Tumorhead, a Xenopus gene product that inhibits neural differentiation through regulation of proliferation

Tumorhead (TH) is a novel maternal gene product from Xenopus laevis containing several basic domains and a weak coiled-coil. Overexpression of wild-type TH resulted in increased proliferation of neural plate cells, causing expansion of the neural field followed by neural tube and craniofacial abnormalities. Overexpressed TH protein repressed neural differentiation and neural crest markers, but did not inhibit the neural inducers, pan-neural markers or mesodermal markers. Loss of function by injection of anti-TH antibody inhibited cell proliferation. Our data are consistent with a model in which tumorhead functions in regulating differentiation of the neural tissues but not neural induction or determination through its effect on cell proliferation.     

Identification of TH-B, a new oligomeric variant of the Xenopus morphogenetic factor, tumorhead

The Xenopus laevis gene tumorhead (TH) is a regulator of cell proliferation of the ectodermal germ layer during embryonic development. TH overexpression results in increased cell proliferation within the developing ectoderm, causing an expansion of the neural plate. Conversely, loss of TH function results in inhibition of proliferation of ectodermal cells. Embryos with altered levels of TH protein are unable to express neural differentiation markers, indicating that the effect of TH in proliferation is linked with differentiation in the nervous system. To date, the molecular mechanism by which TH affects cell proliferation during embryogenesis is unknown. We have utilized the yeast two-hybrid system to identify protein partners of TH that could lead us to define the mechanism or pathway through which TH functions. Using this assay we have identified a new variant of TH designated TH-B, as a potential protein partner of the original TH, now referred to as TH-A. The sequence for TH-B was found to be 85% identical at the amino acid level to the TH-A sequence. Further characterization of the TH-B variant using RT-PCR indicates that it is expressed ubiquitously throughout development from early cleavage stages until at least the tadpole stage. TH-B association with TH-A was confirmed in co-immnoprecipitation studies in Xenopus, indicating that the two variants may function as an oligomer in vivo. These studies reveal the presence of an isoform of TH that may possess novel functional capabilities.     

Induction and patterning of neuronal development,and its connection to cell cycle control

Nervous tissue is derived from early embryonic ectoderm, which also gives rise to epidermal derivatives such as skin. The progression from naive ectoderm to differentiated postmitotic neurons involves multiple steps, two of which are crucial in shaping the final neurogenesis pattern. First, is the identification of the neural plate by the process of neural induction. Second, is the selection of a restricted number of sites within the neural plate where neurogenesis, the process leading to final differentiation of neural precursors, is initiated. Recent findings point to the existence of positive inducers of the neural state, whereas, neurogenesis initiation sites appear to be largely defined by inhibition. However, both neural induction and the initiation of neurogenesis appear to be connected to cell cycle control systems that govern whether stem cell maintenance and cell proliferation, or cell specification and differentiation, take place.     

Uracil nucleotides stimulate human neural precursor cell proliferation and dopaminergic differentiation: involvement of MEK/ERK signalling

Isolation and propagation of neural stem cells derived from human brain tissue uniquely enables the study of human neurogenesis in vitro. In addition, ex vivo-expanded human neural stem/precursor cells (NPCs) may offer novel therapeutic strategies. We investigated the effects of extracellular nucleotides on the proliferation and differentiation of human mesencephalic neural stem/precursor cells (hmNPCs). When combined with the mitogens epidermal growth factor and fibroblast growth factor 2, UTP (1 microm) boosted proliferation of hmNPCs as shown by increased expression of the proliferation marker proliferating cell nuclear antigen (330%). UTP-induced proliferation was abrogated by the preferential P2Y receptor blocker pyridoxal phosphate-6-azophenyl-2',4'-disulphonic acid (PPADS). UTP also stimulated dopaminergic differentiation. Treatment with UTP (100 microm) increased the number of tyrosine hydroxylase (TH)-positive cells and TH protein by 267 and 319% respectively. UTP-stimulated dopaminergic differentiation of hmNPCs was blocked by the P2 receptor antagonists suramin (10 microm) and PPADS (100 microm). In addition, UDP (1 microm) enhanced TH protein expression by 194%. During differentiation, treatment with UTP stimulated the extracellular signal-regulated kinase (ERK) pathway. Both ERK1/2 phosphorylation and dopaminergic differentiation were inhibited by U0126, a selective ERK kinase inhibitor, as well as by suramin. When other P2 receptor agonists (ATP, ADP and adenosine 5'-O-(2-thiophosphate) (ADPbetaS); all 100 microm) were applied, both proliferation and dopaminergic differentiation of NPCs were compromised. We conclude that uracil nucleotides exert specific P2 receptor-mediated effects on midbrain-derived human NPCs, and may be used to enhance both proliferation and dopaminergic differentiation.     

