Transthyretin mouse transgenes direct RFP expression or Cre‐mediated recombination throughout the visceral endoderm

Transthyretin (Ttr) is a thyroid hormone transport protein secreted by cells of the visceral yolk sac and fetal liver in developing embryos, and by hepatocytes and the choroid plexus epithelium of the brain in adult mice. Spatiotemporal localization of Ttr mRNA during embryogenesis suggested that Ttr regulatory elements might drive transgene expression throughout the visceral endoderm of early mouse embryos. We use Ttr cis‐regulatory elements to generate Ttr::RFP and Ttr::Cre strains of mice, driving red fluorescent protein (RFP) and a nuclear‐localized Cre recombinase, respectively. Visualization of RFP fluorescence in Ttr::RFP transgenics confirms reporter localization throughout the visceral endoderm in early embryos and in the visceral yolk sac and fetal liver of later stage embryos. Using both GFP‐based and LacZ‐based Cre reporter strains, we demonstrate that in Ttr::Cre transgenics, Cre‐mediated recombination occurs throughout the visceral endoderm. The Ttr::Cre strain can therefore be used as a tool for genetic modifications within the visceral endoderm lineage. genesis 47:447–455, 2009. © 2009 Wiley‐Liss, Inc.     

Development of Lactococcus lactis encoding fluorescent proteins,GFP, mCherry and iRFP regulated by the nisin-controlled gene expression system

Fluorescent proteins are useful reporter molecules for a variety of biological systems. We present an alternative strategy for cloning reporter genes that are regulated by the nisin-controlled gene expression (NICE) system. Lactoccocus lactis was genetically engineered to express green fluorescent protein (GFP), mCherry or near-infrared fluorescent protein (iRFP). The reporter gene sequences were optimized to be expressed by L. lactis using inducible promoter pNis within the pNZ8048 vector. Expression of constructions that carry mCherry or GFP was observed by fluorescence microscopy 2 h after induction with nisin. Expression of iRFP was evaluated at 700 nm using an infrared scanner; cultures induced for 6 h showed greater iRFP expression than non-induced cultures or those expressing GFP. We demonstrated that L. lactis can express efficiently GFP, mCherry and iRFP fluorescent proteins using an inducible expression system. These strains will be useful for live cell imaging studies in vitro or for imaging studies in vivo in the case of iRFP.     

Ubiquitous expression of the monomeric red fluorescent protein mcherry in transgenic mice

The use of the green fluorescent protein (GFP) to label specific cell types and track gene expression in animal models, such as mice, has evolved to become an essential tool in biological research. Transgenic animals expressing genes of interest linked to GFP, either as a fusion protein or transcribed from an internal ribosomal entry site (IRES) are widely used. Enhanced GFP (eGFP) is the most common form of GFP used for such applications. However, a red fluorescent protein (RFP) would be highly desirable for use in dual‐labeling applications with GFP derived fluorescent proteins, and for deep in vivo imaging of tissues. Recently, a new generation of monomeric (m)RFPs, such as monomeric (m)Cherry, has been developed that are potentially useful experimentally. mCherry exhibits brighter fluorescence, matures more rapidly, has a higher tolerance for N‐terminal fusion proteins, and is more photostable compared with its predecessor mRFP1. mRFP1 itself was the first true monomer derived from its ancestor DsRed, an obligate tetramer in vivo. Here, we report the successful generation of a transgenic mouse line expressing mCherry as a fluorescent marker, driven by the ubiquitin‐C promoter. mCherry is expressed in almost all tissues analyzed including pre‐ and post‐implantation stage embryos, and white blood cells. No expression was detected in erythrocytes and thrombocytes. Importantly, we did not encounter any changes in normal development, general physiology, or reproduction. mCherry is spectrally and genetically distinct from eGFP and, therefore, serves as an excellent red fluorescent marker alone or in combination with eGFP for labelling transgenic animals. genesis 48:723–729, 2010. © 2010 Wiley‐Liss, Inc.     

Characterization of bacterial artificial chromosome transgenic mice expressing mCherry fluorescent protein substituted for the murine smooth muscle α‐actin gene

Smooth muscle α actin (SMA) is a cytoskeletal protein expressed by mesenchymal and smooth muscle cell types, including mural cells (vascular smooth muscle cells and pericytes). Using Bacterial Artificial Chromosome (BAC) recombineering technology, we generated transgenic reporter mice that express a membrane localized cherry red fluorescent protein (mCherry), driven by the full‐length SMA promoter and intronic sequences. We determined that the founders and F1 progeny of five independent lines contain 1–3 copies of the mCherry‐substituted BAC vector. Furthermore, we characterized the expression of SMA‐mCherry in relation to endogenous SMA in the embryo and in adult tissues, and found that the transgenic reporter in each line recapitulated endogenous SMA expression at all time points. We were also able to isolate SMA expressing cells from embryonic tissues using fluorescence‐activated cell sorting (FACS). We demonstrated that this marker can be combined with other vital fluorescent reporters and it can be used for live imaging of embryonic cardiodynamics. Therefore, these transgenic mice will be useful for isolating live SMA‐expressing cells via FACS and for studying the emergence, behavior, and regulation of SMA‐expressing cells, including vascular smooth muscle cells and pericytes throughout embryonic and postnatal development. genesis 48:457–463, 2010. © 2010 Wiley‐Liss, Inc.     

