Isolation of a copper complex and its rate of appearance in roots of Mimulus guttatus

A Cu-complex was isolated from the roots of copper-tolerant Mimulus guttatus. The elution volume of the complex determined by gel permeation chromatography was similar to that of rat-liver cadmium thionein. The complex was heat stable, had a relatively high ratio of absorbance at 254 nm: 280 nm and incorporated ³⁵S. The complex, purified using a combination of gel permeation chromatography and anion-exchange chromatography, contained more glutamine/glutamic acid and glycine residues than mammalian metallothioneins. The amount of the complex in roots increased after 5 h growth in a solution containing 16 M Cu. Induction was preceded by an increase in the concentrations in root tissue of unknown compounds containing sulphur which may serve as precursors. The availability of these compounds appeared to regulate the rate of synthesis of this Cu-complex.Abbreviations CuBP copper-binding protein - HPLC highperformance liquid chromatography - MT metallothionein - Th thionein - Tris 2-amino-2-(hydroxymethyl)1-3-propanediol     

Copper tolerance in Silene cucubalus

The uptake, translocation and subcellular distribution of copper as well as its effect on chloroplasts and plastocyanin synthesis were studied in a copper-sensitive and a copper-tolerant population of Silene cucubalus (L.) Wib. As a function of time, the copper concentration in roots of tolerant plants increased more slowly than that in roots of sensitive ones. Translocation to the shoot occurred more rapidly in tolerant plants than in sensitive ones. Although it was accumulated in leaf cells, copper was not accumulated in the chloroplasts of either sensitive or tolerant plants. Chlorophyll content was not affected by copper in tolerant plants, whereas sensitive plants became chlorotic. Plastocyanin synthesis was not enhanced as a result of high copper concentrations and no difference in plastocyanin content between tolerant and sensitive plants was detected. Measurements of copper in purified cell walls revealed that storage of the metal in cell-wall material does not play an important role in tolerance mechanism. Uptake characteristics, distribution and cytoplasmic detoxification of copper are discussed.     

Copper-binding proteins and copper tolerance in Pisam sativum L.

The effect of high nutrient levels of copper on the low-molecular-weight copper-proteins of leaves from plants of two cultivars of Pisum sativum L., with different sensitivity to copper, was investigated. Gel-filtration chromatography of leaf extracts from Cu-tolerant and Cu-sensitive plants grown with 1 M Cu(II), showed the presence of only two copper peaks (I and II), but growth of plants with 240 M Cu(II) induced two additional copper fractions (III and IV). Fractions II and III were purified by solvent extraction, gel-filtration and ion-exchange chromatography, and their molecular weights, subunit sizes, absorption spectra, metalprotein stoichiometry and amino-acid contents were determined. Fraction II was a polypeptide of M_r 15000 composed of a single chain. The purification of fraction III produced a copper-containing fraction (III-1) of M_r 3700, and a copper-protein (III-2) with an M_r, by sodium dodecyl sulfate-urea-polyacrylamide gel electrophoresis, of 66000. The metal contents of fractions III-1 and III-2 were higher in Cu-tolerant than in Cu-sensitive plants. On the basis of amino-acid analyses, fraction III-1 appeared to be complexes of Cu(II)-poly-isoleucine and Cu(II)-poly-leucine. The results rule out the existence, in pea leaves, of any protein similar to either animal metallothioneins or to any of the low-molecularweight metal-binding proteins or peptides described in other plants and reported to be involved in metal tolerance. In the mechanism of copper tolerance at the leaf level, fractions III-1 (M_r 3700), III-2 (M_r 66000), and IV (M_r 2000) appear to have a role, fraction IV being specifically induced in the tolerant cultivar by Cu(II). Fractions III-1 and III-2 could participate in a different mechanism, adaptive in character, involving an enhanced capacity to bind copper in Cu-tolerant plants.Abbreviations DEAE diethylaminoethyl - M_r relative molecular mass - SDS sodium dodecyl sulfate - PAGE polyacrylamide-gel electrophoresis J.M. Palma was the recipient of a research fellowship from the Caja General de Ahorros y Monte de Piedad de Granada and CSIC. We are grateful to Dr. J. Moreno-Carretero, R + D Department, UNIASA, Granada, for conducting the amino-acid analyses. This work was supported by grant 603/275 from CAICYT-CSIC (Spain).     