Oral/aboral ectoderm differentiation of the sea urchin embryo depends on a planar or secretory signal from the vegetal hemisphere

A monoclonal antibody that recognizes oral ectoderm and esophagus of sea urchin larvae was newly produced. Distribution of the antigen, named Hpoe, was examined by indirect immunofluorescence microscopy. Hpoe did not exist in eggs and appeared during the cleavage stage. In hatched blastulae, Hpoe was detected on the apical surface of all cells. As embryogenesis progressed, Hpoe disappeared from the primary mesenchyme, archenteron and aboral ectoderm. Hpoe reappeared in foregut at the prism stage and was restricted to the oral ectoderm and esophagus at the pluteus stage. Using this antigen as a molecular marker of oral/aboral ectoderm differentiation, the role of the vegetal hemisphere in ectoderm differentiation was examined. All animal hemispheres isolated from 16-cell stage embryos, mesenchyme blastulae, early gastrulae and mid gastrulae developed into epithelial balls and every cell expressed Hpoe. These epithelial balls failed in oral/aboral ectoderm differentiation. Twenty millimolar LiCI-treated whole embryos developed into exo-gastrulae but Hpoe restriction in ectoderm occurred in these exo-gastrulae. These results show that oral/aboral ectoderm differentiation requires an inductive interaction from the vegetal hemisphere and indicate that the inductive interaction depends on a planar or secretory signal, rather than the contact of the esophagus and ectoderm.     

Inductive differentiation of two neural lineages reconstituted in a microculture system from Xenopus early gastrula cells.

Neural induction of ectoderm cells has been reconstituted and examined in a microculture system derived from dissociated early gastrula cells of Xenopus laevis. We have used monoclonal antibodies as specific markers to monitor cellular differentiation from three distinct ectoderm lineages in culture (N1 for CNS neurons from neural tube, Me1 for melanophores from neural crest and E3 for skin epidermal cells from epidermal lineages). CNS neurons and melanophores differentiate when deep layer cells of the ventral ectoderm (VE, prospective epidermis region; 150 cells/culture) and an appropriate region of the marginal zone (MZ, prospective mesoderm region; 5-150 cells/culture) are co-cultured, but not in cultures of either cell type on their own; VE cells cultured alone yield epidermal cells as we have previously reported. The extent of inductive neural differentiation in the co-culture system strongly depends on the origin and number of MZ cells initially added to culture wells. The potency to induce CNS neurons is highest for dorsal MZ cells and sharply decreases as more ventrally located cells are used. The same dorsoventral distribution of potency is seen in the ability of MZ cells to inhibit epidermal differentiation. In contrast, the ability of MZ cells to induce melanophores shows the reverse polarity, ventral to dorsal. These data indicate that separate developmental mechanisms are used for the induction of neural tube and neural crest lineages. Co-differentiation of CNS neurons or melanophores with epidermal cells can be obtained in a single well of co-cultures of VE cells (150) and a wide range of numbers of MZ cells (5 to 100). Further, reproducible differentiation of both neural lineages requires intimate association between cells from the two gastrula regions; virtually no differentiation is obtained when cells from the VE and MZ are separated in a culture well. These results indicate that the inducing signals from MZ cells for both neural tube and neural crest lineages affect only nearby ectoderm cells.     

