Generation of B6‐Ddx4em1(CreERT2)Utr,a novel CreERT2 knock‐in line,for germ cell lineage by CRISPR/Cas9

Germ cell development is essential for maintaining reproduction in animals. In postpubertal females, oogenesis is a highly complicated event for producing fertilizable oocytes. It starts when dormant primordial oocytes undergo activation to become growing oocytes. In postpubertal males, spermatogenesis is a differentiation process for producing sperm from spermatogonial stem cells. To obtain full understanding of the molecular mechanisms underlying germ cell development, the Cre/loxP system has been widely applied for conditional knock‐out mouse studies. In this study, we established a novel knock‐in mouse line, B6‐Ddx4 ^{em1(CreERT2)Utr}, which expresses CreERT2 recombinase under the control of the endogenous DEAD‐box helicase 4 (Ddx4) gene promoter. Ddx4 was specifically expressed in both female and male germ cell lineages. We mated the CreERT2 mice with R26GRR mice, expressing enhanced green fluorescent protein (EGFP) and tDsRed before and after Cre recombination. We found tDsRed signals in the testes and ovaries of tamoxifen‐treated B6‐Ddx4 ^{em1(CreERT2)Utr}::R26GRR mice, but not in untreated mice. Immunostaining of their ovaries clearly showed that Cre recombination occurred in all oocytes at every follicle stage. We also found 100% Cre recombination efficiency in male germ cells via the progeny test. In summary, our results indicate that B6‐Ddx4 ^{em1(CreERT2)Utr} is beneficial for studying female and male germ cell development.     

Msx1creERT2 knock‐In allele: A useful tool to target embryonic and adult cardiac valves

Summary : Heart valve development begins with the endothelial‐to‐mesenchymal transition (EMT) of endocardial cells. Although lineage studies have demonstrated contributions from cardiac neural crest and epicardium to semilunar and atrioventricular (AV) valve formation, respectively, most valve mesenchyme derives from the endocardial EMT. Specific Cre mouse lines for fate‐mapping analyses of valve endocardial cells are limited. Msx1 displayed expression in AV canal endocardium and cushion mesenchyme between E9.5 and E11.5, when EMT is underway. Additionally, previous studies have demonstrated that deletion of Msx1 and its paralog Msx2 results in hypoplastic AV cushions and impaired endocardial signaling. A knock‐in tamoxifen‐inducible Cre line was recently generated (Msx1^CreERT2) and characterized during embryonic development and after birth, and was shown to recapitulate the endogenous Msx1 expression pattern. Here, we further analyze this knock‐in allele and track the Msx1‐expressing cells and their descendants during cardiac development with a particular focus on their contribution to the valves and their precursors. Thus, Msx1^CreERT2 mice represent a useful model for lineage tracing and conditional gene manipulation of endocardial and mesenchymal cushion cells essential to understand mechanisms of valve development and remodeling. genesis 53:337–345, 2015. © 2015 Wiley Periodicals, Inc.     

A Pdgf‐cCreERT2 knock‐in mouse model for tracing PDGF‐C cell lineages during development

PDGF‐C, a member of the platelet‐derived growth factor (PDGF) family, plays important roles in the development of craniofacial structures, the neural system, the vascular system, and tumors. PDGF‐C could also be required for the regulation of certain types of stem or progenitor cells as suggested by its expression in the regions where these cells are located. To further characterize the role of PDGF‐C in development, we generated a Pdgf‐c^CreERT2 mouse strain, in which a tamoxifen‐inducible Cre (CreERT2) cDNA was specifically targeted into the Pdgf‐c genomic locus and controlled by the endogenous Pdgf‐c regulatory elements. We also showed that Cre activity in this mouse strain could be specifically induced by tamoxifen, which allowed the fate of PDGF‐C‐expressing cells to be traced at various stages of development. Using this model system, we demonstrated for the first time that PDGF‐C‐expressing cells could be multipotent, generating multiple cell lineages required for the formation of the cerebellum. Therefore, the Pdgf‐c^CreERT2 mouse strain generated in this study will be a valuable transgenic tool for exploring the function of PDGF‐C in development and stem cell biology.     

