Hexameric,Trimeric, Dimeric,and Monomeric Forms of Inorganic Pyrophosphatase from Escherichia coli

The conditions were found for obtaining trimeric, dimeric, and monomeric forms of the Escherichia coli inorganic pyrophosphatase from its native hexameric form. Interconversions of the oligomers were studied, and rate constants for their dissociation and association were determined. All forms were found to be catalytically active, with the activity decreasing in the following order: hexamer–trimer–dimer–monomer. The activity of trimeric and dimeric forms was high enough to study and to compare their catalytic properties. The monomeric form of the enzyme was unstable.     

In vitro construction of different oligomeric forms of lambdadv DNA and studies of their transforming activities.

Plasmid lambdadv1, which is in a dimeric form, was converted to a linear monomer duplex by the action of EcoRI restriction endonuclease that incises at a unique site in this plasmid genome. The resulting products were then joined by Escherichia coli DNA ligase to produce molecules with various oligomeric forms, and from these monomeric, dimeric, or trimeric circular molecules were purified. By transformation of cells with these DNAs, clones were obtained that carried lambdadv1 in a monomeric or dimeric form. The former type of clones have not been generated in vivo, except for one in a different host strain, and carriers of timeric or tetrameric lambdadv1's have not been obtained so far. It was observed that a considerable fraction of these oligomeric circular DNAs were converted to lower oligomers (e.g., from trimer to dimer) during transformation. The characteristics of the monomeric lambdadv1 carriers obtained were compared with those of dimeric lambdadv1 carriers. The stabilities of the plasmids of the two forms were the same. However, the monomeric plasmid carriers were less tolerant to lambdavir phage infection and perpetuated about 30% less plasmid genomes in monomer units. Furthermore, dimeric plasmid carriers appeared spontaneously and accumulated in cultures of the monomeric lambdadv1 carriers.     

Does the trimeric form of the Photosystem 1 reaction center of cyanobacteria in vivo exist?

When isolating Photosystem 1 from the thylakoid membranes of cyanobacteria, a multiplicity of photosystem complexes can be encountered, which has not yet been observed in any other phototrophic organisms: After solubilisation of thylakoid membranes with detergents, trimeric, dimeric and monomeric forms of Photosystem 1 can be separated. The question must now be answered, which of the stable Photosystem 1 forms is the functional form in vivo-monomeric or trimeric? The two possibilities are discussed, though we mainly present arguments for the existence of the trimeric form of Photosystem 1 in cyanobacterial thylakoid membranes.     

Biophysical studies of the membrane-embedded and cytoplasmic forms of the glucose-specific Enzyme II of the E. coli phosphotransferase system (PTS)

The glucose Enzyme II transporter complex of the Escherichia coli phosphotransferase system (PTS) exists in at least two physically distinct forms: a membrane-integrated dimeric form, and a cytoplasmic monomeric form, but little is known about the physical states of these enzyme forms. Six approaches were used to evaluate protein-protein and protein-lipid interactions in this system. Fluorescence energy transfer (FRET) using MBP-II(Glc)-YFP and MBP-II(Glc)-CFP revealed that the homodimeric Enzyme II complex in cell membranes is stable (FRET(-)) but can be dissociated and reassociated to the heterodimer only in the presence of Triton X100 (FRET(+)). The monomeric species could form a heterodimeric species (FRET(+)) by incubation and purification without detergent exposure. Formaldehyde cross linking studies, conducted both in vivo and in vitro, revealed that the dimeric MBP-II(Glc) activity decreased dramatically with increasing formaldehyde concentrations due to both aggregation and activity loss, but that the monomeric MBP-II(Glc) retained activity more effectively in response to the same formaldehyde treatments, and little or no aggregation was observed. Electron microscopy of MBP-II(Glc) indicated that the dimeric form is larger than the monomeric form. Dynamic light scattering confirmed this conclusion and provided quantitation. NMR analyses provided strong evidence that the dimeric form is present primarily in a lipid bilayer while the monomeric form is present as micelles. Finally, lipid analyses of the different fractions revealed that the three lipid species (PE, PG and CL) are present in all fractions, but the monomeric micellar structure contains a higher percentage of anionic lipids (PG & CL) while the dimeric bilayer form has a higher percentage of zwitterion lipids (PE). Additionally, evidence for a minor dimeric micellar species, possibly an intermediate between the monomeric micellar and the dimeric bilayer forms, is presented. These results provide convincing evidence for interconvertible physical forms of Enzyme-II(Glc).     

