Ignacio Anegon

Knockout Rats via Embryo Microinjection of Zinc-Finger Nucleases

Targeted gene disruption in rats paves the way for new human disease models. The toolbox of rat genetics currently lacks the ability to introduce site-directed, heritable mutations into the genome to create knockout animals. By using engineered zinc-finger nucleases (ZFNs) designed to target an integrated reporter and two endogenous rat genes, Immunoglobulin M (IgM) and Rab38, we demonstrate that a single injection of DNA or messenger RNA encoding ZFNs into the one-cell rat embryo leads to a high frequency of animals carrying 25 to 100% disruption at the target locus. These mutations are faithfully and efficiently transmitted through the germline. Our data demonstrate the feasibility of targeted gene disruption in multiple rat strains within 4 months time, paving the way to a humanized monoclonal antibody platform and additional human disease models.

Knockout rats generated by embryo microinjection of TALENs.

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A critical role for transforming growth factor-beta in donor transfusion-induced allograft tolerance.

Donor-specific (DST) or nonspecific blood transfusions administered before transplantation can enhance survival of vascularized allografts both in humans and animals but the immunological mechanisms of this effect remain unclear. We have analyzed the expression and the role of endogenous TGF-beta1 in a model of heart allograft tolerance, induced by pregraft DST in adult rats. We reported previously that this tolerance occurs despite a strong infiltration of leukocytes into the graft that are unable to produce both Th1- and Th2-related cytokines in vivo. Allografts from DST-treated rats express high levels of TGF-beta1 mRNA and active protein. This phenomenon is correlated with the rapid infiltration of leukocytes producing high amounts of TGF-beta1. TGF-beta1-producing cells are virtually absent among early infiltrating cells in rejected grafts but are found at a later time point. The induction of allograft tolerance in vivo is abrogated by administration of neutralizing anti-TGF-beta mAb. Moreover, overexpression of active TGF- beta1 in heart allografts using a recombinant adenovirus leads to prolonged graft survival in unmodified recipients. Taken together, our results identify TGF-beta as a critical cytokine involved in the suppression of allograft rejection induced by DST and suggest that TGF-beta-producing regulatory cells are also involved in allograft tolerance.

CD40Ig treatment results in allograft acceptance mediated by CD8+CD45RClow T cells, IFN-γ, and indoleamine 2,3-dioxygenase

Treatment with CD40Ig results in indefinite allograft survival in a complete MHC-mismatched heart allograft model in the rat. Here we show that serial second, third, and fourth adoptive transfers of total splenocytes from CD40Ig-treated recipients into secondary recipients led to indefinite donor-specific allograft acceptance. Purification of splenocyte subpopulations from CD40Ig-treated recipients demonstrated that only the adoptively transferred CD8(+)CD45RC(low) subset resulted in donor-specific long-term survival, whereas CD8(+)CD45RC(low) T cells from naive animals did not. Accepted grafts displayed increased indoleamine 2,3-dioxygenase (IDO) expression restricted in the graft to ECs. Coculture of donor ECs with CD8(+)CD45RC(low) T cells purified from CD40Ig-treated animals resulted in donor-specific IDO expression dependent on IFN-gamma. Neutralization of IFN-gamma or IDO triggered acute allograft rejection in both CD40Ig-treated and adoptively transferred recipients. This study demonstrates for what we believe to be the first time that interference in CD40-CD40 ligand (CD40-CD40L) interactions induces allospecific CD8(+) Tregs that maintain allograft survival. CD8(+)CD45RC(low) T cells act through IFN-gamma production, which in turn induces IDO expression by graft ECs. Thus, donor alloantigen-specific CD8(+) Tregs may promote local graft immune privilege through IDO expression.