Inducible gene modification in the gastric epithelium of Tff1‐CreERT2, Tff2‐rtTA,Tff3‐luc mice

Temporal and spatial regulation of genes mediated by tissue‐specific promoters and conditional gene expression systems provide a powerful tool to study gene function in health, disease, and during development. Although transgenic mice expressing the Cre recombinase in the gastric epithelium have been reported, there is a lack of models that allow inducible and reversible gene modification in the stomach. Here, we exploited the gastrointestinal epithelium‐specific expression pattern of the three trefoil factor (Tff) genes and bacterial artificial chromosome transgenesis to generate a novel mouse strain that expresses the CreERT2 recombinase and the reverse tetracycline transactivator (rtTA). The Tg(Tff1‐CreERT2;Tff2‐rtTA;Tff3‐Luc) strain confers tamoxifen‐inducible irreversible somatic recombination and allows simultaneous doxycycline‐dependent reversible gene activation in the gastric epithelium of developing and adult mice. This strain also confers luciferase activity to the intestinal epithelium to enable in vivo bioluminescence imaging. Using fluorescent reporters as conditional alleles, we show Tff1‐CreERT2 and Tff2‐rtTA transgene activity in a partially overlapping subset of long‐term regenerating gastric stem/progenitor cells. Therefore, the Tg(Tff1‐CreERT2;Tff2‐rtTA;Tff3‐Luc) strain can confer intermittent transgene expression to gastric epithelial cells that have undergone previous gene modification, and may be suitable to genetically model therapeutic intervention during development, tumorigenesis, and other genetically tractable diseases. Birth Defects Research (Part A) 106:626–635, 2016. © 2016 Wiley Periodicals, Inc.     

Sox9‐expressing precursors are the cellular origin of the cruciate ligament of the knee joint and the limb tendons

Sox9 expression defines cell progenitors in a variety of tissues during mouse embryogenesis. To establish a genetic tool for cell‐lineage tracing and gene‐function analysis, we generated mice in which the CreERT2 gene was targeted to the endogenous mouse Sox9 locus. In Sox9^CreERT2/+;R26R embryos, tamoxifen activated Cre recombinase exclusively in Sox9‐expressing tissues. To determine the suitability of this mouse line for developmental stage‐specific gene recombination, we investigated the cellular origins of the cruciate ligaments of the knee joint and the limb tendons, in which precursor cells have not been defined. The cells in these tissues were labeled after tamoxifen treatment before or at the stage of chondrogenic mesenchymal condensation, indicating that ligament and tendon cells originated from Sox9‐expressing cells and that cell fate determination occurred at mesenchymal condensation. This mouse line is a valuable tool for the temporal genetic tracing of the progeny of, and inducible gene modification in Sox9‐expressing cells. genesis 48:635–644, 2010. © 2010 Wiley‐Liss, Inc.     

Identification and Characterization of Single‐Nucleotide Polymorphisms in MCH‐R1 and MCH‐R2*

Objective: To identify and functionally characterize single‐nucleotide polymorphisms (SNPs) in melanin‐concentrating hormone (MCH)‐R1 and ‐R2. Research Methods and Procedures: The entire coding regions and intron/exon splice junction regions of MCH‐R1 and MCH‐R2 were sequenced from anonymous white (n = 45) and African‐American (n = 46) individuals. DNA was analyzed, and SNPs were identified using Phred, Phrap, and Consed software. DNA constructs containing MCH‐R1 and MCH‐R2 SNPs were generated and expressed in CHO cells. The effect of the SNPs in MCH‐R1 and MCH‐R2 were assessed in receptor binding assays and functional assays measuring changes in intracellular cAMP and Ca²⁺ levels. Results: We identified 12 SNPs in the MCH‐R1 gene. Two of these SNPs are in coding regions, and one produces an arginine‐for‐glycine substitution at residue 34 in the MCH‐R1 sequence. This SNP is present at a minor allele frequency of 15% in the African‐American population tested in this study. We identified eight SNPs in the MCH‐R2 gene. Four of these SNPs are in coding regions, and two produce amino acid substitutions. Lysine substitutes for arginine at residue 63 of the African‐American population, and glutamine substitutes for arginine at residue 152 in whites (minor allele frequency of 2% for both SNPs). No changes in receptor binding or functional signaling were observed with the SNP mutations in MCH‐R1 or MCH‐R2. Discussion: These data indicate that potential therapeutics designed to act at the MCH receptor are unlikely to have altered effects in subpopulations that express variant forms of MCH‐R1 or MCH‐R2.     

