Immunoglobulin binding to platelets. The effect of aggregated IgG

When fresh platelets were incubated in serum to which heat-aggregated IgG was added, the increase of platelet-associated IgG was paralleled by increased levels of platelet-associated IgM, IgA and albumin as determined by ELISA. The increase was observed regardless of whether the platelets were quantified by conventional platelet counting or with the help of 51Cr-labelling, which was done to avoid potential counting errors induced by platelet fragmentation. In thrombocytopenic patients a correlation between in vivo bound platelet-associated albumin and IgG could be confirmed. It was concluded that aggregated IgG induces an increased binding of serum immunoglobulins and albumin to platelets in vitro.     

Nonimmune binding of Ig to Clostridium perfringens. Preferential binding of IgM and aggregated IgG

In an attempt to find a bacterial IgM receptor, a large number of bacterial strains of different species were screened for the ability to bind human IgM. Certain strains of the anaerobic bacterium Clostridium perfringens were found to bind a major fraction of polyclonal IgM. One bacterial strain showed a particularly high binding capacity and was studied in more detail. This strain is also able to bind a minor fraction of polyclonal IgA and IgG. Inhibition experiments indicate that the different Ig classes bind to one and the same R structure. The ability of the strain to bind polyclonal Ig is correlated to the number of subunits in the Ig. This correlation can most simply be explained by increasing avidity with increasing number of subunits. In agreement with this hypotheses, experiments with aggregated IgG show that binding ability increases with aggregate size. Experiments with Ig fragments indicate that the binding structure in Ig is located in the F(ab')2 region. The ability of this bacterial strain to bind a majority of IgM molecules as well as aggregated IgG is potentially useful in immunologic work and represents a new type of Ig binding to bacteria.     

The occurrence of glycine in bacterial lipopolysaccharides

Abstract The aminoacyl analysis of endotoxic lipopolysaccharides (LPS) isolated from several bacteria revealed essential amounts of glycine, among the inherent LPS components. Significant amounts of the glycine was detected in lipopolysaccharides isolated from over 30 strains of Escherichia, Salmonella, Hafnia, Citrobacter and Shigella species. Glycine as a single amino acid was found only in a core part of LPS. Molar ratio of glycine in core oligosaccharide fraction ranged from 0.2 to 0.6 per 3 heptoses. The oligosaccharide enriched in glycine was isolated using the HPLC. The amino acid appeared to be terminally located in a core oligosaccharide. The labelling of the lipopolysaccharide cores was achieved when the bacteria were cultivated in the presence of radioactive [¹⁴C]glycine. The labelled core oligosaccharide released the radioactivity during treatment with mild alkali or acid (0.1 M NaOH or HCl, 100°C, 4 h). The radioactivity in SDS-polyacrylamide gel electrophoresis migrated exclusively with LPS. The results indicate that amino acid is an integral constituent of core oligosaccharide in lipopolysaccharide.     

Structure of bacterial lipopolysaccharides

Bacterial lipopolysaccharides are the major components of the outer surface of Gram-negative bacteria They are often of interest in medicine for their immunomodulatory properties. In small amounts they can be beneficial, but in larger amounts they may cause endotoxic shock. Although they share a common architecture, their structural details exert a strong influence on their activity. These molecules comprise: a lipid moiety, called lipid A, which is considered to be the endotoxic component, a glycosidic part consisting of a core of approximately 10 monosaccharides and, in "smooth-type" lipopolysaccharides, a third region, named O-chain, consisting of repetitive subunits of one to eight monosaccharides responsible for much of the immunospecificity of the bacterial cell.     

Regulation of the host response to bacterial lipopolysaccharides

Bacterial endotoxins or lipopolysaccharides (LPS) are unique glycolipids present in the outer cell membrane of all gram-negative bacteria. It is now generally recognized that LPS is of primary importance in initiating the pathophysiological changes that often accompany gram-negative bacillary infections in humans including hypotensive shock, disseminated intravascular coagulation, and metabolic abnormalities. Although the biochemical mechanisms of these changes are not well understood, increasing emphasis has been placed on defining the biochemical response of the macrophage (M phi) to LPS. In this paper we describe two M phi-derived factors induced by LPS that may be important in the expression of endotoxic activity in the host. These are a procoagulant activity, which is present on the cell membrane of LPS-treated rabbit liver M phi and acts by directly activating coagulation factor X, and a factor released into the supernatant by LPS-treated peritoneal exudate M phi, which suppresses steroidogenesis in explanted adrenocortical cells. The potential role of the M phi in regulating the binding of LPS to high-density lipoproteins through the induction of acute phase proteins is also considered.     

