Role of protein synthesis in decay and accumulation of mRNA during spore germination in the cellular slime mold Dictyostelium discoideum.

Spore germination in Dictyostelium discoideum is a particularly suitable model for studying the regulation of gene expression, since developmentally regulated changes in both protein and mRNA synthesis occur during the transition from dormant spore to amoeba. The previous isolation of three cDNA clones specific for mRNA developmentally regulated during spore germination allowed for the quantitation of the specific mRNAs during this process. The three mRNAs specific to clones pLK109, pLK229, and pRK270 have half-lives much shorter (minutes) than those of constitutive mRNAs (hours). Using spore germination as a model, we studied the roles of ribosome-mRNA interactions and protein synthesis in mRNA degradation by using antibiotics that inhibit specific reactions in protein biosynthesis. Cycloheximide inhibits the elongation step of protein synthesis. Polysomes accumulate in inhibited cells because ribosomes do not terminate normally and new ribosomes enter the polysome, eventually saturating the mRNA. Pactamycin inhibits initiation, and consequently polysomes break down in the presence of this drug. Under this condition, the mRNA is essentially free of ribosomes. pLK109, pLK229, and pRK270 mRNAs were stabilized in the presence of cycloheximide, but pactamycin had no effect on their normal decay. Since it seems likely that stability of mRNA reflects the availability of sites for inactivation by nucleases, it follows that in the presence of cycloheximide, these sites are protected, presumably by occupancy by ribosomes. No ribosomes are bound to mRNA in the presence of pactamycin, and therefore mRNA degrades at about the normal rate. The data further indicate that a labile protein is probably not involved in mRNA decay or stabilization, since protein synthesis is inhibited equally by both antibiotics. We conclude that it may be important to use more than one type of protein synthesis inhibitor to evaluate whether protein synthesis is required for mRNA decay. The effect of protein synthesis inhibition on mRNA synthesis and accumulation was also studied. mRNA synthesis continues in the presence of inhibitors, albeit at a diminished rate relative to that of the uninhibited control.     

Chronic exposure to uranium leads to iron accumulation in rat kidney cells

After it is incorporated into the body, uranium accumulates in bone and kidney and is a nephrotoxin. Although acute or short-term uranium exposures are well documented, there is a lack of information about the effects of chronic exposure to low levels of uranium on both occupationally exposed people and the general public. The objective of this study was to identify the distribution and chemical form of uranium in kidneys of rats chronically exposed to uranium in drinking water (40 mg uranium liter(-1)). Rats were killed humanely 6, 9, 12 and 18 months after the beginning of exposure. Kidneys were dissected out and prepared for optical and electron microscope analysis and energy dispersive X-ray (XEDS) or electron energy loss spectrometry (EELS). Microscopic analysis showed that proximal tubule cells from contaminated rats had increased numbers of vesicles containing dense granular inclusions. These inclusions were composed of clusters of small granules and increased in number with the exposure duration. Using XEDS and EELS, these characteristic granules were identified as iron oxides. Uranium was found to be present as a trace element but was never associated with the iron granules. These results suggested that the mechanisms of iron homeostasis in kidney could be affected by chronic uranium exposure.     

Biosynthesis of ferritin in rat hepatoma cells and rat livers. II. Binding of iron by ferritin protein.

Ferritin and its protein subunits in rat hepatoma cell clone M-5123-C1 were biosynthetically labeled with [14C]leucine and 59Fe. Radioimmunoassays of ferritin/apoferritin and of protein subunits in the free polyribosome, membrane-bound polyribosome, smooth membrane, and cytosol fractions were done with ferritin-specific and subunit-specific rabbit IgG antibodies at various time intervals after pulsing. Much more 59Fe was bound by ferritin/apoferritin than by subunits in all of the cell fractions. Binding of iron to subunits may have been a random process. When hepatoma cells were simultaneously pulse-labeled with 59Fe and [14C]leucine, uptake of much of the 59Fe by ferritin occurred relatively early, in comparison to incorporation of [14C]leucine, in all of the cell fractions examined. Thus, 59Fe was readily incorporated into pre-existing ferritin. We conclude that most, if not nearly all, of the iron is incorporated after assembly of protein subunits.     

