Your search keyword '"Taste Buds embryology"' showing total 183 results

1. Nkx2-2 expressing taste cells in endoderm-derived taste papillae are committed to the type III lineage.

Author

Qin Y, Sukumaran SK, and Margolskee RF

Subjects

Animals, Animals, Newborn, Antigens, Differentiation biosynthesis, Antigens, Differentiation physiology, Cell Count, Cell Lineage genetics, Female, Homeobox Protein Nkx-2.2, Homeodomain Proteins biosynthesis, Male, Mice, RNA-Seq, Taste Buds cytology, Taste Buds metabolism, Zebrafish Proteins biosynthesis, Cell Lineage physiology, Homeodomain Proteins physiology, Taste Buds embryology, Zebrafish Proteins physiology

Abstract

In mammals, multiple cell-signaling pathways and transcription factors regulate development of the embryonic taste system and turnover of taste cells in the adult stage. Using single-cell RNA-Seq of mouse taste cells, we found that the homeobox-containing transcription factor Nkx2-2, a target of the Sonic Hedgehog pathway and a key regulator of the development and regeneration of multiple cell types in the body, is highly expressed in type III taste cells but not in type II or taste stem cells. Using in situ hybridization and immunostaining, we confirmed that Nkx2-2 is expressed specifically in type III taste cells in the endoderm-derived circumvallate and foliate taste papillae but not in the ectoderm-derived fungiform papillae. Lineage tracing revealed that Nkx2-2-expressing cells differentiate into type III, but not type II or type I cells in circumvallate and foliate papillae. Neonatal Nkx2-2-knockout mice did not express key type III taste cell marker genes, while the expression of type II and type I taste cell marker genes were unaffected in these mice. Our findings indicate that Nkx2-2-expressing cells are committed to the type III lineage and that Nkx2-2 may be critical for the development of type III taste cells in the posterior tongue, thus illustrating a key difference in the mechanism of type III cell lineage specification between ectoderm- and endoderm-derived taste fields., Competing Interests: Declaration of competing interest All authors declare no conflict of interest., (Copyright © 2021. Published by Elsevier Inc.)

Published

2021

2. Taste buds are not derived from neural crest in mouse, chicken, and zebrafish.

Author

Yu W, Wang Z, Marshall B, Yoshida Y, Patel R, Cui X, Ball R, Yin L, Kawabata F, Tabata S, Chen W, Kelsh RN, Lauderdale JD, and Liu HX

Subjects

Animals, Chick Embryo, Chickens, Mice, Mice, Transgenic, Neural Crest cytology, Taste Buds cytology, Zebrafish, Cell Lineage, Neural Crest embryology, Taste Buds embryology

Abstract

Our lineage tracing studies using multiple Cre mouse lines showed a concurrent labeling of abundant taste bud cells and the underlying connective tissue with a neural crest (NC) origin, warranting a further examination on the issue of whether there is an NC derivation of taste bud cells. In this study, we mapped NC cell lineages in three different models, Sox10-iCreER T2 /tdT mouse, GFP + neural fold transplantation to GFP - chickens, and Sox10-Cre/GFP-RFP zebrafish model. We found that in mice, Sox10-iCreER T2 specifically labels NC cell lineages with a single dose of tamoxifen at E7.5 and that the labeled cells were widely distributed in the connective tissue of the tongue. No labeled cells were found in taste buds or the surrounding epithelium in the postnatal mice. In the GFP + /GFP - chicken chimera model, GFP + cells migrated extensively to the cranial region of chicken embryos ipsilateral to the surgery side but were absent in taste buds in the base of oral cavity and palate. In zebrafish, Sox10-Cre/GFP-RFP faithfully labeled known NC-derived tissues but did not label taste buds in lower jaw or the barbel. Our data, together with previous findings in axolotl, indicate that taste buds are not derived from NC cells in rodents, birds, amphibians or teleost fish., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2021

3. Increased activity of mesenchymal ALK2-BMP signaling causes posteriorly truncated microglossia and disorganization of lingual tissues.

Author

Ishan M, Chen G, Sun C, Chen SY, Komatsu Y, Mishina Y, and Liu HX

Subjects

Activin Receptors, Type I metabolism, Animals, Apoptosis genetics, Bone Morphogenetic Proteins metabolism, Cell Proliferation genetics, Epithelium metabolism, Female, Gene Expression Regulation, Developmental drug effects, Gene Expression Regulation, Developmental genetics, Male, Mesoderm metabolism, Mice, Mice, Inbred C57BL, Neural Crest metabolism, Signal Transduction genetics, Taste Buds embryology, Tongue Diseases genetics, Tongue Diseases metabolism, Trans-Activators genetics, Wnt1 Protein genetics, Activin Receptors, Type I genetics, Bone Morphogenetic Proteins genetics, Tongue embryology

Abstract

Proper development of taste organs including the tongue and taste papillae requires interactions with the underlying mesenchyme through multiple molecular signaling pathways. The effects of bone morphogenetic proteins (BMPs) and antagonists are profound, however, the tissue-specific roles of distinct receptors are largely unknown. Here, we report that constitutive activation (ca) of ALK2-BMP signaling in the tongue mesenchyme (marked by Wnt1-Cre) caused microglossia-a dramatically smaller and misshapen tongue with a progressively severe reduction in size along the anteroposterior axis and absence of a pharyngeal region. At E10.5, the tongue primordia (branchial arches 1-4) formed in Wnt1-Cre/caAlk2 mutants while each branchial arch responded to elevated BMP signaling distinctly in gene expression of BMP targets (Id1, Snai1, Snai2, and Runx2), proliferation (Cyclin-D1) and apoptosis (p53). Moreover, elevated ALK2-BMP signaling in the mesenchyme resulted in apparent defects of lingual epithelium, muscles, and nerves. In Wnt1-Cre/caAlk2 mutants, a circumvallate papilla was missing and further development of formed fungiform papillae was arrested in late embryos. Our data collectively demonstrate that ALK2-BMP signaling in the mesenchyme plays essential roles in orchestrating various tissues for proper development of the tongue and its appendages in a region-specific manner., (© 2019 Wiley Periodicals, Inc.)

Published

2020

4. Early taste buds are from Shh + epithelial cells of tongue primordium in distinction from mature taste bud cells which arise from surrounding tissue compartments.

Author

Kramer N, Chen G, Ishan M, Cui X, and Liu HX

Subjects

Animals, Epithelium embryology, Gene Expression Regulation, Developmental, Hedgehog Proteins genetics, Immunohistochemistry, Keratin-14 genetics, Keratin-14 metabolism, Mice, 129 Strain, Mice, Transgenic, Reverse Transcriptase Polymerase Chain Reaction, Signal Transduction genetics, Taste, Taste Buds embryology, Tongue embryology, Epithelial Cells metabolism, Epithelium metabolism, Hedgehog Proteins metabolism, Taste Buds metabolism, Tongue metabolism

Abstract

Mammalian taste buds emerge perinatally and most become mature 3-4 weeks after birth. Mature taste bud cells in rodents are known to be renewed by the surrounding K14 + basal epithelial cells and potentially other progenitor source(s), but the dynamics between initially developed taste buds and surrounding tissue compartments are unclear. Using the K14-Cre and Dermo1-Cre mouse lines to trace epithelial and mesenchymal cell lineages, we found that early taste buds in E18.5 and newborn mouse tongues are not derived from either lineage. At E11.5 when the tongue primordia (i.e., lingual swellings) emerge, the relatively homogeneous sonic hedgehog-expressing (Shh + ) epithelial cells express Keratin (K) 8, a marker that is widely used to label taste buds. Mapping lineage of E11.0 Shh + epithelium of the tongue rudiment with Shh-CreER T2 /RFP mice demonstrated that both the early taste buds and the surrounding lingual epithelium are from the same population of progenitors - Shh + epithelial cells of the tongue primordium. In combination with previous reports, we propose that Shh + K8 + cells in the homogeneous epithelium of tongue primordium at early embryonic stages are programmed to become taste papilla and taste bud cells. Switching off Shh and K8 expression in the Shh + epithelial cells of the tongue primordium transforms the cells to non-gustatory cells surrounding papillae, including K14 + basal epithelial cells which will eventually contribute to the cell renewal of mature taste buds., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

5. SIS-ECM Laden with GMSC-Derived Exosomes Promote Taste Bud Regeneration.

Author

Zhang Y, Shi S, Xu Q, Zhang Q, Shanti RM, and Le AD

Subjects

Animals, Extracellular Matrix metabolism, Humans, Rats, Regeneration physiology, Taste, Taste Buds embryology, Taste Buds metabolism, Exosomes, Tissue Engineering methods, Tongue cytology

Abstract

Oral cancer has a high annual incidence rate all over the world, and the tongue is the most frequently affected anatomic structure. The current standard care is ablative surgery of malignant neoplasm, followed by tongue reconstruction with free flap. However, such reconstructive modalities with postsurgery radiotherapy or chemotherapy can hardly support the functional recovery of the tongue-particularly, functional taste bud regeneration-in reconstructed areas, thus seriously affecting patients' prognosis and life quality. Using a critical-sized tongue defect model in rats, we show that combinatory transplantation of small intestinal submucosa-extracellular matrix (SIS-ECM) with gingival mesenchymal stem cells (GMSCs) or their derivative exosomes promoted tongue lingual papillae recovery and taste bud regeneration as evidenced by increased expression of CK14, CK8, and markers for type I, II, and III taste bud cells (NTPdase 2, PLC-β2, and AADC, respectively). In addition, our results indicate that GMSCs or their derivative exosomes could increase BDNF expression, a growth factor that plays an important role in the proliferation and differentiation of epithelial basal progenitor cells into taste bud cells. Meanwhile, we showed an elevated expression level of Shh-which is essential for development, homeostasis, and maintenance of the taste bud organ-in wounded areas of the tongue among animals treated with GMSC/SIS-ECM or exosome/SIS-ECM as compared with SIS-ECM control. Moreover, our data show that GMSCs or their derivative exosomes promoted innervation of regenerated taste buds, as evidenced by elevated expressions of neurofilament and P2X 3 at the injury areas. Together, our findings indicate that GMSC/SIS-ECM and exosome/SIS-ECM constructs can facilitate taste bud regeneration and reinnervation with promising potential application in postsurgery tongue reconstruction of patients with tongue cancer.

