Ectodermal influx and cell hypertrophy provide early growth for all murine mammary rudiments, and are differentially regulated among them by Gli3.

Mammary gland development starts in utero with one or several pairs of mammary rudiments (MRs) budding from the surface ectodermal component of the mammalian embryonic skin. Mice develop five pairs, numbered MR1 to MR5 from pectoral to inguinal position. We have previously shown that Gli3(Xt-J/Xt-J) mutant embryos, which lack the transcription factor Gli3, do not form MR3 and MR5.

Gli3-mediated somitic Fgf10 expression gradients are required for the induction and patterning of mammary epithelium along the embryonic axes.

Little is known about the regulation of cell fate decisions that lead to the formation of five pairs of mammary placodes in the surface ectoderm of the mouse embryo. We have previously shown that fibroblast growth factor 10 (FGF10) is required for the formation of mammary placodes 1, 2, 3 and 5. Here, we have found that Fgf10 is expressed only in the somites underlying placodes 2 and 3, in gradients across and within these somites.

FGF4, a direct target of LEF1 and Wnt signaling, can rescue the arrest of tooth organogenesis in Lef1(-/-) mice.

Lymphoid enhancer factor (LEF1), a nuclear mediator of Wnt signaling, is required for the formation of organs that depend on inductive interactions between epithelial and mesenchymal tissues. In previous tissue recombination experiments with normal and Lef1(-/-) tooth germs, we found that the effect of LEF1 expression in the epithelium is tissue nonautonomous and transferred to the subjacent mesenchyme. Here we examine the molecular basis for LEF1 function and find that the epithelium of the developmentally arrested Lef1(-/-) tooth rudiments fails to express Fgf4, Shh, and Bmp4, but not Wnt10a.

Mutagenic transgene insertion into a region of high gene density and multiple linkage disruptions on mouse chromosome 11.

We have characterized a 185-kb contig surrounding a transgene on distal mouse chromosome 11, the insertion of which has caused a recessive phenotype with skeletal malformations. By cDNA selection and sequencing we have found six genes (Lasp1, Rpl23, Mllt6, Pip5k2b, Psmb3, Zfp144), one truncated gene (Mel13), and one pseudogene (Rps15-ps) within this region. The murine Mllt6 gene is new, it was identified by its high homology (90% identity) with the human homologue MLLT6.

Genomic organization and chromosome location of the murine Rpl23 gene.

The mouse gene coding for ribosomal protein L23 (Rpl23) has been fully sequenced, including 580 bp of the 5' upstream region. The 5-kb gene comprises 5 exons and contains an unusually long (3,153 bp) third intron. The gene was mapped to the distal region of mouse chromosome 11, homologous to human chromosome 17q21-->q22.

BMP4 rescues a non-cell-autonomous function of Msx1 in tooth development.

The development of many organs depends on sequential epithelial-mesenchymal interactions, and the developing tooth germ provides a powerful model for elucidating the nature of these inductive tissue interactions. In Msx1-deficient mice, tooth development arrests at the bud stage when Msx1 is required for the expression of Bmp4 and Fgf3 in the dental mesenchyme (Bei, M. and Maas, R.

Regulation of mammary gland development by tissue interaction.

Development of the mammary glands is initiated in the embryo but the major part of their development occurs in the adult. While development in puberty and pregnancy is dependent on hormones, prenatal and early postnatal development appear to progress autonomously. Mutual and reciprocal epithelial-mesenchymal interactions are critical for both phases of development.

Pax9-deficient mice lack pharyngeal pouch derivatives and teeth and exhibit craniofacial and limb abnormalities.

Pax genes have been shown to play important roles in mammalian development and organogenesis. Pax9, a member of this transcription factor family, is expressed in somites, pharyngeal pouches, mesenchyme involved in craniofacial, tooth, and limb development, as well as other sites during mouse embryogenesis. To analyze its function in vivo, we generated Pax9 deficient mice and show that Pax9 is essential for the development of a variety of organs and skeletal elements.

Lef1 expression is activated by BMP-4 and regulates inductive tissue interactions in tooth and hair development.

Targeted inactivation of the murine gene encoding the transcription factor LEF-1 abrogates the formation of organs that depend on epithelial-mesenchymal tissue interactions. In this study we have recombined epithelial and mesenchymal tissues from normal and LEF-1-deficient embryos at different stages of development to define the LEF-1-dependent steps in tooth and whisker organogenesis. At the initiation of organ development, formation of the epithelial primordium of the whisker but not tooth is dependent on mesenchymal Lef1 gene expression.

Tissue- and stage-specific activation of an endogenous provirus after transcription through its integration site in the opposite orientation.

Endogenous proviruses of the Moloney murine leukemia retrovirus (Mo-MuLV) are transcriptionally blocked in early embryos and in general remain silent even when the tissues have become permissive to the expression of newly integrated copies. Eventually, activation in presumably very few cells initiates rapid superinfection leading to viremia and leukemia, but the processes leading to provirus activation are unknown. Differences in the onset and development of viremia between several mouse strains carrying an endogenous Mo-MuLV (Mov lines) are attributed to a chromosomal position effect, but neither cell type nor stage of provirus activation is known for any strain.

