Insulin-cholera toxin binding unit conjugate: a hybrid molecule with insulin biological activity and cholera toxin binding specificity

The polypeptide hormone insulin and the binding unit of cholera toxin (CTB) were coupled via a disulfide bond. This hybrid molecule had 1/30 the ability of native insulin to bind to the insulin receptor and 1/30 the biological activity of native insulin in H35 rat hepatoma cells and rat adipocytes. Thus, in these two cell types that are very sensitive to insulin, the biological activity of the hybrid molecule was as predicted on the basis of the ability of the molecule to interact with the insulin receptor. In contrast, in HTC rat hepatoma cells and rat thymocytes, two poorly responsive cell types, the insulin-CTB conjugate had 1/3 the biological activity of native insulin, a value 10 times greater than its insulin receptor binding potency. This increased activity of the conjugate did not appear to be due to cholera toxin in the preparation, since a control of uncoupled CTB had no biological activity. Furthermore, native cholera toxin increased intracellular levels of cAMP by 20-fold, whereas the conjugate had no effect on cAMP levels. The CTB moiety did, however, contribute to the biological activity of the conjugate, since the activity of the hybrid molecule, like cholera toxin, was inhibited by gangliosides, whereas the activity of native insulin was not. Finally, the binding to thymocytes of insulin-CTB conjugate, but not insulin, was inhibited by gangliosides. Thus, a hybrid hormone molecule has been constructed which has insulin-like biological activity with the receptor specificity of cholera toxin in poorly responsive cells.     

Characterization of a family of IAA-amino acid conjugate hydrolases from Arabidopsis

The mechanisms by which plants regulate levels of the phytohormone indole-3-acetic acid (IAA) are complex and not fully understood. One level of regulation appears to be the synthesis and hydrolysis of IAA conjugates, which function in both the permanent inactivation and temporary storage of auxin. Similar to free IAA, certain IAA-amino acid conjugates inhibit root elongation. We have tested the ability of 19 IAA-l-amino acid conjugates to inhibit Arabidopsis seedling root growth. We have also determined the ability of purified glutathione S-transferase (GST) fusions of four Arabidopsis IAA-amino acid hydrolases (ILR1, IAR3, ILL1, and ILL2) to release free IAA by cleaving these conjugates. Each hydrolase cleaves a subset of IAA-amino acid conjugates in vitro, and GST-ILR1, GST-IAR3, and GST-ILL2 have K(m) values that suggest physiological relevance. In vivo inhibition of root elongation correlates with in vitro hydrolysis rates for each conjugate, suggesting that the identified hydrolases generate the bioactivity of the conjugates.     

Characterization of Streptococcus agalactiae CAMP factor as a pore-forming toxin

A recombinant form of CAMP factor of Streptococcus agalactiae has been expressed as glutathione S-transferase-CAMP fusion protein in Escherichia coli. After thrombin cleavage of the fusion protein, the recombinant CAMP factor exhibited hemolytic activity comparable with that of the native form. Osmotic protection experiments with polyethylene glycols show that CAMP factor forms discrete transmembrane pores with a diameter upward of 1.6 nm on susceptible membranes; electron microscopy reveals circular membrane lesions of heterogeneous size, up to 12-15 nm in diameter. Liposome permeabilization studies show that pore formation is a highly cooperative process, which suggests that it involves the oligomerization of CAMP factor. Chemical cross-linking experiments also support an oligomeric mode of action.     