Published

2019

6. TrkB expression and dependence divides gustatory neurons into three subpopulations.

Author

Rios-Pilier J and Krimm RF

Subjects

Animals, Embryo, Mammalian, Geniculate Ganglion embryology, Geniculate Ganglion metabolism, Mice, Mice, Transgenic, Taste Buds embryology, Taste Buds metabolism, Brain-Derived Neurotrophic Factor metabolism, Geniculate Ganglion physiology, Membrane Glycoproteins metabolism, Protein-Tyrosine Kinases metabolism, Taste physiology, Taste Buds physiology

Abstract

Background: During development, gustatory (taste) neurons likely undergo numerous changes in morphology and expression prior to differentiation into maturity, but little is known this process or the factors that regulate it. Neuron differentiation is likely regulated by a combination of transcription and growth factors. Embryonically, most geniculate neuron development is regulated by the growth factor brain derived neurotrophic factor (BDNF). Postnatally, however, BDNF expression becomes restricted to subpopulations of taste receptor cells with specific functions. We hypothesized that during development, the receptor for BDNF, tropomyosin kinase B receptor (TrkB), may also become developmentally restricted to a subset of taste neurons and could be one factor that is differentially expressed across taste neuron subsets., Methods: We used transgenic mouse models to label both geniculate neurons innervating the oral cavity (Phox2b+), which are primarily taste, from those projecting to the outer ear (auricular neurons) to label TrkB expressing neurons (TrkB GFP ). We also compared neuron number, taste bud number, and taste receptor cell types in wild-type animals and conditional TrkB knockouts., Results: Between E15.5-E17.5, TrkB receptor expression becomes restricted to half of the Phox2b + neurons. This TrkB downregulation was specific to oral cavity projecting neurons, since TrkB expression remained constant throughout development in the auricular geniculate neurons (Phox2b-). Conditional TrkB removal from oral sensory neurons (Phox2b+) reduced this population to 92% of control levels, indicating that only 8% of these neurons do not depend on TrkB for survival during development. The remaining neurons failed to innervate any remaining taste buds, 14% of which remained despite the complete loss of innervation. Finally, some types of taste receptor cells (Car4+) were more dependent on innervation than others (PLCβ2+)., Conclusions: Together, these findings indicate that TrkB expression and dependence divides gustatory neurons into three subpopulations: 1) neurons that always express TrkB and are TrkB-dependent during development (50%), 2) neurons dependent on TrkB during development but that downregulate TrkB expression between E15.5 and E17.5 (41%), and 3) neurons that never express or depend on TrkB (9%). These TrkB-independent neurons are likely non-gustatory, as they do not innervate taste buds.

Published

2019

7. Morphogenesis of lingual papillae of one-humped camel (Camelus dromedarius) during prenatal life: A light and scanning electron microscopic study.

Author

Abou-Elhamd AS, Abd-Elkareem M, and El-Zuhry Zayed A

Subjects

Animals, Microscopy, Electron, Scanning veterinary, Taste Buds ultrastructure, Time Factors, Tongue embryology, Camelus embryology, Taste Buds embryology

Abstract

This study was made on 24 camel fetuses of crown-rump vertebral length (CVRL) ranging from 10.5 cm to 105 cm CVRL (94-352 days old). These camel fetuses were classified into three groups representing the three trimesters of prenatal life. During the first trimester (94-142 days), lingual papillae (circumvallate and lentiform papillae) were demonstrated on the lingual root, but lingual body and the apex were almost free of papillae except for some scattered epithelial projections especially near the lateral borders of the body. In the second trimester (152-229 days), the lentiform papillae covered the entire root of the tongue except for areas occupied by the circumvallate papillae. Taste buds with clear pores were observed for the first time in areas between the circumvallate gustatory furrow and surface epithelium of the tongue. In addition, short numerous filiform papillae were observed on the rostral part of the lingual body and the lateral parts of the apex. Fungiform papillae, however, were demonstrated amidst the filiform papillae. In this trimester, taste buds were also seen on the top of the fungiform papillae. In the third trimester (256-352 days), all lingual papillae were clearly demonstrated on the dorsum of the root, body and apex of the tongue. Both types of gustatory papillae (circumvallate and fungiform) had well-developed taste buds. Mechanical papillae (filiform and lentiform) were well developed. Lentiform papillae occupied most of the dorsal aspect of the Torus linguae; they were larger in size with semicircular apices. Filiform papillae, however, were numerous and demonstrated heavily on the lateral and rostral parts of the body as well as on the apex of the tongue., (© 2017 Blackwell Verlag GmbH.)

Published

2018

8. Ultrastructure of Lingual Papillae in Common Chimpanzee (Pan troglodytes) Foetus, Newborn and Adult Specimens.

Author

Pastor JF, Barbosa M, De Paz FJ, San José I, Levanti M, Potau JM, Vega JA, and Cabo R

Subjects

Animals, Diet veterinary, Female, Fruit, Male, Microscopy, Electron, Scanning veterinary, Taste Buds embryology, Taste Buds ultrastructure, Tongue embryology, Vegetables, Yogurt, Aging physiology, Animals, Newborn anatomy & histology, Pan troglodytes anatomy & histology, Pan troglodytes embryology, Tongue ultrastructure

Abstract

Among primates, the two recognized species of chimpanzees (common chimpanzee, Pan troglodytes; pygmy chimpanzee, Pan paniscus) are considered to be the most similar to humans. Importantly, in mammals, the food intake behaviour largely determines the tongue morphology, including the type, proportion and distribution of gustatory and non-gustatory tongue papillae. The lingual papillae form during its development and mature in post-natal life depending on the different feeding. In this study, we have used scanning electron microscopy to analyse the age-related changes in the lingual papillae of foetal, newborn and adult P. troglodytes. Four main types of lingual papillae, denominated filiform, fungiform, foliate and vallate, and one subtype of filiform papillae called conical papillae, were found. The main age-related changes observed in all kinds of papillae were a progressive keratinization and morphological complexity along the lifespan. During the foetal period, there was scarce keratinization, which progressively increases in young animals to adulthood. The number of filiform increased with ageing, and both filiform and fungiform papillae in adult tongues are divided into pseudopapillae. On the other hand, the vallate papillae vary from smooth simple surfaces in foetal tongues to irregular surfaces with grooves and pseudopapillae (microscopic papilla-shaped formations within the papilla itself) in adults. These results describe for the first time the age-related variations in the three-dimensional aspect of lingual papillae of the chimpanzee tongue and provide new data to characterize more precisely these structures in the human closest specie., (© 2017 Blackwell Verlag GmbH.)

Published

2017

9. RNA-Seq analysis on chicken taste sensory organs: An ideal system to study organogenesis.

Author

Cui X, Marshall B, Shi N, Chen SY, Rekaya R, and Liu HX

Subjects

Animals, Chick Embryo, Gene Expression Profiling methods, Mesoderm chemistry, Mesoderm cytology, Organ Specificity, Palate chemistry, Palate cytology, Signal Transduction, Taste Buds chemistry, Taste Buds embryology, Tongue chemistry, Tongue cytology, Chickens genetics, Organogenesis, Sequence Analysis, RNA methods, Taste Buds cytology

Abstract

RNA-Seq is a powerful tool in transcriptomic profiling of cells and tissues. We recently identified many more taste buds than previously appreciated in chickens using molecular markers to stain oral epithelial sheets of the palate, base of oral cavity, and posterior tongue. In this study, RNA-Seq was performed to understand the transcriptomic architecture of chicken gustatory tissues. Interestingly, taste sensation related genes and many more differentially expressed genes (DEGs) were found between the epithelium and mesenchyme in the base of oral cavity as compared to the palate and posterior tongue. Further RNA-Seq using specifically defined tissues of the base of oral cavity demonstrated that DEGs between gustatory (GE) and non-gustatory epithelium (NGE), and between GE and the underlying mesenchyme (GM) were enriched in multiple GO terms and KEGG pathways, including many biological processes. Well-known genes for taste sensation were highly expressed in the GE. Moreover, genes of signaling components important in organogenesis (Wnt, TGFβ/ BMP, FGF, Notch, SHH, Erbb) were differentially expressed between GE and GM. Combined with other features of chicken taste buds, e.g., uniquely patterned array and short turnover cycle, our data suggest that chicken gustatory tissue provides an ideal system for multidisciplinary studies, including organogenesis and regenerative medicine.

