Identification of the Genomic Insertion Site of the Thyroid Peroxidase Promoter–Cre Recombinase Transgene Using a Novel, Efficient, Next-Generation DNA Sequencing Method

Background: It can be useful to know the transgene insertion site in transgenic mice for a variety of reasons, but determining the insertion site generally is a time consuming, expensive, and laborious task. Methods: A simple method is presented to determine transgene insertion sites that combines the enrichment of a sequencing library by polymerase chain reaction (PCR) for sequences containing the transgene, followed by next-generation sequencing of the enriched library. This method was applied to determine the site of integration of the thyroid peroxidase promoter?Cre recombinase mouse transgene that is commonly used to create thyroid-specific gene deletions. Results: The insertion site was found to be between bp 12,372,316 and 12,372,324 on mouse chromosome 9, with the nearest characterized genes being Cntn5 and Jrkl, ?1.5 and 0.9?Mbp from the transgene, respectively. One advantage of knowing a transgene insertion site is that it facilitates distinguishing hemizygous from homozygous transgenic mice. Although this can be accomplished by real-time quantitative PCR, the expected Ct difference is only one cycle, which is challenging to assess accurately. Therefore, the transgene insertion site information was used to develop a 3-primer qualitative PCR assay that readily distinguishes wild type, hemizygous, and homozygous TPO-Cre mice based upon size differences of the wild type and transgenic allele PCR products. Conclusions: Identification of the genomic insertion site of the thyroid peroxidase promoter?Cre mouse transgene should facilitate the use of these mice in studies of thyroid biology.Peer Reviewedhttps://deepblue.lib.umich.edu/bitstream/2027.42/140267/1/thy.2015.0215.pd

The magnitude of hedgehog signaling activity defines skin tumor phenotype

Gain-of-function mutations in SMO have been implicated in constitutive activation of the hedgehog signaling pathway in human basal cell carcinomas (BCCs). We used a truncated keratin 5 (ΔK5) promoter to assess the potential role of the human M2SMO mutant in BCC development in adult transgenic mice. ΔK5-M2SMO mouse epidermis is hyperproliferative, ex presses BCC protein markers and gives rise to numerous epithelial downgrowths invading the underlying dermis. Lesions strikingly similar to human basaloid follicular hamartomas develop, but BCCs do not arise even in elderly mice. Hedgehog target gene transcripts were only modestly upregulated in mouse and human follicular hamartomas, in contrast to the high levels detected in BCCs. Cyclins D1 and D2 were selectively upregulated in mouse BCCs. Our data suggest that the levels of hedgehog pathway activation and G(1) cyclins are major determinants of tumor phenotype in skin, and strongly implicate deregulated hedgehog signaling in the genesis of human basaloid follicular hamartomas. Expression of an activated SMO mutant in keratinocytes appears to be insufficient for the development and/or maintenance of full-blown BCCs

Hedgehog Signaling Regulates Sebaceous Gland Development

Epithelial progenitor cells in skin give rise to multiple lineages, comprising the hair follicle, an associated sebaceous gland, and overlying epidermis; however, the signals that regulate sebocyte development are poorly understood. We tested the potential involvement of the Hedgehog pathway in sebaceous gland development using transgenes designed to either block or stimulate Hedgehog signaling in cutaneous keratinocytes in vivo. Whereas inhibition of the Hedgehog pathway selectively suppressed sebocyte development, Hedgehog pathway activation led to a striking increase both in size and number of sebaceous glands. Remarkably, ectopic Hedgehog signaling also triggered the formation of sebaceous glands from footpad epidermis, in regions normally devoid of hair follicles and associated structures. These ectopic sebaceous glands expressed molecular markers of sebocyte differentiation and were functional, secreting their contents directly onto the skin’s surface instead of into a hair canal. The Hedgehog pathway thus plays a key role in sebocyte cell fate decisions and is a potential target for treatment of skin disorders linked to abnormal sebaceous gland function, such as acne

Bone Morphogenetic Protein Antagonist Noggin Promotes Skin Tumorigenesis via Stimulation of the Wnt and Shh Signaling Pathways

Bone morphogenetic proteins (BMPs) play pivotal roles in the regulation of skin development. To study the role of BMPs in skin tumorigenesis, BMP antagonist noggin was used to generate keratin 14-targeted transgenic mice. In contrast to wild-type mice, transgenic mice developed spontaneous hair follicle-derived tumors, which resemble human trichofolliculoma. Global gene expression profiles revealed that in contrast to anagen hair follicles of wild-type mice, tumors of transgenic mice showed stage-dependent increases in the expression of genes encoding the selected components of Wnt and Shh pathways. Specifically, expression of the Wnt ligands increased at the initiation stage of tumor formation, whereas expression of the Wnt antagonist and tumor suppressor Wnt inhibitory factor-1 decreased, as compared with fully developed tumors. In contrast, expression of the components of Shh pathway increased in fully developed tumors, as compared with the tumor placodes. Consistent with the expression data, pharmacological treatment of transgenic mice with Wnt and Shh antagonists resulted in the stage-dependent inhibition of tumor initiation, and progression, respectively. Furthermore, BMP signaling stimulated Wnt inhibitory factor-1 expression and promoter activity in cultured tumor cells and HaCaT keratinocytes, as well as inhibited Shh expression, as compared with the corresponding controls. Thus, tumor suppressor activity of the BMPs in skin epithelium depends on the local concentrations of noggin and is mediated at least in part via stage-dependent antagonizing of Wnt and Shh signaling pathways