Inducible chromosomal translocation of AML1 and ETO genes through Cre/loxP-mediated recombination in the mouse

Transgenic mice have been used to explore the role of chromosomal translocations in the genesis of tumors. But none of these efforts has actually involved induction of a translocation in vivo. Here we report the use of Cre recombinase to replicate in vivo the t(8;21) translocation found in human acute myeloid leukemia (AML). As in the human tumors, the murine translocation fuses the genes AML1 and ETO. We used homologous recombination to place loxP sites at loci that were syntenic with the break points for the human translocation. Cre activity was provided in mice by a transgene under the control of the Nestin promoter, or in cultured B cells by infecting with a retroviral vector encoding Cre. In both instances, Cre activity mediated interchromosomal translocations that fused the AML1 and ETO genes. Thus, reciprocal chromosomal translocations that closely resemble rearrangements found in human cancers can be achieved in mice.     

Cortical and retinal defects caused by dosage-dependent reductions in VEGF-A paracrine signaling

To determine the function of VEGF-A in nervous system development, we have utilized the Nestin promoter-driven Cre recombinase transgene, in conjunction with a conditional and hypomorphic VEGF-A allele, to lower VEGF-A activity in neural progenitor cells. Mice with intermediate levels of VEGF-A activity showed decreased blood vessel branching and density in the cortex and retina, resulting in a thinner retina and aberrant structural organization of the cortex. Severe reductions in VEGF-A led to decreases in vascularity and subsequent hypoxia, resulting in the specific degeneration of the cerebral cortex and neonatal lethality. Decreased neuronal proliferation and hypoxia was evident at E11.5, leading to increased neuronal apoptosis in the cortex by E15.5. In order to address whether the observed changes in the structural organization of the nervous system were due to a direct and autocrine role of VEGF-A on the neural population, we conditionally inactivated the main VEGF-A receptor, Flk1, specifically in neuronal lineages, by using the Nestin Cre transgene. The normality of these mice ruled out the possibility that VEGF-A/Flk1 signaling has a significant autocrine role in CNS development. VEGF-A dosage is therefore a critical parameter regulating the density of the vascular plexus in the developing CNS that is in turn a key determinant in the development and architectural organization of the nervous system.     

Genetic interaction between the homeobox transcription factors HESX1 and SIX3 is required for normal pituitary development

Hesx1 has been shown to be essential for normal pituitary development. The homeobox gene Six3 is expressed in the developing pituitary gland during mouse development but its function in this tissue has been precluded by the fact that in the Six3-deficient embryos the pituitary gland is not induced. To gain insights into the function of Six3 during pituitary development we have generated Six3^+/−;Hesx1^Cre/+ double heterozygous mice. Strikingly, these mice show marked dwarfism, which is first detectable around weaning, and die by the 5th-6th week of age. Thyroid and gonad development is also impaired in these animals. Analysis of Six3^+/−;Hesx1^Cre/+ compound embryos indicates that hypopituitarism is the likely cause of these defects since pituitary development is severely impaired in these mutants. Similar to the Hesx1-deficient embryos, Rathke's pouch is initially expanded in Six3^+/−;Hesx1^Cre/+ compound embryos due to an increase in cell proliferation. Subsequently, the anterior pituitary gland appears bifurcated, dysmorphic and occasionally ectopically misplaced in the nasopharyngeal cavity, but cell differentiation is unaffected. Our research has revealed a role for Six3 in normal pituitary development, which has likely been conserved during evolution as SIX3 is also expressed in the pituitary gland of the human embryo.     

Highly B lymphocyte‐specific tamoxifen inducible transgene expression of CreERT2 by using the LC‐1 locus BAC vector

The generation of cell type specific inducible Cre transgenic mice is the most challenging and limiting part in the development of spatio‐temporally controlled knockout mouse models. Here we report the generation and characterization of a B lymphocyte‐specific tamoxifen‐inducible Cre transgenic mouse strain, LC‐1‐hCD19‐CreER^T2. We utilized the human CD19 promoter for expression of the tamoxifen‐inducible Cre recombinase (CreER^T2) gene, embedded in genomic sequences previously reported to give minimal position effects after transgenesis. Cre recombinase activity was evaluated by cross‐breeding the LC‐1‐hCD19‐CreER^T2 strain with a strain containing a floxed gene widely expressed in the hematopoietic system. Cre activity was only detected in the presence of tamoxifen and was restricted to B lymphocytes. The efficacy of recombination ranged from 27 to 61% in the hemizygous and homozygous mice, respectively. In conclusion, the LC‐1‐hCD19‐CreER^T2 strain is a powerful tool to study gene function specifically in B lymphocytes at any chosen time point in the lifecycle of the mouse. genesis 47:729–735, 2009. © 2009 Wiley‐Liss, Inc.     