Published

2017

10. FGF signaling refines Wnt gradients to regulate the patterning of taste papillae.

Author

Prochazkova M, Häkkinen TJ, Prochazka J, Spoutil F, Jheon AH, Ahn Y, Krumlauf R, Jernvall J, and Klein OD

Subjects

Adaptor Proteins, Signal Transducing, Animals, Body Patterning genetics, Body Patterning physiology, Bone Morphogenetic Proteins genetics, Bone Morphogenetic Proteins metabolism, Computer Simulation, Female, Fibroblast Growth Factor 10 deficiency, Fibroblast Growth Factor 10 genetics, Hedgehog Proteins genetics, Hedgehog Proteins metabolism, Intracellular Signaling Peptides and Proteins deficiency, Intracellular Signaling Peptides and Proteins genetics, Intracellular Signaling Peptides and Proteins metabolism, Male, Membrane Proteins deficiency, Membrane Proteins genetics, Membrane Proteins metabolism, Mice, Mice, Knockout, Mice, Transgenic, Models, Biological, Pregnancy, Protein Serine-Threonine Kinases, Fibroblast Growth Factor 10 metabolism, Taste Buds embryology, Taste Buds metabolism, Wnt Signaling Pathway

Abstract

The patterning of repeated structures is a major theme in developmental biology, and the inter-relationship between spacing and size of such structures is an unresolved issue. Fungiform papillae are repeated epithelial structures that house taste buds on the anterior tongue. Here, we report that FGF signaling is a crucial regulator of fungiform papillae development. We found that mesenchymal FGF10 controls the size of the papillary area, while overall patterning remains unchanged. Our results show that FGF signaling negatively affects the extent of canonical Wnt signaling, which is the main activation pathway during fungiform papillae development; however, this effect does not occur at the level of gene transcription. Rather, our experimental data, together with computational modeling, indicate that FGF10 modulates the range of Wnt effects, likely via induction of Sostdc1 expression. We suggest that modification of the reach of Wnt signaling could be due to local changes in morphogen diffusion, representing a novel mechanism in this tissue context, and we propose that this phenomenon might be involved in a broader array of mammalian developmental processes., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

11. Grhl3 modulates epithelial structure formation of the circumvallate papilla during mouse development.

Author

Adhikari N, Neupane S, Gwon GJ, Kim JY, An CH, Lee S, Sohn WJ, Lee Y, and Kim JY

Subjects

Animals, DNA-Binding Proteins biosynthesis, DNA-Binding Proteins chemistry, Epithelium chemistry, In Situ Hybridization, Mice, Mice, Inbred ICR, Organogenesis, Taste Buds chemistry, Tissue Culture Techniques, Transcription Factors biosynthesis, Transcription Factors chemistry, DNA-Binding Proteins metabolism, Epithelium metabolism, Taste Buds embryology, Taste Buds metabolism, Transcription Factors metabolism

Abstract

Grainyhead-like 3 (Grhl3) is a transcription factor involved in epithelial morphogenesis. In the present study, we evaluated the developmental role of Grhl3 in structural formation of the circumvallate papilla (CVP), which undergoes dynamic morphological changes during organogenesis. The specific expression pattern of Grhl3 was examined in the CVP-forming region, specifically in the apex and epithelial stalk from E13.5 to E15.5 using in situ hybridization. To determine the role of Grhl3 in epithelial morphogenesis of the CVP, we employed an in vitro tongue culture method, wherein E13.5 tongue were isolated and cultured for 2 days after knocking down of Grhl3. Knockdown of Grhl3 resulted in significant changes to the epithelial structure of the CVP, such that the apical region of the CVP was smaller in size, and the epithelial stalks were more deeply invaginated. To define the mechanisms underlying these morphological alterations, we examined cell migration, proliferation, and apoptosis using phalloidin staining, immunohistochemistry against Ki67, ROCK1, and E-cadherin, and a TUNEL assay, respectively. These results revealed an increase in proliferation, a reduction in apoptosis, and an altered pattern of cytoskeletal formation in the CVP-forming epithelium, following Grhl3 knockdown. In addition, there were changes in the specific expression patterns of signaling and apoptosis-related molecules such as Axin2, Bak1, Bcl2, Casp3, Casp8, Ctnnb1, Cnnd1, Gli3, Lef1, Ptch1, Rock1, Shh, and Wnt11, which could explain the altered cellular and morphological events. Based on these results, we propose that developmental stage-specific Grhl3 plays a significant role in CVP morphogenesis not by just disruption of epithelial integrity but by regulating epithelial cell proliferation, apoptosis, and migration via Shh, Wnt, and apoptosis signaling during mouse embryogenesis.

Published

2017

12. Distribution of α-Gustducin and Vimentin in premature and mature taste buds in chickens.

Author

Venkatesan N, Rajapaksha P, Payne J, Goodfellow F, Wang Z, Kawabata F, Tabata S, Stice S, Beckstead R, and Liu HX

Subjects

Animals, Chickens, Epithelium metabolism, Immunohistochemistry, Phenotype, Tissue Distribution, Gene Expression Regulation, Developmental, Taste Buds embryology, Taste Buds metabolism, Transducin metabolism, Vimentin metabolism

Abstract

The sensory organs for taste in chickens (Gallus sp.) are taste buds in the oral epithelium of the palate, base of the oral cavity, and posterior tongue. Although there is not a pan-taste cell marker that labels all chicken taste bud cells, α-Gustducin and Vimentin each label a subpopulation of taste bud cells. In the present study, we used both α-Gustducin and Vimentin to further characterize chicken taste buds at the embryonic and post-hatching stages (E17-P5). We found that both α-Gustducin and Vimentin label distinct and overlapping populations of, but not all, taste bud cells. A-Gustducin immunosignals were observed as early as E18 and were consistently distributed in early and mature taste buds in embryos and hatchlings. Vimentin immunoreactivity was initially sparse at the embryonic stages then became apparent in taste buds after hatch. In hatchlings, α-Gustducin and Vimentin immunosignals largely co-localized in taste buds. A small subset of taste bud cells were labeled by either α-Gustducin or Vimentin or were not labeled. Importantly, each of the markers was observed in all of the examined taste buds. Our data suggest that the early onset of α-Gustducin in taste buds might be important for enabling chickens to respond to taste stimuli immediately after hatch and that distinctive population of taste bud cells that are labeled by different molecular markers might represent different cell types or different phases of taste bud cells. Additionally, α-Gustducin and Vimentin can potentially be used as molecular markers of all chicken taste buds in whole mount tissue., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

13. Nerve-independent and ectopically additional induction of taste buds in organ culture of fetal tongues.

Author

Honda K and Tomooka Y

Subjects

Animals, Cell Nucleus drug effects, Cell Nucleus metabolism, Cells, Cultured, Epithelium drug effects, Epithelium innervation, Glycogen Synthase Kinase 3 beta antagonists & inhibitors, Glycogen Synthase Kinase 3 beta metabolism, Hedgehog Proteins metabolism, Mice, Inbred ICR, Morphogenesis drug effects, Nerve Tissue drug effects, Phospholipase C beta metabolism, Protein Kinase Inhibitors pharmacology, Protein Transport drug effects, Taste drug effects, Taste Buds drug effects, Wnt Signaling Pathway drug effects, beta Catenin metabolism, Fetus physiology, Nerve Tissue physiology, Organ Culture Techniques methods, Taste Buds embryology, Tongue embryology

Abstract

An improved organ culture system allowed to observe morphogenesis of mouse lingual papillae and taste buds relatively for longer period, in which fetal tongues were analyzed for 6 d. Taste cells were defined as eosinophobic epithelial cells expressing CK8 and Sox2 within lingual epithelium. Addition of glycogen synthase kinase 3 beta inhibitor CHIR99021 induced many taste cells and buds in non-gustatory and gustatory stratified lingual epithelium. The present study clearly demonstrated induction of taste cells and buds ectopically and without innervation.

Published

2016

14. LGN plays distinct roles in oral epithelial stratification, filiform papilla morphogenesis and hair follicle development.

Author

Byrd KM, Lough KJ, Patel JH, Descovich CP, Curtis TA, and Williams SE

Subjects

Animals, Carrier Proteins genetics, Cell Cycle Proteins, Cell Differentiation genetics, Cell Differentiation physiology, Immunohistochemistry, Mice, Microscopy, Electron, Scanning, Morphogenesis genetics, Morphogenesis physiology, Signal Transduction genetics, Signal Transduction physiology, Taste Buds embryology, Taste Buds metabolism, Tongue embryology, Tongue metabolism, Carrier Proteins metabolism, Epithelium metabolism, Hair Follicle embryology, Hair Follicle metabolism

Abstract

Oral epithelia protect against constant challenges by bacteria, viruses, toxins and injury while also contributing to the formation of ectodermal appendages such as teeth, salivary glands and lingual papillae. Despite increasing evidence that differentiation pathway genes are frequently mutated in oral cancers, comparatively little is known about the mechanisms that regulate normal oral epithelial development. Here, we characterize oral epithelial stratification and describe multiple distinct functions for the mitotic spindle orientation gene LGN (Gpsm2) in promoting differentiation and tissue patterning in the mouse oral cavity. Similar to its function in epidermis, apically localized LGN directs perpendicular divisions that promote stratification of the palatal, buccogingival and ventral tongue epithelia. Surprisingly, however, in dorsal tongue LGN is predominantly localized basally, circumferentially or bilaterally and promotes planar divisions. Loss of LGN disrupts the organization and morphogenesis of filiform papillae but appears to be dispensable for embryonic hair follicle development. Thus, LGN has crucial tissue-specific functions in patterning surface ectoderm and its appendages by controlling division orientation., Competing Interests: The authors declare no competing or financial interests., (© 2016. Published by The Company of Biologists Ltd.)