Response to copper and cadmium stress in wild-type and copper tolerant strains of the lichen alga <Emphasis Type="Italic">Trebouxia erici</Emphasis>: metal accumulation,toxicity and non-protein thiols

Cysteine, glutathione (GSH) and phytochelatins were determined in the cells of both wild and copper tolerant strains of the lichen alga Trebouxia erici following short-term (24 h) exposure to copper and cadmium and long-term (4 weeks) exposure to copper. Both metals caused concentration dependent synthesis of phytochelatins (PC₂–PC₅), but cadmium was a more potent activator of phytochelatin synthesis, even inducing synthesis of PC₅. The copper-tolerant strain did not reveal a higher degree of phytochelatin synthesis than the wild strain, and at 5 μM Cu production of phytochelatins was in fact significantly lower. Lower levels of phytochelatin correlated with significantly decreased intracellular copper content in the copper-tolerant strain. Both strains maintained high GSH levels even at a high copper concentration of 5 μM, and only the highest copper concentration (10 μM) was toxic for both strains, causing a decrease of GSH and PC content in algal cells. Cadmium had less effect on GSH in the cells of both tested strains. In the long term experiments, only relatively small amounts of PC₂ were detected in both strains, but the copper-tolerant strain retained significantly higher levels of reduced glutathione, probably due to the lesser degree of oxidative stress caused by Cu. The significant increase of cysteine synthesis in the copper-tolerant strain found in the present study may be related to copper tolerance in T. erici, while decreased intracellular Cu uptake, detoxification by PCs and increased free proline levels for protection of chloroplast membranes may also be implicated.     

Mycorrhizal infection of an Agrostis capillaris population on a copper contaminated soil

To investigate the possible natural development of heavy metal tolerance in VA-mycorrhizal fungi, plants of Agrostis capillaris from an uncontaminated, a copper-contaminated and a zinc/cadmium-contaminated area were examined for VA-mycorrhizal infection. During a period of 5 years (1987 to 1991) the plants of the copper-tolerant population were hardly infected, whereas the population on the uncontaminated soil showed a mean infection of nearly 60% and the zinc/cadmium-tolerant population of 40%. A detailed analysis of the surroundings of the copper-enriched site revealed the presence of VA-mycorrhizal fungi and a negative correlation between the infection rate of A. capillaris and the copper content of the soil. In contrast to the copper-contaminated soil, the abundant presence of VA-mycorrhizal fungi in the area contaminated by zinc and cadmium indicates that these fungi have evolved a zinc and cadmium tolerance and that they may play a role in the zinc and cadmium tolerance of A. capillaris.     

Selection for tolerance to copper during pollen formation in Mimulus guttatus Fischer ex DC

In Mimulus guttatus, copper tolerance is determined largely by a single gene and is expressed in both the sporophyte and microgametophyte. This study explores the extent to which selection during pollen formation affects copper tolerance in the sporophytic generation. Two sets of plants heterozygous for copper tolerance, produced by reciprocal crosses between different copper-tolerant or sensitive families, and the plant on which the original observations were based, were cloned and grown in control or copper-supplemented solutions. Pollen viability and the number of tolerant progeny produced in backcrosses to sensitive plants were compared. In addition, the effect of copper treatment on pollen viability in vitro was compared for plants tolerant, sensitive and heterozygous for copper tolerance. The extent to which in vitro pollen viability decreased in response to copper treatment corresponded to the copper tolerance of the pollen source. When grown with added copper, four of the five plants showed significant reductions in pollen viability, ranging from 18% to 48% of control values. The reductions in pollen viability were correlated with an increase in tolerant progeny (r= 0.679, p=0.004). Increases in tolerant progeny could be large, ranging from 119% to 170% of that of controls, but were usually smaller than was predicted from the reductions in viable pollen. In addition, plants derived from reciprocal crosses differed significantly in the extent to which pollen viability was decreased and sporophytic tolerance increased. Thus, while selection during pollen formation could increase sporophytic tolerance, sporophytic factors, perhaps including cytoplasmic or epigenetic ones, moderated the effectiveness of pollen selection for copper tolerance.     

