A novel panel of mouse models to evaluate the role of human pregnane X receptor and constitutive androstane receptor in drug response.

The pregnane X receptor (PXR) and the constitutive androstane receptor (CAR) are closely related orphan nuclear hormone receptors that play a critical role as xenobiotic sensors in mammals. Both receptors regulate the expression of genes involved in the biotransformation of chemicals in a ligand-dependent manner. As the ligand specificity of PXR and CAR have diverged between species, the prediction of in vivo PXR and CAR interactions with a drug are difficult to extrapolate from animals to humans. We report the development of what we believe are novel PXR- and CAR-humanized mice, generated using a knockin strategy, and Pxr- and Car-KO mice as well as a panel of mice including all possible combinations of these genetic alterations. The expression of human CAR and PXR was in the predicted tissues at physiological levels, and splice variants of both human receptors were expressed. The panel of mice will allow the dissection of the crosstalk between PXR and CAR in the response to different drugs. To demonstrate the utility of this panel of mice, we used the mice to show that the in vivo induction of Cyp3a11 and Cyp2b10 by phenobarbital was only mediated by CAR, although this compound is described as a PXR and CAR activator in vitro. This panel of mouse models is a useful tool to evaluate the roles of CAR and PXR in drug bioavailability, toxicity, and efficacy in humans.

CD41-YFP mice allow in vivo labeling of megakaryocytic cells and reveal a subset of platelets hyperreactive to thrombin stimulation.

OBJECTIVE: Development of a mouse line permitting live imaging of cells expressing CD41/GpIIb as a means to study megakaryopoiesis. MATERIALS AND METHODS: The gene encoding yellow fluorescent protein (eyfp) was inserted by homologous recombination into embryonic stem cells at the start site of the gpIIb locus. A knockin mouse line, designated CD41-yellow fluorescent protein (YFP), was developed and was characterized by fluorescence microscopy and flow cytometry. Activity of YFP(+) platelets was determined by induction of P-selectin expression in response to thrombin stimulation. RESULTS: CD41-YFP mice contained YFP-labeled megakaryocytes and platelets, the proportions of which varied, depending on the genotype and individual animal, while lymphoid, myelomonocytic, and erythroid lineages were negative. In addition, a fraction of hematopoietic stem cells and intermediate progenitors expressed YFP at low levels. Crossing CD41-YFP mice with lysozyme green fluorescent protein and globin cyan fluorescent protein mice, followed by in vivo imaging of fetal liver, revealed megakaryocytic cells as a subset distinct from myeloid and erythroid cells. This experiment is also the first to show the distribution of three hematopoietic lineages in a minimally perturbed organ. Surprisingly, analysis of CD41-YFP platelets showed that the YFP(+) subset is more responsive to thrombin stimulation than the YFP(-) subset. Experiments aimed at determining the stability of the YFP(+) platelets showed that after lethal irradiation of CD41-YFP mice, the proportion of labeled platelets in the blood declines more rapidly than the bulk of the platelets. CONCLUSION: The newly developed mouse line should become useful not only for in vivo imaging experiments of megakaryocytes and platelets, but also for studies on platelet aging and function. Our irradiation experiments suggest that the YFP(+) platelets are enriched for newly made cells because YFP has a shorter half-life than platelets. Therefore, the finding that YFP(+) platelets are more responsive to thrombin stimulation raises the possibility that platelet activity decreases rapidly during physiological aging.

Enhanced efficiency through nuclear localization signal fusion on phage PhiC31-integrase: activity comparison with Cre and FLPe recombinase in mammalian cells.