Decoupling ferritin synthesis from free cytosolic iron results in ferritin secretion

Ferritin is a multisubunit protein that is responsible for storing and detoxifying cytosolic iron. Ferritin can be found in serum but is relatively iron poor. Serum ferritin occurs in iron overload disorders, in inflammation, and in the genetic disorder hyperferritinemia with cataracts. We show that ferritin secretion results when cellular ferritin synthesis occurs in the relative absence of free cytosolic iron. In yeast and mammalian cells, newly synthesized ferritin monomers can be translocated into the endoplasmic reticulum and transits through the secretory apparatus. Ferritin chains can be translocated into the endoplasmic reticulum in an in?vitro translation and membrane insertion system. The insertion of ferritin monomers into the ER occurs under low-free-iron conditions, as iron will induce the assembly of ferritin. Secretion of ferritin chains provides a mechanism that limits ferritin nanocage assembly and ferritin-mediated iron sequestration in the absence of the translational inhibition of ferritin synthesis.     

Modification of ferritin during iron loading

Recombinant human ferritin loaded with iron via its own ferroxidase activity did not sediment through a sucrose-density gradient as a function of iron content. Analysis of the recombinant ferritin by native PAGE demonstrated an increase in altered migration pattern of the ferritins with increasing sedimentation, indicating an alteration of the overall charge of ferritin. Additionally, analysis of the ferritin by SDS-PAGE under nonreducing conditions demonstrated that the ferritin had formed large aggregates, which suggests disulfide bonds are involved in the aggregation. The hydroxyl radical was detected by electron spin resonance spectroscopy during iron loading into recombinant ferritin by its own ferroxidase activity. However, recombinant human ferritin loaded with iron in the presence of ceruloplasmin sedimented through a sucrose-density gradient similar to native ferritin. This ferritin was shown to sediment as a function of iron content. The addition of ceruloplasmin to the iron loading assay eliminated the detection of the DMPO-*OH adduct observed during loading using the ferroxidase activity of ferritin. The elimination of the DMPO-*OH adduct was determined to be due to the ability of ceruloplasmin to completely reduce oxygen to water during the oxidation of the ferrous iron. The implications of these data for the present models for iron uptake into ferritin are discussed.     

Soil-dependent variability of leaf iron accumulation in transgenic tobacco overexpressing ferritin

Ferritin overexpression in transgenic plants has been recently reported to increase leaf and seed iron content. We investigated the influence of various soil conditions on this increase in leaf iron content. One control transgenic tobacco and two transgenic tobaccos overexpressing ferritin in the plastids or in the cytoplasm, respectively, were grown on five different soils, two of them being amended with sewage sludge. Although a significant increase in leaf iron concentration was measured in transgenics overexpressing ferritin grown on three out of five soils, this increase was not a general rule. On some soils, leaf iron concentration of control plants was as high as in transgenics grown on other soils. In addition, an increased phosphorus concentration in the two sewage sludge amended soils correlated with a high leaf iron concentration in control plants, similar to the one measured in ferritin transformed plants. Indeed, growing plants in vitro with various increasing phosphate concentrations revealed a direct P involvement in iron loading of control plants, at a similar level as overexpressing ferritin plants. Also, with one of the soil tested, not only iron but also manganese, zinc and cadmium, and to a much lesser extent copper, nickel and lead were found more abundantly in ferritin transformed plants than in control plants. These data indicate that the iron fortification of leaves, based on ferritin overexpression, could be limited in its biotechnological application because of its high soil dependence.     