Pitx2 deletion in pituitary gonadotropes is compatible with gonadal development, puberty, and fertility

This report introduces a gonadotrope-specific cre transgenic mouse capable of ablating floxed genes in mature pituitary gonadotropes. Initial analysis of this transgenic line, Tg(Lhb-cre)1Sac, reveals that expression is limited to the pituitary cells that produce luteinizing hormone beta, beginning appropriately at e17.5. Cre activity is detectable by a reporter gene in nearly every LHbeta-producing cell, but the remaining hormone-producing cell types and other organs exhibit little to no activity. We used the Tg(Lhb-cre)1Sac strain to assess the role Pitx2 in gonadotrope function. The gonadotrope-specific Pitx2 knockout mice exhibit normal expression of LHbeta, sexual maturation, and fertility, suggesting that Pitx2 is not required for gonadotrope maintenance or for regulated production of gonadotropins.     

Generation and characterization of the PKC gamma-Cre mouse line

PKCgamma is a protein kinase C (PKC) isoform that is expressed in the central nervous system (CNS). We generated a PKCgamma-Cre mouse line and characterized the expression and activity of the Cre protein. Our studies show that Cre expression largely recapitulates the endogenous expression of PKCgamma. Several major sites of Cre expression are the cerebral cortex, hippocampus, thalamus, amygdala, and spinal cord. Examination of PKCgamma-Cre/ROSA26 mice reveals a similar X-gal staining pattern in the CNS, indicating that Cre recombinase is capable of removing LoxP sites in vivo. These data indicate that the PKCgamma-Cre mouse line could be a useful reagent for generating Cre-mediated tissue-specific knockouts in the CNS.     

Development of a pituitary-specific cre line targeted to the Pit-1 lineage

Tissue-specific expression of the Cre recombinase is a well-established genetic tool to analyze gene function in specific tissues and cell types. In this report, we describe the generation of a new transgenic line that expresses Cre under the control of the rat growth hormone releasing hormone receptor (rGhrhr) promoter. This promoter, chosen to target the anterior pituitary, drives cre-mediated recombination in cells of the Pit1 lineage, including somatotrophs, lactotrophs, and thyrotrophs. Cre activity is first detected at embryonic day 13.5, and gradually increases to reach high level expression by postnatal day 2. In addition to the pituitary, rGhrhr-cre expression was detected in vibrissae and in hair follicles of the proximal limb, but not in other tissues. The rGhrhr-cre line will be a valuable tool for the study of the development of the pituitary Pit1 lineage and for the study of tumorigenesis involving these cells.     

Efficient CPP-mediated Cre protein delivery to developing and adult CNS tissues

Background  

Understanding and manipulating gene function in physiological conditions is a major objective for both fundamental and applied research. In contrast to other experimental settings, which use either purely genetic or gene delivery (viral or non-viral) strategies, we report here a strategy based on direct protein delivery to central nervous system (CNS) tissues. We fused Cre recombinase with cell-penetrating peptides and analyzed the intracellular biological activity of the resulting chimerical proteins when delivered into cells endowed with Cre-mediated reporter gene expression.     

Maternal inheritance of Cre activity in a Sox2Cre deleter strain

The Sox2 gene is expressed in several undifferentiated cell types. In an earlier study we described a Sox2Cre transgene that mediates epiblast-specific Cre-mediated modification of gene activity in the embryo. Here we report that this transgene is active in the female germline. Consequently, all offspring that arise from female mice heterozygous for the Sox2Cre transgene have demonstrable Cre activity irrespective of whether they inherit the transgene itself. Maternal inheritance of Cre activity allows the efficient modification of gene activity for functional analysis.     

Odontoblast-specific expression of cre recombinase successfully deletes gene segments flanked by loxP sites in mouse teeth

Embryonic or neonatal lethality of mice with targeted disruption of critical genes preclude them from further characterization of specific roles of these genes during postnatal development and aging. In order to study the molecular roles of such genes in teeth, we generated transgenic mouse lines expressing bacteriophage Cre recombinase under the control of the mouse dentin sialophosphoprotein (dspp) gene promoter. The expression of Cre recombinase protein was mainly detected in the nucleus of the odontoblasts. The efficiency of Cre activity was analyzed by crossing the Dspp-Cre mice with ROSA26 reporter (R26R) mice. The offspring with both genotypes have shown specific deletion of intervening sequences flanked by loxP sites upstream of the reporter gene, thereby facilitating the expression of the beta-galactosidase (beta-gal) gene in the teeth. The activity of beta-gal was initially observed in the odontoblasts of 1-day-old mice and increased with tooth development. Almost all of the odontoblasts have shown lacZ activity by 3 weeks of age. We could not detect Cre recombinase activity in any other cells, including ameloblasts. These studies indicate that the Dspp-Cre transgenic mice will be valuable to generate odontoblast-specific gene knockout mice so as to gain insight into the molecular roles of critical genes in the odontoblasts during dentinogenesis.     