Published

2016

15. Bcl11b/Ctip2 is required for development of lingual papillae in mice.

Author

Nishiguchi Y, Ohmoto M, Koki J, Enomoto T, Kominami R, Matsumoto I, and Hirota J

Subjects

Animals, Cell Differentiation, Keratinocytes cytology, Mice, Morphogenesis genetics, Mouth Mucosa cytology, Mouth Mucosa embryology, Repressor Proteins genetics, Taste Buds embryology, Tongue ultrastructure, Tumor Suppressor Proteins genetics, Repressor Proteins physiology, Tongue embryology, Transcription Factors physiology, Tumor Suppressor Proteins physiology

Abstract

Molecular mechanisms underlying the development and morphogenesis of oral epithelia, comprising the gustatory and nongustatory epithelium, remain unclear. Here, we show that Bcl11b, a zinc finger transcription factor, plays an important role in the development of lingual papillae, especially filiform papillae. In both gustatory and nongustatory epithelium, Bcl11b was expressed in keratin 14-positive epithelial basal cells, which differentiate into keratinocytes and/or taste cells. Loss of Bcl11b function resulted in abnormal morphology of the gustatory papillae: flattened fungiform papillae, shorter trench wall in the foliate and circumvallate papillae, and ectopic invagination in more than half of circumvallate papillae. However, Bcl11b loss caused no effect on differentiation of taste receptor cells. In nongustatory epithelium, the impact of Bcl11b deficiency was much more striking, resulting in a smooth surface on the tongue tip and hypoplastic filiform papillae in the dorsal lingual epithelium. Immunohistochemical analyses revealed that a keratinocyte differentiation marker, Tchh expression was severely decreased in the Bcl11b(-/-) filiform papillae. In addition, expression of Pax9, required for morphogenesis of filiform papillae and its downstream target genes, hard keratins, almost disappeared in the tongue tip and was decreased in the dorsal tongue of Bcl11b(-/-) mice. Gene expression analyses demonstrated a delayed onset of expression of epithelial differentiation complex genes, which disturbed barrier formation in the mutant tongue. These results indicate that Bcl11b regulates the differentiation of keratinocytes in the tongue and identify Bcl11b as an essential factor for the lingual papilla morphogenesis., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

16. Tongue and taste organ development in the ontogeny of direct-developing salamander Plethodon cinereus (Lissamphibia: Plethodontidae).

Author

Budzik KA, Żuwała K, and Kerney R

Subjects

Animals, Epithelium embryology, Epithelium ultrastructure, Taste Buds ultrastructure, Urodela anatomy & histology, Taste Buds embryology, Urodela embryology

Abstract

The latest research on direct developing caecilian and anuran species indicate presence of only one generation of taste organs during their ontogeny. This is distinct from indirect developing batrachians studied thus far, which possess taste buds in larvae and anatomically distinct taste discs in metamorphs. This study is a description of the tongue and taste organ morphology and development in direct developing salamander Plethodon cinereus (Plethodontidae) using histology and electron microscopy techniques. The results reveal two distinct stages tongue morphology (primary and secondary), similar to metamorphic urodeles, although only one stage of taste organ morphology. Taste disc sensory zones emerge on the surface of the oropharyngeal epithelium by the end of embryonic development, which coincides with maturation of the soft tongue. Taste organs occur in the epithelium of the tongue pad (where they are situated on the dermal papillae), the palate and the inner surface of the mandible and the maxilla. Plethodon cinereus embryos only possess taste disc type taste organs. Similar to the direct developing anuran Eleutherodactylus coqui (Eleutherodactylidae), these salamanders do not recapitulate larval taste bud morphology as an embryo. The lack of taste bud formation is probably a broadly distributed feature characteristic to direct developing batrachians. J. Morphol. 277:906-915, 2016. © 2016 Wiley Periodicals, Inc., (© 2016 Wiley Periodicals, Inc.)

Published

2016

17. Ontogeny and innervation of taste buds in mouse palatal gustatory epithelium.

Author

Rashwan A, Konishi H, El-Sharaby A, and Kiyama H

Subjects

Animals, Animals, Newborn, Mice, Inbred C57BL, Mouth Mucosa embryology, Mouth Mucosa growth & development, Mouth Mucosa innervation, Palate cytology, Palate innervation, Taste, Palate embryology, Palate growth & development, Taste Buds embryology, Taste Buds growth & development

Abstract

We investigated the relationship between mouse taste bud development and innervation of the soft palate. We employed scanning electron microscopy and immunohistochemistry using antibodies against protein gene product 9.5 and peripherin to detect sensory nerves, and cytokeratin 8 and α-gustducin to stain palatal taste buds. At E14, nerve fibers were observed along the medial border of the palatal shelves that tracked toward the epithelium. At E15.5, primordial stages of taste buds in the basal lamina of the soft palate first appeared. At E16, the taste buds became large spherical masses of columnar cells scattered in the soft palate basal lamina. At E17, the morphology and also the location of taste buds changed. At E18-19, some taste buds acquired a more elongated shape with a short neck, extending a variable distance from the soft palate basal lamina toward the surface epithelium. At E18, mature taste buds with taste pores and perigemmal nerve fibers were observed on the surface epithelium of the soft palate. The expression of α-gustducin was demonstrated at postnatal day 1 and the number of pored taste buds increased with age and they became pear-shaped at 8 weeks. The percent of pored fungiform-like papillae at birth was 58.3% of the whole palate; this increased to 83.8% at postnatal day 8 and reached a maximum of 95.7% at 12 weeks. The innervation of the soft palate was classified into three types of plexuses in relation to taste buds: basal nerve plexus, intragemmal and perigemmal nerve fibers. This study reveals that the nerve fibers preceded the development of taste buds in the palate of mice, and therefore the nerve fibers have roles in the initial induction of taste buds in the soft palate., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2016

18. Coevolutionary patterning of teeth and taste buds.

Author

Bloomquist RF, Parnell NF, Phillips KA, Fowler TE, Yu TY, Sharpe PT, and Streelman JT

Subjects

Animals, Cichlids embryology, Mice, Molecular Sequence Data, Quantitative Trait Loci, Signal Transduction, Biological Evolution, Body Patterning, Taste Buds embryology, Tooth embryology

Abstract

Teeth and taste buds are iteratively patterned structures that line the oro-pharynx of vertebrates. Biologists do not fully understand how teeth and taste buds develop from undifferentiated epithelium or how variation in organ density is regulated. These organs are typically studied independently because of their separate anatomical location in mammals: teeth on the jaw margin and taste buds on the tongue. However, in many aquatic animals like bony fishes, teeth and taste buds are colocalized one next to the other. Using genetic mapping in cichlid fishes, we identified shared loci controlling a positive correlation between tooth and taste bud densities. Genome intervals contained candidate genes expressed in tooth and taste bud fields. sfrp5 and bmper, notable for roles in Wingless (Wnt) and bone morphogenetic protein (BMP) signaling, were differentially expressed across cichlid species with divergent tooth and taste bud density, and were expressed in the development of both organs in mice. Synexpression analysis and chemical manipulation of Wnt, BMP, and Hedgehog (Hh) pathways suggest that a common cichlid oral lamina is competent to form teeth or taste buds. Wnt signaling couples tooth and taste bud density and BMP and Hh mediate distinct organ identity. Synthesizing data from fish and mouse, we suggest that the Wnt-BMP-Hh regulatory hierarchy that configures teeth and taste buds on mammalian jaws and tongues may be an evolutionary remnant inherited from ancestors wherein these organs were copatterned from common epithelium.

Published

2015

19. Progress and renewal in gustation: new insights into taste bud development.

Author

Barlow LA

Subjects

Animals, Humans, Taste, Taste Buds chemistry, Taste Buds embryology, Taste Buds metabolism

Abstract

The sense of taste, or gustation, is mediated by taste buds, which are housed in specialized taste papillae found in a stereotyped pattern on the surface of the tongue. Each bud, regardless of its location, is a collection of ∼100 cells that belong to at least five different functional classes, which transduce sweet, bitter, salt, sour and umami (the taste of glutamate) signals. Taste receptor cells harbor functional similarities to neurons but, like epithelial cells, are rapidly and continuously renewed throughout adult life. Here, I review recent advances in our understanding of how the pattern of taste buds is established in embryos and discuss the cellular and molecular mechanisms governing taste cell turnover. I also highlight how these findings aid our understanding of how and why many cancer therapies result in taste dysfunction., (© 2015. Published by The Company of Biologists Ltd.)

Published

2015

20. Pharyngeal arch deficiencies affect taste bud development in the circumvallate papilla with aberrant glossopharyngeal nerve formation.

Author

Okubo T and Takada S

Subjects

Animals, Branchial Region cytology, Branchial Region innervation, Embryo, Mammalian cytology, Embryo, Mammalian innervation, Glossopharyngeal Nerve cytology, Mice, Mice, Knockout, Repressor Proteins genetics, Repressor Proteins metabolism, Taste Buds cytology, Branchial Region embryology, Embryo, Mammalian embryology, Glossopharyngeal Nerve embryology, Taste Buds embryology

Abstract

Background: The pharyngeal arches (PAs) generate cranial organs including the tongue. The taste placodes, formed in particular locations on the embryonic tongue surface, differentiate into taste buds harbored in distinct gustatory papillae. The developing tongue also has a complex supply of cranial nerves through each PA. However, the relationship between the PAs and taste bud development is not fully understood., Results: Ripply3 homozygous mutant mice, which have impaired third/fourth PAs, display a hypoplastic circumvallate papilla and lack taste buds, although the taste placode is normally formed. Formation of the glossopharyngeal ganglia is defective and innervation toward the posterior tongue is completely missing in Ripply3 mutant embryos at E12.5. Moreover, the distribution of neuroblasts derived from the epibranchial placode is severely, but not completely, atenuated, and the neural crest cells are diminished in the third PA region of Ripply3 mutant embryos at E9.5-E10.5. In Tbx1 homozygous mutant embryos, which exhibit another type of deficiency in PA development, the hypoplastic circumvallate papilla is observed along with abnormal formation of the glossopharyngeal ganglia and severely impaired innervation., Conclusions: PA deficiencies affect multiple aspects of taste bud development, including formation of the cranial ganglia and innervation to the posterior tongue., (© 2015 Wiley Periodicals, Inc.)

