Manganese Uptake and Efflux in Cultured Rat Astrocytes

Astrocytes play a central role in manganese (Mn) regulation in the CNS. Using primary astrocyte cultures from neonatal rat brains, these studies demonstrate a specific high-affinity transport system for Mn2+. Saturation kinetics are clearly indicated by both 1/v versus 1/s plots (Km = 0.30 +/- 0.03 microM; Vmax = 0.30 +/- 0.02 nmol/mg of protein/min) and plots of v versus [s]. Several divalent cations (Co2+, Zn2+, and Pb2+) failed to inhibit the initial rate of 54Mn2+ uptake. In contrast, extracellular Ca2+ at 10 microM decreased 54Mn2+ uptake. Exchange with extracellular Mn2+ was not obligatory for the efflux of 54Mn2+ into extracellular medium because efflux occurred into Mn(2+)-free extracellular medium, but efflux of 54Mn2+ was enhanced when astrocytes were equilibrated in the presence of unlabeled Mn2+. Efflux of 54Mn2+ was biphasic with both a rapid and a slow component. Efflux was most rapid during the first 10 min of incubation, with 27.5 +/- 2.2% of 54Mn2+ transported extracellularly, and 37.2 +/- 1.2% of preloaded 54Mn2+ was retained by the astrocytes at 120 min. These studies show, for the first time, that mammalian astrocytes can transport Mn via a specific transport system.     

Binding of manganese in human and rat plasma

Albumin, transferrin and 'transmanganin' have all been proposed as the major Mn-binding ligand in plasma. The present investigations were initiated in order to resolve these discrepancies. Compared to other metals tested (109 Cd2+, 65Zn2+, 59Fe3+), 54Mn2+ bound poorly to purified albumin. The addition of exogenous albumin to plasma did not result in an increased 54Mn radioactivity associated with this protein. Also, incubation of 65Zn-albumin in the presence of excess Mn2+ (1 mM) did not result in the displacement of Zn from albumin or Mn binding. In contrast to these results, 54Mn was bound to purified transferrin, not as readily as Fe3+, but better than Zn2+ or Cd2+. Saturation of transferrin with Fe3+ (1.6 micrograms Fe/mg) prevented the binding of 54Mn indicating that Mn probably binds to Fe-binding sites on the protein. Polyacrylamide gel electrophoresis further demonstrated the association of 54Mn with transferrin rather than with albumin in both human and rat plasma. The amount of 54Mn radioactivity recovered with transferrin increased as incubation time was increased, probably due to oxidation of Mn2+ to Mn3+. Mn binding to transferrin reached a maximum within 5 and 12 h of incubation. About 50% of 54Mn migrated with transferrin, whereas only 5% was associated with albumin. A significant portion (20-55%) of the 54Mn radioactivity migrated with electrophoretically slow plasma components whose identity was not determined. Possibilities include alpha 2-macroglobulin, heavy gamma-globulins and/or heavy lipoproteins.     

Saturable Transport of Manganese(II) Across the Rat Blood-Brain Barrier

Unanesthetized adult male rats were infused intravenously with solutions containing 54Mn (II) and one of six concentrations of stable Mn(II). The infusion was timed to produce a near constant [Mn] in plasma for up to 20 min. Plasma was collected serially and on termination of the experiment, samples of CSF, eight brain regions, and choroid plexus (CP) were obtained. Influx of Mn (JMn) was calculated from uptake of 54Mn into tissues and CSF at two different times. Plasma [Mn] was varied 1,000-fold (0.076-78 nmol/ml). Over this plasma concentration range, JMn increased 123 times into CP, 18-120 times into brain, and 706 times into CSF. CP and brain JMn values fit saturation kinetics with Km (nmol/ml) equal to 15 for CP and 0.7-2.1 for brain, and Vmax (10(-2) nmol.g-1.s-1) of 27 for CP and 0.025-0.054 for brain. Brain JMn except at cerebral cortex had a nonsaturable component. CSF JMn varied linearly with plasma [Mn]. These findings suggest that Mn transport into brain and CP is saturable, but transport into CSF is nonsaturable.     

Cadmium-resistant mutant of Bacillus subtilis 168 with reduced cadmium transport.