Oral—aboral ectoderm differentiation of sea urchin embryos is disrupted in response to calcium ionophore

Intracellular signaling mediated by calcium ions has been implicated as important in controlling cell activity. The ability of calcium ionophore (A23187), which causes an increase in calcium ion concentration in the cytoplasm, to alter the pattern of differentiation of cells during sea urchin development was examined. The addition of A23187 to embryos for 3h during early cleavage causes dramatic changes in their development during gastrulation. Using tissue-specific cDNA probes and antibodies, it was shown that A23187 causes the disruption of oral–aboral ectoderm differentiation of sea urchin embryos. The critical period for A23187 to disturb the oral–aboral ectoderm differentiation is during the cleavage stage, and treatment of embryos with A23187 after that time has little effect. The A23187 does not affect the formation of the three germ layers. These results indicate that intracellular signals mediated by calcium ions may play a key role in establishment of the oralaboral axis during sea urchin development.     

ANALYSIS OF CELL PROLIFERATION DURING EARLY EMBRYOGENESIS

Cell proliferation was examined during early embryogenesis of the newt ( Triturus pyrrhogaster ) by various methods. After the two-cell stage, at 23°C, the blastomere (cell) number per whole embryo increased logarithmically until the mid-blastula stage (for about 19 hr) and the rate of increase slowed down in and after the late blastula stage. On the other hand, the synchronous cleavage of the blastomeres at the animal pole continued for 18 hr until the twelfth cleavage (mid-blastula) and the transition from synchronous to asynchronous division occurred abruptly at and after the thirteenth cell division (late blastula). The study also showed that the presumptive neuro-ectoderm consisted mainly of cells of the fifteenth generation (G-15) at the onset of gastrulation (pigment stage).
The present study suggested that the number of ectodermal cells of the early gastrula (stage 12a) nearly doubled during gastrulation at the presumptive neuro-ectoderm. This means that most of the ectodermal cells are in G-16 at the end of gastrulation. On the other hand, both mitotic activity and the rate of cell increase gradually diminished during gastrulation in the ectoderms of both the presumptive neural and epidermal regions, and there are evidently significant differences in both activities between the neuro-ectoderm and the epidermal ectoderm after stage 13b: the epidermal ectoderm showed greater decrease in the rate of both mitotic activity and cell proliferation than the neuro-ectoderm.
These facts suggested that, whether the ectodermal cells will differentiate into neural cells or epidermal cells is determined during G-15 or G-16 in normal primary induction.     

Reversible inhibition by DMSO of hydrocortisone-induced keratinization of chick embryonic skin

Hydrocortisone, at a physiological concentration of 10^?8 M, induces keratinization of chick embryonic tarsometatarsal skin in a chemically defined medium in 4 days [1]. The presence of 1–4% DMSO with hydrocortisone reversibly prevented this keratinization. DMSO suppressed the appearance of epidermal structural protein, which was preferentially induced by hydrocortisone. It also suppressed hydrocortisone-induced epidermal transglutaminase activity; which was presumably responsible for polymerization and decrease in solubility of epidermal protein in keratinization, and it suppressed increase of epidermal protein. When DMSO was added to differentiated skin or added concomitantly with a higher concentration of hydrocortisone, epidermal transglutaminase activity was suppressed. Electron microscopic studies showed that hydrocortisone induced tonofilament bundles and keratinized cells with cellular envelopes, which are all characterestic of α-type keratinization of chick embryonic skin [2], and that DMSO inhibited hydrocortisone induced keratinization and kept the epidermis in an undifferentiated state. Moreover, DMSO inhibited epidermal DNA synthesis and increase in thickness of the epidermis during culture of hydrocortisone-treated skin, indicating that it suppressed cell proliferation as well as cell differentiation. DMSO by itself at 1 or 2 % did not affect epidermal cell differentiation, but suppressed cell proliferation when compared with untreated control.     