Published

2015

21. During development intense Sox2 expression marks not only Prox1-expressing taste bud cell but also perigemmal cell lineages.

Author

Nakayama A, Miura H, Ooki M, and Harada S

Subjects

Aging metabolism, Animals, Female, Gene Expression Regulation, Developmental, Hedgehog Proteins metabolism, Mice, Inbred C57BL, Palate, Soft cytology, Palate, Soft metabolism, Taste Buds metabolism, Time Factors, Cell Lineage, Homeodomain Proteins metabolism, SOXB1 Transcription Factors metabolism, Taste Buds cytology, Taste Buds embryology, Tumor Suppressor Proteins metabolism

Abstract

Sox2 is proposed to regulate the differentiation of bipotential progenitor cells into taste bud cells. However, detailed expression of Sox2 remains unclear. In this report, Sox2 expression during taste bud development in the fungiform (FF), circumvallate (CV) and soft palate (SP) areas is examined together with Prox1. First, we immunohistochemically checked Prox1 expression in adults and found that almost all taste bud cells are Prox1-positive. During FF development, intense Sox2 expression was restricted to taste bud primordia expressing Prox1 at E12.5. However, at E14.5, Sox2 was intensely expressed outside the developing taste buds resolving to perigemmal Sox2 expression in adults. In the SP, at E14.5, taste bud primordia emerged as Prox1-expressing cell clusters. However, intense Sox2 expression was not restricted to taste bud primordia but was detected widely in the epithelium. During development, Sox2 expression outside developing taste buds was generally down-regulated but was retained in the perigemmal region similarly to that in the FF. In the CV, the initial stage of taste bud development remained unclear because of the lack of taste bud primordia comparable to that in the FF and SP. Here, we show that Prox1-expressing cells appear in the apical epithelium at E12.5, in the inner trench wall at E17.5 and in the outer trench wall at E18.5. Sox2 was again not restricted to developing taste bud cells expressing Prox1 during CV development. The expression patterns support that Sox2 does not serve as a cell fate selector between taste bud cells and surrounding keratinocytes but rather may contribute to them both.

Published

2015

22. Expanded terminal fields of gustatory nerves accompany embryonic BDNF overexpression in mouse oral epithelia.

Author

Sun C, Dayal A, and Hill DL

Subjects

Animals, Female, Male, Mice, Mice, Transgenic, Mouth Mucosa embryology, Taste Buds embryology, Taste Buds metabolism, Tongue embryology, Tongue metabolism, Brain-Derived Neurotrophic Factor biosynthesis, Gene Expression Regulation, Developmental, Mouth Mucosa innervation, Mouth Mucosa metabolism, Sensory Receptor Cells metabolism, Taste physiology

Abstract

Brain-derived neurotrophic factor (BDNF) is expressed in gustatory epithelia and is required for gustatory neurons to locate and innervate their correct target during development. When BDNF is overexpressed throughout the lingual epithelium, beginning embryonically, chorda tympani fibers are misdirected and innervate inappropriate targets, leading to a loss of taste buds. The remaining taste buds are hyperinnervated, demonstrating a disruption of nerve/target matching in the tongue. We tested the hypothesis here that overexpression of BDNF peripherally leads to a disrupted terminal field organization of nerves that carry taste information to the brainstem. The chorda tympani, greater superficial petrosal, and glossopharyngeal nerves were labeled in adult wild-type (WT) mice and in adult mice in which BDNF was overexpressed (OE) to examine the volume and density of their central projections in the nucleus of the solitary tract. We found that the terminal fields of the chorda tympani and greater superficial petrosal nerves and overlapping fields that included these nerves in OE mice were at least 80% greater than the respective field volumes in WT mice. The shapes of terminal fields were similar between the two groups; however, the density and spread of labels were greater in OE mice. Unexpectedly, there were also group-related differences in chorda tympani nerve function, with OE mice showing a greater relative taste response to a concentration series of sucrose. Overall, our results show that disruption in peripheral innervation patterns of sensory neurons have significant effects on peripheral nerve function and central organization of their terminal fields., (Copyright © 2015 the authors 0270-6474/15/350409-13$15.00/0.)

Published

2015

23. Developing and regenerating a sense of taste.

Author

Barlow LA and Klein OD

Subjects

Animals, Humans, Species Specificity, Taste Buds cytology, Cell Lineage physiology, Mammals embryology, Models, Biological, Regeneration physiology, Signal Transduction physiology, Taste physiology, Taste Buds embryology

Abstract

Taste is one of the fundamental senses, and it is essential for our ability to ingest nutritious substances and to detect and avoid potentially toxic ones. Taste buds, which are clusters of neuroepithelial receptor cells, are housed in highly organized structures called taste papillae in the oral cavity. Whereas the overall structure of the taste periphery is conserved in almost all vertebrates examined to date, the anatomical, histological, and cell biological, as well as potentially the molecular details of taste buds in the oral cavity are diverse across species and even among individuals. In mammals, several types of gustatory papillae reside on the tongue in highly ordered arrangements, and the patterning and distribution of the mature papillae depend on coordinated molecular events in embryogenesis. In this review, we highlight new findings in the field of taste development, including how taste buds are patterned and how taste cell fate is regulated. We discuss whether a specialized taste bud stem cell population exists and how extrinsic signals can define which cell lineages are generated. We also address the question of whether molecular regulation of taste cell renewal is analogous to that of taste bud development. Finally, we conclude with suggestions for future directions, including the potential influence of the maternal diet and maternal health on the sense of taste in utero., (© 2015 Elsevier Inc. All rights reserved.)

Published

2015

24. Developmental Plasticity of Patterned and Regenerating Oral Organs.

Author

Streelman JT, Bloomquist RF, and Fowler TE

Subjects

Animals, Body Patterning genetics, Epithelium embryology, Epithelium metabolism, Epithelium physiology, Gene Expression Regulation, Developmental, Hedgehog Proteins genetics, Jaw embryology, Jaw metabolism, Regeneration genetics, Signal Transduction genetics, Signal Transduction physiology, Taste Buds embryology, Taste Buds metabolism, Tooth embryology, Tooth metabolism, Body Patterning physiology, Jaw physiology, Regeneration physiology, Taste Buds physiology, Tooth physiology

Abstract

In many aquatic vertebrates, including bony and cartilaginous fishes, teeth and taste buds colocalize on jaw elements. In these animals, taste buds are renewed continuously throughout life, whereas teeth undergo cycled whole-organ replacement by various means. Recently, studies of cichlid fishes have yielded new insights into the development and regeneration of these dental and sensory oral organs. Tooth and taste bud densities covary positively across species with different feeding strategies, controlled by common regions of the genome and integrated molecular signals. Developing teeth and taste buds share a bipotent epithelium during early patterning stages, from which dental and taste fields are specified. Moreover, these organs share a common epithelial ribbon that supports label-retaining cells during later stages of regeneration. During both patterning and regeneration stages, dental organs can be converted to taste bud fate by manipulation of BMP signaling. These observations highlight a surprising long-term plasticity between dental and sensory organ types. Here, we review these findings and discuss the implications of developmental plasticity that spans the continuum of craniofacial organ patterning and regeneration., (© 2015 Elsevier Inc. All rights reserved.)

Published

2015

25. The formation of endoderm-derived taste sensory organs requires a Pax9-dependent expansion of embryonic taste bud progenitor cells.

Author

Kist R, Watson M, Crosier M, Robinson M, Fuchs J, Reichelt J, and Peters H

Subjects

Animals, Endoderm embryology, Epithelial Cells physiology, Gene Expression Regulation, Developmental, Hedgehog Proteins genetics, Hedgehog Proteins metabolism, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Mice, Inbred C57BL, Mice, Transgenic, Mutation, PAX9 Transcription Factor, Paired Box Transcription Factors genetics, Palate, Soft cytology, Palate, Soft embryology, SOX9 Transcription Factor genetics, SOX9 Transcription Factor metabolism, Taste Buds embryology, Tongue cytology, Tumor Suppressor Proteins genetics, Tumor Suppressor Proteins metabolism, Embryonic Stem Cells physiology, Endoderm cytology, Paired Box Transcription Factors metabolism, Tongue embryology

Abstract

In mammals, taste buds develop in different regions of the oral cavity. Small epithelial protrusions form fungiform papillae on the ectoderm-derived dorsum of the tongue and contain one or few taste buds, while taste buds in the soft palate develop without distinct papilla structures. In contrast, the endoderm-derived circumvallate and foliate papillae located at the back of the tongue contain a large number of taste buds. These taste buds cluster in deep epithelial trenches, which are generated by intercalating a period of epithelial growth between initial placode formation and conversion of epithelial cells into sensory cells. How epithelial trench formation is genetically regulated during development is largely unknown. Here we show that Pax9 acts upstream of Pax1 and Sox9 in the expanding taste progenitor field of the mouse circumvallate papilla. While a reduced number of taste buds develop in a growth-retarded circumvallate papilla of Pax1 mutant mice, its development arrests completely in Pax9-deficient mice. In addition, the Pax9 mutant circumvallate papilla trenches lack expression of K8 and Prox1 in the taste bud progenitor cells, and gradually differentiate into an epidermal-like epithelium. We also demonstrate that taste placodes of the soft palate develop through a Pax9-dependent induction. Unexpectedly, Pax9 is dispensable for patterning, morphogenesis and maintenance of taste buds that develop in ectoderm-derived fungiform papillae. Collectively, our data reveal an endoderm-specific developmental program for the formation of taste buds and their associated papilla structures. In this pathway, Pax9 is essential to generate a pool of taste bud progenitors and to maintain their competence towards prosensory cell fate induction.