Enhancing immunoassay detection of antigens with multimeric protein Gs

This paper describes a method for the effective and self-oriented immobilization of antibodies on magnetic silica-nanoparticles using a multimeric protein G. Cysteine-tagged recombinant dimers and trimers of protein G were produced in Escherichia coli BL21 by repeated linking of protein G monomers with a flexible (GGGGS)(3) linker. Amino-functionalized silica-coated magnetic nanoparticles (SiO(2)-MNPs, Fe(3)O(4)@SiO(2)) were prepared and coupled to the protein G multimers, giving the final magnetic immunosensor. The optimal conditions for the reaction between the protein Gs and the SiO(2)-MNPs was a time of 60 min and a concentration of 100 μg/mL, resulting in coupling efficiencies of 77%, 67% and 55% for the monomeric, dimeric and trimeric protein Gs, respectively. Subsequently, anti-hepatitis B surface antigen (HBsAg) was immobilized onto protein G-coupled SiO(2)-MNPs. The quantitative efficiency of antibody immobilization found the trimeric protein G to be the best, followed by the dimeric and monomeric proteins, which differs from the coupling efficiencies. Using all three protein constructs in an HBsAg fluoroimmunoassay, the lowest detectable concentrations were 500, 250 and 50 ng/mL for the monomeric, dimeric and trimeric protein G-coupled SiO(2)-MNPs, respectively. Therefore, multimeric protein Gs, particularly the trimeric form, can be employed to improve antibody immobilization and, ultimately, enhance the sensitivity of immunoassays. In addition, the multimeric protein Gs devised in this study can be utilized in other immunosensors to bind the antibodies at a high efficiency and in the proper orientation.     

Differential susceptibility of Plasmodium falciparum versus yeast and mammalian enolases to dissociation into active monomers

In the past, several unsuccessful attempts have been made to dissociate homodimeric enolases into their active monomeric forms. The main objective of these studies had been to understand whether intersubunit interactions are essential for the catalytic and structural stability of enolases. Further motivation to investigate the properties of monomeric enolase has arisen from several recent reports on the involvement of enolase in diverse nonglycolytic (moonlighting) functions, where it may occur in monomeric form. Here, we report successful dissociation of dimeric enolases from Plasmodium falciparum, yeast and rabbit muscle into active and isolatable monomers. Dimeric enolases could be dissociated into monomers by high concentrations ( approximately 250 mm) of imidazole and/or hydrogen ions. Two forms were separated using Superdex-75 gel filtration chromatography. A detailed comparison of the kinetic and structural properties of monomeric and dimeric forms of recombinant P. falciparum enolase showed differences in specific activity, salt-induced inhibition and inactivation, thermal stability, etc. Furthermore, we found that enolases from the three species differ in their dimer dissociation profiles. Specifically, on challenge with imidazole, Mg(II) protected the enolases of yeast and rabbit muscle but not of P. falciparum from dissociation. The observed differential stability of the P. falciparum enolase dimer interface with respect to mammalian enolases could be exploited to selectively dissociate the dimeric parasite enzyme into its catalytically inefficient, thermally unstable monomeric form. Thus enolase could be a novel therapeutic target for malaria.     

Investigation of the structure of trimeric and monomeric photosystem I reaction centre complexes

Electron microscopy of monomeric and trimeric forms of the reaction centre of photosystem I from the thermophilic cyanobacterium Phormidium laminosum has allowed the construction of a three-dimensional model describing the shape of the complex. The trimeric form of the Photosystem I reaction centre complex was found to have a very regular shape corresponding to a rounded equilateral triangle with edges ˜18 nm long and a thickness of ˜6 nm. A distinctive chiral arrangement of the three reaction centres in the trimer could be observed on one face of the complex, whereas the opposing face appeared to be smooth with no distinctive internal features. The monomeric reaction centre is roughly pearshaped, with a length of ˜15 nm and a width of ˜9 nm. A thickness of 6 nm is assumed from comparison with the trimer. It is predicted to lie with its shortest axis spanning the membrane. A double-lobed structure, with one lobe larger than the other, was occasionally observed for the monomeric reaction centre. No experimental evidence could be obtained for the existence of the trimeric form in the membrane. The formation of the trimeric form after detergent extraction is suggested. The trimeric form was found to be more stable than the monomeric form in solutions containing anionic and non-ionic detergents.     