Cd2+ and Mn2+ accumulation was studied with wild-type Bacillus subtilis 168 and a Cd2+-resistant mutant. After 5 min of incubation in the presence of 0.1 microM 109Cd2+ or 54Mn2+, both strains accumulated comparable amounts of 54Mn2+, while the sensitive cells accumulated three times more 109Cd2+ than the Cd2+-resistant cells did. Both 54Mn2+ and 109Cd2+ uptake, which apparently occur by the same transport system, demonstrated cation specificity; 20 microM Mn2+ or Cd2+ (but not Zn2+) inhibited the uptake of 0.1 microM 109Cd2+ or 54Mn2+. 54Mn2+ and 109Cd2+ uptake was energy dependent and temperature sensitive, but 109Cd2+ uptake in the Cd2+-resistant strain was only partially inhibited by an uncoupler or by a decrease in temperature. 109Cd2+ uptake in the sensitive strain followed Michaelis-Menten kinetics with a Km of 1.8 microM Cd2+ and a Vmax of 1.5 mumol/min X g (dry weight); 109Cd2+ uptake in the Cd2+-resistant strain was not saturable. The apparent Km value for the saturable component of 109Cd2+ uptake by the Cd2+-resistant strain was very similar to that of the sensitive strain, but the Vmax was 25 times lower than the Vmax for the sensitive strain. The Km and Vmax for 54Mn2+ uptake by both strains were very similar. Cd2+ inhibition of 54Mn2+ uptake had an apparent Ki of 3.4 and 21.5 microM Cd2+ for the sensitive and Cd2+-resistant strains, respectively. Mn2+ had an apparent Ki of 1.2 microM Mn2+ for inhibition of 109Cd2+ uptake by the sensitive strain, but the Cd2+-resistant strain had no defined Ki value for inhibition of Cd2+ uptake by Mn2+.     

Acquisition of manganous ions by mutans group streptococci.

The cariogenic bacteria Streptococcus sobrinus and S. cricetus were shown to have an absolute requirement for manganous ion in order to bind glucans or to adhere to glass in the presence of sucrose. The bacteria possessed a reasonably high affinity transport system for 54Mn2+, yielding a Km of about 12 microM. The Vmax for uptake of 54Mn2+ in S. sobrinus was increased when the bacteria were grown in Mn-depleted medium, but the Km remained the same. There was no evidence for two Mn2+ uptake systems, commonly observed for many bacteria. Ions such as Ca2+, Co2+, Co3+, Cu2+, Fe2+, Fe3+, Hg2+, Mg2+, Ni2+, and Zn2+ did not inhibit the uptake of 54Mn2+ by the bacteria, although Cd2+ was a potent inhibitor. Fractionation experiments showed that manganese was distributed in protoplasts (67%) and in the cell wall (33%). Approximately 80% of the 54Mn2+ in S. sobrinus was rapidly exchangeable with nonradioactive Mn2+. Electron spin resonance experiments showed that all of the manganese was bound or restricted in mobility. Proton motive force-dissipating agents increased the acquisition of 54Mn2+ by the streptococci, probably because the wall became more negatively charged when the cell could no longer produce protons.     

Uptake and distribution of 65Zn and 54Mn in wheat grown at sufficient and deficient levels of Zn and Mn II. During grain development

We investigated the uptake and distribution of Zn and Mn inwheat during grain development. Plants were grown in a chelate-bufferednutrient solution with one of the following treatments: control,low Zn or low Mn. Plants were dual-labelled with ⁶⁵Zn and ⁵⁴Mnat 2 and 8 wk post-anthesis for 5 and 24 h, respectively. Afterlabelling, the plants were separated into individual componentsfor analysis. In the plants harvested at 8 wk after anthesis,spikelets were separated into individual structures and analysedfor radioactivity. Little or no root-supplied ⁵⁴Mn was distributed to the leavesof both the controls and low-Mn plants during the grain developmentstages studied here. More ⁵⁴Mn was distributed to the head at8 wk than at 2 wk post-anthesis. In contrast, root-supplied⁶⁵Zn was transported to the leaves at 2 and 8 wk post-anthesis.More⁶⁵Zn was distributed to the leaves of the low-Zn plants thanthe controls during grain development.More esZn was detectedin the head towards grain maturity. Relatively larger amountsof ⁵⁴Mn than ⁶⁵Zn were found in different parts of the florets.Labelled Mn was found in relatively large quantities in thepalea, lemma and in the glumes, even though most ⁵⁴Mn was foundin the grain. A large percentage of the grain MMn was in theouter pericarp. During grain development leaves may still require Zn but notMn, which may be due to the requirement of Zn in maintainingmembrane structure and function. Distribution of Zn and Mn withinthe spikelets suggests that Zn may enter the grain via the phloemwhile Mnmay enter the grain via the xylem. Key words: Zinc, manganese, nutrient transport, grain development, wheat, Triticum aestivum     

