Mechanical feedback in morphogenesis and cell differentiation

Studies of mechanical stresses and mechanical feedback at the cell level are reviewed. It is shown that cells and embryonic tissues respond to external mechanical stresses and can generate such stresses themselves. Regular feedback loops between external (passive) and internal (active) mechanical stresses have been established. They are essential for cell survival, determination of the direction of their differentiation, and selforganization of morphogenetic processes. Relevant experimental data are presented, and models of mechanical feedback loops are discussed.     

Experimental analysis of the mechanisms of somite morphogenesis

Earlier studies have suggested influences on somite morphogenesis by “somite-forming centers,” primitive streak regression, Hensen's node and notochord, and neural plate. Contradictions among these studies were unresolved.Our experiments resolve these conflicts and reveal roles of the primitive streak and notochord in shearing the prospective somite mesoderm into right and left halves and releasing somite-forming capabilities already present. The neural plate appears to be the principal inductor of somites.Embryo fragments containing no somite-forming centers, node, notochord, or streak nevertheless formed somites within 10 hr. Such somites disperse within the next 14–24 hr, which may explain why others failed to see them. In these fragments, an incision alongside the streak substitutes for streak regression in releasing somite formation. All such somites form simultaneously rather than in the normal anteroposterior progression. These fragments contain neural plate, but not notochord. We believe that physical attachment of somites to notochord in normal embryos stabilizes them and prevents dispersal.Pieces of epiblast were rotated 180° putting neural plate over lateral plate mesoderm regions. Somites were induced from the lateral plate by the displaced neural plate region. This is additional evidence of the powerful ability of neuroepithelium to induce somites.     

MnSOD drives neuroendocrine differentiation, androgen independence, and cell survival in prostate cancer cells

An increase in neuroendocrine (NE) cell number has been associated with progression of prostate tumor, one of the most frequent cancers among Western males. We previously reported that mitochondrial manganese superoxide dismutase (MnSOD) increases during the NE differentiation process. The goal of this study was to find whether MnSOD up-regulation is enough to induce NE differentiation. Several human prostate cancer LNCaP cell clones stably overexpressing MnSOD were characterized and two were selected (MnSOD-S4 and MnSOD-S12). MnSOD overexpression induces NE morphological features as well as coexpression of the NE marker synaptophysin. Both MnSOD clones exhibit lower superoxide levels and higher H(2)O(2) levels. MnSOD-overexpressing cells show higher proliferation rates in complete medium, but in steroid-free medium MnSOD-S12 cells are still capable of proliferation. MnSOD up-regulation decreases androgen receptor and prevents its nuclear translocation. MnSOD also induces up-regulation of Bcl-2 and prevents docetaxel-, etoposide-, or TNF-induced cell death. Finally, MnSOD-overexpressing cells enhance growth of androgen-independent PC-3 cells but reduce growth of androgen-dependent cells. These results indicate that redox modulation caused by MnSOD overexpression explains most NE-like features, including morphological changes, NE marker expression, androgen independence, inhibition of apoptosis, and enhancement of cell growth. Many of these events can be associated with the androgen dependent-independent transition during prostate cancer progression.     

Evolving mechanisms of morphogenesis: on the interplay between differential adhesion and cell differentiation

Differential cell adhesion, mediated by e.g. integrin and cadherins/catenines, plays an important role in morphogenesis and it has been shown that there is intimate cross-talk between their expression and modification, and inter-cellular signalling, cell differentiation, cell growth and apoptosis. In this paper, we introduce and use a formal model to explore the morphogenetic potential of the interplay between these processes. We demonstrate the formation of interesting morphologies. Initiated by cell differentiation, differential cell adhesion leads to a long transient of cell migrations, e.g. engulfing and intercalation of cells and cell layers. This transient can be sustained dynamically by further cell differentiation, and by cell growth/division and cell death which are triggered by the (also long range) forces (stretching and squeezing) generated by the cell adhesion. We study the interrelation between modes of cell differentiation and modes of morphogenesis. We use an evolutionary process to zoom in on gene-regulation networks which lead to cell differentiation. Morphogenesis is not selected for but appears as a side-effect. The evolutionary dynamics shows the hallmarks of evolution on a rugged landscape, including long neutral paths. We show that a combinatorially large set of morphologies occurs in the vicinity of a neutral path which sustains cell differentiation. Thus, an almost linear molecular phylogeny gives rise to mosaic evolution on the morphological level.     