A novel reporter mouse strain that expresses enhanced green fluorescent protein upon Cre-mediated recombination

The success of Cre-mediated conditional gene targeting depends on the specificity of Cre recombinase expression in Cre-transgenic mouse lines. As a tool to evaluate the specificity of Cre expression, we developed a reporter transgenic mouse strain that expresses enhanced green fluorescent protein (EGFP) upon Cre-mediated recombination. We demonstrate that the progeny resulting from a cross between this reporter strain and a transgenic strain expressing Cre in zygotes show ubiquitous EGFP fluorescence. This reporter strain should be useful to monitor the Cre expression directed by various promoters in transgenic mice, including mice in which Cre is expressed transiently during embryogenesis under a developmentally regulated promoter.     

绿色荧光蛋白基因在转基因小鼠体内的表达

建立绿色荧光蛋白（GFP）转基因小鼠,继而传代建系。采用显微注射法,将GFP基因注入FVB／NJ小鼠受精卵原核内,获得子代鼠。分娩后3周剪取仔鼠尾,提取基因组DNA,应用PCR、Southern印迹技术进行整合检测。结共用雌性小鼠200只,注射受精卵1586枚,移植卵数386枚,受体鼠32只,怀孕鼠4只,子代鼠18只,有4只为阳性：取2只首建鼠的胚胎,在荧光显微镜下观察GFP表达明显,表明初步获得了转绿色荧光蛋白基因小鼠,     

A transgenic red fluorescent protein‐expressing nude mouse for color‐coded imaging of the tumor microenvironment

The tumor microenvironment (TME) is critical for tumor growth and progression. We have previously developed color‐coded imaging of the TME using a green fluorescent protein (GFP) transgenic nude mouse as a host. However, most donor sources of cell types appropriate for study in the TME are from mice expressing GFP. Therefore, a nude mouse expressing red fluorescent protein (RFP) would be an appropriate host for transplantation of GFP‐expressing stromal cells as well as double‐labeled cancer cells expressing GFP in the nucleus and RFP in the cytoplasm, thereby creating a three‐color imaging model of the TME. The RFP nude mouse was obtained by crossing non‐transgenic nude mice with the transgenic C57/B6 mouse in which the β‐actin promoter drives RFP (DsRed2) expression in essentially all tissues. In crosses between nu/nu RFP male mice and nu/+ RFP female mice, the embryos fluoresced red. Approximately 50% of the offspring of these mice were RFP nude mice. In the RFP nude mouse, the organs all brightly expressed RFP, including the heart, lungs, spleen, pancreas, esophagus, stomach, duodenum, the male and female reproductive systems; brain and spinal cord; and the circulatory system, including the heart, and major arteries and veins. The skinned skeleton highly expressed RFP. The bone marrow and spleen cells were also RFP positive. GFP‐expressing human cancer cell lines, including HCT‐116‐GFP colon cancer and MDA‐MB‐435‐GFP breast cancer were orthotopically transplanted to the transgenic RFP nude mice. These human tumors grew extensively in the transgenic RFP nude mouse. Dual‐color fluorescence imaging enabled visualization of human tumor–host interaction. The RFP nude mouse model should greatly expand our knowledge of the TME. J. Cell. Biochem. 106: 279–284, 2009. © 2008 Wiley‐Liss, Inc.     

Variability of Inducible Expression across the Hematopoietic System of Tetracycline Transactivator Transgenic Mice

The tetracycline (tet)-regulated expression system allows for the inducible overexpression of protein-coding genes, or inducible gene knockdown based on expression of short hairpin RNAs (shRNAs). The system is widely used in mice, however it requires robust expression of a tet transactivator protein (tTA or rtTA) in the cell type of interest. Here we used an in vivo tet-regulated fluorescent reporter approach to characterise inducible gene/shRNA expression across a range of hematopoietic cell types of several commonly used transgenic tet transactivator mouse strains. We find that even in strains where the tet transactivator is expressed from a nominally ubiquitous promoter, the efficiency of tet-regulated expression can be highly variable between hematopoietic lineages and between differentiation stages within a lineage. In some cases tet-regulated reporter expression differs markedly between cells within a discrete, immunophenotypically defined population, suggesting mosaic transactivator expression. A recently developed CAG-rtTA3 transgenic mouse displays intense and efficient reporter expression in most blood cell types, establishing this strain as a highly effective tool for probing hematopoietic development and disease. These findings have important implications for interpreting tet-regulated hematopoietic phenotypes in mice, and identify mouse strains that provide optimal tet-regulated expression in particular hematopoietic progenitor cell types and mature blood lineages.     

