Agrobacterium tumefaciens fur Has Important Physiological Roles in Iron and Manganese Homeostasis, the Oxidative Stress Response, and Full Virulence

In Agrobacterium tumefaciens, the balance between acquiring enough iron and avoiding iron-induced toxicity is regulated in part by Fur (ferric uptake regulator). A fur mutant was constructed to address the physiological role of the regulator. Atypically, the mutant did not show alterations in the levels of siderophore biosynthesis and the expression of iron transport genes. However, the fur mutant was more sensitive than the wild type to an iron chelator, 2,2′-dipyridyl, and was also more resistant to an iron-activated antibiotic, streptonigrin, suggesting that Fur has a role in regulating iron concentrations. A. tumefaciens sitA, the periplasmic binding protein of a putative ABC-type iron and manganese transport system (sitABCD), was strongly repressed by Mn²⁺ and, to a lesser extent, by Fe²⁺, and this regulation was Fur dependent. Moreover, the fur mutant was more sensitive to manganese than the wild type. This was consistent with the fact that the fur mutant showed constitutive up-expression of the manganese uptake sit operon. Fur_At showed a regulatory role under iron-limiting conditions. Furthermore, Fur has a role in determining oxidative resistance levels. The fur mutant was hypersensitive to hydrogen peroxide and had reduced catalase activity. The virulence assay showed that the fur mutant had a reduced ability to cause tumors on tobacco leaves compared to wild-type NTL4.     

Comparative survival analysis of 12 histidine kinase mutants of Deinococcus radiodurans after exposure to DNA-damaging agents

Bacteria are able to adapt to changes in the environment using two-component signal transduction systems (TCSs) composed of a histidine kinase (HK) and a response regulator (RR). Deinococcus radiodurans, one of the most resistant organisms to ionizing radiation, has 20 putative HKs and 25 putative RRs. In this study, we constructed 12 D. radiodurans mutant strains lacking a gene encoding a HK and surveyed their resistance to γ-radiation, UV-B radiation (302 nm), mitomycin C (MMC), and H₂O₂. Five (dr0860 ^?, dr1174 ^?, dr1556 ^?, dr2244 ^?, and dr2419 ^?) of the 12 mutant strains showed at least a one-log cycle reduction in γ-radiation resistance. The mutations (1) dr1174, dr1227, and dr2244 and (2) dr0860, dr2416, and dr2419 caused decreases in resistance to UV radiation and MMC, respectively. Only the dr2416 and dr2419 mutant strains showed higher sensitivity to H₂O₂ than the wild-type. Reductions in the resistance to γ-radiation and H₂O₂, but not to UV and MMC, were observed in the absence of DR2415, which seems to be a cognate RR of DR2416. This result suggests that DR2415/DR2416 (DrtR/S: DNA damage response TCS) may be another TCS responsible for the extreme resistance of D. radiodurans to DNA-damaging agents.     

Reversal of Copper Inhibition in Chloroplast Reactions by Manganese

In the Mehler reaction, a Hill reaction utilizing molecular oxygen as the electron acceptor, rates of net oxygen uptake are stimulated by added manganous ions. Both whole cell photosynthesis and the Mehler reaction are inhibited by copper. Copper inhibition of the Mehler reaction can be reversed by manganese salts. Glutathione. which alone has no effect on Mehler reaction rates, enhances the effect of manganese in reversing copper inhibition. The effects of added Cu²⁺, Cu²⁺ and Mn²⁺, or Cu²⁺, Mn²⁺, and glutathione exhibit no induction phenomena when measured manometrically. Furthermore, the order of addition of these factors is unimportant: final rates are dependent only on the composition of reaction mixtures. Compared to the Mehler reaction, conventional Hill reactions are less sensitive to copper poisoning, while certain chloroplast mediated photoxidations (e.g. the photoxidation of diketogulonic acid) are far more sensitive. In all of the chloroplast mediated photoreactions tested, manganese is effective in reducing the sensitivity to copper poisoning.     

