Concentration and localization of zinc during seed development and germination in wheat

In a field experiment, the effect of foliar Zn applications on the concentration of Zn in seeds of a bread wheat cultivar (Triticum aestivum L. cv. Balatilla) was studied during different stages of seed development. In addition, a staining method using dithizone (DTZ: diphenyl thiocarbazone) was applied to (1) study the localization of Zn in seeds, (2) follow the remobilization of Zn during germination, and (3) develop a rapid visual Zn screening method for seed and flour samples. In all seed development stages, foliar Zn treatments were effective in increasing seed Zn concentration. The highest Zn concentration in the seeds was found in the first stage of seed development (around the early milk stage); after this, seed Zn concentration gradually decreased until maturity. When reacting with Zn, DTZ forms a redcolored complex. The DTZ staining of seed samples revealed that Zn is predominantly located in the embryo and aleurone parts of the seeds. After 36 h of germination, the coleoptile and roots that emerged from seeds showed very intensive red color formation and had Zn concentrations up to 200 mg kg1, indicating a substantial remobilization of Zn from seed pools into the developing roots (radicle) and coleoptile. The DTZ staining method seems to be useful in ranking flour samples for their Zn concentrations. There was a close relationship between the seed Zn concentrations and spectral absorbance of the methanol extracts of the flour samples stained with DTZ. The results suggest that (1) accumulation of Zn in seeds is particularly high during early seed development, (2) Zn is concentrated in the embryo and aleurone parts, and (3) the DTZ staining method can be used as a rapid, semiquantitative method to estimate Zn concentrations of flour and seed samples and to screen genotypes for their Zn concentrations in seeds

Trialling water treatment residuals in the remediation of former mine site soils: investigating improvements achieved for plants, earthworms and soil solution.

During clarification processes of raw water a vast amount of by-product known as drinking water treatment residuals (WTRs) are produced, being principally composed of hydroxides of the Al or Fe salts added during water treatment plus the impurities they remove. Aluminium-based (Al-WTR) and iron-based (Fe-WTR) materials were applied at 10% w/w to degraded, bare (un-vegetated) soils from a restored coal mining site in central England (pH <3.9) to study their potential amelioration effects on earthworm mortality, biomass yield of seedling plants and element concentrations in plant tissues, earthworm tissues and in soil solutions. A separate treatment with agricultural lime was also conducted for comparison to evaluate whether any observed improvements were attributable to the liming capacity of the WTRs. After completion of the trials all samples were subjected to a wet-dry cycle and the experiments were repeated (i.e. simulating longer-term effects in the field). Both types of WTRs significantly increased biomass of plants and, in some treatments, survival of earthworms was also enhanced compared to non-amended soils. Excess plant tissue element concentrations and element concentrations in soil solutions were reduced in amended soils. The implications are that adding WTRs to mining impacted soils is a potentially viable, sustainable and low cost remediation method that could be used globally to improve the soil condition. This article is protected by copyright. All rights reserved

Influential factors on the levels of cation exchange capacity in sediment at Langat river.

An exploratory study was carried out at 22 sampling stations along the Langat River, Selangor in order to investigate on the vitality of cation exchange capacity (CEC) in sediment (0–5 cm). Parameters such as pH, Eh, salinity, and electrical conductivity (EC) were determined. The CEC in sediment has been calculated by the determination of Ca2+, Na+, Mg2+, and K+ using the flame atomic absorption spectrophotometer, while the organic matter content in sediment was ascertained using the loss on ignition method. The characteristic of the sediment shows that pH (3.09–7.46), salinity (0.02–10.71 ppt), EC (3.39–517 μS/cm) and Eh (−16.20–253.10 mV) were substantially high in variation. This study also revealed that exchangeable Ca2+ and Mg2+ were controlled by organic matter contents, while exchangeable Na+ and K+ were influenced by salinity. Salinity was observed to play a major part in controlling all the exchangeable cations, as it gives strong significant correlations with Na+, K+, Mg2+, CEC, and organic matter at p < 0.01. The presence of seawater, clay mineralogy, and organic matter proves that it does play an important role in determining the CEC and soon relates to the pollution magnitude in the sediment