Effect of biliary ligation on manganese accumulation in rat brain

Neurologic and radiologic disorders have been reported to occur in miners inhaling manganese (Mn)-laden dust and in humans receiving long-term parenteral nutrition. These abnormalities have been attributed to Mn intoxication because of elevated serum Mn concentrations. Because the liver, by way of the bile, is the major route of Mn excretion, it is possible that anything that decreases biliary excretion could increase accumulation of Mn in the brain. The purpose of this study was to determine whether biliary ligation would increase Mn accumulation in the brain of rats that were exposed to deficient or adequate amounts of dietary manganese. The first experiment had a 2 x 3 factorial design, two levels of Mn (0 or 45 μg/g diet) and three surgical treatments (control, sham, or bile-ligation). Animals were sacrificed 10 d after being fed⁵⁴Mn. In experiment 2, animals that had a sham operation or bile-ligation were sacrificed at 8 time points after being injected intraportally with⁵⁴Mn complexed to albumin. The biliaryligated animals had a significantly (p < 0.001) smaller percentage of the⁵⁴Mn in their brains (when expressed as a percentage of whole animal⁵⁴Mn) than the sham-operated animals. Mn deficiency had a similar effect. However, we did observe an increased accumulation of the radioisotope in the brain over time. Therefore, in short-term studies, biliary-ligated rats do not appear to be a good model for Mn accumulation in the brains of people with cholestatic liver disease. The U.S. Department of Agriculture, Agriculture Research Service, Northern Plains Area, is an equal opportunity/affirmative action employer and all agency services are available without discrimination.     

L-histidinol dehydrogenase, a Zn2+-metalloenzyme

The enzymatic activity of L-histidinol dehydrogenase from Salmonella typhimurium was stimulated by the inclusion of 0.5 mM MnCl2 in the assay medium. At pH 9.2 the stimulation was correlated with binding of 1 g-atom of 54Mn2+/mol dimer, KD = 37 microM. ZnCl2, which prevented the MnCl2 stimulation, also bound to the enzyme, 1.2 g-atom/mol dimer, KD = 51 microM, and prevented Mn2+ binding. Enzyme activity was lost when histidinol dehydrogenase was incubated in 8 M urea. Reactivation was observed when urea-denatured enzyme was diluted into buffer containing 2-mercaptoethanol but required either MnCl2 or ZnCl2. Histidinol dehydrogenase was inactivated by the transition metal chelator 1,10-phenanthroline or by high levels of 2-mercaptoethanol. The nonchelating 1,7-phenanthroline was not an inactivator, and inactivation by either 1,10-phenanthroline or 2-mercaptoethanol was prevented by MnCl2. Enzyme inactivated by 1,10-phenanthroline could be reactivated by addition of MnCl2 or ZnCl2 in the presence of 2-mercaptoethanol. Reactivation was correlated with the binding of 1.5 g-atom 54Mn2+/mol dimer. Atomic absorption analysis of the native enzyme indicated the presence of 1.65 g-atom Zn/mol dimer, and no Mn was detected. The results demonstrate, therefore, that histidinol dehydrogenase contains two metal binding sites per enzyme dimer, which normally bind Zn2+, but which may bind Mn2+ while retaining enzyme function. Histidinol dehydrogenase is thus the third NAD-linked oxidoreductase in which Zn2+ fulfills an essential structural and/or catalytic role.     