The amino-terminal domain of ClpB supports binding to strongly aggregated proteins

Bacterial heat-shock proteins, ClpB and DnaK form a bichaperone system that efficiently reactivates aggregated proteins. ClpB undergoes nucleotide-dependent self-association and forms ring-shaped oligomers. The ClpB-assisted dissociation of protein aggregates is linked to translocation of substrates through the central channel in the oligomeric ClpB. Events preceding the translocation step, such as recognition of aggregates by ClpB, have not yet been explored, and the location of the aggregate-binding site in ClpB has been under discussion. We investigated the reactivation of aggregated glucose-6-phosphate dehydrogenase (G6PDH) by ClpB and its N-terminally truncated variant ClpBDeltaN in the presence of DnaK, DnaJ, and GrpE. We found that the chaperone activity of ClpBDeltaN becomes significantly lower than that of the full-length ClpB as the size of G6PDH aggregates increases. Using a "substrate trap" variant of ClpB with mutations of Walker B motifs in both ATP-binding modules (E279Q/E678Q), we demonstrated that ClpBDeltaN binds to G6PDH aggregates with a significantly lower affinity than the full-length ClpB. Moreover, we identified two conserved acidic residues at the surface of the N-terminal domain of ClpB that support binding to G6PDH aggregates. Those N-terminal residues (Asp-103, Glu-109) contribute as much substrate-binding capability to ClpB as the conserved Tyr located at the entrance to the ClpB channel. In summary, we provided evidence for an essential role of the N-terminal domain of ClpB in recognition and binding strongly aggregated proteins.     

Selectivity in lipid binding to the bacterial outer membrane protein OmpF

The outer membrane porin OmpF from Escherichia coli has been reconstituted into lipid bilayers of defined composition, and fluorescence spectroscopy is used to characterize its interaction with the surrounding lipid. OmpF is a trimer within the membrane. It contains two Trp residues per monomer, Trp(214) at the lipid-protein interface and Trp(61) at the trimer interface. The fluorescence of Trp-214 in the mutant W61F is quenched by dibromostearoylphosphatidylcholine (di(Br(2)C18:0)PC), whereas the fluorescence of Trp(61) in the mutant W214F is not quenched by di(Br(2)C18:0)PC when fluorescence is excited directly through the Trp rather than through the Tyr residues. Measurements of relative fluorescence quenching for OmpF reconstituted into mixtures of lipid X and di(Br(2)C18:0)PC have been analyzed to give the binding constant of lipid X for OmpF, relative to that for dioleoylphosphatidylcholine (di(C18:1)PC). The phosphatidylcholine showing the strongest binding to OmpF is dimyristoyloleoylphosphatidylcholine (di(C14:1)PC) with binding constants decreasing with either increasing or decreasing fatty acyl chain length. Comparison with various theories for hydrophobic matching between lipids and proteins suggests that in the chain length range from C14 to C20, hydrophobic matching is achieved largely by distortion of the lipid bilayer around the OmpF, whereas for chains longer than C20, distortion of both the lipid bilayer and of the protein is required to achieve hydrophobic matching. Phosphatidylcholine and phosphatidylethanolamine bind with equal affinity to OmpF, but the affinity for phosphatidylglycerol is about half that for phosphatidylcholine.     

Study of the binding between bacterial lipopolysaccharides and polymyxin by a bioluminescent method

For rating the interaction of lipopolysaccharides (LPS) with polymixin B (PmB) a bacterial bioluminescence is offered to be used. Bioluminescence level of bacteria decreases under free antibiotic amounts action. It is shown, that as a result of interaction with LPS antibiotic properties of PmB are reduced, and the intensity of bacterial bioluminescence is restored. The bioluminescence level in such system characterizes the LPS quantity. Kinetic properties of bacterial light emission at the presence of LPS and PmB are investigated as well as equilibrium state of the system. Kinetic and equilibrium constants describing this reaction are determined. The conditions of quantitative bioluminescent definition of LPS in an interval of concentration 0.166-10 micrograms/ml have been chosen and calibration curves are presented.     

