13C-NMR and spectrophotometric studies of alcohol-lipid interactions

The interactions of butanol and mixtures of butanol and ethanol with dipalmitoylphosphatidyl choline (DPPC) liposomes have been investigated by both spectrophotometric measurements and Fourier transform 13C nuclear magnetic resonance spectroscopy. The spectrophotometric experiments indicate that butanol exhibits the same effects on the thermotropic properties of DPPC as the other short chain alcohols, methanol, ethanol and propanol, which have been shown to be characteristic of the alcohol induced transition of the lipid to the interdigitated state. An additive effect of butanol and ethanol on the induction of the interdigitated phase in DPPC was also observed. A decrease in line width and increase in T1 of the choline methyl signal were observed in the 13C-NMR experiments conducted at 32 degrees C when butanol was added to DPPC in increasing amounts suggesting an increase of disorder in the head group region of the lipid. Addition of ethanol to the NMR sample containing butanol produced hysteresis in the heating and cooling curves characteristic of the interdigitated state. In the interdigitated state, the choline methyl signal exhibited a T1 value equal to that when the lipid is in the fluid state. The increase of mobility in the head group region in the interdigitated gel state relative to the bilayer gel can be rationalized by the increase in surface area in that site when the lipid interdigitates.     

Paramagnetic 1H and 13C NMR studies on cobalt-substituted human carbonic anhydrase I carboxymethylated at active site histidine-200: molecular basis for the changes in catalytic properties induced by the modification

Using bromo[1-13C]acetate to modify N tau of His-200 of human carbonic anhydrase isozyme I leads to the introduction of a useful 13C NMR probe into the active site. To complement our previous diamagnetic NMR studies with this probe, we have now succeeded in directly observing the paramagnetically perturbed resonance of the carboxylate in the cobalt-substituted modified enzyme above pH 8. In the pH range 8-10, the resonance undergoes a pH-dependent slow-exchange process, with the more alkaline form having a much smaller pseudocontact shift and a narrower line width. Below pH 8, the resonance apparently undergoes a very large paramagnetic downfield shift that was estimated by extrapolation. An ionization of approximate pK of 6 appears to control this process. Paramagnetic spin-relaxation studies on the resonance under conditions where it was directly observed yielded distance measurements between the carboxylate carbon and the active site cobalt ion. In inhibitor complexes, this distance was in the range of 5-7 A. In the absence of inhibitors, the distance was approximately 3.0-3.2 A at pH 7.9, consistent with the coordination of the carboxylate to the metal. However, at pH 10, the distance was increased to 4.8 A. These distance determinations were aided by relaxation measurements of a paramagnetically shifted proton resonance at 60-65 ppm downfield assigned by others to a proton of a ligand histidine of metal and confirmed by us to be 5.2 +/- 0.1 A from the metal. Our findings provide a molecular basis for the observed changes in catalytic properties that accompany the carboxymethylation.     

Metabolism of DL-Tryptophan-3-14C by the Fruitlets of Citrus aurantifolia

Developing lime fruit [Citrus aurantifolia (Christm.) Swingle] was supplied with dl-tryptophan-3-¹⁴C in a special medium. An incubation period of six hours was sufficient for the radioactivity to reach an equilibrium between the fruit tissue and the incubation medium. Analyses of the fruit tissue and the medium for acidic and neutral metabolites of tryptophan indicated the existence of indolic products. The auxin indole-3-acetic acid (IAA) was identified among the products by dry column chromatography and biological assay. Other acidic metabolites included indolepyruvic acid and an unidentified material. Neutral metabolites included indolealdehyde, indoleacetaldehyde, and two unidentified compounds. Biological activity in the Avena curvature test was obtained from extracted compounds which corresponded to IAA and indolepyruvic acid in the acidic fraction and indoleacetaldehyde in the neutral fraction. Radioactive tryptophan was also found in both the acidic and the neutral fractions due to its amphoteric nature. The experiment demonstrated the conversion of tryptophan to its indolic metabolites, including indole-3-acetic acid, in this Citrus tissue.     