The iron transporter ferroportin can also function as a manganese exporter

The present study examined the hypothesis that the iron exporter ferroportin (FPN1/SLC40A1) can also mediate cellular export of the essential trace element manganese, using Xenopus laevis oocytes expressing human FPN1. When compared to oocytes expressing only the divalent metal transporter-1 (DMT1/NRAMP2), (54)Mn accumulation was lower in oocytes also expressing FPN1. FPN1-expressing oocytes exported more (54)Mn than control oocytes (26.6±0.6% versus 7.1±0.5%, respectively, over 4h at pH 7.4 when preloaded with approximately 16μM (54)Mn); however, there was no difference in (54)Mn uptake between control and FPN1-expressing oocytes. FPN1-mediated Mn export was concentration dependent and could be partially cis-inhibited by 100μM Fe, Co, and Ni, but not by Rb. In addition, Mn export ability was significantly reduced when the extracellular pH was reduced from 7.4 to 5.5, and when Na(+) was substituted with K(+) in the incubation media. These results indicate that Mn is a substrate for FPN1, and that this export process is inhibited by a low extracellular pH and by incubation in a high K(+) medium, indicating the involvement of transmembrane ion gradients in FPN1-mediated transport.     

The liver cell plasma membrane Ca2+ inflow systems exhibit a broad specificity for divalent metal ions.

1. The inflow of Mn2+ across the plasma membranes of isolated hepatocytes was monitored by measuring the quenching of the fluorescence of intracellular quin2, by atomic absorption spectroscopy and by the uptake of 54Mn2+. The inflow of other divalent metal ions was measured using quin2. 2. Under ionic conditions which resembled those present in the cytoplasmic space, Mn2+, Zn2+, Co2+, Ni2+ and Cd2+ each quenched the fluorescence of a solution of Ca2(+)-quin2. 3. The addition of Mn2+, Zn2+, Co2+, Ni2+ or Cd2+ to cells loaded with quin2 caused a time-dependent decrease in the fluorescence of intracellular quin2. Plots of the rate of decrease in fluorescence as a function of the concentration of Mn2+ reached a plateau at 100 microM-Mn2+. 4. The rate of decrease in fluorescence induced by Mn2+ was stimulated by 20% in the presence of vasopressin. The effect of vasopressin was completely inhibited by 200 microM-verapamil. Adrenaline, angiotensin II and glucagon also stimulated the rate of decrease in the fluorescence of intracellular quin2 induced by Mn2+. 5. The rate of decrease in fluorescence induced by Zn2+, Co2+, Ni2+ or Cd2+ was stimulated by between 20 and 190% in the presence of vasopressin or angiotensin II. 6. The rates of uptake of Mn2+ measured by atomic absorption spectroscopy or by using 54Mn2+ were inhibited by about 20% by 1.3 mM-Ca2+o and stimulated by 30% by vasopressin. 7. Plots of Mn2+ uptake, measured by atomic absorption spectroscopy or with 54Mn2+, as a function of the extracellular concentration of Mn2+ were biphasic over the range 0.05-1.0 mM added Mn2+ and did not reach a plateau at 1.0 mM-Mn2+. 8. It is concluded that (i) hepatocytes possess both a basal and a receptor-activated divalent cation inflow system, each of which has a broad specificity for metal ions, and (ii) the receptor-activated divalent cation inflow system is the receptor-operated Ca2+ channel.     

Differential transport of Zn, Me and sucrose along the longitudinal axis of developing wheat grains

The hypothesis that Zn and Mn are transported within the grain in a similar manner to sucrose was investigated in the developing wheat grain. Detached ears were cultured in solution containing ⁶⁵Zn, ⁵⁴Mn and [¹⁴C]-sucrose for 10 to 120 min at 18–22 days post-anthesis. At different times the grain was cut transversely into 1-mm sections and the radioactivity in each section determined The embryo region was damaged in some grains to investigate the effect of reduced accumulation rate on the transport of ⁶⁵Za, ⁵⁴Mn and [¹⁴C]-sucrose to the embryo. The distribution of ⁶⁵Zn. ⁵⁴Mn and [¹⁴C]-sucrose between the endosperm cavity sap. endosperm, embryo and pericarp in grains labelled for 2.5 and 6 h at 18–22 days post-anthesis was also determined. [¹⁴C]-su-crose was initially high in the first, embryo-containing section of the grain but decreased progressively to the distal end of the grain. The amount of ⁶⁵Zn along the longitudinal axis of the grain was distributed evenly in each 1-mm section, whilst ⁵⁴Mn accumulated exponentially in the first proximal 1-mm section of the grain and was distributed evenly in the remaining sections. Damaging the embryo had no effect on ⁶⁵Zn and ⁵⁴Mn transport to the section containing the embryo. The pericarp contained almost all of the grain ⁶⁵Za and ⁵⁴Mn, with small amounts found in the embryo, endosperm and endosperm cavity sap. Increasing amounts of [¹⁴C]-sucrose were found in the endosperm as time progressed. The rate of accumulation of ⁶⁵Zn, ⁵⁴Mn and [¹⁴C]-sucrose was much higher in the embiyo than the endosperm: the difference between the embryo and endosperm was especially large for ⁶⁵Zn and ⁵⁴Mn. It is suggested that ⁶⁵Zn and ⁵⁴Mn are not transported within the grain in the same way as [¹⁴C]-sucrose. [¹⁴C]-sucrose moves laterally out of the vascular system of the crease into the endosperm cavity and is subsequently taken up and stored in the endosperm. In contrast, ⁶⁵Zn and ⁵⁴Mn appear to be retained within the vascular system of the crease and may be transported more slowly to grain parts such as the embryo and pericarp tissue.     