Restricted expression of Mov13 mutant alpha 1(I) collagen gene in osteoblasts and its consequences for bone development.

Cell type-specific differences in the transcriptional control of the mouse gene coding for the alpha 1 chain of collagen type I (Col1a1) have been revealed previously with the help of the Mov13 mouse strain which carries a retroviral insert in the first intron of the gene. Transcription of this mutant Col1a1 allele is completely blocked in all mesodermal cell types tested so far, with the exception of the odontoblast where it is expressed at an apparently normal rate (Kratochwil et al. [1989] Cell 57:807-816).

Transcription of a mutant collagen I gene is a cell type and stage-specific marker for odontoblast and osteoblast differentiation.

The Mov13 allele of the mouse alpha 1(I) collagen gene carries a retroviral insert in its first intron and had been reported to be transcriptionally silent. We have recently shown, however, that this mutant gene is expressed in odontoblasts of transplanted teeth derived from homozygous and heterozygous carrier embryos. The expression of the Mov13 allele has now been followed throughout in vivo development of mandibular teeth and bone in heterozygous animals, by in situ hybridization with a probe that specifically recognizes transcripts of the mutant gene.

Retrovirus-induced insertional mutation in Mov13 mice affects collagen I expression in a tissue-specific manner.

In the Mov13 mouse mutant, transcription of the alpha 1 (1) collagen gene is blocked by a retroviral insert in the first intron. We now report that teeth derived from homozygous embryos produce a dentin layer containing normal amounts of collagen 1. In situ hybridization and RNAase protection experiments indicate that the mutant allele is efficiently transcribed in odontoblasts, in contrast to other cell types.

Use of the collagen I-deficient Mov13 mouse mutant to analyse epithelial-mesenchymal tissue interaction.

The collagen I-deficient mouse mutant (Mov13 - an embryonic recessive lethal) was used to investigate the function of this major constituent of the extracellular matrix (ECM) in organ development. All epithelial-mesenchymal organs tested as explants (lung, kidney, pancreas, salivary glands, skin) developed normally and, in particular, showed typical branching morphogenesis in the absence of collagen I. It is concluded that the ECM of these organs can organize for proper developmental function in the absence of the major interstitial collagen, but a possible morphogenetic function of other fibrillar collagens (types III and V) cannot be excluded.

Corneal morphogenesis in the Mov13 mutant mouse is characterized by normal cellular organization but disordered and thin collagen.

This paper compares corneal development in the normal and in the Mov13 mutant mouse homozygote which does not synthesize type I collagen. During the period 12-14 days of development, there is no obvious difference between cellular organization in the normal and the mutant corneas or, indeed, elsewhere in the eye. In particular, there is normal colonization of the mutant cornea by the mesenchymal cells which will form the endothelium and the fibroblasts.

Normal epithelial branching morphogenesis in the absence of collagen I.

Interstitial collagens are thought to mediate epithelial-mesenchymal interactions during organogenesis. We have used the collagen I-deficient mouse mutant Mov13 to directly investigate the role of this major representative of the interstitial collagens in epithelial branching morphogenesis. Since homozygous embryos die at midgestation, we have studied the development of organ rudiments from Mov13 homozygous (i.

Ontogeny of mesenchymal androgen receptors in the embryonic mouse mammary gland.

We demonstrate the presence of a high affinity androgen-binding site in the embryonic mouse mammary gland, and describe its appearance and development from the initial formation of the gland bud (day 12) through the androgen-responsive stage (day 14) until term (day 19). Binding assays were done on entire organ rudiments exposed to the ligand [( 3H] testosterone, [3H]5 alpha-dihydrotestosterone, or [3H]methyltrienolone) in vitro, and receptor levels are expressed per gland. In competition experiments, the binding site shows a ligand specificity of a typical rodent androgen receptor.

Induction of androgen receptor formation by epithelium-mesenchyme interaction in embryonic mouse mammary gland.

The role of tissue interaction in the development of hormone responsiveness was studied in the embryonic mammary gland of the mouse, which becomes sensitive to testosterone on day 14. Previously, the mesenchyme had been identified as the sole target tissue for the hormone, although it was also demonstrated that its response to testosterone required the presence of mammary epithelium. Using autoradiography, we now show that [3H]testosterone or [3H]5 alpha-dihydrotestosterone is bound only by those mesenchymal cells closest to the epithelial mammary bud.

Specificity of tissue interaction and origin of mesenchymal cells in the androgen response of the embryonic mammary gland.

In the androgen-induced destruction of the mammary rudiments of 14 day male mouse fetuses, the hormone acts directly only on the mesenchyme, which then condenses around the epithelial gland buds and--in some unknown way--causes their necrosis. In this paper we report that an organ-specific but not species-specific influence of mammary epithelium on the surrounding mesenchyme is required to allow its response to the hormone. This epithelial "signal" has a very short range; its transmission may depend on contact between the two tissues.