Endothelial-to-Mesenchymal Transition in Pulmonary Hypertension

Background— The vascular remodeling responsible for pulmonary arterial hypertension (PAH) involves predominantly the accumulation of &agr;-smooth muscle actin–expressing mesenchymal-like cells in obstructive pulmonary vascular lesions. Endothelial-to-mesenchymal transition (EndoMT) may be a source of those &agr;-smooth muscle actin–expressing cells. Methods and Results— In situ evidence of EndoMT in human PAH was obtained by using confocal microscopy of multiple fluorescent stainings at the arterial level, and by using transmission electron microscopy and correlative light and electron microscopy at the ultrastructural level. Findings were confirmed by in vitro analyses of human PAH and control cultured pulmonary artery endothelial cells. In addition, the mRNA and protein signature of EndoMT was recognized at the arterial and lung level by quantitative real-time polymerase chain reaction and Western blot analyses. We confirmed our human observations in established animal models of pulmonary hypertension (monocrotaline and SuHx). After establishing the first genetically modified rat model linked to BMPR2 mutations (BMPR2&Dgr;140Ex1/+ rats), we demonstrated that EndoMT is linked to alterations in signaling of BMPR2, a gene that is mutated in 70% of cases of familial PAH and in 10% to 40% of cases of idiopathic PAH. We identified molecular actors of this pathological transition, including twist overexpression and vimentin phosphorylation. We demonstrated that rapamycin partially reversed the protein expression patterns of EndoMT, improved experimental PAH, and decreased the migration of human pulmonary artery endothelial cells, providing the proof of concept that EndoMT is druggable. Conclusions— EndoMT is linked to alterations in BPMR2 signaling and is involved in the occlusive vas cular remodeling of PAH, findings that may have therapeutic implications.

Transgenesis in rats: Technical aspects and models

The production of transgenic rats by DNA-microinjection into fertilizer ova has now become an established procedure, although fewer than 20 lines have been described during the last 5 years. Overall, transgenic rats remain more difficult to produce than transgenic mice, but satisfactory yields have been obtained by several laboratories. A review of the methods used to generate transgenic rats shows considerable variation between different laboratories, particularly in choice of strain, superovulation protocols and the use of embryo culture before reimplantation. In some instances, the production of transgenic rats has provided data that are new and relevant, compared to data obtained in mice bearing the same transgene. Models have been developed for human diseases such as hypertension and autoimmunity, and applications have been found in the study of carcinogenesis and in pharmacological research. Transgenic rat technology also opens up interesting perspectives for transplantation research, in which microsurgery is an essential procedure. Intensive research is in progress in several laboratories to produce rat embryonic stem (ES) cell lines, but existing lines have not participated in germ line formation a prerequisite for their use in gene knock out experiments.

Gene Transfer of Heme Oxygenase‐1 and Carbon Monoxide Delivery Inhibit Chronic Rejection

The hallmark of chronic rejection is the occlusion of the artery lumen by intima hyperplasia as a consequence of leukocyte infiltration and vascular smooth muscle cell (VSMC) migration and proliferation. Heme oxygenase‐1 (HO‐1) is a tissue protective molecule which degrades heme into carbon monoxide (CO), free iron and biliverdin. We analyzed the effects of HO‐1 gene transfer into the vessel wall using an adenoviral vector (AdHO‐1) and of CO delivery in a model of chronic allogeneic aorta rejection in rats. Carbon monoxide treatment was achieved by a new pharmacological approach in transplantation using methylene chloride (MC), which releases CO after degradation. AdHO‐1‐mediated gene transfer into aorta endothelial cells (ECs) or CO delivery resulted in a significant reduction in intimal thickness compared to untreated or noncoding adenovirus‐treated controls. Aortas transduced with AdHO‐1 or treated with CO showed a reduction in the number of leukocytes as well as in the expression of adhesion molecules, costimulatory molecules and cytokines, with the gene transfer treatment displaying a more pronounced effect than the CO treatment. Conversely, CO inhibited VSMC accumulation in the intima more efficiently than AdHO‐1 treatment. Gene transfer of HO‐1 and pharmacological manipulation of CO are novel approaches to the analysis and treatment of chronic rejection.

Zinc-finger nucleases: a powerful tool for genetic engineering of animals.