Published

2014

26. Sonic hedgehog-expressing basal cells are general post-mitotic precursors of functional taste receptor cells.

Author

Miura H, Scott JK, Harada S, and Barlow LA

Subjects

Animals, Cell Differentiation genetics, Cells, Cultured, Embryonic Stem Cells metabolism, Epithelial Cells metabolism, Female, Gene Expression Regulation, Developmental, Hedgehog Proteins metabolism, Male, Mice, Mice, Inbred C57BL, Mice, Transgenic, Taste Buds cytology, Taste Buds metabolism, Embryonic Stem Cells physiology, Epithelial Cells physiology, Hedgehog Proteins genetics, Mitosis genetics, Sensory Receptor Cells physiology, Taste Buds embryology

Abstract

Background: Taste buds contain ∼60 elongate cells and several basal cells. Elongate cells comprise three functional taste cell types: I, glial cells; II, bitter/sweet/umami receptor cells; and III, sour detectors. Although taste cells are continuously renewed, lineage relationships among cell types are ill-defined. Basal cells have been proposed as taste bud stem cells, a subset of which express Sonic hedgehog (Shh). However, Shh+ basal cells turn over rapidly suggesting that Shh+ cells are post-mitotic precursors of some or all taste cell types., Results: To fate map Shh-expressing cells, mice carrying ShhCreER(T2) and a high (CAG-CAT-EGFP) or low (R26RLacZ) efficiency reporter allele were given tamoxifen to activate Cre in Shh+ cells. Using R26RLacZ, lineage-labeled cells occur singly within buds, supporting a post-mitotic state for Shh+ cells. Using either reporter, we show that Shh+ cells differentiate into all three taste cell types, in proportions reflecting cell type ratios in taste buds (I > II > III)., Conclusions: Shh+ cells are not stem cells, but are post-mitotic, immediate precursors of taste cells. Shh+ cells differentiate into each of the three taste cell types, and the choice of a specific taste cell fate is regulated to maintain the proper ratio within buds., (Copyright © 2014 Wiley Periodicals, Inc.)

Published

2014

27. Genetic dissection of TrkB activated signalling pathways required for specific aspects of the taste system.

Author

Koudelka J, Horn JM, Vatanashevanopakorn C, and Minichiello L

Subjects

Animals, Geniculate Ganglion metabolism, Male, Mice, Mice, Inbred C57BL, Mice, Transgenic, Point Mutation, Receptor, trkB genetics, Taste genetics, Taste Buds embryology, Taste Buds metabolism, Tongue innervation, Geniculate Ganglion embryology, Receptor, trkB metabolism, Signal Transduction genetics, Taste physiology

Abstract

Background: Neurotrophin-4 (NT-4) and brain derived neurotrophic factor (BDNF) bind to the same receptor, Ntrk2/TrkB, but play distinct roles in the development of the rodent gustatory system. However, the mechanisms underlying these processes are lacking., Results: Here, we demonstrate, in vivo, that single or combined point mutations in major adaptor protein docking sites on TrkB receptor affect specific aspects of the mouse gustatory development, known to be dependent on BDNF or NT-4. In particular, mice with a mutation in the TrkB-SHC docking site had reduced gustatory neuron survival at both early and later stages of development, when survival is dependent on NT-4 and BDNF, respectively. In addition, lingual innervation and taste bud morphology, both BDNF-dependent functions, were altered in these mutants. In contrast, mutation of the TrkB-PLCγ docking site alone did not affect gustatory neuron survival. Moreover, innervation to the tongue was delayed in these mutants and taste receptor expression was altered., Conclusions: We have genetically dissected pathways activated downstream of the TrkB receptor that are required for specific aspects of the taste system controlled by the two neurotrophins NT-4 and BDNF. In addition, our results indicate that TrkB also regulate the expression of specific taste receptors by distinct signalling pathways. These results advance our knowledge of the biology of the taste system, one of the fundamental sensory systems crucial for an organism to relate to the environment.

Published

2014

28. The neurotrophin receptor p75 regulates gustatory axon branching and promotes innervation of the tongue during development.

Author

Fei D, Huang T, and Krimm RF

Subjects

Animals, Mice, Mice, Knockout, Receptor, trkB genetics, Taste physiology, Axons ultrastructure, Receptor, Nerve Growth Factor genetics, Taste Buds embryology, Tongue embryology, Tongue innervation

Abstract

Background: Brain-derived neurotrophic factor (BDNF) and neurotrophin-4 (NT4) regulate the survival of gustatory neurons, axon growth and branching, and innervation of taste buds during development. These actions are largely, but not completely, mediated through the tyrosine kinase receptor, TrkB. Here, we investigated the role of p75, the other major receptor for BDNF and NT4, in the development of the taste system., Results: We found that p75-/-mice showed delayed axon outgrowth and reduced branching of gustatory axons at embryonic day (E)13.5. From E14.5 to E18.5, gustatory neurons innervated fewer papillae and completely failed to innervate the mid-region of the tongue in p75-/-mice. These early effects of the p75 mutation on gustatory axons preceded the loss of geniculate ganglion neurons starting at E14.5 and also contributed to a loss of taste buds at and after birth. Because knockouts for the TrkB receptor (TrkB-/-) do not lose as many taste buds as hybrid knockouts for its two ligands (BDNF and NT4), we asked if p75 maintains those additional taste buds in the absence of TrkB. It does not; hybrid TrkB-/-/p75-/-mice had more taste buds than TrkB-/-mice; these additional taste buds were not due to an increase in neurons or innervation., Conclusions: p75 regulates gustatory neuron axon branching and tongue innervation patterns during taste system development. This function is likely accomplished independently of BDNF, NT4, and TrkB. In addition, p75 does not support the remaining neurons or taste buds in TrkB-/-mice.

Published

2014

29. WT1 regulates the development of the posterior taste field.

Author

Gao Y, Toska E, Denmon D, Roberts SG, and Medler KF

Subjects

Animals, Lymphoid Enhancer-Binding Factor 1 metabolism, Mice, Mice, Inbred BALB C, Mice, Inbred C57BL, Mice, Knockout, Patched Receptors, Patched-1 Receptor, Phenotype, Receptors, Cell Surface metabolism, Signal Transduction, Time Factors, Gene Expression Regulation, Developmental, Taste physiology, Taste Buds embryology, Tongue embryology, WT1 Proteins metabolism

Abstract

Despite the importance of taste in determining nutrient intake, our understanding of the processes that control the development of the peripheral taste system is lacking. Several early regulators of taste development have been identified, including sonic hedgehog, bone morphogenetic protein 4 and multiple members of the Wnt/β-catenin signaling pathway. However, the regulation of these factors, including their induction, remains poorly understood. Here, we identify a crucial role for the Wilms' tumor 1 protein (WT1) in circumvallate (CV) papillae development. WT1 is a transcription factor that is important in the normal development of multiple tissues, including both the olfactory and visual systems. In mice, WT1 expression is detectable by E12.5, when the CV taste placode begins to form. In mice lacking WT1, the CV fails to develop normally and markers of early taste development are dysregulated compared with wild type. We demonstrate that expression of the WT1 target genes Lef1, Ptch1 and Bmp4 is significantly reduced in developing tongue tissue derived from Wt1 knockout mice and that, in normal tongue, WT1 is bound to the promoter regions of these genes. Moreover, siRNA knockdown of WT1 in cultured taste cells leads to a reduction in the expression of Lef1 and Ptch1. Our data identify WT1 as a crucial transcription factor in the development of the CV through the regulation of multiple signaling pathways that have established roles in the formation and patterning of taste placodes., (© 2014. Published by The Company of Biologists Ltd.)

Published

2014

30. Gpr177-mediated Wnt Signaling is Required for Fungiform Placode Initiation.

Author

Zhu X, Liu Y, Zhao P, Dai Z, Yang X, Li Y, Qiu M, and Zhang Z

Subjects

Animals, Axin Protein metabolism, Epithelium embryology, Hedgehog Proteins physiology, Intracellular Signaling Peptides and Proteins drug effects, Lithium Chloride pharmacology, Mesoderm embryology, Mice, Mice, Knockout, Receptors, G-Protein-Coupled drug effects, Taste Buds drug effects, Tissue Culture Techniques, Tongue embryology, Wnt Proteins metabolism, Intracellular Signaling Peptides and Proteins physiology, Receptors, G-Protein-Coupled physiology, Taste Buds embryology, Wnt Signaling Pathway physiology

Abstract

Fungiform papillae are formed as patterned rows on the surface of the anterior tongue at early organogenesis and contain one taste bud in each papilla to form one of the important sensory organs. Despite the essential role of Wnt/β-catenin signaling in controlling the development of fungiform taste papillae, the universal function of Wnt ligands in the initiation of the fungiform placode has not been completely elucidated. Here, by Shh (Cre) -mediated oral epithelial deletion of Wntless (Gpr177), a regulator essential for intracellular Wnt trafficking, we demonstrate that an overall function of Wnts is required for initiation of the fungiform placode. Multiple Wnts are expressed in the tongue epithelium at E11.5 before initiation of the fungiform placodes. Epithelial Gpr177 loss-of-function, associated with reduction of canonical Wnt signaling in lingual epithelium as exhibited by a loss of TopGal activity and Axin2 expression, results in the failure of fungiform placode initiation, as assessed by diminished expression of several taste placode molecular markers. Moreover, LiCl treatment of Gpr177 epithelial-deficient tongue explants at E11.5, but not at E12.5, restores tongue placode formation, demonstrating that Wnt ligands in the tongue surface prior to but not after fungiform placode initiation are responsible for fungiform papilla initiation. Epithelium-specific expression of an active β-catenin in the Gpr177-deficient tongue leads to fungiform papillae generation, suggesting that an intra-epithelial response to Wnts is required for placode initiation. Together, these results suggest that Gpr177 controls epithelial initiation of the fungiform placode through signaling via epithelial Wnt ligands., (© International & American Associations for Dental Research.)

