Effect of lithium on granulopoiesis in culture.

Lithium carbonate therapy is associated with polymorphonuclear leukocytosis. In vitro studies have shown that lithium ions stimulate formation of granulocytic colonies. In a study undertaken to determine how lithium acts, colony-forming cells uncontaminated by monocytes (which elaborate colony-stimulating factor [CSF] in vitro) were obtained by means of a two-step cell separation procedure. The effects of lithium on colony formation were then studied in (a) cultures stimulated by humoral CSF, (b) cultures in which monocytes were relied upon to synthesize CSF de novo and (c) unstimulated cultures. Lithium enhanced the action of CSF but did not stimulate colony formation in the absence of CSF. In monocyte-stimulated cultures, colony formation increased with lithium concentrations up to 1 mmol/L but this increase paralleled that in CSF-stimulated cultures and therefore was not due to increased CSF production by monocytes. At higher concentrations of lithium, colony formation decreased in the monocyte-stimulated cultures but increased in the CSF-stimulated cultures. A lithium concentration of 4 mmol/L gave the greatest enhancing effect on colony formation in CSF-stimulated cultures and a concentration greater than 1 mmol/L inhibited de novo synthesis of CSF by monocytes.     

Reaction of T lymphocytes with anti-T3 induces translocation of C-kinase activity to the membrane and specific substrate phosphorylation

Reaction of the T cell membrane with monoclonal antibodies to T3 can initiate cellular activation, and this is associated with increased intracellular Ca2+ and inositol-trisphosphate (IP3) release. We therefore studied the possible involvement of Ca2+/phospholipid-dependent kinase (C-kinase) in these phenomena. Quantitative assays of exogenous substrate phosphorylation in unstimulated cells showed Ca2+/phospholipid-dependent kinase activity in the cytosol, but no comparable activity in the particulate fractions corresponding to membrane and cytoskeleton material. At concentrations of soluble anti-T3 that partially activate T cells in the absence of macrophages, there was a 50 to 60% decrease in C-kinase activity in the cytosol, with a comparable increase in activity in the membrane fraction. A similar transfer of activity was also induced with the known C-kinase activator, 12-O-tetradecanoyl-phorbol-13-acetate, although redistribution was more rapid in onset, more complete, and more sustained. Redistribution of enzyme activity was additionally confirmed by qualitative assays of endogenous substrate phosphorylation. Labeling of intact cells followed by immunoprecipitation analysis with anti-T3 indicated signal-dependent phosphorylation of two components of the T3 complex and an unidentified 94,000 substrate that was resistant to reduction and alkylation. These findings are consistent with an important role for C-kinase in transduction of membrane events by the T3-Ti complex.     

Reduction of the C2 and C4 vinyl groups of Sn-protoporphyrin to form Sn-mesoporphyrin markedly enhances the ability of the metalloporphyrin to inhibit in vivo heme catabolism

Sn (tin)-mesoporphyrin (Sn-protoporphyrin in which the vinyl groups at C2 and C4 have been reduced to ethyl groups) when incubated with rat splenic microsomal heme oxygenase proved to be a potent competitive inhibitor of enzyme activity in vitro, with a Ki of 0.014 microM. Sn-mesoporphyrin (1 mumol/kg body wt) also inhibited hepatic, renal, and splenic heme oxygenase activity in vivo in adult animals for extended periods of time. Sn-mesoporphyrin (1 mumol/kg body wt) prevented the transient increase in serum bilirubin 24 h after birth in the rat neonate and substantially reduced the levels of serum bilirubin in ALA (delta-aminolevulinic acid) induced hyperbilirubinemia in the 7-day-old suckling neonate. Tissue heme oxygenase activity was decreased in both animal models of hyperbilirubinemia. Sn-mesoporphyrin administration led to a prolonged increase in the heme saturation of hepatic tryptophan pyrrolase indicating an increase in the "heme pool" related to tryptophan pyrrolase and the compound also suppressed chemically induced hepatic porphyria. The administration of Sn-mesoporphyrin to bile duct-cannulated rats was followed by a prompt and sustained decrease in bilirubin output in bile. In addition the excretion of heme in bile was enhanced in these animals. These studies indicate that Sn-mesoporphyrin, like Sn-protoporphyrin, decreases serum bilirubin by inhibiting the production of bilirubin in vivo and its mode of action is through a sustained competitive inhibition of heme oxygenase. However, when a direct comparison of Sn-protoporphyrin and Sn-mesoporphyrin was made, these studies clearly established that the reduction of the C2 and C4 vinyl groups of the porphyrin macrocycle to ethyl groups increases the effectiveness of the Sn-mesoporphyrin derivative 10-fold or more as compared with Sn-protoporphyrin in inhibiting heme catabolism in the animal model systems examined. Thus alterations in the side chain substituents as well as of the central metal atom can influence in a significant manner the potency of the resultant synthetic heme analog as an agent capable of inhibiting heme degradation in vivo.     