Manganese uptake and release by cultured human hepatocarcinoma (Hep-G2) cells

The liver is the primary organ involved in manganese (Mn) homeostasis. The human hepato-carcinoma cell line, Hep-G2, shows many liver specific functions. Consequently, Hep-G2 cells were investigated as a possible model of hepatic metabolism of Mn. Initial experiments showed that the concentration of Mn in the diet, or culture medium, similarly affected the retention of Mn by isolated rat hepatocytes and Hep-G2 cells. Manganese uptake by Hep-G2 cells suggested that uptake was followed by release from the cell. Uptake was saturable and half-maximal at 2.0 μmol Mn/L, and was inhibited by iodoacetate, vanadate, cold, and bepridil. The cations Fe²⁺, Cu²⁺, Ni²⁺, Cd²⁺, and Zn²⁺ decreased Mn uptake. Uptake was dependent on Calcium (Ca) concentration in a manner that resembled saturation kinetics. Cells that were pulsed with⁵⁴Mn and then placed into nonradioactive medium quickly released a large portion of their internalized Mn. Release of internalized Mn could be inhibited by low temperature, nocodozole, quinacrine and sodium azide. These data show that Hep-G2 cells are a potentially good model of hepatic Mn metabolism. Mn is taken up by a facilitated process that may be related to Ca uptake. Release apparently is an active, controlled process, that may involve microtubules and lysosomes. The U.S. Department of Agriculture, Agricultural Research Service, Northern Plains Area, is an equal opportunity/affirmative action employer and all agency services are available without discrimination.     

Chemical and physical differentiation of superoxide dismutases in anaerobes.

Superoxide dismutase activity in crude or partially purified cell extracts from several species and strains of obligate anaerobe Bacteroides was inhibited instantaneously by NaN3 and was inactivated rapidly upon incubation with H2O2. The extent of NaN3 inhibition varied from 41 to 93%, and the half-life of the enzymatic activity in 5 mM H2O2 ranged from 1.2 to 6.1 min, depending upon the organism tests. When grown in a defined medium containing 59Fe, Bacteroides fragilis (VPI 2393) incorporated radiolabel into a 40,000-molecular-weight NaN3- and H2O2-sensitive superoxide dismutase but did not incorporate 54Mn into that protein under similar growth conditions. The anaerobe Actinomyces naeslundii (VPI 9985) incorporated 54Mn but not 59Fe into a NaN3-insensitive and H2O2-resistant superoxide dismutase. The apparent molecular weight of the superoxide dismutase from this and several other Actinomyces spp. was estimated to be 110,000 to 140,000. Comparison of these data with studies of homogeneous metallosuperoxide dismutases suggests that the Bacteroides spp. studied contain a ferrisuperoxide dismutase, whereas Actinomyces spp. contain a managanisuperoxide dismutase.     

54Mn uptake by the ovaries and reproductive tract of cycling and anestrous ewes.

The uptake of 54Mn by the ovaries and reproductive tract of cycling and anestrous ewes has been investigated following intravenous injection of a single dose of 54MnCl2 and sacrifice of the ewes 6 h later. The uptake of 54Mn was greater in the Graafian follicle and the corpus luteum (CL) of the cycle than in the other components of the ovary. An increased uptake of radioactivity was recorded in the CL of the 11th day of the cycle when compared with that of the 4th day. The uptake of 54Mn was lower in the corpus albicans and follicles. A low uptake of radiomanganese was found also in the various tissues of the reproductive tract. These findings indicate that manganese may play a role in the normal functioning of ovarian activity in the ewe.     

