A new tool for conditional gene manipulation in a subset of keratin‐expressing epithelia

Megsin is a serine protease inhibitor (Serpin) that has known expression in kidney mesangial cells. Here, we report the generation and characterization of a bacterial artificial chromosome (BAC) transgene expressing Cre under the control of Megsin regulatory elements. When crossed to the ROSA26R‐lacZ reporter mice, the Megsin‐Cre transgene mediates loxP recombination primarily in the skin, forestomach, and esophagus, but surprisingly not in the mesangial cells. Within the skin, cells in all epidermal layers and the hair follicle cells expressed Cre. This transgene also has uniform expression in the epithelium of the forestomach and esophagus. Conditional deletion of Adam10, a gene known to have important functions in skin development, by using this Megsin‐Cre transgene led to severe skin defects. In addition, these mutants appear to have reduced folds and surface area in the forestomach. These results show that the Megsin‐Cre transgene can mediate loxP‐recombination in all epidermal layers of the skin, the hair follicle cells, as well as in the epithelium of the forestomach and esophagus, all of which have known expression of various keratins. This Megsin‐Cre transgene can serve as a new tool for conditional genetic manipulation to study development and diseases in the skin and the upper digestive tract. genesis 50:899–907, 2012. © 2012 Wiley Periodicals, Inc.     

The zinc finger transcription factor Gfi1, implicated in lymphomagenesis,is required for inner ear hair cell differentiation and survival

Gfi1 was first identified as causing interleukin 2-independent growth in T cells and lymphomagenesis in mice. Much work has shown that Gfi1 and Gfi1b, a second mouse homolog, play pivotal roles in blood cell lineage differentiation. However, neither Gfi1 nor Gfi1b has been implicated in nervous system development, even though their invertebrate homologues, senseless in Drosophila and pag-3 in C. elegans are expressed and required in the nervous system. We show that Gfi1 mRNA is expressed in many areas that give rise to neuronal cells during embryonic development in mouse, and that Gfi1 protein has a more restricted expression pattern. By E12.5 Gfi1 mRNA is expressed in both the CNS and PNS as well as in many sensory epithelia including the developing inner ear epithelia. At later developmental stages, Gfi1 expression in the ear is refined to the hair cells and neurons throughout the inner ear. Gfi1 protein is expressed in a more restricted pattern in specialized sensory cells of the PNS, including the eye, presumptive Merkel cells, the lung and hair cells of the inner ear. Gfi1 mutant mice display behavioral defects that are consistent with inner ear anomalies, as they are ataxic, circle, display head tilting behavior and do not respond to noise. They have a unique inner ear phenotype in that the vestibular and cochlear hair cells are differentially affected. Although Gfi1-deficient mice initially specify inner ear hair cells, these hair cells are disorganized in both the vestibule and cochlea. The outer hair cells of the cochlea are improperly innervated and express neuronal markers that are not normally expressed in these cells. Furthermore, Gfi1 mutant mice lose all cochlear hair cells just prior to and soon after birth through apoptosis. Finally, by five months of age there is also a dramatic reduction in the number of cochlear neurons. Hence, Gfi1 is expressed in the developing nervous system, is required for inner ear hair cell differentiation, and its loss causes programmed cell death.     

Generation of a KOR‐Cre knockin mouse strain to study cells involved in kappa opioid signaling

The kappa opioid receptor (KOR) has numerous important roles in the nervous system including the modulation of mood, reward, pain, and itch. In addition, KOR is expressed in many non‐neuronal tissues. However, the specific cell types that express KOR are poorly characterized. Here, we report the development of a KOR‐Cre knockin allele, which provides genetic access to cells that express KOR. In this mouse, Cre recombinase (Cre) replaces the initial coding sequence of the Opkr1 gene (encoding the kappa opioid receptor). We demonstrate that the KOR‐Cre allele mediates recombination by embryonic day 14.5 (E14.5). Within the brain, KOR‐Cre shows expression in numerous areas including the cerebral cortex, nucleus accumbens and striatum. In addition, this allele is expressed in epithelium and throughout many regions of the body including the heart, lung, and liver. Finally, we reveal that KOR‐Cre mediates recombination of a subset of bipolar and amacrine cells in the retina. Thus, the KOR‐Cre mouse line is a valuable new tool for conditional gene manipulation to enable the study of KOR. genesis 54:29–37, 2016. © 2015 Wiley Periodicals, Inc.     

Development of a general‐purpose method for cell purification using Cre/loxP‐mediated recombination

A mammalian body is composed of more than 200 different types of cells. The purification of a certain cell type from tissues/organs enables a wide variety of studies. One popular cell purification method is immunological isolation, using antibodies against specific cell surface antigens. However, this is not a general‐purpose method, since suitable antigens have not been found in certain cell types, including embryonic gonadal somatic cells and Sertoli cells. To address this issue, we established a knock‐in mouse line, named R26 KI, designed to express the human cell surface antigen hCD271 through Cre/loxP‐mediated recombination. First, we used the R26 Kl mouse line to purify embryonic gonadal somatic cells. Gonadal somatic cells were purified from the R26 KI; Nr5a1‐Cre‐transgenic (tg) embryos almost equally as efficiently as from Nr5a1‐hCD271‐tg embryos. Second, we used the R26 KI mouse line to purify Sertoli cells successfully from R26 KI; Amh‐Cre‐tg testes. In summary, we propose that the R26 KI mouse line is a powerful tool for the purification of various cell types. genesis 53:387–393, 2015. © 2015 Wiley Periodicals, Inc.     