Isolation and characterization of monoclonal antibodies directed against plant plasma membrane and cell wall epitopes: identification of a monoclonal antibody that recognizes extensin and analysis of the process of epitope biosynthesis in plant tissues and cell cultures

Membranes from tobacco cell suspension cultures were used as antigens for the preparation of monoclonal antibodies. Use of solid phase and indirect immunofluorescence assays led to the identification of hybridomas producing antibodies directed against cell surface epitopes. One of these monoclonal antibodies (11.D2) was found to recognize a molecular species which on two-dimensional analysis (using nonequilibrium pH-gradient electrophoresis and SDS-PAGE) was found to have a high and polydisperse molecular mass and a very basic isoelectric point. This component was conspicuously labeled by [3H]proline in vivo. The monoclonal antibody cross-reacted with authentic tomato extensin, but not with potato lectin nor larch arabinogalactan. Use of the monoclonal antibody as an immunoaffinity reagent allowed the purification of a tobacco glycoprotein which was identical in amino acid composition to extensin. Finally, immunocytological analyses revealed tissue-specific patterns of labeling by the monoclonal antibody that were identical to those observed with a polyclonal antibody raised against purified extensin. We have concluded that monoclonal antibody 11.D2 recognizes an epitope that is carried exclusively by extensin. Analysis of cellular homogenates through differential and isopycnic gradient centrifugation revealed that biosynthesis of the extensin epitope was found on or within the membranes of the endoplasmic reticulum, Golgi region and plasma membrane. This result is consistent with the progressive glycosylation of the newly-synthesized extensin polypeptide during its passage through a typical eukaryotic endomembrane pathway of secretion. The 11.D2 epitope was not found in protoplasts freshly isolated from leaf tissues. However, on incubation of these protoplasts in appropriate culture media, biosynthesis of the epitope was initiated. This process was not impeded by the presence of chemicals that are reported to be inhibitors of cell wall production or of proline hydroxylation.     

Polymyxin B causes coordinate inhibition of phorbol ester-induced C-kinase activity and proliferation of B lymphocytes

Lymphocytes were found to be rich in phospholipid/Ca2+-dependent (C-kinase) activity. Addition of polymyxin B (PMB) to in vitro assays of endogenous and exogenous phosphorylation resulted in profound inhibition of C-kinase activity. The phorbol ester 12-o-tetradecanoyl phorbol-13-acetate (TPA) directly activated C-kinase, leading to increased phosphorylation of the same substrates. TPA also stimulated proliferation of B cells as assessed by 3H-thymidine uptake, and PMB strongly inhibited this effect. This coordinate inhibition of TPA-induced phosphorylation and mitogenesis indicates that PMB is a potentially useful inhibitor of C-kinase activity, and that this enzyme may play an important role in mediating B cell responses.     

Heme binding to murine erythroleukemia cells. Evidence for a heme receptor

Friend virus transformed murine erythroleukemia (MEL) cells are known to take up heme from the surrounding medium and to incorporate it into newly synthesized hemoglobin (Granick, J. L., and Sassa, S. (1978) J. Biol. Chem. 253, 5402-5406), but the mechanism of its uptake is unknown. We hypothesized the existence of a specific receptor for heme in the plasma membrane. Using [55Fe]heme, we examined the characteristics of its interaction with MEL cells at 4 degrees C. [55Fe]heme binding reached equilibrium within 4 h, was 80% dissociable by 16 h, and was independent of pH over the range 7.0-8.2. Specific heme binding was linear with cell number, and competitive binding studies with various heme analogues, such as free protoporphyrin IX, metal-substituted protoporphyrin IX, Fe-mesoporphyrin IX, and Fe-deuteroporphyrin IX, revealed significant stereospecificity for Fe-protoporphyrin IX. The dissociation constant of the interaction was 0.03 nM-1 with no evidence of cooperativity or multiple classes of sites. The average number of sites/cell was approximately 10,300. Reduction of binding following preincubation with trypsin, in conjunction with the above data, suggests that this cell type may display a receptor for heme which is comprised, as least in part, of protein.     

The regulation of exogenous NAD(P)H oxidation in spinach (Spinacia oleracea) leaf mitochondria by pH and cations.

Essentially chlorophyll-free mitochondria were isolated from green leaves of spinach (Spinacia oleracea L. cv. Viking II). Uncoupled oxidation of exogenous NADPH (1 mM) to oxygen had an optimum at pH 6.0, and activity was relatively low at pH 7.0, even in the presence of 1 mM-CaCl2. There was a proportional increase in the apparent Km for NADPH with decreasing H+ concentrations, suggesting that NADPH protonated on the 2'-phosphate group was the true substrate. Exogenous NADH was oxidized by oxygen with an optimum at pH 6.9. Under low-cation conditions, EGTA or EDTA (both 1 mM) had no effect on the Vmax. of NADH oxidation, although the removal of bivalent cations from the membrane surface by the chelators could be observed by use of 9-aminoacridine fluorescence. In contrast, under high-cation conditions, chelators lowered the Vmax. by about 50%, probably due to a better approach of the negatively charged chelators to the negative membrane surface than under low-cation conditions. In a low-cation medium, the Vmax. of NADH oxidation was increased by about 50% by the addition of cations. This was caused by a lowering of the size of the negative surface potential through charge screening. In contrast with other cations, La3+ inhibited NADH oxidation, possibly through binding to lipids essential for NADH oxidation. The apparent Km for NADH varied 6-fold in response to changes in the size of the surface potential, suggesting that the approach of the negatively charged NADH to the active site is hampered by the negative surface potential. The results demonstrate that the spinach leaf cell can regulate the mitochondrial NAD(P)H oxidation through several mechanisms: the pH; the cation concentration in general; and the concentration of Ca2+ in particular. The results also emphasize the importance of electrostatic considerations when investigating the kinetic behaviour of membrane-bound enzymes.