Petra Celá

Instability restricts signaling of multiple fibroblast growth factors.

Fibroblast growth factors (FGFs) deliver extracellular signals that govern many developmental and regenerative processes, but the mechanisms regulating FGF signaling remain incompletely understood. Here, we explored the relationship between intrinsic stability of FGF proteins and their biological activity for all 18 members of the FGF family. We report that FGF1, FGF3, FGF4, FGF6, FGF8, FGF9, FGF10, FGF16, FGF17, FGF18, FGF20, and FGF22 exist as unstable proteins, which are rapidly degraded in cell cultivation media. Biological activity of FGF1, FGF3, FGF4, FGF6, FGF8, FGF10, FGF16, FGF17, and FGF20 is limited by their instability, manifesting as failure to activate FGF receptor signal transduction over long periods of time, and influence specific cell behavior in vitro and in vivo. Stabilization via exogenous heparin binding, introduction of stabilizing mutations or lowering the cell cultivation temperature rescues signaling of unstable FGFs. Thus, the intrinsic ligand instability is an important elementary level of regulation in the FGF signaling system.

Embryonic Toxicity of Nanoparticles

Applications of nanoparticles (NP) in medicine, industry and other branches of human activities undoubtedly contribute to technology development and well-being. However, as NP are very small units in a wide range of materials, there is a lack of information related to possible side effects potentially affecting the health of organisms. There is increasing experimental interest in the determination of environmental effects on humans exposed to NP. Most such experimental studies focus on adult populations or adult experimental animals. However, embryos can be more sensitive to pollutants and environmental impacts in some species. Therefore, some investigations dealing particularly with the effects of NP on embryonic development have appeared recently and this issue is becoming of great concern. The aim of this review is to summarize the knowledge on the effects of various nanomaterials on embryonic development. A comprehensive collection of significant experimental nanotoxicity data is presented, which also indicate how the toxic effect of NP can be mediated and modulated with respect to possible effective protection strategies.

MORN5 Expression during Craniofacial Development and Its Interaction with the BMP and TGFβ Pathways

MORN5 (MORN repeat containing 5) is encoded by a locus positioned on chromosome 17 in the chicken genome. The MORN motif is found in multiple copies in several proteins including junctophilins or phosphatidylinositol phosphate kinase family and the MORN proteins themselves are found across the animal and plant kingdoms. MORN5 protein has a characteristic punctate pattern in the cytoplasm in immunofluorescence imaging. Previously, MORN5 was found among differentially expressed genes in a microarray profiling experiment of the chicken embryo head. Here, we provided in situ hybridization to analyse, in detail, the MORN5 expression in chick craniofacial structures. The expression of MORN5 was first observed at stage HH17-18 (E2.5). MORN5 expression gradually appeared on either side of the primitive oral cavity, within the maxillary region. At stage HH20 (E3), prominent expression was localized in the mandibular prominences lateral to the midline. From stage HH20 up to HH29 (E6), there was strong expression in restricted regions of the maxillary and mandibular prominences. The frontonasal mass (in the midline of the face) expressed MORN5, starting at HH27 (E5). The expression was concentrated in the corners or globular processes, which will ultimately fuse with the cranial edges of the maxillary prominences. MORN5 expression was maintained in the fusion zone up to stage HH29. In sections MORN5 expression was localized preferentially in the mesenchyme. Previously, we examined signals that regulate MORN5 expression in the face based on a previous microarray study. Here, we validated the array results with in situ hybridization and QPCR. MORN5 was downregulated 24 h after Noggin and/or RA treatment. We also determined that BMP pathway genes are downstream of MORN5 following siRNA knockdown. Based on these results, we conclude that MORN5 is both regulated by and required for BMP signaling. The restricted expression of MORN5 in the lip fusion zone shown here supports the human genetic data in which MORN5 variants were associated with increased risk of non-syndromic cleft lip with or without cleft palate.