The response of recombinant inbred strains of mice to bacterial lipopolysaccharides.

Fourteen recombinant inbred strains of mice have been produced by the inbreeding of the F2 generation of a cross between C57BL/6J and C3H/HeJ progenitor mice. The responses of these BXH strains to bacterial lipopolysaccharides (LPS) have been characterized. Four BXH strains are high LPS responders and nine strains are low LPS responders. One BXH strain shows intermediate responsiveness which may reflect residual heterozygosity. F1 hybrid mice from low x high responder strains were intermediate in their response to LPS suggesting additive genetic control. The LPS responses in backcross mice from the F1 x low LPS responders showed segregation consistent with LPS responsiveness being determined by a single gene. In 13/14 BXH strains, there was concordant inheritance of LPS responsiveness and the major urinary protein locus Mup-1b. The association of the expression of the Mup-1 alleles with LPS responsiveness in the BXH strains suggests that the defective LPS response gene in C3H/HeJ mice is located on chromosome 4.     

Human Nod1 confers responsiveness to bacterial lipopolysaccharides

The immune response to microbial pathogens is initiated by recognition of specific pathogen components by host cells both at the cell surface and in the cytosol. While the response triggered by pathogen products at the surface of immune cells is well characterized, that initiated in the cytosol is poorly understood. Nod1 is a member of a growing family of intracellular proteins with structural homology to apoptosis regulators Apaf-1/Ced-4 and a class of plant disease-resistant gene products. Here we show that bacterial lipopolysaccharides, but not other pathogen components tested, induced TLR4- and MyD88-independent NF-kappaB activation in human embryonic kidney 293T cells expressing trace amounts of Nod1. Nod2, another Nod family member, also conferred responsiveness to bacterial components but with a response pattern different from that observed with Nod1. As it was reported for plant disease-resistant R proteins, the leucine-rich repeats of Nod1 and Nod2 were required for lipopolysaccharide-induced NF-kappaB activation. A lipopolysaccharide binding activity could be specifically coimmunopurified with Nod1 from cytosolic extracts. These observations suggest that Nod1 and Nod2 are mammalian counterparts of plant disease-resistant gene products that may function as cytosolic receptors for pathogen components derived from invading bacteria.     

Structural basis for selective GABA binding in bacterial pathogens

GABA acts as an intercellular signal in eukaryotes and as an interspecies signal in host–microbe interactions. Structural characteristics of selective eukaryotic GABA receptors and bacterial GABA sensors are unknown. Here, we identified the selective GABA‐binding protein, called Atu4243, in the plant pathogen Agrobacterium tumefaciens. A constructed atu4243 mutant was affected in GABA transport and in expression of the GABA‐regulated functions, including aggressiveness on two plant hosts and degradation of the quorum‐sensing signal. The GABA‐bound Atu4243 structure at 1.28 Å reveals that GABA adopts a conformation never observed so far and interacts with two key residues, Arg²⁰³ and Asp²²⁶ of which the role in GABA binding and GABA signalling in Agrobacterium has been validated using appropriate mutants. The conformational GABA‐analogue trans‐4‐aminocrotonic acid (TACA) antagonizes GABA activity, suggesting structural similarities between the binding sites of the bacterial sensor Atu4243 and mammalian GABA_C receptors. Exploration of genomic databases reveals Atu4243 orthologues in several pathogenic and symbiotic proteobacteria, such as Rhizobium, Azospirillum, Burkholderia and Pseudomonas. Thus, this study establishes a structural basis for selective GABA sensors and offers opportunities for deciphering the role of the GABA‐mediated communication in several host–pathogen interactions.     

Clearance of bacterial lipopolysaccharides and lipid A by the liver and the role of argininosuccinate synthase