PCNS: a novel protocadherin required for cranial neural crest migration and somite morphogenesis in Xenopus

Protocadherins (Pcdhs), a major subfamily of cadherins, play an important role in specific intercellular interactions in development. These molecules are characterized by their unique extracellular domain (EC) with more than 5 cadherin-like repeats, a transmembrane domain (TM) and a variable cytoplasmic domain. PCNS (Protocadherin in Neural crest and Somites), a novel Pcdh in Xenopus, is initially expressed in the mesoderm during gastrulation, followed by expression in the cranial neural crest (CNC) and somites. PCNS has 65% amino acid identity to Xenopus paraxial protocadherin (PAPC) and 42-49% amino acid identity to Pcdh 8 in human, mouse, and zebrafish genomes. Overexpression of PCNS resulted in gastrulation failure but conferred little if any specific adhesion on ectodermal cells. Loss of function accomplished independently with two non-overlapping antisense morpholino oligonucleotides resulted in failure of CNC migration, leading to severe defects in the craniofacial skeleton. Somites and axial muscles also failed to undergo normal morphogenesis in these embryos. Thus, PCNS has essential functions in these two important developmental processes in Xenopus.     

beta-Catenin controls hair follicle morphogenesis and stem cell differentiation in the skin

beta-Catenin is an essential molecule in Wnt/wingless signaling, which controls decisive steps in embryogenesis. To study the role of beta-catenin in skin development, we introduced a conditional mutation of the gene in the epidermis and hair follicles using Cre/loxP technology. When beta-catenin is mutated during embryogenesis, formation of placodes that generate hair follicles is blocked. We show that beta-catenin is required genetically downstream of tabby/downless and upstream of bmp and shh in placode formation. If beta-catenin is deleted after hair follicles have formed, hair is completely lost after the first hair cycle. Further analysis demonstrates that beta-catenin is essential for fate decisions of skin stem cells: in the absence of beta-catenin, stem cells fail to differentiate into follicular keratinocytes, but instead adopt an epidermal fate.     

Role of cell division in branching morphogenesis and differentiation of the embryonic pancreas

A new culture system for the embryonic pancreas enables the formation of a branched organ in vitro. In such cultures, each terminal branch originates as a small bud and the number of buds and of terminal branches increases progressively with the expansion of the culture. However buds can also be resorbed during growth. The normal labelling index of cells in incipient buds ("tips") is greater than between buds ("dips") suggesting that budding may be driven by a local increase of cell division. Consistent with this, treatments that reduce cell division repress the formation of buds and branches. It is not possible to initiate budding in isolated endodermal epithelium by treatment with fibroblast growth factor, although this does increase the degree of differentiation of exocrine cells. Cultures in which cell division is completely inhibited by aphidicolin treatment will produce more endocrine cells than usual and inhibit the differentiation of exocrine cells. Consistent with this it is found that in untreated cultures the division of endocrine precursors cannot be detected by BrdU labelling whereas the division of exocrine precursors is frequent. It is concluded that cell division is necessary for bud formation in the embryonic pancreas and that the growth factors required for this normally come from the mesenchyme. Cell division is also necessary for exocrine differentiation. Endocrine cells, however, can arise from undifferentiated progenitors without cell division.     

