Microscopic biomineralization processes and Zn bioavailability: a synchrotron-based investigation of Pistacia lentiscus L. roots.

Plants growing on polluted soils need to control the bioavailability of pollutants to reduce their toxicity. This study aims to reveal processes occurring at the soil-root interface of Pistacia lentiscus L. growing on the highly Zn-contaminated tailings of Campo Pisano mine (SW Sardinia, Italy), in order to shed light on possible mechanisms allowing for plant adaptation. The study combines conventional X-ray diffraction (XRD) and scanning electron microscopy (SEM) with advanced synchrotron-based techniques, micro-X-ray fluorescence mapping (µ-XRF) and X-ray absorption spectroscopy (XAS). Data analysis elucidates a mechanism used by P. lentiscus L. as response to high Zn concentration in soil. In particular, P. lentiscus roots take up Al, Si and Zn from the rhizosphere minerals in order to build biomineralizations that are part of survival strategy of the species, leading to formation of a Si-Al biomineralization coating the root epidermis. XAS analysis rules out Zn binding to organic molecules and indicates that Zn coordinates Si atoms stored in root epidermis leading to the precipitation of an amorphous Zn-silicate. These findings represent a step forward in understanding biological mechanisms and the resulting behaviour of minor and trace elements during plant-soil interaction and will have significant implications for development of phytoremediation techniques.

Control of neoclassical tearing modes by sawtooth control.

The onset of a neoclassical tearing mode (NTM) depends on the existence of a large enough seed island. It is shown in the Joint European Torus that NTMs can be readily destabilized by long-period sawteeth, such as obtained by sawtooth stabilization from ion-cyclotron heating or current drive. This has important implications for burning plasma scenarios, as alpha particles strongly stabilize the sawteeth. It is also shown that, by adding heating and current drive just outside the inversion radius, sawteeth are destabilized, resulting in shorter sawtooth periods and larger beta values being obtained without NTMs.

Transfer and expression of the human multiple drug resistance gene in human CD34+ cells.

The human multiple-drug resistance (MDR1) gene has been transferred into human hematopoietic progenitors using retroviral gene transfer. Human bone marrow cells and isolated CD34+ cells isolated from marrow were exposed to growth factors interleukin-3 (IL-3), IL-6, and stem cell factor for 48 hours and then to two changes of MDR retroviral supernatants over the next 24 hours. Progenitor assays in methylcellulose at this time showed that 18% to 70% of BFU-E and 30% to 60% of CFU-GM contain the transferred MDR gene by polymerase chain reaction analysis. Up to 11.2% of the progeny of these cells express increased amounts of MDR glycoprotein on their surface by fluorescence-activated cell sorter (FACS) analysis. In addition, transduced cells are enriched in high MDR-expressing cells after exposure to taxol as assessed by FACS analysis, and by resistance of BFU-E to taxol (Bristol-Myers Squibb, Princeton, NJ). These studies indicate the feasibility of using MDR gene transfer as a means of enriching marrow for MDR-transduced cells. They also provide the basis of a phase 1 clinical protocol in patients with advanced cancers not involving the bone marrow for the use of MDR gene transfer as a means of protecting marrow cells, which normally express low levels of MDR, from the myelosuppressive effects of drugs like taxol.

Mouse fetal liver cells lack functional amphotropic retroviral receptors.

We have been transducing mouse hematopoietic cells with the human MDR1 (MDR) gene in retroviral vectors to determine the optimal conditions for retroviral gene transfer as a model system for potential human gene therapy. In these studies, we have demonstrated transduction and expression of the human MDR gene using ecotropic and amphotropic MDR-retroviral producer lines. To obtain more mouse hematopoietic cells for detailed study, mouse fetal liver cells (FLC) have been used for MDR transduction and expression, and to reconstitute the ablated marrows of live adult mice. FLC contain hematopoietic cells that have a reconstituting capacity comparable to that of adult mouse bone marrow cells. However, to our surprise, FLC can only be transduced with ecotropic retrovirus and not with amphotropic virus. This restriction of transduction of FLC cannot be overcome by higher titer virus. The resistance to amphotropic transduction by FLC may be part of a changing developmental program that results in a different antigen repertoire on FLC as compared with adult bone marrow cells.

Use of gene therapy to induce human-mouse xenogeneic chimerism.