Characterization and multiple molecular forms of TorD from Shewanella massilia,the putative chaperone of the molybdoenzyme TorA

Several bacteria use trimethylamine N-oxyde (TMAO) as an exogenous electron acceptor for anaerobic respiration. This metabolic pathway involves expression of the tor operon that codes for a periplasmic molybdopterin-containing reductase of the DMSO/TMAO family, a pentahemic c-type cytochrome, and the TorD cytoplasmic chaperone, possibly required for acquisition of the molybdenum cofactor and translocation of the reductase by the twin-arginine translocation system. In this report, we show that the TorD chaperone from Shewanella massilia forms multiple and stable oligomeric species. The monomeric, dimeric, and trimeric forms were purified to homogeneity and characterized by analytical ultracentrifugation. Small-angle X-ray scattering (SAXS) and preliminary diffraction data indicated that the TorD dimer is made of identical protein modules of similar size to the monomeric species. Interconversion of the native oligomeric forms occurred at acidic pH value. In this condition, ANS fluorescence indicates a non-native conformation of the polypeptide chain in which, according to the circular dichroism spectra, the alpha-helical content is similar to that of the native species. Surface plasmon resonance showed that both the monomeric and dimeric species bind the mature TorA enzyme, but that the dimer binds its target protein more efficiently. The possible biologic significance of these oligomers is discussed in relation to the chaperone activity of TorD, and to the ability of another member of the TorD family to bind the Twin Arginine leader sequences of the precursor of DMSO/TMAO reductases.     

Polydispersity of Bacillus thuringiensis Cry1 toxins in solution and its effect on receptor binding kinetics

Dynamic light scattering and surface plasmon resonance techniques were used to investigate the influence of ionic strength, buffer composition and pH on the multimerization of trypsin-activated Cry1Ac and Cry1C toxins over time and the subsequent effects of the different multimers on receptor binding models. In carbonate buffer at pH 10.5, Cry1Ac and Cry1C assumed a monomeric state. After 24 h, a complete conversion of monomeric toxin to a dimeric or trimeric form was observed only for Cry1Ac under low ionic strength condition. Cry1C and Cry1Ac in high ionic strength buffer remained monomeric. Substitution of CAPS pH 11 for carbonate buffer suppressed this Cry1Ac oligomerization effect. Once Cry1Ac toxin was in an aggregated form, increases in ionic strength failed to revert the aggregated toxin back to a monomeric form. Monomeric Cry1Ac bound to a purified 115 kDa aminopeptidase N receptor from Manduca sexta in a 2:1 molar ratio thus confirming the existence of two binding sites on this receptor. Binding rates of dimeric or higher aggregated Cry1Ac toxin forms were different from those generated using the monomeric form and could not be fitted to existing binding models. In summary, our results confirm that the M. sexta 115 kDa aminopeptidase N receptor possesses two Cry1Ac binding sites. They further suggest that although high pH and low salt conditions promote Cry1Ac aggregation, this observation cannot be applied universally to other members of the Cry family.     

The monomeric dUTPase from Epstein-Barr virus mimics trimeric dUTPases

Deoxyuridine 5'-triphosphate pyrophosphatases (dUTPases) are ubiquitous enzymes cleaving dUTP into dUMP and pyrophosphate. They occur as monomeric, dimeric, or trimeric molecules. The trimeric and monomeric enzymes both contain the same five characteristic sequence motifs but in a different order, whereas the dimeric enzymes are not homologous. Monomeric dUTPases only occur in herpesviruses, such as Epstein-Barr virus (EBV). Here, we describe the crystal structures of EBV dUTPase in complex with the product dUMP and a substrate analog alpha,beta-imino-dUTP. The molecule consists of three domains forming one active site that has a structure extremely similar to one of the three active sites of trimeric dUTPases. The three domains functionally correspond to the subunits of the trimeric form. Domains I and II have the dUTPase fold, but they differ considerably in the regions that are not involved in the formation of the unique active site, whereas domain III has only little secondary structure.     