Post-embryonic nerve-associated precursors to adult pigment cells: genetic requirements and dynamics of morphogenesis and differentiation

The pigment cells of vertebrates serve a variety of functions and generate a stunning variety of patterns. These cells are also implicated in human pathologies including melanoma. Whereas the events of pigment cell development have been studied extensively in the embryo, much less is known about morphogenesis and differentiation of these cells during post-embryonic stages. Previous studies of zebrafish revealed genetically distinct populations of embryonic and adult melanophores, the ectotherm homologue of amniote melanocytes. Here, we use molecular markers, vital labeling, time-lapse imaging, mutational analyses, and transgenesis to identify peripheral nerves as a niche for precursors to adult melanophores that subsequently migrate to the skin to form the adult pigment pattern. We further identify genetic requirements for establishing, maintaining, and recruiting precursors to the adult melanophore lineage and demonstrate novel compensatory behaviors during pattern regulation in mutant backgrounds. Finally, we show that distinct populations of latent precursors having differential regenerative capabilities persist into the adult. These findings provide a foundation for future studies of post-embryonic pigment cell precursors in development, evolution, and neoplasia.     

Cellular differentiation and morphogenesis in Cordylophora

Summary The interstitial cells ofCordylophora were destroyed by treating animals with 4,500 Roentgens of x-irradiation. Within 5–6 days after treatment no interstitial cells were detected in the treated animals and they were never seen in later stages. Some cell divisions were noted in the epidermal epithelio-muscular cells of the x-rayed animals which survived for four weeks. This was ample time to perform reaggregation-reconstitution experiments.Isolated, untreated coenosarc formed a mass from which hydranths and stolons arose. X-rayed coenosarc also formed these structures, although regenerative capacity was less than that of normal coenosarc. The number of stolons and hydranths produced decreased with length of time after irradiation. Both normal and x-rayed coenosarc masses exhibited a tendency to form a greater number of hydranths than stolons when the ratio of epidermis to gastrodermis was low and a greater number of stolons when the ratio of epidermis to gastrodermis was high. Masses prepared from the amounts of epidermis and gastrodermis normally found in intact animals produced intermediate numbers of hydranths and stolons.Isolated, untreated epidermis produced a gastrodermal layer from interstitial cells. They migrated to the inner surface of the epidermal epithelio-muscular cells, enlarged and differentiated into typical gastrodermal-digestive cells. These preparations formed hydranths and developed into colonies. X-irradiated epidermis did not form an inner gastrodermal layer but did secrete perisarc on the periphery. In some ases a second layer of epidermal epithelio-muscular cells was noted on the interior of the x-rayed masses. However, none of the irradiated epidermal masses produced hydranths or stolons or survived to form colonies.Gastrodermis was isolated from normal animals and although the cells rounded up into a spherical mass no morphogenesis occurred and the masses disintegrated within 12–24 hours. Irradiated gastrodermis behaved in the same manner.Normal epidermis was applied to x-rayed gastrodermis and from these preparations normal animals were produced.Normal, untreated gastrodermis combined with x-rayed epidermis yielded viable animals. Interstitial cells appeared to be produced by dedifferentiation of gland cells. The interstitial cells thus formed were able to divide and differentiate into cnidoblasts typical of epidermis.Thus, inCordylophora both epidermal and gastrodermal cells have the capacity to form cell types characteristic of the reciprocal layer.

