its activity but could also be used, washed and reused at least six times without significant loss of activity. An average of 1.4 ± 0.6 mg of reusable ALPase per gram of glass fibre was immobilized based on the activity of the soluble equivalent.

Anti-enrofloxacin antibody production by using enrofloxacin-screened HSA as an immunogen

A two-step zero-length cross-linking procedure using active esters was successfully adopted for conjugating enrofloxacin (EF) to human serum albumin (HSA). The derived conjugate was characterized by UV spectrum and then used for immunization of BALB/C mice. In enzyme-linked immunosorbent assay (ELISA) and competitive inhibition ELISA experiments, the derived antiserum exhibited high antibody titer (greater than 1:250 000) as well as varied cross-reactivity (from 97.8% to 161.7%) to three analogs of EF belonging to fluoroquinolones family. But over the concentration range studied, no significant cross-reactivity was observed to other group of antibiotics (chloramphenicol, oxytetracycline, sulphamethoxazole and nysfungin). It was confirmed that the synthesized immunogen was highly antigenic and elicited specific antibody responses in BALB/C mice against EF.

Direct interaction between prion protein and tubulin

Recently published data show that the prion protein in its cellular form (PrP C) is a component of multimolecular complexes. In this report, zero-length cross-linking with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) allowed us to identify tubulin as one of the molecules interacting with PrP C in complexes observed in porcine brain extracts. We found that porcine brain tubulin added to these extracts can be cross-linked with PrP C. Moreover, we observed that the 34 kDa species identified previously as full-length diglycosylated prion protein co-purifies with tubulin. Cross-linking of PrP C species separated by Cu 2+-loaded immobilized metal affinity chromatography confirmed that only the full-length protein but not the N-terminally truncated form (C1) binds to tubulin. By means of EDC cross-linking and cosedimentation experiments, we also demonstrated a direct interaction of recombinant human PrP (rPrP) with tubulin. The stoichiometry of cosedimentation implies that rPrP molecules are able to bind both the α- and β-isoforms of tubulin composing microtubule. Furthermore, prion protein exhibits higher affinity for microtubules than for unpolymerized tubulin.

Zero-Length Cross-Linking Reveals that Tight Interactions between the Extracellular and Transmembrane Domains of the Luteinizing Hormone Receptor Persist during Receptor Activation

Several molecular models of glycoprotein hormone receptor activation have been proposed. It has been suggested that ligand binding to the ectodomain (ECD) leads to major changes in intramolecular interactions between the ECD and the transmembrane domain. We studied these intramolecular modifications by generating a recombinant LH/CG receptor (LHR) bearing an intramolecular cleavage site. We did this by inserting a furin site at position 316 in the hinge region of the ECD (LHR_Fur316). Affinity for human chorionic gonadotropin (hCG) and cAMP production upon hCG stimulation was identical to those of wild-type LHR. Western blot analysis showed that the LHR_Fur316 receptor was cleaved into two subunits linked by disulfide bridges. Chemical shedding of the ECD from the transmembrane domain did not increase basal adenylate cyclase activity, indicating that the first 294 residues did not act as an inverse agonist. The truncated LHR_316 was still activated by hCG but with an EC50 higher than that for the wild-type receptor. Zero length cross-linking was used to study intramolecular interactions between the two domains of LHR_Fur316. Cross-linking efficiency was similar for the basal and activated states, which indicated that the two domains interacted closely in the basal state, and this tight interaction persisted during activation. Our data suggest that activation of the LHR results from subtle modifications of intramolecular interactions between the two domains and low-affinity binding of hCG to the extracellular loops or residues preceding the first transmembrane segment.