BACKGROUND: Bone marrow transplantation (BMT) has been used in the laboratory to overcome the immunologic barriers to xenotransplantation and results in chimerism and specific tolerance to donor antigens in lethally irradiated mice. Clinically, BMT carries the considerable risks of graft-versus-host disease and graft failure. Retrovirus-mediated gene transfer could provide a means of introducing foreign major histocompatibility (MHC) genes into host bone marrow cells (BMC) and thus accomplish the immunologic goals of BMT, without the associated risks. METHODS: Using a Moloney virus-based vector, a replication defective retrovirus was constructed that contained a complementary DNA encoding the human MHC antigen HLA-A2. Three million C57BL/6 mouse BMC were cocultured for 48 hours with 1 x 10(6) HLA-A2 virus "producer" cells in the presence of 15% WEHI supernatant (interleukin-3) and 200 units/ml interleukin-6. Putatively infected BMC were then used at 2 to 3 x 10(6) BMC/animal to reconstitute lethally irradiated syngeneic mice. RESULTS: Twelve days after reconstitution, spleen colonies were found to have integrated the full-length retroviral sequences. Thirty days after BMT, the introduced DNA could be found in the bone marrow, thymus, and spleen, and approximately 5% of T cells in the spleen expressed the HLA-A2 surface antigen. CONCLUSIONS: These data show that xenogeneic MHC genes can be introduced and expressed in mouse hematopoietic cells in vivo and indicate that gene therapy potentially may be used in the future to manipulate the immune system to induce transplantation tolerance.

Long-term high-level expression of human beta-globin occurs following transplantation of transgenic marrow into irradiated mice.

When the human beta-globin gene is transferred into the bone marrow cells of live mice, its expression is very low. To investigate the reason for this, we transferred the bone marrow of transgenic mice containing and expressing the human beta-globin into irradiated recipients. We demonstrate that long-term high level expression of the human beta-globin gene can be maintained in the marrow and blood of irradiated recipients following transplantation. Although expression decreased over time in most animals because of host marrow reconstitution, the ratio of human beta-globin transgene expression to endogenous mouse beta-globin gene expression in donor-derived erythroid cells remained constant over time. We conclude that there is no inherent limitation to efficient expression of an exogenous human beta-globin gene in mouse bone marrow cells following marrow transplantation.

Transfer and expression of the human multidrug resistance gene in mouse erythroleukemia cells.

Gene therapy in humans requires the transplantation of genetically modified cells, and it is important to select only those cells capable of expressing high levels of protein from the transferred gene. Expression of the human multiple drug resistance (MDR) gene confers resistance to a variety of compounds in vitro and in vivo. To determine the feasibility of conferring recipient erythroid cells with the MDR phenotype, we have transduced mouse erythroleukemia cells (MELC) with the MDR gene in a retroviral vector. We show here that MELC clones resistant to exposure to colchicine (an MDR-responsive agent) can be isolated, and demonstrate high levels of MDR RNA and protein expression. Increasing doses of colchicine increase the level of MDR RNA and protein expression significantly. These results indicate that it is possible to transfer and express the human MDR phenotype in mouse erythroid cells by retrovirally mediated gene transfer, and that drug selection can be used to enrich or purify populations of cells containing and expressing this gene.

Transfer and expression of the human multiple drug resistance gene into live mice.

The human multiple drug resistance (MDR) gene has been used as a selectable marker to increase the proportion of bone marrow cells that contain and express this gene by drug selection. By constructing retroviral vectors containing and expressing the MDR gene and a nonselectable gene such as the beta-globin gene, enrichment for cells containing both of these genes can be achieved. A retroviral construct containing MDR cDNA in a Harvey virus-based vector has been used to transfect our ecotropic 3T3 retroviral packaging line GP+E86. Clones have been isolated by exposure of the retrovirally transfected cells (MDR producer cells) to colchicine (60 ng/ml), a selective agent that kills MDR-negative cells. Flow cytometry analysis (fluorescence-activated cell sorting) with an antibody to MDR demonstrates expression of human MDR protein on the surface of these colchicine-resistant producer clones. Untransfected GP+E86 cells are negative. Colchicine-resistant clones were titered using clone supernatants and the highest titer clone (4 x 10(4) viral particles per ml) was cocultured with 10(6) donor mouse bone marrow cells for 24-48 hr. The donor cells were then injected into congenic irradiated mice, and the presence of the MDR gene was assayed by the polymerase chain reaction (PCR) analysis using MDR-specific primers. In one experiment eight of nine transduced mice were positive for MDR by PCR of peripheral blood 14 and 50 days posttransplantation; after 240 days three of nine transduced mice were positive. Bone marrow obtained from one of these positive animals was stained with the MDR monoclonal antibody and the granulocyte population was analyzed by FACS. Approximately 14% of the total granulocyte pool contain increased levels of MDR protein. In addition, the bone marrow cells of several mice initially positive for MDR gene by PCR, and subsequently negative, were exposed to taxol, a drug whose detoxification depends on MDR gene expression; a positive signal was obtained in all of these mice, indicating drug selection of MDR-positive marrow cells. Cell sorting studies of these mice also show an increased number of high-MDR-expressing marrow cells, selected after exposure to taxol. Thus, in this live animal model MDR transduction is effective in selecting a human MDR-expressing population of marrow cells resistant to taxol chemotherapy. This strategy may, thus, be useful in humans to prevent the marrow toxicity induced by anticancer agents such as taxol and as a selectable marker to enrich for cells simultaneously transduced with a nonselectable gene.