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Zusammenfassung Die Interstitialzellen vonCordylophora wurden durch Röntgenbestrahlung (4,500 r) zerstört. 5–6 Tage nach der Bestrahlung waren keine Interstitialzellen mehr feststellbar, und auch in späteren Stadien traten nie mehr solche auf. Einige Zellteilungen wurden in den Epithel-Muskelzellen der bestrahlten Tiere beobachtet. Die Tiere blieben 4 Wochen am Leben, so daß Reaggregations- und Rekonstitutionsexperimente durchgeführt werden konnten.Isoliertes, unbehandeltes Coenosark bildete eine Zellmasse, aus der heraus Hydranthen und Stolonen wuchsen. Dieselben Strukturen entstanden aus bestrahltem Coenosark, wenn auch die Regenerationsfähigkeit des bestrahlten Cornosarks vermindert war. Die Zahl der gebildeten Hydranthen und Stolonen nahm mit zunehmender Zeit nach der Bestrahlung ab. Normale und auch bestrahlte Coenosark-Massen bildeten im allgemeinen mehr Hydranthen als Stolonen, wenn das Verhältnis Epidermis: Gastrodermis niedrig war, aber mehr Stolonen, wenn dag Verhältnis hoch war. Coenosark-Massen, die Epidermis und Gastrodermis im normalerweise vorhandenen Verhältnis enthielten, bildeten intermediäre Zahlen von Hydranten und Stolonen aus.Isolierte, unbehandelte Epidermis bildete aus Interstitialzellen eine Gastrodermisschicht. Dabei wanderten die Interstitialzellen auf die innere Oberfläche der epidermalen Epithelmuskelzellen, wurden größer, und bildeten typische gastrodermale Verdauungszellen. Solche Präparate bildeten Hydranthen und entwickelten sich in Kolonien. Bestrahlte Epidermis bildete keine Gastrodermis aus, sezernierte aber Perisark auf der Peripherie. In einigen Fällen wurde eine zweite Schicht von epidermalen Epithelmuskelzellen beobachtet im Innern der bestrahlten Massen. Me aber bildete eine bestrahlte Epidermismasse Hydranthen oder Stolonen, und nie Kolonien.Wenn Gastrodermis aus normalen Tieren isoliert wurde, rundeten sich die Zellen sich zu einer kugeligen Masse ab, aber es kam nie zu einer Morphogenese, und die Massen desintegrierten innerhalb 12–24 Std. Bestrahlte Gastrodermis verhielt sich ebenso.Wenn normale Epidermis auf bestrahlte Gastrodermis gepflanzt wurde, entstanden normale Tiere.Wenn normale Gastrodermis mit bestrahlter Epidermis kombiniert wurde, entstanden ebenfalls normale Tiere. Interstitialzellen entstanden durch Dedifferenzierung von Drüsenzellen. Die dabei gebildeten Interstitialzellen teilten sich und bildeten für Epidermis typische Cnidoblasten. Bei Cordylophora haben demzufolge epidermale, als auch gastrodermale Zellen die Fähigkeit, Zellen der reziproken Zellschicht auszubilden.

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The author wishes to acknowledge the financial aid received for this project from the National Institutes of Health, Bethesda, Md. through their University Biomedical Sciences Support Program.     

Medial pioneer fibers pattern the morphogenesis of early myoblasts derived from the lateral somite

The first wave of myoblasts which constitutes the post-mitotic myotome stems from the medial epithelial somite. Whereas medial pioneers extend throughout the entire mediolateral myotome at cervical and limb levels, at flank regions they are complemented laterally by a population of early myoblasts emerging from the lateral epithelial somite. These myoblasts delaminate underneath the nascent dermomyotome and become post-mitotic. They are Myf5-positive but express MyoD and desmin only a day later while differentiating into fibers. Overexpression of Noggin in the lateral somite triggers their premature differentiation suggesting that lateral plate-BMP4 maintains them in an undifferentiated state. Moreover, directly accelerating their differentiation by MyoD overexpression prior to arrival of medial fibers, generates a severely mispatterned lateral myotome. This is in contrast to medial pioneers that have the capacity for self-organization. Furthermore, inhibiting differentiation of medial pioneers with dominant-negative MyoD also disrupts lateral myoblast patterning and differentiation. Thus, we propose that medial pioneers are needed for proper morphogenesis of the lateral population which is kept as undifferentiated mesenchyme by BMP4 until their arrival. In addition, medial pioneers also organize dermomyotome lip-derived fibers suggesting that they have a general role in patterning myotome development.     