Characterization of a dipartite iron uptake system from uropathogenic Escherichia coli strain F11

In the uropathogenic Escherichia coli strain F11, in silico genome analysis revealed the dicistronic iron uptake operon fetMP, which is under iron-regulated control mediated by the Fur regulator. The expression of fetMP in a mutant strain lacking known iron uptake systems improved growth under iron depletion and increased cellular iron accumulation. FetM is a member of the iron/lead transporter superfamily and is essential for iron uptake by the Fet system. FetP is a periplasmic protein that enhanced iron uptake by FetM. Recombinant FetP bound Cu(II) and the iron analog Mn(II) at distinct sites. The crystal structure of the FetP dimer reveals a copper site in each FetP subunit that adopts two conformations: CuA with a tetrahedral geometry composed of His⁴⁴, Met⁹⁰, His⁹⁷, and His¹²⁷, and CuB, a second degenerate octahedral geometry with the addition of Glu⁴⁶. The copper ions of each site occupy distinct positions and are separated by ∼1.3 Å. Nearby, a putative additional Cu(I) binding site is proposed as an electron source that may function with CuA/CuB displacement to reduce Fe(III) for transport by FetM. Together, these data indicate that FetMP is an additional iron uptake system composed of a putative iron permease and an iron-scavenging and potentially iron-reducing periplasmic protein.     

Accumulation and precipitation of Mn2+ by the cells of Oscillatoria terebriformis

The cyanobacterium Oscillatoria terebriformis was shown to exhibit resistance to high manganese concentrations, remaining viable at 2.5 mM MnCl₂ in the medium. Cyanobacterial cells were capable of considerable manganese consumption from the medium. The dynamics of Mn sorption by the cells were the same in all experimental variants, independent of the manganese concentration. Manganese concentration in the biomass peaked after 2–3 days and depended on Mn²⁺ concentration in the medium and on the amount of biomass introduced. In the case of O. terebriformis, manganese removed from the medium may be subdivided into Mn absorbed by the cell, Mn bound to the cell wall, Mn absorbed by the glycocalix, and chemically precipitated Mn. Of the total 21.25 ± 1.0 mg of consumed manganese, biological absorption and chemical precipitation were responsible for 11.78 ± 0.98 and 9.2 ± 0.8 mg, respectively. In the presence of cyanobacteria, Mn removal from the medium was 2.28 times higher than in the control. This process depended considerably on Mn sorption by exopolysaccharides. At 1.3 mM Mn²⁺, a lamellar mat was formed with interlayers of manganese carbonate.     

九州虫草菌丝体对Mn的耐性及富集

重金属耐性真菌的研究是生物修复的重要研究内容。本文研究了九州虫草（Cordyceps kyusyuensis）对于Mn的耐性及富集。在液体培养基中添加不同浓度（0—60 g/L）的Mn离子,测定其菌丝生物量、菌丝Mn含量、菌丝抗氧化酶活性和过氧化水平以及菌体细胞离子交换量、Mn在细胞中的分布的变化情况。实验结果表明九州虫草菌丝生物量与Mn浓度呈显著负相关,Mn浓度60 g/L为九州虫草菌丝生长极限浓度。菌丝中Mn含量随培养基中Mn浓度的增大而显著升高,10 g/L Mn时,菌丝细胞中Mn积累量达到细胞干重的1.0013%。九州虫草菌丝中过氧化产物丙二醛（MDA）、可溶性蛋白（SP）含量、可溶性糖浓度与培养基中Mn浓度呈负相关,实验组与对照组差异显著。抗氧化酶（过氧化氢酶（CAT）、过氧化物酶（POD）、超氧化物歧化酶（SOD））活性随着培养基中Mn浓度增大而显著升高,但变化趋势不同。九州虫草菌丝细胞不可溶性组分中Mn的量（91.51%—98.6%）显著高于可溶部分（1.40%—8.49%）。九州虫草菌丝细胞壁离子交换量（CEC）随着培养基中Mn浓度的升高变化不明显。说明在九州虫草菌丝对Mn的富集过程中,其细胞壁、细胞膜和细胞器对于Mn结合发挥了主要作用,细胞质中可溶性成分对Mn的结合发挥次要作用。在Mn的胁迫下,增强抗氧化酶系统的协同作用以清除大量自由基是细胞对锰耐性的重要机制。     