Flipping the switch from monomeric to dimeric CV-N has little effect on antiviral activity

Cyanovirin-N can exist in solution in monomeric and domain-swapped dimeric forms, with HIV-antiviral activity being reported for both. Here we present results for CV-N variants that form stable solution dimers: the obligate dimer [DeltaQ50]CV-N and the preferential dimer [S52P]CV-N. These variants exhibit comparable DeltaG values (10.6 +/- 0.5 and 9.4 +/- 0.5 kcal.mol(-1), respectively), similar to that of stabilized, monomeric [P51G]CV-N (9.8 +/- 0.5 kcal.mol(-1)), but significantly higher than wild-type CV-N (4.1 +/- 0.2 kcal.mol(-1)). During folding/unfolding, no stably folded monomer was observed under any condition for the obligate dimer [DeltaQ50]CV-N, whereas two monomeric, metastable species were detected for [S52P]CV-N at low concentrations. This is in contrast to our previous results for [P51G]CV-N and wild-type CV-N, for which the dimeric forms were found to be the metastable species. The dimeric mutants exhibit comparable antiviral activity against HIV and Ebola, similar to that of wild-type CV-N and the stabilized [P51G]CV-N variant.     

Heterogeneity of molecular forms of phenol oxidase from grape leaves

The substrate specificity and some kinetic properties of the monomeric (Mr = 26 000--35 000) and dimeric (Mr = 55 000--70 000) forms of phenol oxidase from vine leaves were studied. These forms possess different hydroxylating and o-diphenol oxidase activities. A kinetic analysis demonstrated that the monomeric form of the enzyme possesses a higher affinity for monophenols and can more effectively accomplish the hydroxylation reaction as compared to the dimeric one. During vine vegetation the ratio of molecular forms of phenol oxidase is altered manifesting itself in quantitative and qualitative changes of enzymatic activity. During plant maturation the dimeric fraction is predominant. The maturation process is associated with a sharp rise of the o-phenol oxidase activity, a disappearance of the hydroxylating activity and a substantial deceleration of phenol compounds production.     

Occurrence of various forms of metallothionein in the rat after a short-term cadmium injection regimen

1. Results are presented showing that the metal-binding metallothionein (Mt) species induced in rat liver in response to Cd administration consist of dimeric and trimeric forms of Mt. A monomeric form might be the first step in the polymerization process. 2. Two proteins (about 8 and 20 kDa mol. wt) are found in hippocampus, but not in brain cortex. 3. These proteins could not be demonstrated to cross-react with our Mt antibody, but the largest of them has strong Cd-binding capacity. 4. Our Mt antibody cross-reacts with a high metal affinity protein present in both brain cortex and hippocampus of twice the mol.wt (20 kDa) of our purified rat liver Mt standard. 5. The results indicate, however, that these Mt like proteins probably emerge from high molecular or membrane bound forms in the cells. 6. A theory is proposed that the predominant polyacrylamide gel band, matching the monomeric, rat liver Mt standard band, seen for all tissues studied in the present work originate from two sources, namely membrane bound and heavy metal induced monomeric form. 7. It is furthermore suggested that those tissues playing an active role in heavy metal metabolism and in protection against toxicity of such metals contain soluble Mts whose active metal-binding forms are oligomers.     