Characterization of high-order diphtheria toxin oligomers

In 3D domain swapping, a domain of a protein breaks its noncovalent bonds with the protein core and its place is taken by the identical domain of another molecule, creating a strongly bound dimer or higher order oligomer. For some proteins, including diphtheria toxin, 3D domain swapping may affect protein function. To explore the molecular basis of 3D domain swapping in a well-characterized protein system, domain-swapped oligomers of diphtheria toxin were produced by freezing and thawing under a variety conditions, including in various salts and buffers, and at various temperatures. Reaction yields were followed by high-performance size-exclusion chromatography. The traditional low pH pulse produced by freeze-thawing in mixed sodium phosphate buffer induces the oligomerization of DT, but the addition of alkali chloride salts was found to increase the yield in the order of Li(+) > Na(+) > K(+). Unexpectedly, oligomers also formed when DT was frozen and thawed in the presence of 1 M LiCl alone. Slower freezing and thawing of the mixture led to the production of more and larger oligomers. DT oligomers were also produced by exposure to acidic buffers, and were found by electron microscopy to adopt both linear and cyclized forms in a wide distribution of sizes. Upon the basis of these results, the model for the production of DT oligomers by freezing and thawing was expanded to include a salt-mediated pathway. We present a mechanism for the formation of high-order DT oligomers by acidification that takes into account domain swapping and hydrophobic interactions.     

Characterization of a clinical polymer‐drug conjugate using multiscale modeling

The molecular conformation of certain therapeutic agents has been shown to affect the ability to gain access to target cells, suggesting potential value in defining conformation of candidate molecules. This study explores how the shape and size of poly‐γ‐glutamyl‐glutamate paclitaxel (PGG‐PTX), an amphiphilic polymer‐drug with potential chemotherapeutic applications, can be systematically controlled by varying hydrophobic and hydrophilic entities. Eighteen different formulations of PGG‐PTX varying in three PTX loading fractions (f_PTX) of 0.18, 0.24, and 0.37 and six spatial arrangements of PTX (‘clusters’, ‘ends’, ‘even’, ‘middle’, ‘random’, and ‘side’) were explored. Molecular dynamics (MD) simulations of all‐atom (AA) models of PGG‐PTX were run until a statistical equilibrium was reached at 100 ns and then continued as coarse‐grained (CG) models until a statistical equilibrium was reached at an effective time of 800 ns. Circular dichroism spectroscopy was used to suggest initial modeling configurations. Results show that a PGG‐PTX molecule has a strong tendency to form coil shapes, regardless of the PTX loading fraction and spatial PTX arrangement, although globular shapes exist at f_PTX = 0.24. Also, less uniform PTX arrangements such as ‘ends’, ‘middle’, and ‘side’ produce coil geometries with more curvature. The prominence of coil shapes over globules suggests that PGG‐PTX may confer a long circulation half‐life and high propensity for accumulation to tumor endothelia. This multiscale modeling approach may be advantageous for the design of cancer therapeutic delivery systems. © 2010 Wiley Periodicals, Inc. Biopolymers 93: 936–951, 2010.     

Characterization of a full-length, active-site mutant of diphtheria toxin.

A full-length recombinant mutant of diphtheria toxin containing serine in place of a crucial active-site glutamate has been purified and characterized. The serine substitution caused a minor structural alteration in the toxin as measured by trypsinolysis. ADP-ribosyltransferase activity and cytotoxicity of the mutant were both decreased by approximately 500-fold. A similar reduction in cytotoxicity was found when the enzymic fragments of both the wild-type and mutant toxins were introduced into the cytosol of fibroblasts by osmotically lysing pinosomes. The mutation did not alter the binding of the toxin to cell surface receptors and had no apparent effect on membrane translocation. The results suggest that the decreased cytotoxicity of the mutant is solely due to the reduced ADP-ribosyltransferase activity.     

Characterization of the diphtheria toxin receptor-binding domain

The carboxyl-terminal region of diphtheria toxin (DT) has been analysed in order to determine regions of receptor recognition. Biochemical cleavage of the toxin with hydroxylamine (HA) was used to generate the peptides HA9DT (residues 454–535), HA6DT (residues 482–535), and HA3DT (residues 454–461). Characterization of HA6DT demonstrated that the final 54 amino acids of DT are sufficient to constitute the receptor-binding domain of the toxin. Within HA9DT, the region encompassing HA3DT and containing the highly cationic polyphosphate-binding site did not contribute to the binding ability of HA6DT. Consistent with this observation, HA3DT itself did not compete for binding of radiolabelled DT to Vero cells. A 30-amino acid synthetic peptide composed of residues 506–535 did not block receptor binding of DT, indicating that residues toward the amino-terminus of HA6DT, or the entire HA6DT region, are required for receptor recognition.     