Kinetics of uptake and intracellular location of cobalt,manganese and zinc in the estuarine green alga Chlorella salina

Summary The uptake kinetics and intracellular location of cobalt (⁶⁰Co), manganese (⁵⁴Mn) and zinc (⁶⁵Zn) have been characterized in Chlorella salina. Uptake of all three metals was biphasic. The initial rapid phase was independent of light, temperature or the presence of metabolic inhibitors. This first phase of metabolism-independent biosorption was followed by a slower phase of uptake that was apparently dependent on metabolism and decreased by incubation in the dark, or in the light at low temperature or in the presence of metabolic inhibitors. This latter phase of metal accumulation followed Michaelis-Menten kinetics. However, when expressed in the form of a Lineweaver-Burk plot two distinct phases were apparent for each metal with the following K_m values (M); Co²⁺, 19 and 266; Mn²⁺, 2 and 760; Zn²⁺, 4 and 635. For all three metals cellular compartmentation analysis showed that large amounts of metal were bound to intracellular components and to the cell wall. There was also a higher concentration of each metal in the vacuole than in the cytosol, indicating transport of the metals across the tonoplast which may, in part, account for the multi-phasic uptake systems detected. The influence of competing divalent ions on the active uptake of Co²⁺ and Mn²⁺ was also studied. When the concentration of divalent ion was the same as that of Co²⁺ the uptake of the latter was not affected, indicating a specific system for the uptake of Co²⁺. However, Mn²⁺ uptake inhibited by Mg²⁺, Zn²⁺ and Cd²⁺, but not by Co²⁺, which indicated that Mn²⁺, Mg²⁺ and Cd²⁺ may enter the cells via a common system with different affinities for each metal.     

Superior Therapeutic Index of Calmangafodipir in Comparison to Mangafodipir as a Chemotherapy Adjunct

Mangafodipir is a magnetic resonance imaging contrast agent with manganese superoxide dismutase (MnSOD) mimetic activity. The MnSOD mimetic activity protects healthy cells against oxidative stress-induced detrimental effects, e.g., myelosuppressive effects of chemotherapy drugs. The contrast property depends on in vivo dissociation of Mn²⁺ from mangafodipir—about 80% dissociates after injection. The SOD mimetic activity, however, depends on the intact Mn complex. Complexed Mn²⁺ is readily excreted in the urine, whereas dissociated Mn²⁺ is excreted slowly via the biliary route. Mn is an essential but also a potentially neurotoxic metal. For more frequent therapeutic use, neurotoxicity due to Mn accumulation in the brain may represent a serious problem. Replacement of 4/[5] of Mn²⁺ in mangafodipir with Ca²⁺ (resulting in calmangafodipir) stabilizes it from releasing Mn²⁺ after administration, which roughly doubles renal excretion of Mn. A considerable part of Mn²⁺ release from mangafodipir is governed by the presence of a limited amount of plasma zinc (Zn²⁺). Zn²⁺ has roughly 10³ and 10⁹ times higher affinity than Mn²⁺ and Ca²⁺, respectively, for fodipir. Replacement of 80% of Mn²⁺ with Ca²⁺ is enough for binding a considerable amount of the readily available plasma Zn²⁺, resulting in considerably less Mn²⁺ release and retention in the brain and other organs. At equivalent Mn²⁺ doses, calmangafodipir was significantly more efficacious than mangafodipir to protect BALB/c mice against myelosuppressive effects of the chemotherapy drug oxaliplatin. Calmangafodipir did not interfere negatively with the antitumor activity of oxaliplatin in CT2[6] tumor-bearing syngenic BALB/c mice, contrary calmangafodipir increased the antitumor activity.     