Generation of knock‐in mice that express nuclear enhanced green fluorescent protein and tamoxifen‐inducible Cre recombinase in the notochord from Foxa2 and T loci

The node and the notochord are important embryonic signaling centers that control embryonic pattern formation. Notochord progenitor cells present in the node and later in the posterior end of the notochord move anteriorly to generate the notochord. To understand the dynamics of cell movement during notochord development and the molecular mechanisms controlling this event, analyses of cell movements using time‐lapse imaging and conditional manipulation of gene activities are required. To achieve this goal, we generated two knock‐in mouse lines that simultaneously express nuclear enhanced green fluorescent protein (EGFP) and tamoxifen‐inducible Cre, CreER^T2, from two notochord gene loci, Foxa2 and T (Brachury). In Foxa2^{nEGFP‐CreERT2/+} and T^{nEGFP‐CreERT2/+} embryos, nuclei of the Foxa2 or T‐expressing cells, which include the node, notochord, and endoderm (Foxa2) or wide range of posterior mesoderm (T), were labeled with EGFP at intensities that can be used for live imaging. Cre activity was also induced in cells expressing Foxa2 and T 1 day after tamoxifen administration. These mice are expected to be useful tools for analyzing the mechanisms of notochord development. genesis 51:210–218, 2013. © 2013 Wiley Periodicals, Inc.     

The following two articles for this Special Issue were previously published and can be found in their respective issues online

Reactive oxygen species signaling in primordial germ cell development in Drosophila embryos (58:6) https://doi.org/10.1002/dvg.23362 Generation of B6‐Ddx4 ^{em1(CreERT2)Utr}, a novel CreERT2 knock‐in line, for germ cell lineage by CRISPR /Cas9 (58:7) https://doi.org/10.1002/dvg.23367     

Generation of a NK1R‐CreER knockin mouse strain to study cells involved in Neurokinin 1 Receptor signaling

The Neurokinin 1 Receptor (NK1R), which binds Substance P, is expressed in discrete populations of neurons throughout the nervous system, where it has numerous roles including the modulation of pain and affective behaviors. Here, we report the generation of a NK1R‐CreER knockin allele, in which CreER^T2 replaces the coding sequence of the TACR1 gene (encoding NK1R) in order to gain genetic access to these cells. We find that the NK1R‐CreER allele mediates recombination in many regions of the nervous system that are important in pain and anxiety including the amygdala, hypothalamus, frontal cortex, raphe nucleus, and dorsal horn of the spinal cord. Other cell types that are labeled by this allele include amacrine cells in the retina and fibroblasts in the skin. Thus, the NK1R‐CreER mouse line is a valuable new tool for conditional gene manipulation enabling the visualization and manipulation of cells that express NK1R.     

A multifunctional reporter mouse line for Cre‐ and FLP‐dependent lineage analysis

The Cre/lox and FLP/FRT recombination systems have been used extensively for both conditional knockout and cell lineage analysis in mice. Here we report a new multifunctional Cre/FLP dual reporter allele (R26^NZG) that exhibits strong and apparently ubiquitous marker expression in embryos and adults. The reporter construct, which is driven by the CAG promoter, was knocked into the ROSA26 locus providing an open chromatin domain for consistent expression and avoiding site‐of‐integration effects often observed with transgenic reporters. R26^NZG directs Cre‐dependent nuclear‐localized β‐galactosidase (β‐gal) expression, and can be converted into a Cre‐dependent EGFP reporter (R26^NG) by germline excision of the FRT‐flanked nlslacZ cassette. Alternatively, germline excision of the floxed PGKNEO cassette in R26^NZG generates an FLP‐dependent EGFP reporter (R26^ZG) that expresses β‐gal in FLP‐nonexpressing cells. Finally, by the simultaneous use of both Cre and FLP deleters, R26^NZG allows lineage relationships to be interrogated with greater refinement than is possible with single recombinase reporter systems. genesis 47:107–114, 2009. © 2009 Wiley‐Liss, Inc.     