Crystal structure of yeast Sco1

The Sco family of proteins are involved in the assembly of the dinuclear Cu_A site in cytochrome c oxidase (COX), the terminal enzyme in aerobic respiration. These proteins, which are found in both eukaryotes and prokaryotes, are characterized by a conserved CXXXC sequence motif that binds copper ions and that has also been proposed to perform a thiol:disulfide oxidoreductase function. The crystal structures of Saccharomyces cerevisiae apo Sco1 (apo-ySco1) and Sco1 in the presence of copper ions (Cu–ySco1) were determined to 1.8- and 2.3-Å resolutions, respectively. Yeast Sco1 exhibits a thioredoxin-like fold, similar to that observed for human Sco1 and a homolog from Bacillus subtilis. The Cu–ySco1 structure, obtained by soaking apo-ySco1 crystals in copper ions, reveals an unexpected copper-binding site involving Cys181 and Cys216, cysteine residues present in ySco1 but not in other homologs. The conserved CXXXC cysteines, Cys148 and Cys152, can undergo redox chemistry in the crystal. An essential histidine residue, His239, is located on a highly flexible loop, denoted the Sco loop, and can adopt positions proximal to both pairs of cysteines. Interactions between ySco1 and its partner proteins yeast Cox17 and yeast COX2 are likely to occur via complementary electrostatic surfaces. This high-resolution model of a eukaryotic Sco protein provides new insight into Sco copper binding and function.     

<Emphasis Type="Italic">In silico</Emphasis> modeling of the Menkes copper-translocating P-type ATPase 3rd metal binding domain predicts that phosphorylation regulates copper-binding

The Menkes (ATP7A) P_1B-type ATPase is a transmembrane copper-translocating protein. It contains six similar high-affinity metal-binding domains (MBDs) in the N-terminal cytoplasmic tail that are important for sensing intracellular copper and regulating ATPase function through the transfer of copper between domains. Molecular characterization of copper-binding and transfer is predominantly dependent on NMR structures derived from E. coli expression systems. A limitation of these models is the exclusion of post-translational modifications. We have previously shown that the third copper-binding domain, MBD3, uniquely contains two phosphorylated residues: Thr-327, which is phosphorylated only in the presence of elevated copper; and Ser-339, which is constitutively phosphorylated independent of copper levels. Here, using molecular dynamic simulations, we have incorporated these phosphorylated residues into a model based on the NMR structures of MBD3. Our data suggests that constitutively phosphorylated Ser-339, which is in a loop facing the copper-binding site, may facilitate the copper transfer process by exposing the CxxC copper-binding region of MBD3. Copper-induced phosphorylation of Thr327 is predicted to stabilize this change in conformation. This offers new molecular insights into how cell signaling (phosphorylation) can affect MBD structure and dynamics and how this may in turn affect copper-binding and thus copper-translocation functions of ATP7A.     

Copper chaperones,intracellular copper trafficking proteins. Function,structure, and mechanism of action

This review summarizes findings on a new family of small cytoplasmic proteins called copper chaperones. The copper chaperones bind and deliver copper ions to intracellular compartments and insert the copper into the active sites of specific partners, copper-dependent enzymes. Three types of copper chaperones have been found in eukaryotes. Their three-dimensional structures have been determined, intracellular target proteins identified, and mechanisms of action have been revealed. The Atx1 copper chaperone binds Cu(I) and interacts directly with the copper-binding domains of a P-type ATPase copper transporter, its physiological partner. The copper chaperone CCS delivers Cu(I) to Cu,Zn-superoxide dismutase 1. Cox17 and Cox11 proteins serve as copper chaperones for cytochrome c oxidase, a copper-dependent enzyme.     