Manganous Ion as a Spin Label in Studies of Mitochondrial Uptake of Manganese

Manganous ion (Mn²⁺) has been used as a spin label for studies of divalent cation uptake by rat liver mitochondria. Spin exchange, observed in the electron paramagnetic resonance (EPR) spectrum of a fraction of the transported Mn²⁺, shows that this fraction is bound in regions of high local concentration within the mitochondria. The average separation of manganese ions in that fraction is estimated to be 4.0 ±0.6 A at the time of greatest concentration.     

Substrate Profile and Metal-ion Selectivity of Human Divalent Metal-ion Transporter-1

Divalent metal-ion transporter-1 (DMT1) is a H⁺-coupled metal-ion transporter that plays essential roles in iron homeostasis. DMT1 exhibits reactivity (based on evoked currents) with a broad range of metal ions; however, direct measurement of transport is lacking for many of its potential substrates. We performed a comprehensive substrate-profile analysis for human DMT1 expressed in RNA-injected Xenopus oocytes by using radiotracer assays and the continuous measurement of transport by fluorescence with the metal-sensitive PhenGreen SK fluorophore. We provide validation for the use of PhenGreen SK fluorescence quenching as a reporter of cellular metal-ion uptake. We determined metal-ion selectivity under fixed conditions using the voltage clamp. Radiotracer and continuous measurement of transport by fluorescence assays revealed that DMT1 mediates the transport of several metal ions that were ranked in selectivity by using the ratio I_max/K_0.5 (determined from evoked currents at −70 mV): Cd²⁺ > Fe²⁺ > Co²⁺, Mn²⁺ ≫ Zn²⁺, Ni²⁺, VO²⁺. DMT1 expression did not stimulate the transport of Cr²⁺, Cr³⁺, Cu⁺, Cu²⁺, Fe³⁺, Ga³⁺, Hg²⁺, or VO⁺. ⁵⁵Fe²⁺ transport was competitively inhibited by Co²⁺ and Mn²⁺. Zn²⁺ only weakly inhibited ⁵⁵Fe²⁺ transport. Our data reveal that DMT1 selects Fe²⁺ over its other physiological substrates and provides a basis for predicting the contribution of DMT1 to intestinal, nasal, and pulmonary absorption of metal ions and their cellular uptake in other tissues. Whereas DMT1 is a likely route of entry for the toxic heavy metal cadmium, and may serve the metabolism of cobalt, manganese, and vanadium, we predict that DMT1 should contribute little if at all to the absorption or uptake of zinc. The conclusion in previous reports that copper is a substrate of DMT1 is not supported.     