BMP signaling regulates the fate of chondro-osteoprogenitor cells in facial mesenchyme in a stage-specific manner

Background: Lineage tracing has shown that most of the facial skeleton is derived from cranial neural crest cells. However, the local signals that influence postmigratory, neural crest‐derived mesenchyme also play a major role in patterning the skeleton. Here, we study the role of BMP signaling in regulating the fate of chondro‐osteoprogenitor cells in the face. Results: A single Noggin‐soaked bead inserted into stage 15 chicken embryos induced an ectopic cartilage resembling the interorbital septum within the palate and other midline structures. In contrast, the same treatment in stage 20 embryos caused a loss of bones. The molecular basis for the stage‐specific response to Noggin lay in the simultaneous up‐regulation of SOX9 and downregulation of RUNX2 in the maxillary mesenchyme, increased cell adhesiveness as shown by N‐cadherin induction around the beads and increased RA pathway gene expression. None of these changes were observed in stage 20 embryos. Conclusions: These experiments demonstrate how slight changes in expression of growth factors such as BMPs could lead to gain or loss of cartilage in the upper jaw during vertebrate evolution. In addition, BMPs have at least two roles: one in patterning the skull and another in regulating the skeletogenic fates of neural crest‐derived mesenchyme. Developmental Dynamics 245:947–962, 2016.

Effect of FGFR inhibitors on chicken limb development

Fibroblast growth factor (FGF) signalling appears essential for the regulation of limb development, but a full complexity of this regulation remains unclear. Here, we addressed the effect of three different chemical inhibitors of FGF receptor tyrosine kinases (FGFR) on growth and patterning of the chicken wings. The inhibitor PD173074 caused shorter and thinner wing when using lower concentration. Microinjection of higher PD173074 concentrations (25 and 50 mmol/L) into the wing bud at stage 20 resulted in the development of small wing rudiment or the total absence of the wing. Skeletal analysis revealed the absence of the radius but not ulna, deformation of metacarpal bones and/or a reduction of digits. Treatment with PD161570 resembled the effects of PD173074. NF449 induced shortening and deformation of the developing wing with reduced autopodium. These malformed embryos mostly died at the stage HH25–29. PD173074 reduced chondrogenesis also in the limb micromass cultures together with early inhibition of cartilaginous nodule formation, evidenced by lack of sulphated proteoglycan and peanut agglutinin expression. The effect of FGFR inhibition on limb development observed here was unlikely mediated by excessive cell death as none of the inhibitors caused massive apoptosis at low concentrations. More probably, FGFR inhibition decreased both the proliferation and adhesion of mesenchymal chondroprogenitors. We conclude that FGFR signalling contributes to the regulation of the anterior‐posterior patterning of zeugopod during chicken limb development.

Role of Primary Cilia in Odontogenesis

Primary cilium is a solitary organelle that emanates from the surface of most postmitotic mammalian cells and serves as a sensory organelle, transmitting the mechanical and chemical cues to the cell. Primary cilia are key coordinators of various signaling pathways during development and maintenance of tissue homeostasis. The emerging evidence implicates primary cilia function in tooth development. Primary cilia are located in the dental epithelium and mesenchyme at early stages of tooth development and later during cell differentiation and production of hard tissues. The cilia are present when interactions between both the epithelium and mesenchyme are required for normal morphogenesis. As the primary cilium coordinates several signaling pathways essential for odontogenesis, ciliary defects can interrupt the latter process. Genetic or experimental alterations of cilia function lead to various developmental defects, including supernumerary or missing teeth, enamel and dentin hypoplasia, or teeth crowding. Moreover, dental phenotypes are observed in ciliopathies, including Bardet-Biedl syndrome, Ellis-van Creveld syndrome, Weyers acrofacial dysostosis, cranioectodermal dysplasia, and oral-facial-digital syndrome, altogether demonstrating that primary cilia play a critical role in regulation of both the early odontogenesis and later differentiation of hard tissue–producing cells. Here, we summarize the current evidence for the localization of primary cilia in dental tissues and the impact of disrupted cilia signaling on tooth development in ciliopathies.