Bioavailability in soils

The consumption of locally-produced vegetables by humans may be an important exposure pathway for soil contaminants in many urban settings and for agricultural land use. Hence, prediction of metal and metalloid uptake by vegetables from contaminated soils is an important part of the Human Health Risk Assessment procedure. The behaviour of metals (cadmium, chromium, cobalt, copper, mercury, molybdenum, nickel, lead and zinc) and metalloids (arsenic, boron and selenium) in contaminated soils depends to a large extent on the intrinsic charge, valence and speciation of the contaminant ion, and soil properties such as pH, redox status and contents of clay and/or organic matter. However, chemistry and behaviour of the contaminant in soil alone cannot predict soil-to-plant transfer. Root uptake, root selectivity, ion interactions, rhizosphere processes, leaf uptake from the atmosphere, and plant partitioning are important processes that ultimately govern the accumulation ofmetals and metalloids in edible vegetable tissues. Mechanistic models to accurately describe all these processes have not yet been developed, let alone validated under field conditions. Hence, to estimate risks by vegetable consumption, empirical models have been used to correlate concentrations of metals and metalloids in contaminated soils, soil physico-chemical characteristics, and concentrations of elements in vegetable tissues. These models should only be used within the bounds of their calibration, and often need to be re-calibrated or validated using local soil and environmental conditions on a regional or site-specific basis.Mike J. McLaughlin, Erik Smolders, Fien Degryse, and Rene Rietr

Elemental hydrochemistry assessment on its variation and quality status in Langat River, Western Peninsular Malaysia.

This paper discusses the hydrochemistry variation and its quality status in Langat River, based on the chemistry of major ions, metal concentrations and suitability for drinking purposes. Water samples were collected from 30 different stations to assess their hydrochemical characteristics. The physico-chemical parameters selected were temperature, electrical conductivity, total dissolved solids (TDS), salinity, dissolved oxygen , pH, redox potential, HCO3, Cl, SO4, NO3, Ca, Na, K, Mg, 27Al, 138Ba, 9Be, 111Cd, 59Co, 63Cu, 52Cr, 57Fe, 55Mn, 60Ni, 208Pb, 80Se and 66Zn to investigate the variation of the constituents in the river water. Most of the parameters comply with the Drinking Water Quality Standard of the World Health Organization and the Malaysian National Standard for Drinking Water Quality by the Malaysia Ministry of Health except for EC, TDS, Cl, HCO3, SO4, Na, Mg, Al, Fe and Se. The results show that the Langat River is unsuitable for drinking purposes directly without treatment

Identification of a possible role of thymine DNA glycosylase (TDG) in epigenome maintenance