Nrl‐Cre transgenic mouse mediates loxP recombination in developing rod photoreceptors

The developing mouse retina is a tractable model for studying neurogenesis and differentiation. Although transgenic Cre mouse lines exist to mediate conditional genetic manipulations in developing mouse retinas, none of them act specifically in early developing rods. For conditional genetic manipulations of developing retinas, a Nrl‐Cre mouse line in which the Nrl promoter drives expression of Cre in rod precursors was created. The results showed that Nrl‐Cre expression was specific to the retina where it drives rod‐specific recombination with a temporal pattern similar to endogenous Nrl expression during retinal development. This Nrl‐Cre transgene does not negatively impact retinal structure and function. Taken together, the data suggested that the Nrl‐Cre mouse line was a valuable tool to drive Cre‐mediated recombination specifically in developing rods. genesis 54:129–135, 2016. © 2016 Wiley Periodicals, Inc.     

Inducible cardiomyocyte‐specific gene disruption directed by the rat Tnnt2 promoter in the mouse

We developed a conditional and inducible gene knockout methodology that allows effective gene deletion in mouse cardiomyocytes. This transgenic mouse line was generated by coinjection of two transgenes, a “reverse” tetracycline‐controlled transactivator (rtTA) directed by a rat cardiac troponin T (Tnnt2) promoter and a Cre recombinase driven by a tetracycline‐responsive promoter (TetO). Here, Tnnt2‐rtTA activated TetO‐Cre expression takes place in cardiomyocytes following doxycycline treatment. Using two different mouse Cre reporter lines, we demonstrated that expression of Cre recombinase was specifically and robustly induced in the cardiomyocytes of embryonic or adult hearts following doxycycline induction, thus, allowing cardiomyocyte‐specific gene disruption and lineage tracing. We also showed that rtTA expression and doxycycline treatment did not compromise cardiac function. These features make the Tnnt2‐rtTA;TetO‐Cre transgenic line a valuable genetic tool for analysis of spatiotemporal gene function and cardiomyocyte lineage tracing during developmental and postnatal periods. genesis 48:63–72, 2010. © 2009 Wiley‐Liss, Inc.     

A mart-1::Cre transgenic line induces recombination in melanocytes and retinal pigment epithelium

The number of transgenic mouse lines expressing Cre in either type of pigment cells (melanocytes and retinal pigment epithelium, RPE) is limited, and the available lines do not always offer sufficient specificity. In this study, we addressed this issue and we report on the generation of a MART‐1::Cre BAC transgenic mouse line, in which the expression of Cre recombinase is controlled by regulatory elements of the pigment cell‐specific gene MART‐1 (mlana). When MART‐1::Cre BAC transgenic mice were bred with the ROSA26‐R reporter line, ß‐galactosidase expression was observed in RPE from E12.5 onwards, and in melanocyte precursors from E17.5, indicating that the MART‐1::Cre line provides Cre recombinase activity in pigment‐producing cells rather than in a particular lineage. In addition, breeding of this mouse line to mice carrying a conditional allele of RBP‐Jκ corroborated the reported phenotypes in both pigment cell lineages, inducing hair greying and microphthalmia. Our results thus suggest, that the MART‐1::Cre line may serve as a novel and useful tool for functional studies in melanocytes and the RPE.genesis 49:403–409, 2011. © 2011 Wiley‐Liss, Inc.     

Generation of BAF53b‐Cre transgenic mice with pan‐neuronal Cre activities

Molecular and functional studies of genes in neurons in mouse models require neuron‐specific Cre lines. The current available neuronal Cre transgenic or knock‐in lines either result in expression in a subset of neurons or expression in both neuronal and non‐neuronal tissues. Previously we identified BAF53b as a neuron‐specific subunit of the chromatin remodeling BAF complexes. Using a bacteria artificial chromosome (BAC) construct containing the BAF53b gene, we generated a Cre transgenic mouse under the control of BAF53b regulatory elements. Like the endogenous BAF53b gene, we showed that BAF53b‐Cre is largely neuron‐specific. In both central and peripheral nervous systems, it was expressed in all developing neurons examined and was not observed in neural progenitors or glial cells. In addition, BAF53b‐Cre functioned in primary cultures in a pan‐neuron‐specific manner. Thus, BAF53b‐Cre mice will be a useful genetic tool to manipulate gene expression in developing neurons for molecular, biochemical, and functional studies. genesis, 53:440–448, 2015. © 2015 Wiley Periodicals, Inc.     

