Fluorescent excitation transfer immunoassay. A general method for determination of antigens.

A general immunochemical method for the assay of haptens and proteins has been devised and applied to morphine, a morphine-albumin conjugate, and human immunoglobulin G. A fluorescein-labeled antigen and a quencher-labeled antibody are employed. By use of fluorescein and rhodamine as the fluorescer and quencher, respectively, dipole-dipole-coupled excitation energy transfer can occur within the antigen-antibody complex. The resulting quenching of fluorescence can be inhibited by competitive binding with unlabeled antigen, Alternatively, separate antibody samples can be labeled with fluorescein and rhodamine, respectively. Unlabeled antigen causes aggregation of the separately labeled components with resultant quenching. Using the latter method, experiments suggest that up to about 20 anti-morphine antibody binding sites will associate with morphine-albumin conjugates. When an excess of the conjugate is present the antibodies appear to assemble in clumps on the protein surface. Mathematical analysis of the quenching of fluorescein-labeled morphine by rhodamine-labeled anti-morphine gives an approximate fit to the quenching data, but the calculations are very dependent on the assumptions used.

Mechanism by which antibodies inhibit hapten-malate dehydrogenase conjugates. An enzyme immunoassay for morphine.

Antimorphine antibodies inhibit the activity of morphine conjugates of mitochondrial malate dehydrogenase. Conjugation of malate dehydrogenase through tyrosine and amino groups resulted in only moderate losses of enzyme activity. On conjugation through disulfide bonds the enzyme activity first increased but dropped sharply with increasing substitution. Only the former conjugates were inhibited by excess antibodies. The degree of inhibition (up to 86%) was directly related to the number of morphine residues bonded directly to amino groups. The maximum number of antibody binding sites that bind to enzyme was nearly equal to the number of haptens provided there were 16 or less haptens/enzyme. However up to 26 haptens/enzyme became completely bound by antibody on long incubation. Inhibition of enzyme activity was detectably reduced by 2 times 10 minus 9 M morphine or 2 times 10 minus 10 M codeine, thus providing a sensitive assay for these drugs. The data suggest that enzyme inhibition occurs by conformational freezing of the enzyme when antibody binds to a morphine residue attached to one specific amino group.

Polyamine metabolism in potassium-deficient bacteria.

The metabolism of polyamines was studied in K(+)-dependent strains of Escherichia coli. When these stringent organisms were in a medium containing Na(+) instead of K(+), protein synthesis was arrested, but synthesis of ribonucleic acid continued as it would in a relaxed organism. The Na(+) medium inhibited synthesis of spermidine and S-adenosylmethionine. However, the synthesis of putrescine was accelerated at least five- to eightfold. Exogenous ornithine doubled even this rate of putrescine synthesis but did not increase the low level of putrescine synthesis in the K(+) medium. In K(+) or Na(+) media, with or without 0.3 mm arginine, putrescine was derived almost entirely from ornithine via ornithine decarboxylase. Addition of spermidine (5 mm) to a Na(+) culture markedly inhibited putrescine synthesis. The ornithine decarboxylase of an extract of a K(-)-dependent strain prepared at low ionic strength was separated from ribosomes, deoxyribonucleic acid, and associated polyamines by centrifugation, and from many ions by ultrafiltration and fractionation on Sephadex G-100. Addition of Na(+) and K(+) salts to 200 mm was markedly inhibitory. The combined reductions both in synthesis of the inhibitor spermidine and in intracellular ionic strength may explain the in vivo activation of this enzyme.

Synthetic capabilities of plasmolyzed cells and spheroplasts of Escherichia coli.

Effects of plasmolysis and spheroplast formation on deoxyribonucleic acid (DNA), ribonucleic acid (RNA), protein, and phospholipid synthesis by Escherichia coli strain THU were studied. RNA and protein synthesis were severely diminished. DNA and phospholipid synthesis were inhibited, but less so; they could be partly restored. DNA synthesis could be restored by replacing thymine in the medium with thymidine, and phospholipid synthesis, by adding back small quantities of soluble cell extract. Plasmolysis effected marked reductions in rates of growth and macro-molecule synthesis, and temporarily reduced culture viability. Plasmolysis also caused an anomalous stimulation of phospholipid synthesis. Spheroplasts and plasmolyzed cells synthesized small amounts of ribosomal RNA that sedimented normally. However, this ribosomal RNA was very inefficiently packaged to ribosome subunits. Spheroplasts were unable to carry out induced synthesis of beta-galactosidase, and plasmolyzed cells were delayed in this function. Radioautographs examined in an electron microscope showed that DNA synthesis in plasmolyzed cells and spheroplasts was performed by a substantial fraction of the culture populations. That DNA and membrane were associated in the spheroplasts used in this study was suggested by formation of M-bands containing membrane and most of the cell's DNA. The results are discussed in terms of alterations of membrane structure and conformation attending plasmolysis and spheroplasting.