A new gain‐of‐function mouse line to study the role of Wnt3a in development and disease

Wnt/β‐catenin signals are important regulators of embryonic and adult stem cell self‐renewal and differentiation and play causative roles in tumorigenesis. Purified recombinant Wnt3a protein, or Wnt3a‐conditioned culture medium, has been widely used to study canonical Wnt signaling in vitro or ex vivo. To study the role of Wnt3a in embryogenesis and cancer models, we developed a Cre recombinase activatable Rosa26^Wnt3a allele, in which a Wnt3a cDNA was inserted into the Rosa26 locus to allow for conditional, spatiotemporally defined expression of Wnt3a ligand for gain‐of‐function (GOF) studies in mice. To validate this reagent, we ectopically overexpressed Wnt3a in early embryonic progenitors using the T‐Cre transgene. This resulted in up‐regulated expression of a β‐catenin/Tcf‐Lef reporter and of the universal Wnt/β‐catenin pathway target genes, Axin2 and Sp5. Importantly, T‐Cre; Rosa26^Wnt3a mutants have expanded presomitic mesoderm (PSM) and compromised somitogenesis and closely resemble previously studied T‐Cre; Ctnnb1^ex3 (β‐catenin^GOF) mutants. These data indicate that the exogenously expressed Wnt3a stimulates the Wnt/β‐catenin signaling pathway, as expected. The Rosa26^Wnt3a mouse line should prove to be an invaluable tool to study the function of Wnt3a in vivo.     

Autism‐related behaviors in the cyclooxygenase‐2‐deficient mouse model

Prostaglandin E2 (PGE2) is an endogenous lipid molecule involved in normal brain development. Cyclooxygenase‐2 (COX2) is the main regulator of PGE2 synthesis. Emerging clinical and molecular research provides compelling evidence that abnormal COX2/PGE2 signaling is associated with autism spectrum disorder (ASD). We previously found that COX2 knockout mice had dysregulated expression of many ASD genes belonging to important biological pathways for neurodevelopment. The present study is the first to show the connection between irregular COX2/PGE2 signaling and autism‐related behaviors in male and female COX2‐deficient knockin, (COX)‐2^?, mice at young (4‐6 weeks) or adult (8‐11 weeks) ages. Autism‐related behaviors were prominent in male (COX)‐2^? mice for most behavioral tests. In the open field test, (COX)‐2^? mice traveled more than controls and adult male (COX)‐2^? mice spent less time in the center indicating elevated hyperactive and anxiety‐linked behaviors. (COX)‐2^? mice also buried more marbles, with males burying more than females, suggesting increased anxiety and repetitive behaviors. Young male (COX)‐2^? mice fell more frequently in the inverted screen test revealing motor deficits. The three‐chamber sociability test found that adult female (COX)‐2^? mice spent less time in the novel mouse chamber indicative of social abnormalities. In addition, male (COX)‐2^? mice showed altered expression of several autism‐linked genes: Wnt2, Glo1, Grm5 and Mmp9. Overall, our findings offer new insight into the involvement of disrupted COX2/PGE2 signaling in ASD pathology with age‐related differences and greater impact on males. We propose that (COX)‐2^? mice might serve as a novel model system to study specific types of autism.     

A mouse model with tamoxifen‐inducible thyrocyte‐specific cre recombinase activity

We have created a mouse model expressing tamoxifen‐inducible Cre recombinase (CreER^T2) under the control of the thyroglobulin (Tg) gene promoter to be able to study the role of defined genetic modifications in the regulation of thyroid function. We chose the thyroglobulin promoter, as it is expressed specifically in the thyroid. In order to obtain reliable expression under the control of the Tg promoter, we used a P1 artificial chromosome (PAC) containing a large piece of the Tg promoter. A tamoxifen inducible CreER^T2 construct was selected to avoid the possible consequences of the gene deletion for the development of the thyroid gland, and to study the role of gene deletion in the adult thyroid. Transgenic lines (TgCreER^T2) carrying this construct were generated and analyzed by crossing the TgCreER^T2 mice with the ROSA26LacZ reporter strain. The activity and specificity of the Cre recombinase was tested by staining for β‐galactosidase activity and by immunohistochemistry using an anti‐Cre‐antibody. In the TgCreER^T2xROSA26LacZ reporter line, Cre‐mediated recombination occurred specifically in the thyrocytes only after tamoxifen administration, and no significant staining was observed in controls. The recombination efficiency was nearly complete, since almost all thyrocytes showed X‐gal staining. We could also induce the recombination in utero by giving tamoxifen to the pregnant female. In addition, mice expressing TgCreER^T2 had no obvious histological changes, hormonal alterations, or different response to growth stimuli as compared to controls. These results demonstrate that the TgCreER^T2 mouse line is a powerful tool to study temporally controlled deletion of floxed genes in the thyroid. genesis 52:333–340, 2014. © 2014 Wiley Periodicals, Inc.