Ca2+-dependent monomer and dimer formation switches CAPRI Protein between Ras GTPase-activating protein (GAP) and RapGAP activities

CAPRI is a member of the GAP1 family of GTPase-activating proteins (GAPs) for small G proteins. It is known to function as an amplitude sensor for intracellular Ca(2+) levels stimulated by extracellular signals and has a catalytic domain with dual RasGAP and RapGAP activities. Here, we have investigated the mechanism that switches CAPRI between its two GAP activities. We demonstrate that CAPRI forms homodimers in vitro and in vivo in a Ca(2+)-dependent manner. The site required for dimerization was pinpointed by deletion and point mutations to a helix motif that forms a hydrophobic face in the extreme C-terminal tail of the CAPRI protein. Deletion of this helix motif abolished dimer formation but did not affect translocation of CAPRI to the plasma membrane upon cell stimulation with histamine. We found that dimeric and monomeric CAPRI coexist in cells and that the ratio of dimeric to monomeric CAPRI increases upon cell stimulation with histamine. Free Ca(2+) at physiologically relevant concentrations was both necessary and sufficient for dimer formation. Importantly, the monomeric and dimeric forms of CAPRI exhibited differential GAP activities in vivo; the wild-type form of CAPRI had stronger RapGAP activity than RasGAP activity, whereas a monomeric CAPRI mutant showed stronger RasGAP than RapGAP activity. These results demonstrate that CAPRI switches between its dual GAP roles by forming monomers or homodimers through a process regulated by Ca(2+). We propose that Ca(2+)-dependent dimerization of CAPRI may serve to coordinate Ras and Rap1 signaling pathways.     

Human hemi-myeloperoxidase. Initial chlorinating activity at neutral pH, compound II and III formation, and stability towards hypochlorous acid and high temperature.

Human neutrophilic myeloperoxidase (MPO) is involved in the defence mechanism of the body against micro-organisms. The enzyme catalyses the generation of the strong oxidant hypochlorous acid (HOCl) from hydrogen peroxide and chloride ions. In normal neutrophils MPO is present in the dimeric form (140 kDa). The disulphide-linked protomers each consist of a heavy subunit and a light one. Reductive alkylation converts the dimeric enzyme into two promoters, 'hemi-myeloperoxidase'. We studied the initial activities of human dimeric MPO and hemi-MPO at the physiological pH of 7.2 and found no significant differences in chlorinating activity. These results indicate that, at least at neutral pH, the protomers of MPO function independently. The absorption spectra of MPO compounds II and III, both inactive forms concerning HOCl generation, and the rate constants of their formation were the same for dimeric MPO and hemi-MPO, but hemi-MPO required a slightly larger excess of H2O2 for complete conversion. Hemi-MPO was less stable at a high temperature (80 degrees C) as compared to the dimeric enzyme. Furthermore, the resistance of the chlorinating activity of hemi-MPO against its oxidative product hypochlorous acid was somewhat lower (IC50 = 32 microM HOCl) compared to dimeric MPO (IC50 = 50 microM HOCl). The higher stability of dimeric MPO in the presence of its oxidative product compared to that of monomeric MPO might be the reason for the occurrence of MPO as a dimer.     

Dimeric ("big") human placental lactogen. Immunological and biological activity.

Dimeric ("big") human placental lactogen has been isolated in near homogeneous form from placental tissue. It consists of a disulfide-linked (stable) form and a noncovalently associated (unstable) form of the native hormone. The two forms were separated by exposure to denaturing conditions and resolution by gel exclusion chromatography. Both forms retained immunological activity, ability to bind mammary membranes, and ability to induce mammary N-acetyllactosamine synthetase in vitro. On a molar basis, stable dimeric placental lactogen was more active than placental lactogen in the radioimmunoassay indicating that the immunological determinants on both monomeric units could bind to antibody. On a molar basis, stable dimeric placental lactogen was equally active with monomeric placental lactogen in competing for mammary gland membrane binding sites, indicating that only one active site in the molecule could interact with the membrane at a time. Stable dimeric placental lactogen was also active in an in vitro bioassay using the induction of N-acetyllactosamine synthetase. It is concluded that dimer formation does not alter the biologically active portion of the placental lactogen molecule. Since the carboxyl-terminal region (residues 182-191) is involved in the interchain disulfide bonds of dimeric placental lactogen, this portion of the molecule is probably not necessary for its biological activity.     

