Your search keyword '"Ruiz Oscar N"' showing total 5 results

1. Characterization of mercury bioremediation by transgenic bacteria expressing metallothionein and polyphosphate kinase.

Author

Ruiz ON, Alvarez D, Gonzalez-Ruiz G, and Torres C

Subjects

Biodegradation, Environmental, Cloning, Molecular, Escherichia coli drug effects, Escherichia coli genetics, Escherichia coli Proteins biosynthesis, Escherichia coli Proteins genetics, Genetic Vectors, Metallothionein biosynthesis, Metallothionein genetics, Phenotype, Phosphotransferases (Alcohol Group Acceptor) biosynthesis, Phosphotransferases (Alcohol Group Acceptor) genetics, Transgenes, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Mercury pharmacokinetics, Metallothionein metabolism, Phosphotransferases (Alcohol Group Acceptor) metabolism

Abstract

Background: The use of transgenic bacteria has been proposed as a suitable alternative for mercury remediation. Ideally, mercury would be sequestered by metal-scavenging agents inside transgenic bacteria for subsequent retrieval. So far, this approach has produced limited protection and accumulation. We report here the development of a transgenic system that effectively expresses metallothionein (mt-1) and polyphosphate kinase (ppk) genes in bacteria in order to provide high mercury resistance and accumulation., Results: In this study, bacterial transformation with transcriptional and translational enhanced vectors designed for the expression of metallothionein and polyphosphate kinase provided high transgene transcript levels independent of the gene being expressed. Expression of polyphosphate kinase and metallothionein in transgenic bacteria provided high resistance to mercury, up to 80 μM and 120 μM, respectively. Here we show for the first time that metallothionein can be efficiently expressed in bacteria without being fused to a carrier protein to enhance mercury bioremediation. Cold vapor atomic absorption spectrometry analyzes revealed that the mt-1 transgenic bacteria accumulated up to 100.2 ± 17.6 μM of mercury from media containing 120 μM Hg. The extent of mercury remediation was such that the contaminated media remediated by the mt-1 transgenic bacteria supported the growth of untransformed bacteria. Cell aggregation, precipitation and color changes were visually observed in mt-1 and ppk transgenic bacteria when these cells were grown in high mercury concentrations., Conclusion: The transgenic bacterial system described in this study presents a viable technology for mercury bioremediation from liquid matrices because it provides high mercury resistance and accumulation while inhibiting elemental mercury volatilization. This is the first report that shows that metallothionein expression provides mercury resistance and accumulation in recombinant bacteria. The high accumulation of mercury in the transgenic cells could present the possibility of retrieving the accumulated mercury for further industrial applications.

Published

2011

2. Metallothionein expression in chloroplasts enhances mercury accumulation and phytoremediation capability.

Author

Ruiz ON, Alvarez D, Torres C, Roman L, and Daniell H

Subjects

Biodegradation, Environmental, Chelating Agents chemistry, Chelating Agents metabolism, Gene Expression Regulation, Plant, Genetic Engineering methods, Genetic Vectors genetics, Mercury chemistry, Metallothionein metabolism, Plant Leaves genetics, Plant Leaves metabolism, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Polymerase Chain Reaction methods, Transformation, Genetic, Transgenes, Chloroplasts genetics, Chloroplasts metabolism, Mercury metabolism, Metallothionein biosynthesis, Metallothionein genetics

Abstract

Genetic engineering to enhance mercury phytoremediation has been accomplished by expression of the merAB genes that protects the cell by converting Hg[II] into Hg[0] which volatilizes from the cell. A drawback of this approach is that toxic Hg is released back into the environment. A better phytoremediation strategy would be to accumulate mercury inside plants for subsequent retrieval. We report here the development of a transplastomic approach to express the mouse metallothionein gene (mt1) and accumulate mercury in high concentrations within plant cells. Real-time PCR analysis showed that up to 1284 copies of the mt1 gene were found per cell when compared with 1326 copies of the 16S rrn gene, thereby attaining homoplasmy. Past studies in chloroplast transformation used qualitative Southern blots to evaluate indirectly transgene copy number, whereas we used real-time PCR for the first time to establish homoplasmy and estimate transgene copy number and transcript levels. The mt1 transcript levels were very high with 183,000 copies per ng of RNA or 41% the abundance of the 16S rrn transcripts. The transplastomic lines were resistant up to 20 μm mercury and maintained high chlorophyll content and biomass. Although the transgenic plants accumulated high concentrations of mercury in all tissues, leaves accumulated up to 106 ng, indicating active phytoremediation and translocation of mercury. Such accumulation of mercury in plant tissues facilitates proper disposal or recycling. This study reports, for the first time, the use of metallothioneins in plants for mercury phytoremediation. Chloroplast genetic engineering approach is useful to express metal-scavenging proteins for phytoremediation., (© 2011 The Authors. Plant Biotechnology Journal © 2011 Society for Experimental Biology, Association of Applied Biologists and Blackwell Publishing Ltd.)