Cre-mediated recombination in cell lineages that express the progesterone receptor

Using gene-targeting methods, a progesterone receptor Cre knockin (PR-Cre) mouse was generated in which Cre recombinase was inserted into exon 1 of the PR gene. The insertion positions the Cre gene downstream (and under the specific control) of the endogenous PR promoter. As for heterozygotes for the progesterone receptor knockout (PRKO) mutation, mice heterozygous for the Cre knockin insertion are phenotypically indistinguishable from wildtype. Crossing the PR-Cre with the ROSA26R reporter revealed that Cre excision activity is restricted to cells that express PR in progesterone-responsive tissues such as the uterus, ovary, oviduct, pituitary gland, and mammary gland. Initial characterization of the PR-Cre mouse underscores the utility of this model to precisely ablate floxed target genes specifically in cell lineages that express the PR. In the wider context of female reproductive tissue ontology, this model will be indispensable in tracing the developmental fate of cell lineages that descend from PR positive progenitors.     

Synaptotagmin10-Cre, a driver to disrupt clock genes in the SCN

Surgical lesion of the suprachiasmatic nuclei (SCN) profoundly affects the circadian timing system. A complication of SCN ablations is the concomitant scission of SCN afferents and efferents. Genetic disruption of the molecular clockwork in the SCN provides a complementary, less invasive experimental approach. The authors report the generation and functional analysis of a new Cre recombinase driver mouse that evokes homologous recombination with high efficiency in the SCN. They inserted the Cre recombinase cDNA into the Synaptotagmin10 (Syt10) locus, a gene strongly expressed in the SCN. Heterozygous Synaptotagmin10-Cre (Syt10(Cre)) mice have no obvious circadian locomotor phenotype, and homozygous animals show slightly reduced light-induced phase delays. Crosses of Syt10(Cre) mice with β-galactosidase reporter animals revealed strong Cre activity in the vast majority of SCN cells. Cre activity is not detected in nonneuronal tissues with the exception of the testis. The authors demonstrate that conditionally deleting the clock gene Bmal1 using the Syt10(Cre) driver renders animals arrhythmic.     

The proteolipid protein promoter drives expression outside of the oligodendrocyte lineage during embryonic and early postnatal development

The proteolipid protein (Plp) gene promoter is responsible for driving expression of one of the major components of myelin--PLP and its splice variant DM-20. Both products are classically thought to express predominantly in oligodendrocytes. However, accumulating evidence suggests Plp expression is more widespread than previously thought. In an attempt to create a mouse model for inducing oligodendrocyte-specific gene deletions, we have generated transgenic mice expressing a Cre recombinase cDNA under control of the mouse Plp promoter. We demonstrate Plp promoter driven Cre expression is restricted predominantly to mature oligodendrocytes of the central nervous system (CNS) at postnatal day 28. However, crosses into the Rosa26(LacZ) and mT/mG reporter mouse lines reveal robust and widespread Cre activity in neuronal tissues at E15.5 and E10.5 that is not strictly oligodendrocyte lineage specific. By P28, all CNS tissues examined displayed high levels of reporter gene expression well outside of defined white matter zones. Importantly, our study reinforces the emerging idea that Plp promoter activity is not restricted to the myelinating cell lineage, but rather, has widespread activity both during embryonic and early postnatal development in the CNS. Specificity of the promoter to the oligodendrocyte cell lineage, as shown through the use of a tamoxifen inducible Plp-CreER(t) line, occurs only at later postnatal stages. Understanding the temporal shift in Plp driven expression is of consequence when designing experimental models to study oligodendrocyte biology.     

Cre reconstitution allows for DNA recombination selectively in dual-marker-expressing cells in transgenic mice

Cre/LoxP-based DNA recombination has been used to introduce desired DNA rearrangements in various organisms, having for example, greatly assisted genetic analyses in mice. For most applications, single gene promoters are used to drive Cre production for conditional gene activation/inactivation or lineage-tracing experiments. Such a manipulation introduces Cre in all cells in which the utilized promoter is active. To overcome the limited selectivity of single promoters for cell-type-specific recombination, we have explored the ‘dual promoter combinatorial control’ of Cre activity, so that Cre activity could be restricted to cells that express dual protein markers. We efficiently reconstituted Cre activity from two modified, inactive Cre fragments. Cre re-association was greatly enhanced by fusing the Cre fragments separately to peptides that can form a tight antiparallel leucine zipper. The co-expressed Cre fusion fragments showed substantial activity in cultured cells. As proof of principle of the utility of this technique in vivo for manipulating genes specifically in dual-marker-positive cells, we expressed each inactive Cre fragments in transgenic mice via individual promoters. Result showed the effective reconstitution of Cre activates LoxP recombination in the co-expressing cells.