Characterization of a dimeric canine form of surfactant protein C (SP-C)

Canine pulmonary surfactant protein C (SP-C) is a small hydrophobic peptide which has one palmitoylated cysteine residue. SP-C enhances the insertion of phospholipids into a monolayer. Two forms of canine SP-C were isolated using Sephadex LH-60 chromatography. It was found that canine SP-C exists in a palmitoylated monomeric form of 3.5 kDa, and a non-acylated dimeric form of 7 kDa. Circular dichroism showed that both forms of SP-C exhibit similar secondary structures at the air/water interface. Both forms of SP-C were able to induce the insertion of phospholipids into a monolayer as measured with the Wilhelmy plate technique. In contrast to the palmitoylated monomeric form of SP-C, the non-acylated dimeric form of SP-C does not require calcium ions to insert phospholipids into a monolayer without the negatively charged phosphatidylglycerol. It is concluded that two forms of canine SP-C exist, but the physiological significance of these different forms remains to be established.     

Design and receptor interactions of obligate dimeric mutant of chemokine monocyte chemoattractant protein-1 (MCP-1)

Chemokine-receptor interactions regulate leukocyte trafficking during inflammation. CC chemokines exist in equilibrium between monomeric and dimeric forms. Although the monomers can activate chemokine receptors, dimerization is required for leukocyte recruitment in vivo, and it remains controversial whether dimeric CC chemokines can bind and activate their receptors. We have developed an obligate dimeric mutant of the chemokine monocyte chemoattractant protein-1 (MCP-1) by substituting Thr(10) at the dimer interface with Cys. Biophysical analysis showed that MCP-1(T10C) forms a covalent dimer with similar structure to the wild type MCP-1 dimer. Initial cell-based assays indicated that MCP-1(T10C) could activate chemokine receptor CCR2 with potency reduced 1 to 2 orders of magnitude relative to wild type MCP-1. However, analysis of size exclusion chromatography fractions demonstrated that the observed activity was due to a small proportion of MCP-1(T10C) being monomeric and highly potent, whereas the majority dimeric form could neither bind nor activate CCR2 at concentrations up to 1 μM. These observations help to reconcile previous conflicting results and indicate that dimeric CC chemokines do not bind to their receptors with affinities approaching those of the corresponding monomeric chemokines.     

Study of the quaternary structure of rat 1-Cys peroxiredoxin

Peroxiredoxins (Prx) are a family of antioxidant proteins with peroxidase activity. The ability of 1-Cys Prx to self-associate was studied with the use of native PAGE and Western blotting. Two protein bands corresponding to monomeric and dimeric forms were detected in the preparation of the recombinant 1-Cys Prx subjected to native PAGE, with dimers being more abundant. The third band corresponding to the oligomeric form was detected after incubation of the recombinant 1-Cys Prx with DTT, although monomers and dimers were also observed. These results indicate that monomeric, dimeric, and oligomeric states of the protein are likely to be interchangeable. Native PAGE in combination with Western blot analysis revealed that self-association of 1-Cys Prx also occurred at physiologically relevant concentrations in vivo. The native 1-Cys Prx existed in the monomeric and dimeric forms in rat olfactory epithelium, with monomers being more common. The structural sensitivity of the recombinant 1-Cys Prx to imidazole was shown.     

Characterization of active and inactive forms of the phenol hydroxylase stimulatory protein DmpM.

The stimulatory protein DmpM of phenol hydroxylase from methylphenol-degrading Pseudomonas sp. strain CF600 has been found to exist in two forms. DmpM purified from the native strain was mostly active in stimulating phenol hydroxylase activity, whereas an inactive form accumulated in a recombinant strain. Both forms exhibited a molecular mass of 10 361.3 +/- 1.3 Da by electrospray mass spectrometry, but nondenaturing gel filtration showed molecular masses of 31 600 Da for the inactive form and 11 500 Da for the active form. Cross-linking and sedimentation velocity results were consistent with the inactive form being a dimer. Partial thermal or chemical denaturation, or treatment with trifluoroethanol, readily activated dimeric DmpM. A combination of circular dichroism and fluorescence spectroscopies, activity assays, and native and urea gel electrophoresis were used to further characterize reactivation with urea. These results showed that dissociation of the dimeric form of DmpM precedes denaturation at low protein concentrations and results in activation. The same concentration of urea that effects dissociation also converts the monomeric form to a different conformation.