Magnetic resonance studies of the mitochondrial divalent cation carrier

Measurements of water proton spin relaxation enhancements (ε) can be used to discriminate high-affinity binding of Mn²⁺ or Gd³⁺ to biological membranes, from low-affinity binding. In rat liver mitochondria, ε_b values of approx. 11 are observed upon binding of Mn²⁺ to the inner membrane, while internal or low-affinity binding remains invisible to this technique. Energy-driven Mn²⁺ uptake by liver mitochondria results in the subsequent decay of ε¹.Comparison of ε¹ with the initial velocity of Mn²⁺ uptake in rat liver mitochondria reveals a linear correlation, which holds at all temperatures between 0 °C and 40 °C, regardless of the mitochondrial protein concentration. Consequently, enhancement appears to reflect the binding of Mn²⁺ to the divalent cation pump.Binding of Mn²⁺ to blowfly flight muscle also results in substantial ε¹, which is associated with the glycerol-1-phosphate dehydrogenase instead of divalent cation transport. Consequently, no decay in ε¹ due to uptake occurs after Mn²⁺ is bound.Lanthanide ions are also bound and transported by mitochondria. Addition of Gd³⁺ to pigeon heart or rat liver mitochondria results in ε_b ≈ 5–6, which decays with similar kinetics in both systems. The uptake velocity of Gd³⁺ in rat liver mitochondria is about $\text{1}\text{6}$ the rate with which Mn²⁺ is transported. Lanthanides also diminish ε¹ due to the addition of Mn²⁺, and greatly retard the Mn²⁺ uptake kinetics. The presence of carbonylcyanide-p-trifluoromethoxyphenylhydrazone depresses ε¹ upon addition of Mn²⁺ or Gd³⁺ and also uncouples energy-driven uptake. On the other hand, prolonged anaerobic incubation in the presence of antimycin and rotenone exhausts the mitochondria of their energy stores, blocks the uptake of Mn²⁺, but does not affect ε¹ significantly. Evidently, the uncoupler-induced disappearance of divalent cation binding sites is not the result of “de-energization”.Measurements of ε¹ at several NMR frequencies indicate a correlation time (τ_b) for carrier-bound Mn²⁺ in rat liver mitochondria between 20 ns and 4 ns as one varies the temperature between 10 °C and 30 °C. The 13 Kcal/mole activation energy for τ_b suggests that the 11 ns time constant at room temperature represents the movement of the Mn^II-carrier complex. On the other hand, τ_b is probably approx. 100 times too short to represent the rotational motion of a carrier protein. Apparently, Mn²⁺ binds to a small arm of the carrier which moves independently of the main body of any protein.In addition to Mn(H₂O)₆²⁺, other complexes of Mn²⁺ may also be bound and transported by rat liver mitochondria. Only a small increase in ε¹ occurs upon addition of MnHPO₄, yet this species is accumulated by the mitochondria. Consequently, the carrier does not recognize divalent metal ions on the basis of charge.     

Divalent metal ion effects on a mutant histidinol phosphate phosphatase from Salmonella typhimurium

The effect of divalent metal ions on the activity of a mutant histidinol phosphate phosphatase has been studied. The enzyme was isolated from strain TA387, a mutant of Salmonella typhimurium with a nonsense lesion near the midpoint of the bifunctional hisB gene. Mn²⁺, Mg²⁺, Co²⁺, and Zn²⁺ shift the optimal pH of phosphatase activity to 6.5 while Be²⁺ and Ca²⁺ have no effect on the shape of the pH profile. In the absence of divalent metal ions, the pH optimum is 7.5. Four Me²⁺ ions, Mn²⁺, Co²⁺, Zn²⁺, and Fe²⁺ decreased the K_m of histidinol phosphate at pH 6.5 from 5.5 mm (without Me²⁺) to 0.14 mm. Ni²⁺ and Be²⁺ increased the K_m to 22.2 and 25.0 mm, respectively, and Ca²⁺ and Mg²⁺ had an intermediate effect. Changes in maximal velocity were substantially less, only about 2-fold changes being observed. It was shown that the maximal velocity at optimal pH was the same in the absence and presence of Mn²⁺. Kinetic analysis indicated that there was a rapid equilibrium-ordered addition of Mn²⁺ to the enzyme before the addition of the substrate, histidinol phosphate. A k_imn²⁺ of 4.3 μm was calculated for the metal ion activation at both pH 6.5 and 7.5. Addition of ethyl-enediaminetetracetate (EDTA) strongly inhibited the phosphatase; inhibition could be reversed by addition of several Me²⁺ ions, Mg²⁺ being the most efficient followed by Mn²⁺. Prolonged incubation with EDTA led to irreversible inactivation.     