Are Phytochelatins Involved in Differential Metal Tolerance or Do They Merely Reflect Metal-Imposed Strain?

Plants from nontolerant and copper-tolerant populations of Silene vulgaris both produce phytochelatins upon exposure to copper. The threshold copper concentration for induction of phytochelatin and the copper concentration at which maximum phytochelatin contents occurs increase proportionally with the level of tolerance to copper. When exposed to their own highest no-effect concentration or 50%-effect concentration of copper for root growth, tolerant and nontolerant plants exhibit equal phytochelatin contents in the root apex, which is the primary copper target. This also holds for distinctly tolerant nonsegregating F₃ families, derived from a single cross of a nontolerant plant to a tolerant one. Therefore, the phytochelatin content of the root apex can be used as a quantitative tolerance-independent measure of the degree of toxicity experienced by the plant. Differential copper tolerance in S. vulgaris does not appear to rely on differential phytochelatin production.     

Thermodynamics of the alkaline transition in phytocyanins

The thermodynamics of the alkaline transition which influences the spectral and redox properties of the type 1 copper center in phytocyanins has been determined spectroscopically. The proteins investigated include Rhus vernicifera stellacyanin, cucumber basic protein and its Met89Gln variant, and umecyanin, the stellacyanin from horseradish roots, along with its Gln95Met variant. The changes in reaction enthalpy and entropy within the protein series show partial compensatory behavior. Thus, the reaction free energy change (hence the pK _a value) is rather variable. This indicates that species-dependent differences in reaction thermodynamics, although containing an important contribution from changes in the hydrogen-bonding network of water molecules in the hydration sphere of the protein (which feature enthalpy–entropy compensation), are to a large extent protein-based. The data for axial ligand variants are consistent with the hypothesis of a copper-binding His as the deprotonating residue responsible for this transition.     

Growth and copper resistance of recombinantSaccharomyces cerevisiae containing a metallothionein gene

Summary Resistance to copper's toxicity inS. cerevisiae is mediated by a copper-binding protein, metallothionein (MT). Overexpression of MT in the recombinant yeast containing multiple copies of the MT gene on plasmid leads to a four-fold increase in the critical copper resistance level and an eight-fold enhancement of specific growth rate in a 2mM CuSO₄ medium compared with the parental host strain. The recombinant yeast grown in a 5mM CuSO₄ medium was found to accumulate 24.1mg of Cu per g of dry cell mass.     

Nickel and copper tolerance and toxicity in three Tuscan populations of Silene paradoxa

Three Tuscan ecotypes of Silene paradoxa L. were studied to evaluate the occurrence of multiple tolerance or co-tolerance mechanisms and to underline some tolerance strategies in plants naturally adapted to toxic concentrations of heavy metals. Seeds were collected from non-toxic calcareous soil, a serpentine outcrop with high nickel content and a copper mine dump. The evaluation of the toxic effects of the metals on root growth showed the copper-tolerant population as nickel co-tolerant, whereas the opposite was not the case. This suggests the occurrence of a non-reciprocal co-tolerance mechanism.
The nickel-tolerant population seemed able to tolerate nickel by limiting its inhibiting effect on the peroxisomal H₂O₂ scavenging enzymes since, in the sensitive population, this inhibition revealed itself as one of the causes of nickel-induced oxidative stress. A very low copper root and shoot concentration seemed to be characteristic of the copper-tolerant population, combined with a low susceptibility to metal-induced oxidative stress.     