The liver is thought to be involved in the systemic clearance and detoxification of lipopolysaccharide (LPS). Argininosuccinate synthase (AS), a liver cytosolic urea cycle enzyme, has been found to bind to and inactivate LPS and lipid A. To elucidate the participation of AS in the clearance of LPS by liver and hepatocytes, we investigated the correlation between AS content and the removal of lipid A and LPS in vivo and in vitro, tracing levels of biological activity. A hepatotoxic model in which mice were injected with CCl(4) revealed a significant reduction in lipid A clearance along with liver failure on day 1; total body clearance was changed to 0.534 ml/min from 1.42 ml/min. AS content in liver concomitantly decreased to about half and AS leaked to blood at about 6 microg/ml. Total body clearance of i.v. injected AS was estimated at 0.083 ml/min, which predicted about 24-h leakage of AS after CCl(4) injection. The treatment also reduced the clearance of R-type LPSs to a lesser degree the larger its polysaccharide portion. S-type LPS, which has a large O-antigen polysaccharide, exhibited enhancement of clearance on CCl(4) treatment. When pretreated in vitro with AS and injected into normal mice, lipid A and R-type LPS showed a similar pattern of clearance of residual activities to the untreated forms, but S-type LPS exhibited enhancement of clearance. Comparison between different strains of mice revealed a correlation of AS content in liver and lipid A clearance, where the higher AS strain C3H/He mice showed a more rapid clearance than the lower AS strains C57BL/6 and BALB/c. Primary spheroid cultures of hepatocytes treated with 0.1 microM dexamethasone and 1 microM glucagon showed about a 2-fold increase in AS amount and a more rapid clearance of LPS from culture medium than untreated cells. These results suggest that AS in hepatocytes may be involved in the process of lipid A and LPS clearance and the extracellular leakage of AS may also participate in the systemic detoxification.     

Thermolytical techniques to characterize fungal polysaccharides and bacterial lipopolysaccharides.

The present work constitutes an entirely novel contribution in the scope of microbiology and especially in taxonomy, introducing thermolysis curves as a rapid method of characterization of fungal polysaccharides and bacterial lipopolysaccharides. The thermal analysis techniques applied were thermogravimetry and derivative thermogravimetry (TG-DTG), differential thermal analysis (DTA), and differential scanning calorimetry (DSC). Each thermogram of a sample is represented by one or a few temperatures and, in DSC, by complementary enthalpy data. The temperatures of the thermograms from structurally unknown polysaccharides are compared with those used as references, and thus, information on their composition, linkage types, and anomeric configuration can be deduced. The situation is more complicated for bacterial lipopolysaccharides, but in whatever mode, a structural estimation is always possible. In the course of the development and validation of the thermal method, structural findings on relative stabilities of linkage types (valuable in carbohydrate research) have been recognized and are therefore also described in this work.     

Structural and functional analyses of bacterial lipopolysaccharides

Bacterial lipopolysaccharides (LPSs) are powerful immunomodulators in infected hosts, and may cause endotoxic shock. Most of them share a common architecture but vary considerably in structural motifs from one genus, species, and strain to another. Cells of the innate immune response recognize evolutionarily conserved LPS molecular patterns of endotoxins and structural details thereby greatly influencing their response.     

Mapping of the binding specificity for five monoclonal antibodies recognizing 3-deoxy-D-manno-octulosonic acid in bacterial lipopolysaccharides

Mouse mAb were produced against the deep rough strains Salmonella minnesota R 595, Salmonella typhimurium SL 1102, and Escherichia coli D21f2 and screened by enzyme immunoassay against LPS of several chemotypes. Five antibodies were selected for their ability to bind to chemotype deep rough (Re) LPS which has two 3-deoxy-D-manno-octulosonic acid (Kdo) residues in its nonreducing end. Structurally verified oligosaccharides isolated from rough LPS and synthetic analogues of Kdo were used in an enzyme immunoassay inhibition test to determine the binding epitopes for the antibodies. According to their specificities, the antibodies could be divided into three groups. For two of the groups, the recognized structure was the alpha-Kdo (2----4) Kdo disaccharide and for one group the alpha-Kdo (2----4) alpha-Kdo beta-D-GlcN (1----6) alpha-D-GlcN tetrasaccharide, representing a partial structure of the Re LPS. Inhibition studies with synthetic analogues of Kdo showed that the anomeric configuration and the free carboxyl group of the Kdo residue are important features for antibody binding. Changes in the C-1 to C-6 region of the Kdo molecule do influence the antibody recognition considerably whereas changes in the exocyclic C-7 to C-8 region are of secondary importance. Calculation of the conformation of the inner core region showed that the alpha-Kdo (2----4) alpha-Kdo (2---- disaccharide was free and accessible in chemotype Re LPS, but that linkage of a L-glycero-D-manno-heptose to O-5 of the subterminal Kdo both changes the conformation of the Kdo-disaccharide and covers it thereby making it less accessible.