Generation of Elf5‐Cre knockin mouse strain for trophoblast‐specific gene manipulation

Placental development is a complex and highly controlled process during which trophoblast stem cells differentiate to various trophoblast subtypes. The early embryonic death of systemic gene knockout models hampers the investigation of these genes that might play important roles during placentation. A trophoblast specific Cre mouse model would be of great help for dissecting out the potential roles of these genes during placental development. For this purpose, we generate a transgenic mouse with the Cre recombinase inserted into the endogenous locus of Elf5 gene that is expressed specifically in placental trophoblast cells. To analyze the specificity and efficiency of Cre recombinase activity in Elf5‐Cre mice, we mated Elf5‐Cre mice with Rosa26^mT/mG reporter mice, and found that Elf5‐Cre transgene is expressed specifically in the trophoectoderm as early as embryonic day 4.5 (E4.5). By E12.5, the activity of Elf5‐Cre transgene was detected exclusively in all derivatives of trophoblast lineages, including spongiotrophoblast, giant cells, and labyrinth trophoblasts. In addition, Elf5‐Cre transgene was also active during spermatogenesis, from spermatids to mature sperms, which is consistent with the endogenous Elf5 expression in testis. Collectively, our results provide a unique tool to delete specific genes selectively and efficiently in trophoblast lineage during placentation.     

A Tlx2‐Cre mouse line uncovers essential roles for hand1 in extraembryonic and lateral mesoderm

Hand1 regulates development of numerous tissues within the embryo, extraembryonic mesoderm, and trophectoderm. Systemic loss of Hand1 results in early embryonic lethality but the cause has remained unknown. To determine if Hand1 expression in extraembryonic mesoderm is essential for embryonic survival, Hand1 was conditionally deleted using the HoxB6‐Cre mouse line that expresses Cre in extraembryonic and lateral mesoderm. Deletion of Hand1 using HoxB6‐Cre resulted in embryonic lethality identical to systemic knockout. To determine if lethality is due to Hand1 function in extraembryonic mesoderm or lateral mesoderm, we generated a Tlx2‐Cre mouse line expressing Cre in lateral mesoderm but not extraembryonic tissues. Deletion of Hand1 using the Tlx2‐Cre line results in embryonic survival with embryos exhibiting herniated gut and thin enteric smooth muscle. Our results show that Hand1 regulates development of lateral mesoderm derivatives and its loss in extraembryonic mesoderm is the primary cause of lethality in Hand1‐null embryos. genesis 48:479–484, 2010. © 2010 Wiley‐Liss, Inc.     

Pdgfrb‐Cre targets lymphatic endothelial cells of both venous and non‐venous origins

The Pdgfrb‐Cre line has been used as a tool to specifically target pericytes and vascular smooth muscle cells. Recent studies showed additional targeting of cardiac and mesenteric lymphatic endothelial cells (LECs) by the Pdgfrb‐Cre transgene. In the heart, this was suggested to provide evidence for a previously unknown nonvenous source of LECs originating from yolk sac (YS) hemogenic endothelium (HemEC). Here we show that Pdgfrb‐Cre does not, however, target YS HemEC or YS‐derived erythro‐myeloid progenitors (EMPs). Instead, a high proportion of ECs in embryonic blood vessels of multiple organs, as well as venous‐derived LECs were targeted. Assessment of temporal Cre activity using the R26‐mTmG double reporter suggested recent occurrence of Pdgfrb‐Cre recombination in both blood and lymphatic ECs. It thus cannot be excluded that Pdgfrb‐Cre mediated targeting of LECs is due to de novo expression of the Pdgfrb‐Cre transgene or their previously established venous endothelial origin. Importantly, Pdgfrb‐Cre targeting of LECs does not provide evidence for YS HemEC origin of the lymphatic vasculature. Our results highlight the need for careful interpretation of lineage tracing using constitutive Cre lines that cannot discriminate active from historical expression. The early vascular targeting by the Pdgfrb‐Cre also warrants consideration for its use in studies of mural cells. genesis 54:350–358, 2016. © 2016 The Authors. Genesis Published by Wiley Periodicals, Inc.     

Utility of HoxB2 enhancer‐mediated Cre activity for functional studies in the developing inner ear

The rhombomere 4(r4)‐restricted expression of the mouse Hoxb2 gene is regulated by a 1.4‐kb enhancer‐containing fragment. Here, we showthat transgenic mouse lines expressing cre driven by this fragment (B2‐r4‐Cre), activated the R26R Cre reporter in rhombomere 4 and the second branchial arch, the epithelium of the first branchial arch, apical ectodermal ridge of the limb buds and the tail region. Of particular interest is Cre activity in the developing inner ear. Cre activity was found in the preotic field and otic placode at E8.5 and otocyst at E9.5–E12.5, in the cochleovestibular and facio‐acoustic ganglia at E10.5 and the vestibular and spiral ganglia and all the otic epithelia derived from the otocyst at E15.5 and P0. Our data suggest that the B2‐r4‐Cre transgenic mice provide an important tool for conditional gene manipulation and lineage tracing in the inner ear. In combination with other transgenic lines expressing cre exclusively in the otic vesicle, the relative contributions of the hindbrain, periotic mesenchyme and otic epithelium in otic development can be dissected. genesis 47:361–365, 2009. © 2009 Wiley‐Liss, Inc.