Uptake and distribution of 65Zn and 54Mn in wheat grownat sufficient and deficient levels of Zn and Mn: I. During vegetative growth

The uptake and distribution of ⁶⁵Zn and ⁵⁴Mn by wheat (Triticumaestivum cv. Aroona) was investigated. Plantswere grown in achelate-buffered nutrient solution with either sufficient Znand Mn, low Zn or low Mn. A single representative seminal rootfrom 14-d-old and 42-d-old plants was dual-labelled with ⁶⁵Znand ⁵⁴Mn. The 14-d-old plants were harvested every 10 min from10–140 min of labelling, whilst the 42-d-old plants wereharvested after 2 h of labelling. At harvest, each plant wasseparated into leaves, main stem, unexposedroots, and tillers.In addition, the crown was separatedfrom the stem in the 14-d-oldplants In the control plants labelled at 14 d, ⁶⁵Zn was firstdetectedand accumulated in the crown of the roots after 40–60min. Labelled Zn was then detected in the stem, followed bythe leaves. The oldest and youngest leaves received less ⁶⁵Znthan the second and third oldest leaves. The plants grown underlow Zn conditions accumulated more ⁶⁵Zn in their older leavesand transferred ⁶³Zn to the unexposed roots. Distribution of⁵⁴Mn was similar in the controls to that of ⁶⁵Zn, except theolder leaves received no HMn, At the second harvest, a similardistribution pattern of ⁶⁵Zn and ⁵⁴Mn was observed with regardto leaf age. Large amounts of ⁶⁵Zn and ⁵⁴Mn were detected withinthe unexposed roots of all treatments. It is suggested thatthe distribution of root-supplied Zn and Mn may be determinedby micronutrient status and its relationship with leaf transpirationrates. Key words: Distribution, manganese, vegetative growth, wheat, zinc     

Ganglioside biosynthesis. Characterization of uridine diphosphate galactose: GM2 galactosyltransferase in golgi apparatus from rat liver.

An enzyme that transfers galactose from UDP-Gal to ganglioside GM2 (Tay-Sachs ganglioside) was concentrated 50 times in Golgi apparatus from rat liver relative to total homogenates. This enzyme required detergents or phospholipids as dispersing agents. Of the numerous detergents tested, sodium taurocholate and Triton CF-54 were most effective in stimulating the reaction. Cardiolipin alone was more effective than any of the detergents tested in stimulating enzyme activity. The pH optimum for the reaction varied with the nature of the dispersing agent. With sodium taurocholate, Triton CF-54 and cardiolipin, the pH optima were 6.2, 5.9, and 5.6, respectively. The enzyme had a nearly absolute requirement for Mn2+, with maximum activity being attained at a concentration of 15 mM Mn2+. Other divalent or trivalent cations were either less effective than Mn2+ or inhibited the transferase reaction. The Km values calculated for UDP-Gal and GM2 were 1.1 X 10(-4) M and 9.9 X 10(-5) M, respectively. The enzyme could not be dissociated from Golgi apparatus fractions by treatment with ultrasound, indicating that it is tightly associated with the membrane and not part of the luminal contents. The newly synthesized GM2, the product of the reaction, was incorporated into or became tightly associated with the membranes of the Golgi apparatus.     

L-threonine dehydrogenase from Escherichia coli K-12: thiol-dependent activation by Mn2+

Addition of 1 mM Mn2+ to all solutions in the final chromatographic step used to purify L-threonine dehydrogenase (L-threonine:NAD+ oxidoreductase, EC 1.1.1.103) from extracts of Escherichia coli K-12 routinely provides 30-40 mg of pure enzyme per 100 g wet weight of cells with specific activity = 20-30 units/mg. Enzyme dialyzed exhaustively against buffers containing Chelex-100 resin has a specific activity = 8 units/mg and contains 0.003 or 0.02 mol of Mn2+/mol of enzyme as determined by radiolabeling studies with 54Mn2+ or by atomic absorption spectroscopy, respectively. Dehydrogenase activity is completely abolished by low concentrations of either Hg2+ or Ag+; of a large spectrum of other metal ions tested, only Mn2+ and Cd2+ have an activating effect. Activation of threonine dehydrogenase by Mn2+ is thiol-dependent and is saturable with an activation Kd = 9.0 microM and a Vmax = 105 units/mg. Stoichiometry of Mn2+ binding was found to be 0.86 mol of Mn2+/mol of enzyme subunit with a dissociation constant (Kd) = 8.5 microM. Mn2+ appears to interact directly with threonine dehydrogenase; gel filtration studies with the dehydrogenase plus 54Mn2+ in the presence of either NAD+, NADH, L-threonine, or combinations thereof show that only Mn2+ coelutes with the enzyme whereas all other ligands elute in the salt front and the stoichiometry of the dehydrogenase-Mn2+ interaction is not affected in any instance. A theoretical curve fit to data for the pH-activity profile of Mn2+-saturated enzyme has a pKa = 7.95 for one proton ionization. The data establish L-threonine dehydrogenase of E. coli to be a metal ion activated enzyme.     