Epidermal cell proliferation and terminal differentiation in skin organ culture after topical exposure to sodium dodecyl sulphate

Summary Epidermal cell proliferation and differentiation were investigated in vitro after exposure to the anionic surfactant sodium dodecyl sulfate (SDS). Human skin organ cultures were exposed topically to various concentrations of SDS for 22 h, after which the irritant was removed. Cell proliferation was measured immunohistochemically by incorporation of bromodeoxyuridine (BrdU) into the DNA of cells during S-phase, while the expression of transglutaminase and involucrin were used as markers of differentiation. Cell proliferation was moderately increased at concentrations of SDS that did not affect the histomorphology (0.1% and 0.2% SDS). A marked increase of cell proliferation was observed 22 to 44 h after removal of SDS at a concentration (0.4%) that induced slight cellular damage. Exposure of human skin organ cultures to a toxic concentration of SDS (1.0%) led to decreased cell proliferation. Transglutaminase and involucrin were expressed in the more basal layers of the epidermis after exposure to 0.4% or 1.0% SDS. Moreover, intra-epidermal sweat gland ducts were positive for transglutaminase at these irritant concentrations. These in vitro data demonstrate that SDS-induced alterations of epidermal cell kinetics, as described in vivo are at least partly due to local mechanisms and do not require the influx of infiltrate cells. However, we were unable to relate the altered cell kinetics to the release of interleukin-1α or interleukin-6. Furthermore, supplementation of the culture medium with 12-hydroxyeicosantetraenoic acid did not affect epidermal cell proliferation. Rabbit skin cultures appeared more sensitive to SDS than human skin. At nontoxic doses, the irritant induced an increase of epidermal cell proliferation, similar to that observed in human skin discs.     

Induction of differentiation of HL-60 cells by protein kinase C inhibitor, K252a

To clarify the role of protein kinase C and protein kinase A in cell proliferation and differentiation, the effects of K252a and its derivatives (K252b, KT5720), which have different inhibitory activity to these protein kinases, on the proliferation and differentiation of HL-60 cells were investigated. The proliferation and DNA synthesis of the HL-60 cells were inhibited by K252a in a dose dependent manner. However, K252b and KT5720 which are more specific inhibitors of protein kinase C or protein kinase A, respectively, had no observable effect on cell proliferation. K252a (40nM) enhanced the differentiation of HL-60 cells induced by 1,25(OH)2D3, retinoic acid and DMSO. K252b and KT5720 did not affect 1,25(OH)2D3-induced differentiation. K252a significantly inhibited the differentiation induced by PMA. These results demonstrate that K252a but not its derivatives can function as an antitumor drug and enhancer of the differentiation induced by various inducers.     

Phenoloxidase, a marker enzyme for differentiation of the neural ectoderm and the epidermal ectoderm during embryonic development of amphioxus Branchiostoma belcheri tsingtaunese

The development of phenoloxidase during amphioxus embryogenesis was spectrophotometrically and histochemically studied for the first time in the present study. It was found that (1) PO activity initially appeared in the general ectoderm including the neural ectoderm and the epidermal ectoderm at the early neurula stage but not in the mesoderm or the endoderm, and (2) PO activity disappeared in the neural plate cells but remained unchanged in the epidermal cells when the neural plate was morphologically quite distinct from the rest of the ectoderm. It is apparent that PO could serve as a marker enzyme for differentiation of the neural ectoderm from the epidermal ectoderm during embryonic development of amphioxus.     

