Changes in nuclear protein pattern by glucocorticoid treatment of lymphoid cells.

Glucocorticoids initiate a cytolytic process in lymphoid cells. The ultimate response is preceded by several phenomena. It is generally accepted that these are mediated through messenger proteins. The induction of these proteins is considered the primary effect of glucocorticoids. However, as yet specific gene products have not been identified. In electrophoretic assays, we observed an increased concentration of 6 nuclear proteins within a few hours of exposure of lymphoid cells to glucocorticoids. These proteins displayed prominent DNase activity. However, further studies showed: (1) that the proteins concerned are histones, (2) that histones are more easily extracted after glucocorticoid-induced alterations of lymphoid cells, and (3) that basic proteins in general express nuclease activity under certain experimental conditions. This nuclease activity is, however, artifactual. Therefore, though the changes observed are certainly related to glucocorticoid-induced effects, these do not reflect the induction of specific proteins. The results of the study indicate that glucocorticoid-induced changes in the concentration of cellular proteins should be interpreted with caution.

Mitochondrial biogenesis during the activation of lymphocytes by mitogens: the immunosuppressive action of tetracyclines.

The role of mitochondrial biogenesis and function during mitogenic stimulation of rat thymocytes was investigated. The results show that mitochondrial biogenesis is required to provide the ATP for the energy-requiring processes occurring during blastogenesis. Impairment of mitochondrial biogenesis by inhibition of mitochondrial protein synthesis inhibits blast transformation. Since the tetracyclines impair mitochondrial protein synthesis, the results offer an explanation for the well-known immunosuppressive effects of these antibiotics.

Inhibition of mitochondrial protein synthesis influences the glucocorticoid sensitivity of lymphoid cells.

Inhibition of mitochondrial protein synthesis impairs the formation of the 13 polypeptides encoded on the mitochondrial genome. These polypeptides are part of enzyme complexes involved in oxidative phosphorylation. Prolonged inhibition of mitochondrial protein synthesis thus reduces the oxidative phosphorylation capacity which ultimately results in impairment of energy-requiring processes. Via a different mechanism glucocorticoid hormones also decrease the oxidative phosphorylation capacity of, e.g., lymphoid cells. The present study shows that inhibition of mitochondrial protein synthesis influences glucocorticoid-induced responses of lymphoid cells in two opposing manners. (a) It is enhanced after induction in cells with a reduced oxidative phosphorylation capacity resulting from preceding inhibition of mitochondrial protein synthesis. This can be explained by the synergistic effects of glucocorticoids and prolonged inhibition of mitochondrial protein synthesis on energy-producing processes. (b) It is counteracted when mitochondrial protein synthesis is impaired during induction of the response. The latter observation suggests that mitochondrial protein synthesis is involved in the generation of glucocorticoid-induced effects on lymphoid cells.

Mitochondrial biogenesis and mitochondrial activity during the progression of the cell cycle of human leukemic cells.

Mitochondrial (mt) biogenesis and mt function were investigated during the cell cycle of leukemic cells. The study shows that the activity of enzymes involved in oxidative phosphorylation increases in the early G1 phase. This increase in activity precedes that of other mt enzymes such as citrate synthase and adenylate kinase. Therefore, the synthesis of mt enzymes, needed for the reduplication of the mt mass in the course of the cell cycle, occurs in a sequential order. The enzymes of the system for oxidative phosphorylation are composed of several subunits. Some of these subunits are encoded on mtDNA and synthesized by mt-specific RNA and protein synthesis. This explains why inhibition of mt protein synthesis during the progression of the cell cycle of G1-enriched cells results in an increasing shortage of ATP. This lack of ATP results first in progression delay and, subsequently, in a cell cycle block in early G1. Furthermore, shortage of ATP impairs the increase in activity of at least one mt matrix enzyme. This study offers new information about a number of aspects of mt biogenesis and mt function during cell cycle progression and elucidates the cytostatic mechanism resulting from prolonged inhibition of mt protein synthesis.

Different effects of oxytetracycline and doxycycline on mitochondrial protein synthesis in rat liver after long-term treatment.

The tetracyclines inhibit specifically mitochondrial (mt) and bacterial protein synthesis when they are present in low concentrations (2-10 micrograms/ml). There is no difference between the various members of this group of antibiotics in this respect. In the present study, however, it is shown that the inhibitory effect of doxycycline on mt-protein synthesis in rat liver is partially lost after continuous treatment for more than 1 week, whereas oxytetracycline continues to inhibit mt-protein synthesis effectively after 1 week of treatment. To find an explanation for this difference between doxycycline and oxytetracycline, a detailed study was made of the distribution and the effects on mt-protein synthesis of both tetracyclines under various conditions in rat liver. The results of the studies lead to the hypothesis that doxycycline treatment induces the formation of a doxycycline complex, and thus to a reduced amount of free doxycycline. This may explain the loss of effective inhibition of mt-protein synthesis.

The effect of inhibition of mitochondrial protein synthesis on the proliferation and phenotypic properties of a rat leukemia in different stages of in-vivo tumor development.

It has been shown before that prolonged treatment with doxycycline (DC), an inhibitor of mitochondrial protein synthesis, leads to proliferation arrest of a leukemia in the rat and, moreover, to eradication of this tumor. It has also been demonstrated that the period of treatment required to achieve this is shorter when DC administration is started in later stages of tumor progression. Therefore, the leukemic cells may have properties with regard to DC sensitivity which change with time during tumor progression. In the present study this hypothesis was tested by studying the permeability for DC, the presence of cell-surface molecules, and the mitochondrial content of the leukemic cells in various stages of tumor development in control and in DC-treated rats. Changes in DC permeability or antigenic phenotype were not observed, but the content of mitochondria decreases during tumor progression. DC treatment leads to an additional reduction of the content of functional mitochondria which results in proliferation arrest. The higher mitochondrial content of the leukemic cells during the earlier stages of tumor development explains thus why a longer period of DC treatment is needed to achieve growth arrest when treatment is started in these stages.

Arrest of the proliferation of renal and prostate carcinomas of human origin by inhibition of mitochondrial protein synthesis.

The results described in this paper demonstrate that proliferation arrest by low concentrations of tetracyclines, which has previously been shown in experiments with animal tumor systems, can also be achieved in tumor systems of human origin. Tetracyclines specifically inhibit mitochondrial protein synthesis. Prolonged and continuous impairment of protein synthesis inside the mitochondria leads to reduction of the cellular concentration of the polypeptide products which are coded and synthesized within mitochondria. These products are part of the oxidative phosphorylative system of the cell. Long-term tetracycline treatment leads to a decrease of oxidative ATP-generating capacity as monitored by cytochrome c oxidase activity. This may cause severe energetic or metabolic disturbances which explain the proliferation arrest observed. Proliferation arrest, provided that mitochondrial protein synthesis is blocked effectively, is found in vitro as well as in vivo. It is shown that the effect of doxycycline is not limited to cytostasis; prolonged doxycycline treatment is clearly cytotoxic for the tumor cells.