Published

2011

3. Genetic engineering to enhance mercury phytoremediation.

Author

Ruiz ON and Daniell H

Subjects

Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Biodegradation, Environmental, Genetic Engineering methods, Mercury metabolism

Abstract

Most phytoremediation studies utilize merA or merB genes to modify plants via the nuclear or chloroplast genome, expressing organomercurial lyase and/or mercuric ion reductase in the cytoplasm, endoplasmic reticulum or within plastids. Several plant species including Arabidopsis, tobacco, poplar, rice, Eastern cottonwood, peanut, salt marsh grass and Chlorella have been transformed with these genes. Transgenic plants grew exceedingly well in soil contaminated with organic (approximately 400 microM PMA) or inorganic mercury (approximately 500 microM HgCl(2)), accumulating Hg in roots surpassing the concentration in soil (approximately 2000 microg/g). However, none of these plants were tested in the field to demonstrate real potential of this approach. Availability of metal transporters, translocators, chelators and the ability to express membrane proteins could further enhance mercury phytoremediation capabilities.

Published

2009

4. Phytoremediation of mercury and organomercurials in chloroplast transgenic plants: enhanced root uptake, translocation to shoots, and volatilization.

Author

Hussein HS, Ruiz ON, Terry N, and Daniell H

Subjects

Volatilization, Chloroplasts metabolism, Environmental Restoration and Remediation methods, Mercury metabolism, Plant Roots metabolism, Plant Shoots metabolism, Plants, Genetically Modified metabolism

Abstract

Transgenic tobacco plants engineered with bacterial merA and merB genes via the chloroplast genome were investigated to study the uptake, translocation of different forms of mercury (Hg) from roots to shoots, and their volatilization. Untransformed plants, regardless of the form of Hg supplied, reached a saturation point at 200 microM of phenylmercuric acetate (PMA) or HgCl2, accumulating Hg concentrations up to 500 microg g(-1) with significant reduction in growth. In contrast, chloroplast transgenic lines continued to grow well with Hg concentrations in root tissues up to 2000 microg g(-1). Chloroplasttransgenic lines accumulated both the organic and inorganic Hg forms to levels surpassing the concentrations found in the soil. The organic-Hg form was absorbed and translocated more efficiently than the inorganic-Hg form in transgenic lines, whereas no such difference was observed in untransformed plants. Chloroplast-transgenic lines showed about 100-fold increase in the efficiency of Hg accumulation in shoots compared to untransformed plants. This is the first report of such high levels of Hg accumulation in green leaves or tissues. Transgenic plants attained a maximum rate of elemental-Hg volatilization in two days when supplied with PMA and in three days when supplied with inorganic-Hg, attaining complete volatilization within a week. The combined expression of merAB via the chloroplast genome enhanced conversion of Hg2+ into Hg,0 conferred tolerance by rapid volatilization and increased uptake of different forms of mercury, surpassing the concentrations found in the soil. These investigations provide novel insights for improvement of plant tolerance and detoxification of mercury.

Published

2007

5. Phytoremediation of Organomercurial Compounds via Chloroplast Genetic Engineering.

Author

Ruiz, Oscar N., Hussein, Hussein S., Terry, Norman, and Daniell, Henry

Subjects

*PHYTOREMEDIATION, *ORGANOMERCURY compounds, *GENETIC engineering, *CHLOROPLASTS, *MERCURY

Abstract

Studies the phytoremediation of organomercurial compounds through the use of chloroplast genetic engineering. Characterization of chloroplast as the primary target for mercury damage; Inhibition of electron transport and photosynthesis by mercury; Enhancement of the capacity of plants for phytoremediation.

Published

2003