Neural induction: New achievements and prospects

Neural induction is a triggering of neural differentiation in a portion of cells of the vertebrate embryonic ectoderm in response to signals emanating from adjacent tissues. As revealed more than ten years ago in experiments with Xenopus embryos, the major role in neural induction is played by suppression of the bone morphogenetic protein (BMP) signaling cascade in neural cell precursors. Consequently, the epidermal differentiation program is blocked and a neural program is activated in such cells by default. The so-called default model of neural induction was supported with other experimental subjects. An important role in neural induction is also played by the FGF and Wnt signaling cascades via their interactions with the BMP cascade. As new regulatory proteins involved in neural induction were identified and their properties analyzed in detail, it became possible to apply mathematical modeling to study, with the example of neural induction, the spatial self-organization of cell differentiation in the embryo as one of the main problems of developmental biology.     

Bmp activity establishes a gradient of positional information throughout the entire neural plate.

Bone morphogenetic proteins (Bmps) are key regulators of dorsoventral (DV) patterning. Within the ectoderm, Bmp activity has been shown to inhibit neural development, promote epidermal differentiation and influence the specification of dorsal neurons and neural crest. In this study, we examine the patterning of neural tissue in mutant zebrafish embryos with compromised Bmp signalling activity. We find that although Bmp activity does not influence anteroposterior (AP) patterning, it does affect DV patterning at all AP levels of the neural plate. Thus, we show that Bmp activity is required for specification of cell fates around the margin of the entire neural plate, including forebrain regions that do not form neural crest. Surprisingly, we find that Bmp activity is also required for patterning neurons at all DV levels of the CNS. In swirl/bmp2b(-) (swr(-)) embryos, laterally positioned sensory neurons are absent whereas more medial interneuron populations are hugely expanded. However, in somitabun(-) (sbn(-)) embryos, which probably retain higher residual Bmp activity, it is the sensory neurons and not the interneurons that are expanded. Conversely, in severely Bmp depleted embryos, both interneurons and sensory neurons are absent and it is the most medial neurons that are expanded. These results are consistent with there being a gradient of Bmp-dependent positional information extending throughout the entire neural and non-neural ectoderm.     

SIRT1 regulates tyrosine hydroxylase expression and differentiation of neuroblastoma cells via FOXO3a

To examine the function of SIRT1 in neuronal differentiation, we employed all-trans retinoic acid (ATRA)-induced differentiation of neuroblastoma cells. Nicotinamide inhibited neurite outgrowth and tyrosine hydroxylase (TH) expression. Inhibition of PARP or histone deacetylase did not inhibit TH expression, showing the effect to be SIRT1 specific. Expression of FOXO3a and its target proteins were increased during the differentiation and reduced by nicotinamide. FOXO3a deacetylation was increased by ATRA and blocked by nicotinamide. SIRT1 and FOXO3a siRNA inhibited ATRA-induced up-regulation of TH and differentiation. Taken together, these results indicate that SIRT1 is involved in ATRA-induced differentiation of neuroblastoma cells via FOXO3a.     

Inhibited morphological terminal differentiation and enhanced proliferation of cultured mouse epidermal cells at different concentrations of dimethyl sulphoxide

Dimethyl sulphoxide (DMSO), at concentrations of 1-2%, induces terminal differentiation in several different cell types in vitro and enhances the growth of newborn mouse epidermal cells in primary culture under conditions that also permit terminal differentiation. We have found that DMSO concentrations approaching 4% reversibly inhibited (with little overt toxicity) terminal differentiation of normal epidermal cells from newborn SENCAR mice. Cells cultured in medium containing 4% DMSO and calcium in excess of 1 mM did not stratify extensively or slough large amounts of keratinized debris into the medium as occurred in control cultures, nor did they form large numbers of squamous cells or keratin bundles, as revealed by light and electron microscopy. The number of detergent-insoluble cornified envelopes was similarly reduced. Long-term growth of epidermal colonies in secondary culture was optimum in 1% DMSO, this concentration also permitting normal terminal differentiation of these cells. Since DMSO had these effects on epidermal cells in vitro, it may also affect epidermal cell proliferation and terminal differentiation in vivo, an important consideration should DMSO ever be approved for topical use in the US.