Unusual susceptibility of heme proteins to damage by glucose during non-enzymatic glycation

Glucose modifies the amino groups of proteins by a process of non-enzymatic glycation, leading to potentially deleterious effects on structure and function that have been implicated in the pathogenesis of diabetic complications. These changes are extremely complex and occur very slowly. We demonstrate here that hemoglobin and myoglobin are extremely susceptible to damage by glucose in vitro through a process that leads to complete destruction of the essential heme group. This process appears in addition to the expected formation of so-called advanced glycation end products (AGEs) on lysine and other side-chains. AGE formation is enhanced by the iron released. In contrast, the heme group is not destroyed during glycation of cytochrome c, where the sixth coordination position of the heme iron is not accessible to solvent ligands. Glycation leads to reduction of ferricytochrome c in this case. Since hydrogen peroxide is known to destroy heme, and the destruction observed during glycation of hemoglobin and myoglobin is sensitive to catalase, we propose that the degradation process is initiated by hydrogen peroxide formation. Damage may then occur through reaction with superoxide generated (a reductant of ferricytochrome c), or hydroxyl radicals, or with both.     

Utilizing Environmental Friendly Iron as a Substitution Element in Spinel Structured Cathode Materials for Safer High Energy Lithium‐Ion Batteries

Suppressing oxygen release from lithium ion battery cathodes during heating is a critical issue for the improvement of the battery safety characteristics because oxygen can exothermically react with the flammable electrolyte and cause thermal runaway. Previous studies have shown that oxygen release can be reduced by the migration of transition metal cations from octahedral sites to tetrahedral sites during heating. Such site‐preferred migration is determined by the electronic structure of cations. Taking advantage of the unique electronic structure of the environmental friendly Fe, this is selected as substitution element in a high energy density material LiNi_0.5Mn_1.5O₄ to improve the thermal stability. The optimized LiNi_0.33Mn_1.33Fe_0.33O₄ material shows significantly improved thermal stability compared with the unsubstituted one, demonstrated by no observed oxygen release at temperatures as high as 500°C. Due to the electrochemical contribution of Fe, the high energy density feature of LiNi_0.5Mn_1.5O₄ is well preserved.     

Amadorins: novel post-Amadori inhibitors of advanced glycation reactions

The present review focuses on the background and progress that led to discovery of specific inhibition of post-Amadori formation of advanced glycation end products, or AGEs. The "classic" or Hodge pathway begins with glucose condensation with amino groups to form a Schiff base aldimine adduct that undergoes rearrangement to a ketoamine Amadori product. This pathway is considered an important route to AGE formation that has been implicated in glucose-mediated damage in vivo (3-5). We recently described a facile procedure for isolation of proteins rich in Amadori adducts but free of AGEs, thus permitting study of pathways of conversion of Amadori compounds to AGEs. This in turn led to a unique and rapid post-Amadori screening assay for putative "Amadorins," which we define here as inhibitors of the conversion of Amadori intermediates to AGEs in the absence of excess free or reversibly bound (Schiff base) sugar. Our screening assay then led to the identification of pyridoxamine (Pyridorin) as the first member of this class of Amadorin compounds. Rather unexpectedly, the assay also led to the clear demonstration that the well-known AGE inhibitor aminoguanidine, currently in Phase 3 clinical trials for treatment of diabetic nephropathy, has negligible Amadorin activity. In view of the importance of Amadori compounds as intermediates in AGE formation in vivo, the therapeutic potential of Pyridorin is currently being investigated and is now showing highly promising results in different animal models.     