Expression, function and regulation of Evi-1 during embryonic avian development.

Ecotropical viral integration site 1 (Evi-1) is a transcription factor essential for vascularisation and cell proliferation during embryonic development. The chimeric transcription factor AML1-EVI-1 is activated in leukaemia where it plays a role as a differentiation block and stimulator of proliferation. Here, we cloned chicken Evi-1 and analysed its expression during embryonic development. There was early expression in the pharyngeal arches, in the brain and intermediate mesoderm of chicken embryos at stage 15. Later at stage 20, Evi-1 mesenchymal expression was concentrated in the second pharyngeal arch, and weaker expression was found in the mandibular and maxillary prominences. Facial expression decreased in intensity during development. Evi-1 expression in the limb was also limited to the mesenchyme with the most prominent expression in the anterior margin. Evi-1 was not detectable in the posterior limb bud. At later stages, Evi-1 was expressed in the peripheral mesenchyme of the limb but not in the developing precartilage blastema. At stage 29, the expression became restricted to the perichondrium and interdigital areas; however, the cartilage condensations themselves were negative. To study the function of Evi-1 in chondrogenesis, we knocked down expression in limb micromass cultures using siRNA. Chondrogenesis was significantly reduced in both anterior and posterior cultures. Since Evi-1 was expressed adjacent to the apical ectodermal ridge and this area is a source of FGFs, we tested whether endogenous FGF receptor signalling was necessary to maintain its expression. Inhibitors of FGFRs (PD161570 and SU5402) were applied to wing mesenchyme, and downregulation of Evi-1 expression was observed after treatment with both inhibitors. Therefore, Evi-1 may be a transcription factor mediating the effects of FGF and may also be defining the size of cartilage elements in the limb.

Ciliopathy Protein Tmem107 Plays Multiple Roles in Craniofacial Development

A broad spectrum of human diseases called ciliopathies is caused by defective primary cilia morphology or signal transduction. The primary cilium is a solitary organelle that responds to mechanical and chemical stimuli from extracellular and intracellular environments. Transmembrane protein 107 (TMEM107) is localized in the primary cilium and is enriched at the transition zone where it acts to regulate protein content of the cilium. Mutations in TMEM107 were previously connected with oral-facial-digital syndrome, Meckel-Gruber syndrome, and Joubert syndrome exhibiting a range of ciliopathic defects. Here, we analyze a role of Tmem107 in craniofacial development with special focus on palate formation, using mouse embryos with a complete knockout of Tmem107. Tmem107–/– mice were affected by a broad spectrum of craniofacial defects, including shorter snout, expansion of the facial midline, cleft lip, extensive exencephaly, and microphthalmia or anophthalmia. External abnormalities were accompanied by defects in skeletal structures, including ossification delay in several membranous bones and enlargement of the nasal septum or defects in vomeronasal cartilage. Alteration in palatal shelves growth resulted in clefting of the secondary palate. Palatal defects were caused by increased mesenchymal proliferation leading to early overgrowth of palatal shelves followed by defects in their horizontalization. Moreover, the expression of epithelial stemness marker SOX2 was altered in the palatal shelves of Tmem107–/– animals, and differences in mesenchymal SOX9 expression demonstrated the enhancement of neural crest migration. Detailed analysis of primary cilia revealed region-specific changes in ciliary morphology accompanied by alteration of acetylated tubulin and IFT88 expression. Moreover, Shh and Gli1 expression was increased in Tmem107–/– animals as shown by in situ hybridization. Thus, TMEM107 is essential for proper head development, and defective TMEM107 function leads to ciliary morphology disruptions in a region-specific manner, which may explain the complex mutant phenotype.