Thymine DNA glycosylase (TDG) was discovered as an enzyme capable of removing uracil (U) and thymine (T) from G/U and G/T mispairs, respectively. Owing to this ability, TDG was proposed to initiate restoration of C/G pairs at sites of cytosine or 5-methycytosine (5-meC) deamination. In addition to products of base deamination, the substrate spectrum of TDG covers a wide range of DNA base damages resulting from base oxidation and alkylation. TDG was also found to engage in physical and functional interactions with transcription factors, and more recent evidence supports additional interactions with the de novo DNA methyltransferases Dnmt3a and 3b in the context of gene transcription. Together with its biochemical properties, these observations suggest that TDG might be targeted to gene regulatory sequences as part of a macromolecular assembly to control their functional integrity. TDG may counteract the mutagenic effects of C and 5-meC deamination in CG-rich regions and/or be involved in the maintenance of CpG promoter methylation patterns. A tight regulation of CpG methylation at gene regulatory regions is critical for accurate gene expression, proper cellular differentiation and embryonic development. A somewhat surprising but in this context consistent finding was that, in contrast to other DNA glycosylases, TDG is essential for proper fetal development since a targeted knockout of the gene leads to embryonic lethality. To gain insights into the biological functions of TDG, we aimed to establish and apply biochemical fractionation procedures for high affinity purification and structural and functional characterization of TDG containing proteins complexes. The first part of the thesis was concerned with biochemical characterization of the protein interaction network of TDG in living mammalian cells. To this end, I applied different approaches allowing high affinity isolation of protein complexes from mammalian cells, such as the tandem affinity purification (TAP) method as well as immunoprecipitation of endogenous protein and of the TDGa isoform from TdgA overexpressing embryonic stem (ES) cells. These efforts, however, did not reveal any TDG interacting partners in subsequent mass spectrometry (MS) analyses. These results were surprising, as TDG was previously reported to interact with transcription factors and DNA methyltransferases. Remarkably, however, all previously identified protein interactors of TDG were discovered in screen with the respective partner proteins, and under conditions of simultaneous overexpression of both interacting proteins. The only proteins ever identified in screen with TDG were Sumo1 and Sumo3, which turned out to covalently modify the glycosylase. For this reason, we decided to pursue our search with classical cell fractionation experiments. We first did gel filtration experiments from total cell lysates and showed that TDG is indeed able to form distinct multiprotein complexes in undifferentiated mouse embryonic stem cells that may also contain the RNA helicase p68. Further subcellular fractionation experiments then revealed that TDG is present in all cell compartments, with a significant fraction of nuclear TDG being associated with chromatin, together with p68 and de novo DNA methyltransferases. Together with published findings, these results suggested that protein complexes containing TDG might act in a chromatin-associated context, at gene regulatory regions. The developmental phenotype of Tdg-/- knockout mice and the interactions of TDG with factors involved in developmental gene regulation (e.g. retinoic acid receptors RAR/RXR) implicate a function of TDG during early development and cell differentiation, at times governed by dynamic changes in gene expression, DNA methylation and histone modifications. Such changes have been studied using a well-established during in vitro differentiation of ES cells to lineage committed neuronal progenitors (NPs). We thus aimed to address the function of TDG as part of chromatin associated protein complexes during the process of retinoic acid induced differentiation of ES cells to NPs. In the second part of the thesis we made use of a this well-established in vitro differentiation system to examine the genome-wide localization of TDG to chromatin by TDG chromatin immunoprecipitation (ChIP) and to correlate TDG association to chromatin with gene expression and DNA methylation changes linked to cellular differentiation. TDG ChIP combined with high throughput sequencing showed that TDG associates with high preference to CpG islands in promoters of actively transcribed genes or genes poised for transcriptional activation. Such CpG rich sequences are normally unmethylated in mammalian genomes. Interestingly, we found TDG to localize to promoters of many genes controlling pluripotency (e.g. Oct4, Nanog) and developmental processes (e.g. Sfrp2, Tgfb2, Gata6), thus, supporting a function of TDG in cell differentiation and/or embryonic development. As different lines of circumstantial evidence have associated TDG with changes in CpG methylation following activation of hormone responsive gene promoters, we went on to further test genome-wide promoter methylation in Tdg+/- and Tdg-/- NPs making use of a combination of methylated DNA immunoprecipitation (MeDIP) and microarray technology. This showed that the loss of TDG does not affect global promoter DNA methylation. Nevertheless, there were a number of significant differences, suggesting that TDG might affect the CpG methylation pattern at some promoters. Also, owing to the limited resolution of the MeDIP method, however, we could not exclude an involvement of TDG in the control of DNA methylation of specific promoter CpGs. Additional bisulfite sequencing of promoters of TDG bound developmental genes (e.g. Sfrp2, Tgfb2) in NPs and differentiated mouse embryonic fibroblasts (MEFs) have indeed proved that loss of TDG affects local changes in DNA methylation at particular CpGs. Subsequent analysis of genome-wide gene expression profiles of ES cells and differentiated Tdg+/- and Tdg-/- NPs revealed that a limited number of genes (229) are differentially regulated in ES, whereas substantial differences in gene expression in were observed in NPs (1022 genes). This implicated a specific function of TDG in the regulation of cell differentiation triggered gene expression changes. Detailed analysis of the expression of the Pax6 gene, accurate regulation of which is essential for proper neuron development, showed that its promoter is bound by TDG and that its transcription is inappropriately regulated upon further differentiation of Tdg-/- NPs into the neuronal lineage. Whereas Tdg+/- NPs efficiently downregulated Pax6 (50x) and further differentiated into neuron-like cells, Tdg-/- NPs only partially downregulated Pax6 gene expression (6x) and underwent apoptosis at day 2 after plating in neuronal medium. This phenotype was complemented by expression of TDGa, clearly implicating TDG in the regulation of Pax6 expression during differentiation of ES cells to terminal neurons. We further observed misregulation of pluripotency genes (e.g. Oct4) regulated by TDG bound promoters during early differentiation of ES cells. In the absence of TDG, ES cells showed the tendency to enter spontaneous and/or RA induced differentiation, suggesting a role for TDG in the regulation of pluripotency. During RA induced differentiation we further observed the activation of the neuron specific gene Lrrtm2 exclusively in TDG proficient cells. In addition, ChIP experiments showed that transcription factors involved in the activation of the Lrrtm2 gene (e.g. COUP-TFI, RAR) are not recruited to the respective promoter in Tdg-/- cells, suggesting that TDG might act passively as a scaffold factor important for the recruitment of transcription factors to promoter regions. I set out to clarify the biological function of TDG by investigating its molecular interactions in mammalian cells. I found that TDG, as a DNA repair enzyme, associates tightly with chromatin, where it localizes with high preference to CpG island promoters of active genes and genes poised to be expressed. I also found that the loss of TDG causes misregulation of genes during cell differentiation and that this appears to be related to a function of TDG in establishing and/or maintaining CpG methylation pattern in gene regulatory sequences. These discoveries implicate a novel function of DNA repair, in the maintenance not only of the genome, but also the epigenome