Epidermal growth factor inhibits morphogenesis and cell differentiation in cultured mouse embryonic teeth

Although local epithelial-mesenchymal tissue interactions which are presumably mediated by extracellular matrix molecules are important regulators of tooth morphogenesis and differentiation, our studies have indicated that these developmental processes also depend on circulating molecules. The iron-carrying serum protein transferrin is necessary for the early morphogenesis of mouse tooth in organ culture (A-M. Partanen, I. Thesleff, and P. Ekblom, 1984, Differentiation 27, 59-66). In the present study we have examined the effects of other growth factors on mouse tooth germs grown in a chemically defined medium containing transferrin. Fibroblast growth factor and platelet derived growth factor had no detectable effects but epidermal growth factor (EGF) inhibited dramatically the morphogenesis of teeth, and prevented odontoblast and ameloblast cell differentiation. EGF stimulated cell proliferation in the explants measured as [3H]thymidine incorporation in DNA. However, when the distribution of dividing cells was visualized in autoradiographs, it was observed that cell proliferation was stimulated in the dental epithelium but was inhibited in the dental mesenchyme. The inhibition of cell proliferation in the dental mesenchyme apparently caused the inhibition of morphogenesis. We do not know whether the dental epithelium or mesenchyme was the primary target for the action of EGF in the inhibition of morphogenesis. It is, however, apparent that the response of the dental mesenchymal cells to EGF (inhibition of proliferation) is regulated by their local environment, since EGF enhanced proliferation when these cells were disaggregated and cultured as monolayers. This indicates that the organ culture system where the various embryonic cell lineages are maintained in their original environment corresponds better to the in vivo situation when the roles of exogenous growth factors during development are examined.     

Semaphorin 3A contributes to distal pulmonary epithelial cell differentiation and lung morphogenesis

Rationale

Semaphorin 3A (Sema3A) is a neural guidance cue that also mediates cell migration, proliferation and apoptosis, and inhibits branching morphogenesis. Because we have shown that genetic deletion of neuropilin-1, which encodes an obligatory Sema3A co-receptor, influences airspace remodeling in the smoke-exposed adult lung, we sought to determine whether genetic deletion of Sema3A altered distal lung structure.

Methods

To determine whether loss of Sema3A signaling influenced distal lung morphology, we compared pulmonary histology, distal epithelial cell morphology and maturation, and the balance between lung cell proliferation and death, in lungs from mice with a targeted genetic deletion of Sema3A (Sema3A^-/-) and wild-type (Sema3A^+/+) littermate controls.

Results

Genetic deletion of Sema3A resulted in significant perinatal lethality. At E17.5, lungs from Sema3A^-/- mice had thickened septae and reduced airspace size. Distal lung epithelial cells had increased intracellular glycogen pools and small multivesicular and lamellar bodies with atypical ultrastructure, as well as reduced expression of type I alveolar epithelial cell markers. Alveolarization was markedly attenuated in lungs from the rare Sema3A^-/- mice that survived the immediate perinatal period. Furthermore, Sema3A deletion was linked with enhanced postnatal alveolar septal cell death.

Conclusions

These data suggest that Sema3A modulates distal pulmonary epithelial cell development and alveolar septation. Defining how Sema3A influences structural plasticity of the developing lung is a critical first step for determining if this pathway can be exploited to develop innovative strategies for repair after acute or chronic lung injury.     

Sequential activation of three myogenic regulatory genes during somite morphogenesis in quail embryos.

We report the cloning of two new quail myogenic cDNAs, quail myogenic factor 2 (qmf2) and qmf3, which encode helix-loop-helix proteins homologous to mammalian myogenic factors myogenin and myf-5. In situ hybridization has been used to investigate the developmental expression of qmf2 and qmf3, as well as qmf1, the quail homologue to mammalian MyoD1, during the formation of the brachial somites. These studies show that qmf1 and qmf3 are activated sequentially in medially localized somite cells, immediately following somite formation but prior to myotome formation. qmf1, qmf2, and qmf3 are expressed in the myotome of compartmentalized somites. These findings suggest that determination of the myogenic cell lineage in quail somites is a progressive process controlled by influences of the neural tube on the expression of the qmf regulatory genes in newly forming somites.