Genetic Analysis of Glutamate Transport and Glutamate Decarboxylase in Escherichia coli

The location of the Escherichia coli K-12 genes determining or regulating glutamate transport, and the location of the gene determining glutamate decarboxylase synthesis, were established by conjugation. The ability to grow on glutamate as the sole source of carbon and energy was used to select for glutamate transport recombinants. Two genes determining the ability to grow on glutamate as the sole source of carbon and energy were mapped. One (gltC) is located near mtl (mannitol), and the other (gltH) appears to be located between the gal (galactose) and trp (tryptophan) loci. The glutamate decarboxylase gene (gad) is strongly linked to gltC. The gltC(+) recombinants grow on glutamate much faster and accumulate this amino acid to a greater extent than do the gltH(+) recombinants. The gltH(+) gene functioned only in one female strain (P678), whereas the gltC gene functioned in all the female strains tested (P678, C600, W1).     

THE EFFECT OF CULTURE CONDITIONS ON THE HYDROCARBON CONTENT OF CHLORELLA VULGARIS12

Cultures of Chlorella vulgaris were grown aulo-trophically under fluorescent light and heterotrophically on glucose and inorganic salts. Hydrocarbons were extracted and analyzed by gas-liquid chromatography, molecular sieve separations, and silicic acid-AgNO₃ chromatography. Chlorella vulgaris grown under both culture conditions contained a series of saturated n-paraffins ranging from 17 to 36 carbon atoms in length. This is in contrast to reports in the early literature which indicated that the hydrocarbon fraction of algae was composed of only 1 or 2 specific hydrocarbons. Only under heterotrophic conditions, however, did C. vulgaris produce 1-penta-cosene and 1-heptacosene as the primary components of the hydrocarbon mixture. Other Chlorella species were examined, but only C. vulgaris produced significant quantities of these compounds.     

Increase in nuclear aluminum concentration during hepatic regeneration: study by analytical ionic microscopy

20 hrs. after partial hepatectomy, a significant increase in the aluminum concentration of liver cell nuclei has been measured by analytical ion microscopy. These results indicate a possible role of aluminium in an in vivo induced proliferative response.     

Release of iron from ferritin by semiquinone, anthracycline, bipyridyl, and nitroaromatic radicals

The cytotoxicity of many xenobiotics is related to their ability to undergo redox reactions and iron dependent free radical reactions. We have measured the ability of a number of redox active compounds to release iron from the cellular iron storage protein, ferritin. Compounds were reduced to their corresponding radicals with xanthine oxidase/hypoxanthine under N₂ and the release of Fe²⁺ was monitored by complexation with ferrozine. Ferritin iron was released by a number of bipyridyl radicals including those derived from diquat and paraquat, the anthracycline radicals of adriamycin, daunorubicin and epirubicin, the semiquinones of anthraquinone-2-sulphonate, 1,5 and 2,6-dihydroxyanthraquinone, 1-hydroxyanthraquinone, purpurin, and plumbagin, and the nitroaromatic radicals of nitrofurantoin and metronidazole. In each case, iron release was more efficient than with an equivalent flux of superoxide. Introduction of air decreased the rate of iron release, presumably because the organic radicals reacted with O₂ to form superoxide. In air, iron release was inhibited by superoxide dismutase. Semiquinones of menadione, benzoquinone, duroquinone, anthraquinone 1,5 and 2,6-disulphonate, 1,4 naphthoquinone-2-sulphonate and naphthoquinone, when formed under N₂, were unable to release ferrin iron. In air, these systems gave low rates of superoxide dismutase-inhibitible iron release. Of the compounds investigated, those with a single electron reduction potential less than that of ferritin were able to release ferritin iron.     

Self-binding antibodies (autobodies) form specific complexes in solution

In this report we have shown that members of the murine self-binding antibody family, S107, form soluble complexes and precipitate under conditions in which non-self-binding antibodies remain in solution. Two approaches were used to demonstrate the self-association of autobodies: size-exclusion column chromatography and polyethylene glycol (PEG)-mediated precipitation assay. The anti-phosphorylcholine antibody T15 and two somatic variants, U4, which binds DNA, and U10, which has no identified specificity, produced larger precipitates in 10% PEG than other non-self-binding antibodies. The selectivity of PEG-mediated precipitation of self-binding antibodies is demonstrated by reduction of precipitation with specific haptens known to inhibit self-binding in solid-phase assays. Phosphorylcholine and nucleotides reduced precipitation of T15 and U4, respectively, but not U10. To rule out Fc-Fc mediated self-association in solution, we have also demonstrated self-complexing of F(ab')2 fragments of T15 using PEG. The self-binding locus was further dissected using peptides derived from V regions. A 24-residue peptide derived from the second hypervariable region of the VH of S107 specifically enhanced precipitation of T15, U4, and U10, but not other antibodies. These results provide evidence of a dormant potential of self-binding antibodies to precipitate under conditions that reduce the solubility of proteins. The implication of this potential is discussed with respect to pathological complex formation.