The integrase of the phage PhiC31 recombines an attP site in the phage genome with a chromosomal attB site of its Streptomyces host. We have utilized the integrase-mediated reaction to achieve episomal and genomic deletion of a reporter gene in mammalian cells, and provide the first comparison of its efficiency with other recombinases in a new assay system. This assay demonstrated that the efficiency of PhiC31-integrase is significantly enhanced by the C-terminal, but not the N-terminal, addition of a nuclear localization signal and becomes comparable with that of the widely used Cre/loxP system. Furthermore, we found that the improved FLP recombinase, FLPe, exhibits only 10% recombination activity on chromosomal targets as compared with Cre, whereas the Anabaena derived XisA recombinase is essentially inactive in mammalian cells. These results provide the first demonstration that a nuclear localisation signal and its position within a recombinase can be important for its efficiency in mammalian cells and establish the improved PhiC31-integrase as a new tool for genome engineering.

Rapid generation of inducible mouse mutants.

We have generated an optimized inducible recombination system for conditional gene targeting based on a Cre recombinase-steroid receptor fusion. This configuration allows efficient Cre-mediated recombination in most organs of the mouse upon induction, without detectable background activity. An ES cell line, was established that carries the inducible recombinase and a loxP-flanked lacZ reporter gene. Out of this line, completely ES cell-derived mice were efficiently produced through tetraploid blastocyst complementation, without the requirement of mouse breeding. Our findings provide a new concept allowing the generation of inducible mouse mutants within 6 months, as compared to 14 months using the current protocol.

Comparison of the microbicidal and muramidase activities of mouse lysozyme M and P.

Lysozyme is one of the most abundant antimicrobial proteins in the airspaces of the lung. Mice express two lysozyme genes, lysozyme M and P, but only the M enzyme is detected in abundance in lung tissues. Disruption of the lysozyme M locus significantly increased bacterial burden and mortality following intratracheal infection with a Gram-negative bacterium. Unexpectedly, significant lysozyme enzyme activity (muramidase activity) was detected in the airspaces of uninfected lysozyme M-/- mice, amounting to 25% of the activity in wild-type mice. Muramidase activity in lysozyme M-/- mice was associated with increased lysozyme P mRNA and protein in lung tissue and bronchoalveolar lavage fluid respectively. The muramidase activity of recombinant lysozyme P was less than that of recombinant M lysozyme. Recombinant P lysozyme was also less effective in killing selected Gram-negative bacteria, requiring higher concentrations than lysozyme M to achieve the same level of killing. The lower antimicrobial activity of P lysozyme, coupled with incomplete compensation by P lysozyme in lysozyme M-/- mice, probably accounts for the increased susceptibility of null mice to infection. Recombinant lysozyme M and P were equally effective in killing selected Gram-positive organisms. This outcome suggests that disruption of both M and P loci would significantly increase susceptibility to airway infections, particularly those associated with colonization by Gram-positive organisms.

High-throughput transfection and engineering of primary cells and cultured cell lines - an invaluable tool for research as well as drug development.

The manipulation of eukaryotic cells by introducing nucleic acids and other substrates using chemical, physical or viral methods is one of the ground-breaking tools in the life sciences. Changes in the molecular equipment of a cell induced by introducing different molecules not only enable the dissection of signal transduction and metabolic pathways, but also allow the exploitation of engineered cells as bio-factories for the production of proteins in the processes of target research and drug development. In addition to the application of engineered cells for modern cell-based assays, medically relevant engineered cells can be used in clinical settings for adoptive immunotherapy or gene therapy. With the advent of methods exploiting RNA interference (RNAi), gene identification and functional validation in eukaryotic cells have clearly become one of the most exciting methods in life sciences during the past few years. To accelerate research and development in these areas, high-quality, high-throughput approaches (i.e., using sample formats of at least 96 wells) for cell engineering are needed with increasing demand. Recent developments, especially in the field of electroporation, now allow the efficient, high-throughput engineering of virtually any cell type, including primary cells, many of which were previously considered difficult or even impossible to transfect. Primary cells freshly isolated from native tissues are gaining more and more interest, as data obtained with these cells are considered to be of higher physiological relevance than data obtained with immortalized cell lines that have been cultured for extensive periods. In this review, the various methods for cell engineering (with focus on higher eukaryotic cells) are summarized and their impact for high-throughput applications in research and drug development is discussed.