The generation of genetically modified animals or plants with gene-targeted deletions or modifications is a powerful tool to analyze gene function, study disease and produce organisms of economical interest. Until recently, the generation of animals with gene targeted manipulations has been accomplished by homologous recombination (HR) in embryonic stem (ES) cells or cloning through nuclear transfer and has been limited to a few species. Recently, a new technology based on the use of gene-targeted zinc-finger nucleases (ZFNs) was developed and used for the generation of organisms with gene-targeted deletions and/or modifications when combined with HR. ZFNs have been used to generate modified organisms such as plants, Drosophila, zebra fish and rats with gene-targeted mutations. This perspective manuscript is a short review on the use of ZFNs for the genetic engineering of plants and animals, with particular emphasis on our recent work involving rats. We also discuss the application of other targeted nucleases, including homing endonucleases. Microinjection of plasmid or mRNA for ZFNs into rat embryos allowed targeted, rapid, complete, permanent and heritable disruption of endogenous loci. The application of ZFNs to generate gene-targeted knockouts in species where ES cells or cloning techniques are not available is an important new development to answer fundamental biological questions and develop models of economical interest such as for the production of humanized antibodies. Further refinements of ZFN technology in combination with HR may allow knock-ins in early embryos even in species where ES cells or cloning techniques are available.

Heme oxygenase-1 inhibits rat and human breast cancer cell proliferation: mutual cross inhibition with indoleamine 2,3-dioxygenase

Heme oxygenase‐1 (HO‐1) is the rate limiting enzyme of heme catabolism whereas indoleamine 2,3 dioxygenase (IDO) catabolizes tryptophan through the kynurenine pathway. We analyzed the expression and biological effects of these enzymes in rat and human breast cancer cell lines. We show that rat (NMU and 13762) but not human cells (MCF‐7 and T47D) express HO‐1. When overexpressed, we found this enzyme to have anti‐proliferative and proapoptotic effects by antioxidant mechanisms in these four cell lines. We show that IDO is expressed by rat and human breast cancer cells. IDO inhibition with 1‐MT and siRNA leads to diminished proliferation in rat cells. In contrast, HO‐1 negative human cell lines increase proliferation upon IDO inhibition. Since we also demonstrate that IDO inhibits the anti‐proliferative HO‐1, we propose that IDO has opposite effects on proliferation depending on the coexpression or not of HO‐1. We also describe that HO‐1 inhibits IDO at the post‐translational level through heme starvation. In vivo, we show that rat normal breast expresses HO‐1 and IDO. In contrast, N‐nitrosomethylurea‐induced breast adenocarcinomas only express IDO. In conclusion, we show that HO‐1/IDO cross‐regulation modulates apoptosis and proliferation in rat and human breast cancer cells.—Hill, M., Pereira, V., Chauveau, C., Zagani, R., Remy, S., Tesson, L., Mazal, D., Ubillos, L., Brion, R., Ashgar, K., Mashreghi, M. F., Kotsch, K., Moffett, J., Doebis, C., Seifert, M., Boczkowski, J., Osinaga, E., Anegon, I. Heme oxygenase‐1 inhibits rat and human breast cancer cells proliferation: mutual cross inhibition with indoleamine 2,3‐dioxygenase. FASEB J. 19, 1957–1968 (2005)

A Nonionic Amphiphile Agent Promotes Gene Delivery In Vivo to Skeletal and Cardiac Muscles

Direct injection of naked DNA into skeletal or cardiac muscle induces detectable gene expression. Although this provides a practical system for transgene expression, the reported efficacy is too low to confer a therapeutic benefit. By following a rational strategy based on the supramolecular structures adopted by active complexes, we have discovered a novel nonionic amphiphile synthetic agent [poly(ethyleneoxide)(13)-poly(propyleneoxide)(30)-poly(ethyleneoxide)(13) block copolymer; PE6400] that enables gene expression in up to 35% of muscle fibers from mouse tibial cranial muscle. PE6400 abolishes the ceiling effect on transgene expression of increasing amounts of naked DNA and permits long-term expression of the beta-galactosidase reporter gene in immunologically tolerant transgenic rats. This improvement in gene expression over naked DNA was observed irrespective of the reporter gene, ranging from 0.7 to 3.4 kb, and of the animal model used. In skeletal muscle, the PE6400 formulation led to a level of transfection efficiency similar to that obtained by electrotransfer. PE6400 also promotes high transgene expression in cardiac muscle. In contrast, PE6400-DNA formulations were inefficient in vitro in established cell lines and in isolated cardiomyocytes. When microinjected into the cell cytoplasm, PE6400 promotes DNA trafficking into the nucleus and induces gene expression. PE6400 provides a simple gene delivery system for skeletal and myocardial gene transfer. We propose that the PE6400 formulation could serve for the treatment of diseases primarily affecting muscle or for the expression of therapeutic proteins for local or systemic benefit.