Published

2014

31. Neuroepithelial structures associated with the subepithelial nerve plexus of taste buds: a fortuitous finding resembling the juxtaoral organ of Chievitz.

Author

Palazzolo MJ, Fowler CB, Magliocca KR, and Gnepp DR

Subjects

Aged, Biomarkers analysis, Biopsy, Carcinoma, Squamous Cell pathology, Carcinoma, Squamous Cell surgery, Cell Proliferation, Epithelium embryology, Female, Head and Neck Neoplasms pathology, Head and Neck Neoplasms surgery, Humans, Immunohistochemistry, Male, Middle Aged, Tongue Diseases pathology, Tongue Diseases surgery, Cheek, Taste Buds embryology, Tongue innervation

Abstract

Numerous embryologic epithelial remnants are described in the oral region, when intimately associated with peripheral nerves, may pose a diagnostic pitfall for pathologists. The literature contains cases in which the juxtaoral organ of Chievitz (JOC) was identified in specimens removed because of a malignancy and the correct recognition of this structure potentially avoids unnecessary treatment. To our knowledge, this is the description of neuroepithelial structures similar to the JOC were found in the posterior tongue in close association with the subepithelial nerve plexus of taste buds. Four cases are reported. The nerve fibers of the subepithelial nerve plexus showed strong positivity for S-100, CD56, and synaptophysin, and were intimately associated with epithelial islands. CD56 showed positivity around the periphery of the epithelial islands. Proper recognition of these anatomic structures is crucial to prevent misdiagnosis of squamous cell carcinoma with perineural invasion., (Published by Mosby, Inc.)

Published

2014

32. Taste neurons consist of both a large TrkB-receptor-dependent and a small TrkB-receptor-independent subpopulation.

Author

Fei D and Krimm RF

Subjects

Animals, Brain-Derived Neurotrophic Factor genetics, Brain-Derived Neurotrophic Factor metabolism, Cell Survival, Female, Gene Expression, Geniculate Ganglion embryology, Geniculate Ganglion metabolism, Mice, Mice, Knockout, Nerve Growth Factors genetics, Nerve Growth Factors metabolism, Neurons metabolism, Receptor, trkB genetics, Receptors, Purinergic P2X3 metabolism, Taste Buds embryology, Receptor, trkB metabolism, Taste Buds metabolism

Abstract

Brain-derived neurotrophic factor (BDNF) and neurotrophin-4 (NT-4) are two neurotrophins that play distinct roles in geniculate (taste) neuron survival, target innervation, and taste bud formation. These two neurotrophins both activate the tropomyosin-related kinase B (TrkB) receptor and the pan-neurotrophin receptor p75. Although the roles of these neurotrophins have been well studied, the degree to which BDNF and NT-4 act via TrkB to regulate taste development in vivo remains unclear. In this study, we compared taste development in TrkB(-/-) and Bdnf(-/-)/Ntf4(-/-) mice to determine if these deficits were similar. If so, this would indicate that the functions of both BDNF and NT-4 can be accounted for by TrkB-signaling. We found that TrkB(-/-) and Bdnf(-/-)/Ntf4(-/-) mice lose a similar number of geniculate neurons by E13.5, which indicates that both BDNF and NT-4 act primarily via TrkB to regulate geniculate neuron survival. Surprisingly, the few geniculate neurons that remain in TrkB(-/-) mice are more successful at innervating the tongue and taste buds compared with those neurons that remain in Bdnf(-/-)/Ntf4(-/-) mice. The remaining neurons in TrkB(-/-) mice support a significant number of taste buds. In addition, these remaining neurons do not express the TrkB receptor, which indicates that either BDNF or NT-4 must act via additional receptors to influence tongue innervation and/or targeting.

Published

2013

33. Multiple Shh signaling centers participate in fungiform papilla and taste bud formation and maintenance.

Author

Liu HX, Ermilov A, Grachtchouk M, Li L, Gumucio DL, Dlugosz AA, and Mistretta CM

Subjects

Aging metabolism, Animals, Animals, Newborn, Cell Compartmentation, Cell Lineage, Cell Proliferation, Cellular Microenvironment, Epithelial Cells cytology, Epithelial Cells metabolism, Female, Kruppel-Like Transcription Factors metabolism, Ligands, Mesoderm cytology, Mesoderm embryology, Mesoderm metabolism, Mice, Mice, Inbred C57BL, Patched Receptors, Patched-1 Receptor, Receptors, Cell Surface metabolism, Taste Buds cytology, Taste Buds ultrastructure, Time Factors, Zinc Finger Protein GLI1, Zinc Finger Protein Gli2, Epithelium embryology, Epithelium metabolism, Hedgehog Proteins metabolism, Signal Transduction, Taste Buds embryology, Taste Buds metabolism

Abstract

The adult fungiform taste papilla is a complex of specialized cell types residing in the stratified squamous tongue epithelium. This unique sensory organ includes taste buds, papilla epithelium and lateral walls that extend into underlying connective tissue to surround a core of lamina propria cells. Fungiform papillae must contain long-lived, sustaining or stem cells and short-lived, maintaining or transit amplifying cells that support the papilla and specialized taste buds. Shh signaling has established roles in supporting fungiform induction, development and patterning. However, for a full understanding of how Shh transduced signals act in tongue, papilla and taste bud formation and maintenance, it is necessary to know where and when the Shh ligand and pathway components are positioned. We used immunostaining, in situ hybridization and mouse reporter strains for Shh, Ptch1, Gli1 and Gli2-expression and proliferation markers to identify cells that participate in hedgehog signaling. Whereas there is a progressive restriction in location of Shh ligand-expressing cells, from placode and apical papilla cells to taste bud cells only, a surrounding population of Ptch1 and Gli1 responding cells is maintained in signaling centers throughout papilla and taste bud development and differentiation. The Shh signaling targets are in regions of active cell proliferation. Using genetic-inducible lineage tracing for Gli1-expression, we found that Shh-responding cells contribute not only to maintenance of filiform and fungiform papillae, but also to taste buds. A requirement for normal Shh signaling in fungiform papilla, taste bud and filiform papilla maintenance was shown by Gli2 constitutive activation. We identified proliferation niches where Shh signaling is active and suggest that epithelial and mesenchymal compartments harbor potential stem and/or progenitor cell zones. In all, we report a set of hedgehog signaling centers that regulate development and maintenance of taste organs, the fungiform papilla and taste bud, and surrounding lingual cells. Shh signaling has roles in forming and maintaining fungiform papillae and taste buds, most likely via stage-specific autocrine and/or paracrine mechanisms, and by engaging epithelial/mesenchymal interactions., (© 2013 Elsevier Inc. All rights reserved.)

Published

2013

34. Expression of sall4 in taste buds of zebrafish.

Author

Jackson R, Braubach OR, Bilkey J, Zhang J, Akimenko MA, Fine A, Croll RP, and Jonz MG

Subjects

Animals, Animals, Genetically Modified, Epithelium embryology, Epithelium innervation, Epithelium metabolism, Transcription Factors biosynthesis, Zebrafish, Zebrafish Proteins biosynthesis, Gene Expression Regulation, Developmental, Taste Buds embryology, Taste Buds metabolism, Transcription Factors genetics, Zebrafish Proteins genetics

Abstract

We characterized the expression of sall4, a gene encoding a zinc finger transcription factor involved in the maintenance of embryonic stem cells, in taste buds of zebrafish (Danio rerio). Using an enhancer trap line (ET5), we detected enhanced green fluorescent protein (EGFP) in developing and adult transgenic zebrafish in regions containing taste buds: the lips, branchial arches, and the nasal and maxillary barbels. Localization of EGFP to taste cells of the branchial arches and lips was confirmed by co-immunolabeling with antibodies against calretinin and serotonin, and a zebrafish-derived neuronal marker (zn-12). Transgenic insertion of the ET construct into the zebrafish genome was evaluated and mapped to chromosome 23 in proximity (i.e. 23 kb) to the sall4 gene. In situ hybridization and expression analysis between 24 and 96 h post-fertilization (hpf) demonstrated that transgenic egfp expression in ET5 zebrafish was correlated with the spatial and temporal pattern of expression of sall4 in the wild-type. Expression was first observed in the central nervous system and branchial arches at 24 hpf. At 48 hpf, sall4 and egfp expression was observed in taste bud primordia surrounding the mouth and branchial arches. At 72 and 96 hpf, expression was detected in the upper and lower lips and branchial arches. Double fluorescence in situ hybridization at 3 and 10 dpf confirmed colocalization of sall4 and egfp in the lips and branchial arches. These studies reveal sall4 expression in chemosensory cells and implicate this transcription factor in the development and renewal of taste epithelia in zebrafish., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

35. Developing a sense of taste.

Author

Kapsimali M and Barlow LA

Subjects

Animals, Cell Differentiation, Epithelial-Mesenchymal Transition, Humans, Signal Transduction, Taste Buds cytology, Taste Buds growth & development, Taste Buds embryology

Abstract

Taste buds are found in a distributed array on the tongue surface, and are innervated by cranial nerves that convey taste information to the brain. For nearly a century, taste buds were thought to be induced by nerves late in embryonic development. However, this view has shifted dramatically. A host of studies now indicate that taste bud development is initiated and proceeds via processes that are nerve-independent, occur long before birth, and governed by cellular and molecular mechanisms intrinsic to the developing tongue. Here we review the state of our understanding of the molecular and cellular regulation of taste bud development, incorporating important new data obtained through the use of two powerful genetic systems, mouse and zebrafish., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2013