Cytoplasmic male sterility and nuclear restorer genes in a natural population of Beta maritima: genetical and molecular aspects

Summary One natural population (F₀ generation) of Beta maritima situated on the French Atlantic coast has been analysed. It was composed of 62% female, 30% hermaphrodite and 8% intermediate plants. The analysis of half-sib progeny (F₁ generation) obtained from in situ open pollination demonstrates the cytoplasmic determination of male sterility in Beta maritima and the restoration of fertility by nuclear genes. The mitochondrial DNA (mtDNA) and the chloroplast DNA (ctDNA) of sixteen F₁ plants, extracted from offspring of the three sexual phenotypes, were analysed using the restriction enzymes Sal I and Bam HI, respectively. Two cytoplasmic lines with their own peculiar genetic characteristics were distinguished using the restriction enzyme patterns of mtDNA: (i) the S cytoplasmic line was found in segregating progeny of two F₀ plants; all three phenotypes were produced (that is, progeny including hermaphrodite, female and intermediate plants); (ii) the N cytoplasmic line was found in the progeny of one F₀ hermaphrodite plant; this produced only hermaphrodites. Thus, segregating and non-segregating hermaphrodite F₀ plants can be distinguished. The nuclear genes maintaining sterility or restoring fertility are expressed in line S. At the same time the analysis of Beta vulgaris material has been carried out at the molecular level: N cytoplasmic lines of B. vulgaris and B. maritima differed only by 3 fragments of mtDNA; but the S cytoplasmic line of B. maritima was very different from Owen's cytoplasmic male sterile line of B. vulgaris. No variation in the ctDNA pattern was detected within and between the two taxa.     

Enhanced ATP-dependent copper efflux across the root cell plasma membrane in copper-tolerant Silene vulgaris

We studied copper uptake in inside-out plasma membrane vesicles derived from roots of copper-sensitive, moderately copper-tolerant and highly copper-tolerant populations of Silene vulgaris (Amsterdam, Marsberg and Imsbach, respectively). Plasma membrane vesicles were isolated using the two-phase partitioning method and copper efflux was measured using direct filtration experiments. Vesicles derived from Imsbach plants accumulated two and three times more copper than those derived from Marsberg and Amsterdam plants, respectively. This accumulation was ATP-dependent. Also, 9-amino-6-chloro-2-methoxyacridine fluorescence quenching rates upon copper addition decreased in the order Imsbach>Marsberg>Amsterdam. Our results support the hypothesis that efflux of copper across the root plasma membrane plays a role in the copper tolerance mechanism in S. vulgaris .     

Morphologic,cytogenetic, and enzymatic variation in tissue culture regenerated plants of apomictic old-world bluestem grasses (Bothriochloa sp.)

Somaclonal variant plants may be of use in broadening the germplasm base of plant species and providing useful stocks for cytogenetic investigations. This study was conducted to compare morphologic, cytogenetic and enzymatic characteristics of 21 R₁ (initial regenerate) bluestem,Bothriochloa sp., plants, visibly identified in a field-grown population of 522 plants as probable variants, with their respective R₀ (explant donor) progenitor. An R₂ seedling population was grown to ascertain the transmission of the variant R₁ phenotypes. All R₁ plants differed from their respective R₀ progenitors in one or more morphological characters. Foliage colour was the most pronounced difference in most cases. Four of the plants, three of which were dwarfed, produced no inflorescences. The R₁ plants tended to be shorter than R₀ progenitors and had corresponding decreases in lengths on inflorescences and lowest racemes. All R₁ plants of accessions 8911C and 8793 had an increase in chromosome number from2n=4x=40 to2n=5x=50. Three dwarfed R₁ plants, derived from accession 8873B, were aneuploids, two having2n=48 chromosomes and the third being a probable mixoploid with 55–58 chromosomes. Other plants of accession 8873B had the R₀ chromosome number. Fertility, as estimated by pollen stainability and seed set, generally was reduced in R₁ plants relative to the R₀. This reduction was not drastic, however, with all flowering plants having 45% or higher seed set. Apomixis apparently maintained fertility in all R₁ plants, including those with a pentaploid chromosome number. All R₁ plants differed from their respective R₀ plants in peroxidase and esterase banding patterns. All R₁ plants of accessions 8911C, and 8793, respectively, had identical peroxidase and esterase bands. For both enzyme systems two banding patterns were present in R₁ plants of accession 8873B, with 12 of 13 plants exhibiting common patterns. Examination of R₂ progeny plants confirmed the genetic transmission of the variant phenotypes and, by virtue of uniformity, indicated apomictic reproduction in the R₁ plants. The results demonstrate the production of potentially useful genetic and cytogenetic variant plants via tissue culture in these apomictic species.     