Dual promoter expression system with insulator ensures a stringent tissue-specific regulation of two reporter genes in the transgenic fish

The precise control of spatiotemporal expression of target genes is crucial when establishing transgenic animals, and the introduction of genes for fluorescent marker proteins is inevitable for accelerating research at molecular levels. To assist this, we constructed a novel dual promoter expression vector for two independent reporter genes, green fluorescent protein (GFP) and red fluorescent protein (mCherry). Their expression is designed under the control of two distinct tissue-specific promoters, e.g. zebrafish cardiac muscle-specific promoter (cmlc2) and medaka skeletal muscle-specific promoter (myl2) derived from the myosin light chain 2 genes, and they are placed in a head-to-head orientation. After microinjecting the dual promoter expression vector into fertilized eggs of medaka, the developing fish embryos and the resulting transgenic fish lines showed strong GFP signal in the whole body (skeletal muscle) and mCherry signal in the heart (cardiac muscle). However, weak GFP signal was observed in the heart, indicating a leakiness of the skeletal muscle promoter. To improve the stringency of dual promoter expression, we inserted two chicken-derived insulators, e.g. tandem copies of the core sequence (250 bp) of cHS4 (5′-hypersensitive site-4 chicken beta-globin insulator), in the boundary of two promoters. The dual promoter expression vector with insulator now ensured the stringent tissue-specific expression in the transgenic fish lines. Thus, our dual promoter expression system with insulator is compatible to the conventional IRES and fused reporter gene systems and will be an alternative method to produce the transgenic fishes.     

Green fluorescent protein as a marker in transgenic mice

Green fluorescent protein (GFP) found in Aequorea victoria absorbs blue light and emits green fluorescence without exogenous substrates or co-factors. We studied the possibility of using the GFP as a marker in mammals. Transgenic mice were produced using the GFP coding sequence, ligated with the chicken beta-actin promoter. Green fluorescence was observed in muscle, pancreas, kidney, heart and other organs in all the three transgenic mouse lines. Detection of the transgenic mouse was possible by observing a tail or fingers of new born pups under a fluorescent microscope. The marker also enabled us to detect localized expression of the transgene in intact tissues without preliminary steps. It was also demonstrated that the GFP expression could be quantified by measuring the fluorescence in tissue extracts.     

In vivo cell tracking of mouse embryonic myoblasts and fast fibers during development

Fast and slow TnI are co‐expressed in E11.5 embryos, and fast TnI is present from the very beginning of myogenesis. A novel green fluorescent protein (GFP) reporter mouse lines (FastTnI/GFP lines) that carry the primary and secondary enhancer elements of the mouse fast troponin I (fast TnI), in which reporter expression correlates precisely with distribution of the endogenous fTnI protein was generated. Using the FastTnI/GFP mouse model, we characterized the early myogenic events in mice, analyzing the migration of GFP+ myoblasts, and the formation of primary and secondary myotubes in transgenic embryos. Interestingly, we found that the two contractile fast and slow isoforms of TnI are expressed during the migration of myoblasts from the somites to the limbs and body wall, suggesting that both participate in these events. Since no sarcomeres are present in myoblasts, we speculate that the function of fast TnI in early myogenesis is, like Myosin and Tropomyosin, to participate in cell movement during the initial myogenic stages. genesis 52:793–808, 2014. © 2014 Wiley Periodicals, Inc.     

Disabled-2 is essential for endodermal cell positioning and structure formation during mouse embryogenesis

The signal transduction adapter protein Disabled-2 (Dab2) is one of the two mammalian orthologs of the Drosophila Disabled. The brain-specific Disabled-1 (Dab1) functions in positional organization of brain cells during development. Dab2 is widely distributed and is highly expressed in many epithelial cell types. The dab2 gene was interrupted by in-frame insertion of beta-galactosidase (LacZ) in embryonic stem cells and transgenic mice were produced. Dab2 expression was first observed in the primitive endoderm at E4.5, immediately following implantation. The homozygous Dab2-deficient mutant is embryonic lethal (earlier than E6.5) due to defective cell positioning and structure formation of the visceral endoderm. In E5.5 dab2 (-/-) conceptus, visceral endoderm-like cells are present in the deformed primitive egg cylinder; however, the visceral endoderm cells are not organized, the cells of the epiblast have not expanded, and the proamniotic cavity fails to form. Disorganization of the visceral endodermal layer is evident, as cells with positive visceral endoderm markers are scattered throughout the dab2 (-/-) conceptus. Only degenerated remains were observed at E6.5 for dab2 (-/-) embryos, and by E7.5, the defective embryos were completely reabsorbed. In blastocyst in vitro culture, initially cells with characteristics of endoderm, trophectoderm, and inner cell mass were observed in the outgrowth of the hatched dab2 (-/-) blastocysts. However, the dab2 (-/-) endodermal cells are much more dispersed and disorganized than those from wild-type blastocysts, the inner cell mass fails to expand, and the outgrowth degenerates by day 7. Thus, Dab2 is required for visceral endodermal cell organization during early mouse development. The absence of an organized visceral endoderm in Dab2-deficient conceptus leads to the growth failure of the inner cell mass. We suggest that Dab2 functions in a signal pathway to regulate endodermal cell organization using endocytosis of ligands from the blastocoel cavity as a positioning cue.