Cell influx and contractile actomyosin force drive mammary bud growth and invagination

Attribution–Noncommercial–Share Alike–No Mirror Sites licenseThe mammary gland develops from the surface ectoderm during embryogenesis and proceeds through morphological phases defined as placode, hillock, bud, and bulb stages followed by branching morphogenesis. During this early morphogenesis, the mammary bud undergoes an invagination process where the thickened bud initially protrudes above the surface epithelium and then transforms to a bulb and sinks into the underlying mesenchyme. The signaling pathways regulating the early morphogenetic steps have been identified to some extent, but the underlying cellular mechanisms remain ill defined. Here, we use 3D and 4D confocal microscopy to show that the early growth of the mammary rudiment is accomplished by migration-driven cell influx, with minor contributions of cell hypertrophy and proliferation. We delineate a hitherto undescribed invagination mechanism driven by thin, elongated keratinocytes-ring cells-that form a contractile rim around the mammary bud and likely exert force via the actomyosin network. Furthermore, we show that conditional deletion of nonmuscle myosin IIA (NMIIA) impairs invagination, resulting in abnormal mammary bud shape.Peer reviewe

Integration of IRF6 and Jagged2 signalling is essential for controlling palatal adhesion and fusion competence

In mammals, adhesion and fusion of the palatal shelves are essential mechanisms during the development of the secondary palate; failure of these processes leads to the congenital anomaly, cleft palate. The mechanisms that prevent pathological adhesion between the oral and palatal epithelia while permitting adhesion and subsequent fusion of the palatal shelves via their medial edge epithelia remain obscure. In humans, mutations in the transcription factor interferon regulatory factor 6 (IRF6) underlie Van der Woude syndrome and popliteal pterygium syndrome. Recently, we have demonstrated that mice homozygous for a mutation in Irf6 exhibit abnormalities of epithelial differentiation that results in cleft palate as a consequence of adhesion between the palatal shelves and the tongue. In the current paper, we demonstrate that Irf6 is essential for oral epithelial differentiation and that IRF6 and the Notch ligand Jagged2 function in convergent molecular pathways during this process. We further demonstrate that IRF6 plays a key role in the formation and maintenance of the oral periderm, spatio-temporal regulation of which is essential for ensuring appropriate palatal adhesion

Epidermal Differentiation: Transgenic/Knockout Mouse Models Reveal Genes Involved in Stem Cell Fate Decisions and Commitment to Differentiation

Epidermal development and differentiation are similar processes and therefore the study of one is likely to provide insight into the other. The signaling cascades required for epidermal differentiation are largely unknown. Recent evidence, however, has implicated two proteins, p63 and c-Myc, in different stages of epidermal development and differentiation. p63 was shown to be required for embryonic epidermal development. Mice lacking p63 do not develop stratified epithelia and appendages suggesting a role for p63 in the commitment to squamous epithelial lineages. Subsequent stem cell fate decisions are required to form the different structures of stratified epithelia including hair follicles, sebaceous glands, and epidermis. Several genes of the Wnt signaling pathway have been implicated in this process, including c-Myc, a downstream target of the Wnt pathway. Interestingly, targeted overexpression of c-Myc in the basal layer of the epidermis results in an increase in sebaceous gland size and number at the expense of hair follicles. This suggests that c-Myc promotes differentiation of epidermal stem cells into sebaceous glands. In this review, we discuss transgenic/knockout mouse models that have provided evidence linking c-Myc and p63 to different stages of epidermal development and differentiation

Adult Langerhans cells derive predominantly from embryonic fetal liver monocytes with a minor contribution of yolk sac–derived macrophages

Langerhans cells (LCs) are the dendritic cells (DCs) of the epidermis, forming one of the first hematopoietic lines of defense against skin pathogens. In contrast to other DCs, LCs arise from hematopoietic precursors that seed the skin before birth. However, the origin of these embryonic precursors remains unclear. Using in vivo lineage tracing, we identify a first wave of yolk sac (YS)–derived primitive myeloid progenitors that seed the skin before the onset of fetal liver hematopoiesis. YS progenitors migrate to the embryo proper, including the prospective skin, where they give rise to LC precursors, and the brain rudiment, where they give rise to microglial cells. However, in contrast to microglia, which remain of YS origin throughout life, YS-derived LC precursors are largely replaced by fetal liver monocytes during late embryogenesis. Consequently, adult LCs derive predominantly from fetal liver monocyte-derived cells with a minor contribution of YS-derived cells. Altogether, we establish that adult LCs have a dual origin, bridging early embryonic and late fetal myeloid development