Characterization of a lipophilic plasmid DNA condensate formed with a cationic peptide fatty acid conjugate

In the presence of cationic ligands, DNA molecules can become aggregated into larger particles in a process known as condensation. DNA condensates are of interest as models for the dense packing found in naturally occurring structures such as phage heads and chromatin. They have found extensive application in DNA transfection and also provide convenient models with which to study DNA damage by the direct effect of ionizing radiation. Further, conjugates of cationic peptides with fatty acids may represent a class of attractive ligands for these areas because of their simple synthesis. When plasmid pUC18 is used as the DNA target and N-caproyl-penta-arginine amide (Cap-R(5)-NH(2)) is used as the ligand, the physical properties of the resulting mixtures were characterized using static and dynamic light scattering, sedimentation, dye exclusion, circular dichroism, nanoparticle tracking, and atomic force microscopy. Their chemical properties were assayed using solvent extraction and protection against hydroxyl radical attack and nuclease digestion. Titration of the plasmid with the Cap-R(5)-NH(2) ligand produced sharply defined changes in both chemical and physical properties, which was associated with the formation of condensed DNA particles in the 100-2000 nm size range. The caproyl group at the ligand's N-terminus produced a large increase in the partitioning of the resulting condensate from water into chloroform and in its binding to the neutral detergent Pluronic F-127. Both the physical and chemical data were all consistent with condensation of the plasmid by the ligand where the presence in the ligand of the caproyl group conferred an extensive lipophilic character upon the condensate.     

Development of a diphtheria toxin mutant conjugate directed against antigen-specific B cells expressing high affinity surface Ig

Modification of a mutant diphtheria toxin, possessing reduced binding capacity, with TNP groups resulted in an Ag-toxin conjugate capable of eliminating TNP-specific B cells. Previous experimental approaches to the elimination of Ag-specific B cells have involved the conjugation of Ag to holoricin molecules or ricin A chain. Holoricin conjugates possess efficacy, but display high nonspecific toxicity. A chain conjugates, which appear specific, lack high potency. In developing the diphtheria toxin-based conjugate, we found high potency for target anti-TNP hybridoma cells and for spleen cells isolated from TNP-immunized mice. The similar intoxication of nontarget cells required concentrations approximately three orders of magnitude higher. Additionally, it was found that the TNP-specific agent may have selectively depleted B cells producing high affinity IgG anti-TNP antibodies.     

Characterization of a glutathione conjugate of the 1,4-benzosemiquinone-free radical formed in rat hepatocytes

Rat hepatocytes treated with 1,4-benzoquinone formed 1,4-benzosemiquinone and 2-S-glutathionyl-1,4-benzosemiquinone radicals as detected by ESR spectroscopy. The 2-S-glutathionyl-1,4-benzosemiquinone radical was first obtained from the reaction of 1,4-benzoquinone with glutathione. Glutathione both reduced benzoquinone to form benzosemiquinone and conjugated benzoquinone to form 2-S-glutathionyl-1,4-benzosemiquinone radical. The ratio of these two radicals depended upon the ratio of 1,4-benzoquinone to glutathione. At near equimolar ratios, the 2-S-glutathionyl-1,4-benzosemiquinone radical was predominantly formed. This radical was characterized by computer simulation of the experimental spectra and identified by comparison of its hyperfine coupling constants with those of chemical analogues. The 2-S-glutathionyl-1,4-benzosemiquinone radicals formed inside hepatocytes, and then crossed the plasma membrane into the media.     