The Translocation and Redistribution of Manganese in Avena

⁵⁴Mn present in the first two leaves of oat seedlings subsequentlydeprived of manganese was later redistributed to leaves 4 and5. ⁵⁴Mn was found in leaves 3 and 4 even when the roots of seedlingswere excised immediately after exposure to ⁵⁴Mn, but more wasdetected if the roots were left intact. ⁵⁴Mn applied as a drop to the 4th leaf of manganese-deficientoat plants was concentrated in the stem and translocated primarilyto the youngest developing leaf or to the grain if present.⁵⁴Mn was readily detected in the roots but almost none was translocatedto the first three leaves. More ⁵⁴Mn was translocated in 96hrs. than 24, but little or no more was translocated in 192hrs. Plants which were given 0.5 p.p.m. stable manganese until theyreached the 4th leaf stage, and were then exposed to ⁵⁴Mn, showeda fairly uniform distribution of ⁵⁴Mn throughout the plant.There was relatively slight concentration at active growth centres. It is concluded that physiologically significant redistributionof manganese occurs in the oat plant.     

Thallium transport and the evaluation of olfactory nerve connectivity between the nasal cavity and olfactory bulb

Little is known regarding how alkali metal ions are transported in the olfactory nerve following their intranasal administration. In this study, we show that an alkali metal ion, thallium is transported in the olfactory nerve fibers to the olfactory bulb in mice. The olfactory nerve fibers of mice were transected on both sides of the body under anesthesia. A double tracer solution (thallium-201, (201)Tl; manganese-54, (54)Mn) was administered into the nasal cavity the following day. Radioactivity in the olfactory bulb and nasal turbinate was analyzed with gamma spectrometry. Auto radiographic images were obtained from coronal slices of frozen heads of mice administered with (201)Tl or (54)Mn. The transection of the olfactory nerve fibers was confirmed with a neuronal tracer. The transport of intranasal administered (201)Tl/(54)Mn to the olfactory bulb was significantly reduced by the transection of olfactory nerve fibers. The olfactory nerve transection also significantly inhibited the accumulation of fluoro-ruby in the olfactory bulb. Findings indicate that thallium is transported by the olfactory nerve fibers to the olfactory bulb in mice. The assessment of thallium transport following head injury may provide a new diagnostic method for the evaluation of olfactory nerve injury.     

Effects of simulated acid precipitation on the cycling of manganese under Sitka spruce (Picea sitchensis)

Simulated acid rain at pH 3.3, 4.3 and 5.3 has been applied by overheadspraying to reconstructed soil profiles and young Sitka spruce (Piceasitchensis) trees in pots to assess the effect of rainfall acidityonthe fate and recycling efficiency of Mn from ⁵⁴Mn-labelled Sitkaspruce litter. The concentration of ⁵⁴Mn in throughfall wassignificantly increased by acidification of the rain, but ⁵⁴Mnactivity in drainage water remained low and was not significantly affected. Thefact that only < 1.5% of ⁵⁴Mn was lost in drainage water suggeststhat forest ecosystems efficiently retain Mn, at least in the short term. Thebulk of ⁵⁴Mn (approximately 60 to 70%) was retained in the litterlayer. Compared with rain at pH 4.3, rain at pH 3.3 acidified L/F and H/Ahorizon soils. The amount of ⁵⁴Mn found in the different soilhorizons was only influenced significantly by rainfall acidity in the E horizonsoil, however, where ⁵⁴Mn activity was increased by the most acidtreatment. The activity of ⁵⁴Mn in Sitka spruce needles did notdiffer significantly with treatments.