Inhibition of protein synthesis in cortical neurons during exposure to hydrogen peroxide

Transient cerebral ischemia, which is accompanied by a sustained release of glutamate and zinc, as well as H(2)O(2) formation during the reperfusion period, strongly depresses protein synthesis. We have previously demonstrated that the glutamate-induced increase in cytosolic Ca(2+) is likely responsible for blockade of the elongation step of protein synthesis, whereas Zn(2+) preferentially inhibits the initiation step. In this study, we provide evidence indicating that H(2)O(2) and thapsigargin mobilized a common intracellular Ca(2+) pool. H(2)O(2) treatment stimulated a slow increase in intracellular Ca(2+), and precluded the effect of thapsigargin on Ca(2+) mobilization. H(2)O(2) stimulated the phosphorylation of both eIF-2alpha and eEF-2, in a time- and dose-dependent manner, suggesting that both the blockade of the elongation and of the initiation step are responsible for the H(2)O(2)-induced inhibition of protein synthesis. However, kinetic data indicated that, at least during the first 15 min of H(2)O(2) treatment, the inhibition of protein synthesis resulted mainly from the phosphorylation of eEF-2. In conclusion, H(2)O(2) inhibits protein translation in cortical neurons by a process that involves the phosphorylation of both eIF-2alpha and eEF-2 and the relative contribution of these two events depends on the duration of H(2)O(2) treatment.     

Delta-crystallin mRNA in chick lens cells: mRNA accumulates during differential stimulation of delta-crystallin synthesis in cultured cells.

Increasing specialization for δ-crystallin synthesis is a prominent feature of the differentiation of chick lens epithelial cells into lens fiber cells and can be studied in cultured embryonic lens epithelia. Quantitation of δ-crystallin mRNA by molecular hybridizaton to a [³H]DNA complementary to δ-crystallin mRNA demonstrates that differentiation, both in ovo and in tissue culture, is associated with the accumulation of δ-crystallin mRNA. In the cultures, there is an overall stimulation of protein synthesis, including δ-crystallin mRNA during the first 5 hr in vitro. Between 5 and 24 hr in vitro there is a differential stimulation of δ-crystallin synthesis and an accumulation of δ-crystallin mRNA that can quantitatively account for this stimulation.     

Serum iron, serum ferritin and tissue ferritin during development in ducks

Serum ferritin and tissue ferritin from kidney, heart, small intestine, spleen and liver from ducks during development from 16 to 112 days of age were measured by radioimmunoassay using rabbit anti-duck liver ferritin antibodies and goat second antibody. Serum iron concentration and tissue ferritin iron content are given. Serum ferritin concentration, tissue ferritin and ferritin iron content increase gradually during development. The decrease in all these parameters at 8 weeks of age might be due to molting.     

Release of iron from ferritin by xanthine oxidase. Role of the superoxide radical.

Mobilization of iron from ferritin by xanthine oxidase was studied under aerobic and anaerobic conditions. Aerobic iron release amounted to approx. 3.7 nmol/ml in 10 min. This amount was decreased by approx. 30% under anaerobic conditions. Aerobic iron mobilization involved two mechanisms. About 70% was released by O2.- generated by xanthine oxidase. The rest was released by O2(.-)-independent mechanisms, which also accounted for the total iron release when O2 was absent. A possible transfer of reducing equivalents directly from xanthine oxidase to ferritin is discussed. The results imply that, in pathological conditions with increased formation of O2.-, iron may be released from ferritin. Furthermore, in hypoxic tissues xanthine oxidase can release iron from ferritin by an O2(.-)-independent process. Free iron is liable to catalyse the formation of the extremely reactive and damaging OH. radical.     

DNA synthesis and mRNA accumulation during germination of embryos of the orchidSpathoglottis plicata

Summary Germination of embryos of the orchid,Spathoglottis plicata Blume involves the formation of a protocorm in which DNA synthesis and cell divisions are confined to the proximal end whereas cells at the distal end undergo enlargement. Although³H-thymidine was incorporated into the distal cells of the embryo during the early period of germination, DNA synthesis was not followed by mitosis and cytokinesis. Poly(A)-RNA detected by in situ hybridization of sections to³H-poly-(U) was present uniformly in all cells of the embryo of the dry seed. However, coincident with the formation of the apical meristem, there was an increase in the density of auto-radiographic silver grains in the cells of the embryo, with a concentration of silver grains in the proximal part. The results indicate that regulatory events in the embryo prior to seed maturity determine the fate of its proximal and distal parts during germination.Dedicated to the memory of Professor John G. Torrey