Characterization of a toxin produced by a rhizobacterialPseudomonas sp. that inhibits wheat growth

A toxin produced by a deleterious rhizobacterial pseudomonad that inhibits both winter wheat (Triticum aestivum L.) root andEscherichia coli growth was characterized. The toxin was rapidly deactivated at pH 2 and 12 and by autoclaving (121°C, 15 minutes). Less toxin was destroyed as the temperature and time of exposure decreased, and at 40°C it was stable for at least 24 hours. The toxin was extremely polar and could not be extracted from culture filtrates with organic solvents. The compound eluted after the void volume from a Sephadex G-10 column indicating a molecular weight of less than 700. The toxin adsorbed to Dowex 50W strong cation exchange resin and eluted with 2M NH₄OH. Numerous thin layer chromatography solvent systems were unsuccessful at purifying the toxin. The partially purified toxin inhibited several different microorganisms while the producing strains were resistant. The toxin appears unique to toxins produced by recognized plant pathogenic bacteria.Contribution from the Agric. Res. Serv., U.S. Dept. of Agriculture in cooperation with the College of Agric. and Home Econ., Res. Ctr., Washington State University, Pullman, WA 99164, USA     

Characterization of the deoxyribonuclease activity of diphtheria toxin

Having discovered that the A domain of diphtheria toxin exhibits intrinsic nuclease activity (Chang, M. P., Baldwin, R. L., Bruce, B., and Wisnieski, B. J. (1989) Science 246, 1165-1168), we proceeded to examine the requirements for optimal enzymic expression. In vitro assays with linear double-stranded DNA demonstrated that optimal activity occurs at pH 7.5 and 37 degrees C. A characterization of the stringent cation-dependence of the reaction revealed increasing activity with increasing Mn2+ up to 30 mM. In contrast, activity levels with Ca2+ or Zn2+ alone peaked at 100 microM and with Mg2+ alone at 1 mM. The Zn2(+)- and Mg2(+)-stimulated activities appear to be dependent on trace amounts of Ca2+. Indeed, inclusion of 2 mM Ca2+ plus 3 mM Mg2+ in the reaction buffer promoted a high level of DNA cleavage even though very little cleavage was seen with either cation alone at 2-3 mM. Addition of 20-200 mM NaCl or KCl caused progressive inhibition. Detection of diphtheria toxin nuclease activity under physiologically relevant conditions suggests that it may be operative in vivo and supports our contention that diphtheria toxin-induced cytolysis is not a simple consequence of protein synthesis inhibition, but rather the final step in a cytolytic pathway linked to chromosomal integrity.     

Characterization of pertussis toxin by LC-MS/MS

Liquid chromatography-mass spectrometry (LC-MS) with a dual spray electrospray ionization source has been used to measure the molecular weights of pertussis toxin (PT) subunits. Measurement accuracy better than 0.4 Da was achieved for all PT subunits in the molecular weight range of 11,000 to 27,000 Da. At this mass assignment accuracy level, the sequences of the PT subunits investigated in this study are easily determined based on molecular weight alone. The subunits 1, 2, and 5 of PT were observed to undergo oxidation under normal storage conditions as ammonium sulfate suspension at 2 to 8 degrees C. These oxidized subunits can be separated completely or partially by reverse-phase high-performance liquid chromatography (HPLC) from their native counterparts. For the determination of oxidation sites, the oxidized subunits and their nonoxidized counterparts were fraction collected, trypsin digested, and mapped by LC-MS. The oxidized peptides and their nonoxidized counterparts were further studied by liquid chromatography-tandem mass spectrometry (LC-MS/MS) to confirm their identities. The methionines at position 212 of subunit 1, at position 89 of subunit 2, and at position 40 of subunit 5 were found to be the primary sites of oxidation.     