Reflections on Edsall's carbonic anhydrase: paradoxes of an ultra fast enzyme

John Edsall's investigations of human erythrocyte carbonic anhydrase, a zinc metalloenzyme that powerfully catalyzes the reversible hydration of carbon dioxide, highlighted a conundrum regarding the correct hydration product. The measured kinetic parameters could not be reconciled with the choice of carbonic acid, since its bimolecular recombination rate with enzyme would exceed the diffusion limit. The alternate choice of bicarbonate obviated the recombination rate problem but required that the active site deprotonation exceed the diffusion-limited maximum rate by an even greater extent. This paradox was resolved in favor of bicarbonate when the unsuspected role of buffer species indirectly deprotonating the enzyme was finally proposed, spurring numerous investigations to verify the hypothesis. Edsall's laboratory also reported the accidental discovery of the first competitive inhibitor, imidazole. This opened new avenues to understanding the binding of the CO₂ substrate and stimulated many investigations on this inhibitor. Paramagnetic NMR and crystallographic studies demonstrated that the only other known competitive inhibitor, phenol, apparently shared this unusual binding site. Despite enormous progress since Edsall's retirement, particularly the use of site-directed mutagenesis approaches, the precise interactions of carbon dioxide and bicarbonate with specific active site moieties remain as elusive today as when Edsall first considered these questions.     

Modification of proteins in vitro by physiological levels of glucose: pyridoxamine inhibits conversion of Amadori intermediate to advanced glycation end-products through binding of redox metal ions

Hyperglycemic conditions of diabetes accelerate protein modifications by glucose leading to the accumulation of advanced glycation end-products (AGEs). We have investigated the conversion of protein-Amadori intermediate to protein-AGE and the mechanism of its inhibition by pyridoxamine (PM), a potent AGE inhibitor that has been shown to prevent diabetic complications in animal models. During incubation of proteins with physiological diabetic concentrations of glucose, PM prevented the degradation of the protein glycation intermediate identified as fructosyllysine (Amadori) by 13C NMR using [2-13C]-enriched glucose. Subsequent removal of glucose and PM led to conversion of protein-Amadori to AGE Nepsilon-carboxymethyllysine (CML). We utilized this inhibition of post-Amadori reactions by PM to isolate protein-Amadori intermediate and to study the inhibitory effect of PM on its degradation to protein-CML. We first tested the hypothesis that PM blocks Amadori-to-CML conversion by interfering with the catalytic role of redox metal ions that are required for this glycoxidative reaction. Support for this hypothesis was obtained by examining structural analogs of PM in which its known bidentate metal ion binding sites were modified and by determining the effect of endogenous metal ions on PM inhibition. We also tested the alternative hypothesis that the inhibitory mechanism involves formation of covalent adducts between PM and protein-Amadori. However, our 13C NMR studies demonstrated that PM does not react with the Amadori. Because the mechanism of interference with redox metal catalysis is operative under the conditions closely mimicking the diabetic state, it may contribute significantly to PM efficacy in preventing diabetic complications in vivo. Inhibition of protein-Amadori degradation by PM also provides a simple procedure for the isolation of protein-Amadori intermediate, prepared at physiological levels of glucose for relevancy, to study both the biological effects and the chemistry of post-Amadori pathways of AGE formation.     

IL-12 p40 homodimer-dependent macrophage chemotaxis and respiratory viral inflammation are mediated through IL-12 receptor beta 1

Leukocyte recruitment to the airway lumen is a central feature of inflammatory conditions such as asthma and respiratory viral infection. Characterization of mediators that regulate leukocyte recruitment in these conditions revealed increased IL-12 p40 homodimer (p80) levels were associated with enhanced airway macrophage accumulation. To examine this association, we used in vivo and in vitro assays to demonstrate p80, but not IL-12 or p40, provided a macrophage chemoattractant signal. Macrophages from genetically deficient mice indicated p80-dependent chemotaxis was independent of IL-12 and required IL-12Rbeta1 (Rbeta1) expression. Furthermore, analysis of murine cell lines and primary culture macrophages revealed Rbeta1 expression, with an intact cytoplasmic tail, was necessary and sufficient to mediate p80-dependent chemotaxis. To examine the role for Rbeta1 in mediating macrophage accumulation in vivo, we contrasted Sendai virus-driven airway inflammation in wild-type and Rbeta1-deficient mice. Despite similar viral burden and production of the macrophage chemoattractant p80, the Rbeta1-deficient mice displayed a selective decrease in airway macrophage accumulation and resistance to viral-dependent mortality. Thus, Rbeta1 mediates p80-dependent macrophage chemotaxis and inhibition of the p80-Rbeta1 interaction may provide a novel anti-inflammatory strategy to manipulate the inflammation associated with asthma and respiratory viral infection.