Summation of connectivity strengths in the visual cortex reveals stability of neuronal microcircuits after plasticity

Abstract : Background: Within sensory systems, neurons are continuously affected by environmental stimulation. Recently, we showed that, on cell-pair basis, visual adaptation modulates the connectivity strength between similarly tuned neurons to orientation and we suggested that, on a larger scale, the connectivity strength between neurons forming sub-networks could be maintained after adaptation-induced-plasticity. In the present paper, based on the summation of the connectivity strengths, we sought to examine how, within cell-assemblies, functional connectivity is regulated during an exposure-based adaptation. Results: Using intrinsic optical imaging combined with electrophysiological recordings following the reconfiguration of the maps of the primary visual cortex by long stimulus exposure, we found that within functionally connected cells, the summed connectivity strengths remain almost equal although connections among individual pairs are modified. Neuronal selectivity appears to be strongly associated with neuronal connectivity in a “homeodynamic” manner which maintains the stability of cortical functional relationships after experience-dependent plasticity. Conclusions: Our results support the “homeostatic plasticity concept” giving new perspectives on how the summation in visual cortex leads to the stability within labile neuronal ensembles, depending on the newly acquired properties by neurons

Phytostabilization of metals in mine soils using Brassica juncea in combination with organic amendments

Background and aims The high metal bioavailability and the poor conditions of mine soils yield a low plant biomass, limiting the application of phytoremediation techniques. A greenhouse experiment was performed to evaluate the effects of organic amendments on metal stabilization and the potential of Brassica juncea L. for phytostabilization in mine soils. Methods Plants were grown in pots filled with soils collected from two mine sites located in Central Spain mixed with 0, 30 and 60 tha?1 of pine bark compost and horse- and sheep-manure compost. Plant biomass and metal concentrations in roots and shoots were measured. Metal bioavailability was assessed using a rhizosphere-based method (rhizo), which consists of a mixture of low-molecular-weight organic acids to simulate root exudates. Results Manure reduced metal concentrations in shoots (10?50 % reduction of Cu and 40?80 % of Zn in comparison with non-amended soils), bioconcentration factor (10?50 % of Cu and 40?80 % of Zn) and metal bioavailability in soil (40?50 % of Cu and 10?30 % of Zn) due to the high pH and the contribution of organic matter. Manure improved soil fertility and was also able to increase plant biomass (5?20 times in shoots and 3?30 times in roots), which resulted in a greater amount of metals removed from soil and accumulated in roots (increase of 2?7 times of Cu and Zn). Plants grown in pine bark treatments and in non-amended soils showed a limited biomass and high metal concentrations in shoots. Conclusions The addition of manure could be effective for the stabilization of metals and for enhancing the phytostabilization ability of B. juncea in mine soils. In this study, this species resulted to be a potential candidate for phytostabilization in combination with manure, differing from previous results, in which B. juncea had been recognized as a phytoextraction plant