Uptake and accumulation of Mn2+ and Sr2+ in Saccharomyces cerevisiae

Initial uptake of Mn²⁺ and Sr²⁺ in the yeast Saccharomyces cerevisiae was studied in order to investigate the selectivity of the divalent cation uptake system and the possible involvement of the plasma-membrane ATPase in this uptake. The initial uptake rates of the two ions were not significantly different. This ruled out a direct role of the plasma-membrane ATPase, since this ATPase is specific for Mn²⁺ compared to Sr²⁺. After 1 h uptake, Mn²⁺ had accumulated 10-times more than Sr²⁺. Influx of Mn²⁺ and Sr²⁺ remained unchanged during that time, however. The differences in accumulation level found for Mn²⁺ and Sr²⁺ could be ascribed to a greater efflux of Sr²⁺ as compared with Mn²⁺. Probably this greater efflux of Sr²⁺ was only apparent, since differential extraction of the yeast cells revealed that Mn²⁺ is more compartmentalised than Sr²⁺, giving rise to a lower relative cytoplasmic Mn²⁺ concentration.     

Involvement of histidine permease (Hip1p) in manganese transport in Saccharomyces cerevisiae

In a search for components involved in Mn²⁺ homeostasis in the budding yeast Saccharomyces cerevisiae, we isolated a mutant with modifications in Mn²⁺ transport. The mutation was found to be located in HIP1, a gene known to encode a high-affinity permease for histidine. The mutation, designated hip1–272, caused a frameshift that resulted in a stop codon at position 816 of the 1812-bp ORF. This mutation led to Mn²⁺ resistance, whereas the corresponding null mutation did not. Both hip1–272 cells and the null mutant exhibited low tolerance to divalent cations such as Co²⁺, Ni²⁺, Zn²⁺, and Cu²⁺. The Mn²⁺ phenotype was not influenced by supplementary histidine in either mutant, whereas the sensitivity to other divalent cations was alleviated by the addition of histidine. The cellular Mn²⁺ content of the hip1–272 mutant was lower than that of wild type or null mutant, due to increased rates of Mn²⁺ efflux. We propose that Hip1p is involved in Mn²⁺ transport, carrying out a function related to Mn²⁺ export.     

Manganese‐oxidizing bacteria mediate the degradation of 17α‐ethinylestradiol

Manganese (II) and manganese‐oxidizing bacteria were used as an efficient biological system for the degradation of the xenoestrogen 17α‐ethinylestradiol (EE2) at trace concentrations. Mn²⁺‐derived higher oxidation states of Mn (Mn³⁺, Mn⁴⁺) by Mn²⁺‐oxidizing bacteria mediate the oxidative cleavage of the polycyclic target compound EE2. The presence of manganese (II) was found to be essential for the degradation of EE2 by Leptothrix discophora, Pseudomonas putida MB1, P. putida MB6 and P. putida MB29. Mn²⁺‐dependent degradation of EE2 was found to be a slow process, which requires multi‐fold excess of Mn²⁺ and occurs in the late stationary phase of growth, implying a chemical process taking place. EE2‐derived degradation products were shown to no longer exhibit undesirable estrogenic activity.     

Effect of pH on Mn absorption by barley genotypes in a chelate-buffered nutrient solution

A new chelate-buffering technique was used to investigate the effect of pH (6.00, 6.85 and 7.70) on manganese (Mn) absorption from nutrient solution by three genotypes of barley plants differeing in Mn efficiency. The nutrient composition was adjusted such that the calculated activities of Mn²⁺, Zn²⁺, Cu²⁺ and Ni²⁺ were similar in each pH, thus eliminating any effect of the pH treatment on Mn²⁺ supply. Increasing pH from 6.00 to 7.70 increased the rate of Mn absorption and decreased the external Mn requirement for optimal growth rate. With increasing pH, Mn concentrations in roots rose markedly, and were higher than those in shoots at pH 7.70. Genotypic differences in Mn concentration of roots appeared only at higher pH. We suggest that higher Mn concentration in roots of inefficient plants may be related to Mn immobilisation in roots, and this may be a factor in the mechanism of Mn efficiency.