Role of Transmembrane Protein 107 in Craniofacial Development is Tissue Specific

Preimplantation development in rodent and primate establishes the founding cell population of the foetus in the epiblast and segregates two extraembryonic lineages, trophoblast and hypoblast. Most of our current knowledge about these cell-fate decisions is derived from studies in mouse. However, transcriptional profiling of human embryos has suggested substantial differences to the mouse paradigm. Here, we set out to delineate the primate-specific aspects of preimplantation development. We present a high-quality single-cell RNA-seq dataset from zygote to late blastocyst in marmoset (Callithrix jacchus). In addition, we generated stage-matched samples in mouse (Mus musculus) and re-analysed three human single-cell datasets. Weighted gene network analysis independently identified the establishment of epiblast and hypoblast transcriptional modules. NANOG, SOX2, TDGF1 and TFCP2L1 were highly expressed in the epiblast of all three species. In contrast, KLF17, ARGFX, KHDC3L, LEFTY2 and CTSF represented primate-specific factors of the pluripotency network in vivo. Global features of epiblast and hypoblast segregation included the ERK cascade, apoptosis and extracellular matrix, while we identified elevated levels of BMP and WNT signalling components in primates. Strikingly, the mouse epiblast marker Otx2 is specifically expressed in human and marmoset hypoblast. Our cross-species analysis approach demarcates conserved and primate-specific features of mammalian preimplantation development and provides a rich resource for comparative embryology.

Detection of active apoptotic molecules with femtogram sensitivity in single cells: a pilot study

T epidermis is a dynamic epithelium with constant renewal throughout life. Epidermal homeostasis depends on two types of proliferative cells, keratinocyte stem cells (KSCs), and transit amplifying (TA) cells. In the case of chronologic aging, levels of KSCs tend to decrease and change functionally. However, little is known about the effect of photoaging on epidermal proliferative subtype populations. The aim of this study was to validate involucrin/beta1-integrin ratio as a molecular marker of epidermal photoaging, and to investigate the effects of photoaging caused by chronic UV exposure on the proliferative subtype populations. A total of 15 male volunteers (age range 20-24 and 77-85 years) provided sun-exposed and sun-protected skin samples. The expression of beta1-integrin was found to be significantly reduced in photoaged skin and ratios of the expressions of involucrin to beta1-integrin were increased 2.6-fold only in elderly subjects. Interestingly, immunostaining of the sun-exposed skins of elderly subjects showed aberrant beta1-integrin expression over the basal layer and greater numbers of Ki-67-positive cells than in sun-protected buttock skin. Flow cytometric analysis revealed that the proportion of KSCs to TA cells was reversed in sun-exposed and sun-protected skins of elderly subjects. Our results suggest that KSC numbers may be lower in photoaged skin than in chronologically aged skin and could be applied to hyperplastic pattern of photoaging. These findings suggest that the epidermis of photoaged skin is impaired in terms of its proliferative potential by attempting to repair chronic UV exposure and that photoaging may be associated with alteration in the two proliferative cell fractions.N exhibit modified chemical and physical properties that give them the ability to interact with the biological systems at the cellular and molecular levels. These interactions enhance the biomedical applications of nanotechnology in the field of tissue regeneration. A wide range of nanomaterials made of organic and inorganic composites could be self assembled in nanoscale size that simulates more accurately the dimensions of the natural human tissues such as nanoparticles, nanosurfaces and nanoscaffolds. These novel nanomaterials significantly influence the behavior and development of stem cells. The applications of nanotechnology in specific tissue regeneration, such as bone, cartilage, cardiovascular and neural tissues were investigated by several researchers. Nanostructures have been used to promote stem cell viability, proliferation and differentiation. Nanotechnology provides biodegradable and biocompatible biomimetic fabricates that restore and improve the tissue functions. Nanocomposition and nanotopography of a tissue engineered material determine the implant fate providing 3 dimentional tissue culture systems that promote normal cell growth and differentiation without adverse tissue reaction. Recent progress in the synthesis allows the cultured cells to react to the internal and external stimuli and to exchange the signaling factors between those cells and the external environment. However, further understanding to the interactions of nanomaterials with the biological system and more investigations of the safety of these nanostructures are still required before their full application in human tissue repair