Molecular analysis of two functional homologues of the S 3 allele of the Papaver rhoeas self-incompatibility gene isolated from different populations

The S ₃ allele of the S gene has been cloned from Papaver rhoeas cv. Shirley. The sequence predicts a hydrophilic protein of 14.0 kDa, showing 55.8% identity with the previously cloned S ₁ allele, preceded by an 18 amino acid signal sequence. Expression of the S ₃ coding region in Escherichia coli produced a form of the protein, denoted S₃e, which specifically inhibited S₃ pollen in an in vitro bioassay. The recombinant protein was ca. 0.8 kDa larger than the native stigmatic form, indicating post-translational modifications in planta, as was previously suggested for the S₁ protein. In contrast to other S proteins identified to date, S₃ protein does not appear to be glycosylated. Of particular significance is the finding that despite exhibiting a high degree of sequence polymorphism, secondary structure predictions indicate that the S₁ and S₃ proteins may adopt a virtually identical conformation. Sequence analysis also indicates that the P. rhoeas S alleles share some limited homology with the SLG and SRK genes from Brassica oleracea. Previously, cross-classification of different populations of P. rhoeas had revealed a number of functionally identical alleles. Probing of western blots of stigma proteins from plants derived from a wild Spanish population which contained an allele functionally identical to the Shirley S ₃ allele with antiserum raised to S₃e, revealed a protein (S ₃ s) which was indistinguishable in pI and M _r from that in the Shirley population. A cDNA encoding S ₃ s was isolated, nucleotide sequencing revealing a coding region with 99.4% homology with the Shirley-derived clone at the DNA level, and 100% homology at the amino acid level.     

Synthesis and properties of glutathione reductase in stressed peas

We have subjected peas (Pisum sativum L.) to four different oxidative stresses: cold conditions (4 °C) in conjunction with light, treatment with paraquat, fumigation with ozone, and illumination of etiolated seedlings (greening). In crude extracts of leaves from stressed plants, an increase (up to twofold) in activity of glutathione reductase (GR) was observed which was consistent with previous reports from several laboratories. In all cases, except for ozone fumigation, the increase in activity was not due to an elevation in the steady-state levels of GR protein. None of the applied stresses had any effect on steady-state levels of GR mRNA. In contrast to the small increase in GR activity, the K _m of GR for glutathione disulphide showed a marked decrease when determined for extracts of stressed leaves, compared with that from unstressed plants. This indicates that GR from stressed plants has an increased affinity for glutathione disulphide. The profile of GR activity bands fractionated on non-denaturing acrylamide gels varied for extracts from differently stressed leaves and when compared with GR from unstressed plants. The changes in GR-band profiles and the alteration in the kinetic properties are best explained as changes in the isoform population of pea GR in response to stress.Abbreviations GR glutathione reductase - GSSG glutathione disulphide - Rubisco Ribulose-1,5-bisphosphate carboxylase-oxygenase - RNase A/T1 ribonucleases A and T1 We are grateful to Prof. Alan Wellburn and Dr. Phil Beckett (Division of Biological Sciences, University of Lancaster, UK) for providing ozone-fumigated material and Dr. Jeremy Harbinson for providing material grown at 4° C. This work was supported by a grant-in-aid to the John Innes Institute from the Agricultural and Food Research Council. E.A.E. and C.E. gratefully acknowledge the support of a John Innes Foundation studentship and a European Molecular Biology Organisation Fellowship respectively.