Characterization of the glutathione conjugate of the semisynthetic flavonoid monoHER

Flavonoids protect against oxidative stress by scavenging free radicals. During this protection flavonoids are oxidized. The oxidized flavonoids formed are often reactive. Consequently, protection by flavonoids can result in the formation of toxic products. In this study the oxidation of 7-mono-O-(β-hydroxyethyl)rutoside (monoHER), which is a constituent of the registered drug Venoruton, was studied in the absence and presence of glutathione (GSH). MonoHER was oxidized by horseradish peroxidase/H₂O₂. Spectrophotometric and HPLC analysis showed that in the presence of GSH, a monoHER–GSH conjugate was formed, which was identified as 2′-glutathionyl monohydroxyethylrutoside by mass spectrometric analysis and ¹H NMR. Preferential formation of this glutathione adduct in the B ring at C2′ was confirmed by molecular quantum chemical calculations. This conjugate was also detected in the bile fluid of a healthy volunteer after iv administration of monoHER, demonstrating its formation in vivo. These results indicate that in the process of offering protection against free radicals, monoHER is converted into an oxidation product that is reactive toward thiols. The formation of this thiol-reactive oxidation product is potentially harmful. Thus, the supposed beneficial effect of monoHER as an antioxidant may be accompanied by the formation of products with an electrophilic, toxic potential.     

Characterization of a toxin fromParthenium hysterophorus and its mode of excretion in animals

Fractionation of methanolic extracts of air dried aerial parts ofParthenium resulted in the isolation of a toxic constituent which was identified as parthenin, the major sesquiterpene lactone from the weed. The LD₅₀ (minimal lethal dose required to cause 50% mortality) for parthenin in rats was 42 mg/kg body weight. When [³H]-parthenin was given orally or by intravenous administration, radioactivity appeared in the milk of lactating laboratory and dairy animals. Tissue distribution of radioactivity revealed that maximum label was detectable in kidneys.     

Characterization of a novel killer toxin encoded by a double-stranded linear DNA plasmid of Kluyveromyces lactis

A novel killer toxin, encoded by a double-stranded linear DNA plasmid pGK l-1 (5.4 MDa) in Kluyveromyces lactis IFO 1267 was purified 320 000-fold from the culture broth of yeast. The toxin was obtained in an electrophoretically homogeneous state with a yield of 24% by hydroxyapatite column chromatography, chromatofocusing and polyacrylamide gel electrophoresis. The purified toxin was dissociated into two subunits with molecular masses of 27 kDa and above 80 kDa, as estimated by Laemmli's sodium dodecylsulfate gel electrophoresis; the exact composition ratio of the two subunits remains unestablished. The isoelectric point was between 4.4 and 4.8. As compared with the reported narrow pH range of action and instability of k1 killer toxin encoded by a double-stranded RNA plasmid of Saccharomyces cerevisiae, the K. Lactis toxin was effective with sensitive strains of S. cerevisiae in a relatively wider pH range between 4 and 8; it was stable for several months at pH 6.0 when stored below -20 degrees C. In contrast to the simple protein nature of the k1 killer toxin with a molecular mass of 11.47 kDa, the K. lactis toxin maintained a mannoprotein nature, as it was absorbed by a ConA-Sepharose column and eluted by methyl alpha-D-mannoside. The growth inhibitory activity of K. lactis toxin was enhanced 2-35-fold by the presence of 4-60% glycerol.     

Characterization of purified Shiga toxin from Shigella dysenteriae 1

Shiga toxin was purified from the culture supernatant of Shigella dysenteriae 1 by ammonium sulfate fractionation, DEAE-cellulose column chromatography and repeated chromatofocusing column chromatography. About 1.6 mg of purified Shiga toxin was obtained from 15 liters of culture with a yield of about 27%. The molecular weight of purified Shiga toxin was estimated to be 62,000. The toxin consisted of A and B subunits with molecular weights of about 30,000 and 5,000-6,000, respectively. The isoelectric point of purified Shiga toxin was 7.0. Purified Shiga toxin showed the following biological activities: lethal toxicity to mice when injected intraperitoneally with an LD50 of 28 ng per mouse; cytotoxicity to Vero cells, killing about 50% of the cells at 1 pg and all of the cells at 10 pg; and fluid accumulation in rabbit ileal loops at a concentration of more than 1 microgram.