36. Neural crest contribution to lingual mesenchyme, epithelium and developing taste papillae and taste buds.

Author

Liu HX, Komatsu Y, Mishina Y, and Mistretta CM

Subjects

Animals, Animals, Newborn, Epithelium embryology, Epithelium growth & development, Epithelium metabolism, Female, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Immunohistochemistry, Integrases genetics, Integrases metabolism, Male, Mesoderm embryology, Mesoderm growth & development, Mice, Mice, Transgenic, Microscopy, Confocal, Models, Anatomic, Neural Crest embryology, Neural Crest growth & development, Taste Buds embryology, Taste Buds growth & development, Time Factors, Tongue embryology, Tongue growth & development, Wnt1 Protein genetics, Wnt1 Protein metabolism, beta-Galactosidase genetics, beta-Galactosidase metabolism, Mesoderm metabolism, Neural Crest metabolism, Taste Buds metabolism, Tongue metabolism

Abstract

The epithelium of mammalian tongue hosts most of the taste buds that transduce gustatory stimuli into neural signals. In the field of taste biology, taste bud cells have been described as arising from "local epithelium", in distinction from many other receptor organs that are derived from neurogenic ectoderm including neural crest (NC). In fact, contribution of NC to both epithelium and mesenchyme in the developing tongue is not fully understood. In the present study we used two independent, well-characterized mouse lines, Wnt1-Cre and P0-Cre that express Cre recombinase in a NC-specific manner, in combination with two Cre reporter mouse lines, R26R and ZEG, and demonstrate a contribution of NC-derived cells to both tongue mesenchyme and epithelium including taste papillae and taste buds. In tongue mesenchyme, distribution of NC-derived cells is in close association with taste papillae. In tongue epithelium, labeled cells are observed in an initial scattered distribution and progress to a clustered pattern between papillae, and within papillae and early taste buds. This provides evidence for a contribution of NC to lingual epithelium. Together with previous reports for the origin of taste bud cells from local epithelium in postnatal mouse, we propose that NC cells migrate into and reside in the epithelium of the tongue primordium at an early embryonic stage, acquire epithelial cell phenotypes, and undergo cell proliferation and differentiation that is involved in the development of taste papillae and taste buds. Our findings lead to a new concept about derivation of taste bud cells that include a NC origin., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

37. Lineage tracing of the endoderm during oral development.

Author

Rothova M, Thompson H, Lickert H, and Tucker AS

Subjects

Animals, Female, Male, Mice, Salivary Glands embryology, Taste Buds embryology, Tooth embryology, Endoderm embryology, Mouth embryology

Abstract

Background: The contribution of the endoderm to the oral tissues of the head has been debated for many years. With the arrival of Cre/LoxP technology endoderm progenitor cells can now be genetically labeled and tissues derived from the endoderm traced. Using Sox17-2A-iCre/Rosa26 reporter mice we have followed the fate of the endoderm in the teeth, glands, and taste papillae of the oral cavity., Results: No contribution of the endoderm was observed at any stage of tooth development, or in development of the major salivary glands, in the reporter mouse during development. In contrast, the minor mucous glands of the tongue were found to be of endodermal origin, along with the circumvallate papilla and foliate papillae. The mucous minor salivary glands of the palate, however, were of mixed ectodermal and endodermal origin., Conclusions: In contrast to urodele studies, the epithelium of murine teeth is derived solely from the ectoderm. The border between the ectoderm- and endoderm-derived epithelium may play a role in determining the position of the lingual glands and taste buds, and may explain differences observed between taste buds in the anterior and posterior part of the tongue., (Copyright © 2012 Wiley Periodicals, Inc.)

Published

2012

38. Separate and distinctive roles for Wnt5a in tongue, lingual tissue and taste papilla development.

Author

Liu HX, Grosse AS, Iwatsuki K, Mishina Y, Gumucio DL, and Mistretta CM

Subjects

Animals, Blotting, Western, Bromodeoxyuridine, Female, Galactosides, Hedgehog Proteins metabolism, Immunohistochemistry, In Situ Hybridization, Indoles, Mesoderm embryology, Mice, Mice, Knockout, Microscopy, Electron, Scanning, Rats, Rats, Sprague-Dawley, Taste Buds metabolism, Wnt-5a Protein, Mesoderm metabolism, Signal Transduction physiology, Taste Buds embryology, Tongue embryology, Wnt Proteins metabolism

Abstract

Although canonical Wnt signaling is known to regulate taste papilla induction and numbers, roles for noncanonical Wnt pathways in tongue and taste papilla development have not been explored. With mutant mice and whole tongue organ cultures we demonstrate that Wnt5a protein and message are within anterior tongue mesenchyme across embryo stages from the initiation of tongue formation, through papilla placode appearance and taste papilla development. The Wnt5a mutant tongue is severely shortened, with an ankyloglossia, and lingual mesenchyme is disorganized. However, fungiform papilla morphology, number and innervation are preserved, as is expression of the papilla marker, Shh. These data demonstrate that the genetic regulation for tongue size and shape can be separated from that directing lingual papilla development. Preserved number of papillae in a shortened tongue results in an increased density of fungiform papillae in the mutant tongues. In tongue organ cultures, exogenous Wnt5a profoundly suppresses papilla formation and simultaneously decreases canonical Wnt signaling as measured by the TOPGAL reporter. These findings suggest that Wnt5a antagonizes canonical Wnt signaling to dictate papilla number and spacing. In all, distinctive roles for Wnt5a in tongue size, fungiform papilla patterning and development are shown and a necessary balance between non-canonical and canonical Wnt paths in regulating tongue growth and fungiform papillae is proposed in a model, through the Ror2 receptor., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2012

39. Development of gustatory papillae in the absence of Six1 and Six4.

Author

Suzuki Y, Ikeda K, and Kawakami K

Subjects

Animals, Gene Expression Regulation, Developmental, Immunohistochemistry, Mice, Mice, Inbred C57BL, Taste Buds metabolism, Tongue embryology, Tongue metabolism, Embryo, Mammalian physiology, Homeodomain Proteins metabolism, Taste Buds embryology, Trans-Activators metabolism

Abstract

Six family genes encode homeobox transcription factors, and a deficiency in them leads to abnormal structures of the sensory organs. In a previous paper, Six1 was reported to be expressed in the taste bud-bearing lingual papillae of mice, and loss of Six1 affected the development of these gustatory papillae. We show here that embryos lacking both Six1 and Six4 revealed more severe abnormalities than those lacking Six1 alone during morphogenesis of their gustatory papillae. By in situ hybridization, Six4 was shown to be broadly distributed in the epithelium of the lateral lingual swellings at embryonic day (E) 11.5, and in the tongue epithelium, mesenchyme, and muscles at E12.5. From E14, Six4 was similar in expression pattern to Six1, as previously reported. In the fungiform papillae, Six4 was expressed in the epithelium at E14-E16.5. In the circumvallate and foliate papillae, Six4 expression was observed in the trench wall of these papillae at E15.5-P0. Although Six4-deficient mice had no abnormalities, Six1/Six4-deficient mice showed distinct morphological changes: fusion of the lateral lingual swellings was delayed, and the tongue was poorly developed. The primordia of fungiform papillae appeared earlier than those in the wild-type or Six1-deficient mice, and the papillae rapidly increased in size; thus fusion of each papilla was evident. The circumvallate papillae showed severe defects; for example, invagination of the trenches started asymmetrically, which resulted in longer and shorter trenches. The foliate papillae elevated initially, and showed stunted trenches. Therefore, Six1 and Six4 function synergistically to form gustatory papillae during development of the tongue., (© 2011 The Authors. Journal of Anatomy © 2011 Anatomical Society of Great Britain and Ireland.)

Published

2011

40. Fgf signaling controls pharyngeal taste bud formation through miR-200 and Delta-Notch activity.

Author

Kapsimali M, Kaushik AL, Gibon G, Dirian L, Ernest S, and Rosa FM

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Fibroblast Growth Factors metabolism, Intracellular Signaling Peptides and Proteins metabolism, Membrane Proteins metabolism, Receptors, Notch metabolism, Taste Buds growth & development, Transcription Factors, Zebrafish growth & development, Zebrafish Proteins genetics, Zebrafish Proteins metabolism, MicroRNAs genetics, Signal Transduction, Taste Buds embryology, Taste Buds metabolism, Zebrafish embryology, Zebrafish metabolism

Abstract

Taste buds, the taste sensory organs, are conserved in vertebrates and composed of distinct cell types, including taste receptor, basal/presynaptic and support cells. Here, we characterize zebrafish taste bud development and show that compromised Fgf signaling in the larva results in taste bud reduction and disorganization. We determine that Fgf activity is required within pharyngeal endoderm for formation of Calb2b(+) cells and reveal miR-200 and Delta-Notch signaling as key factors in this process. miR-200 knock down shows that miR-200 activity is required for taste bud formation and in particular for Calb2b(+) cell formation. Compromised delta activity in mib(-/-) dramatically reduces the number of Calb2b(+) cells and increases the number of 5HT(+) cells. Conversely, larvae with increased Notch activity and ascl1a(-/-) mutants are devoid of 5HT(+) cells, but have maintained and increased Calb2b(+) cells, respectively. These results show that Delta-Notch signaling is required for intact taste bud organ formation. Consistent with this, Notch activity restores Calb2b(+) cell formation in pharyngeal endoderm with compromised Fgf signaling, but fails to restore the formation of these cells after miR-200 knock down. Altogether, this study provides genetic evidence that supports a novel model where Fgf regulates Delta-Notch signaling, and subsequently miR-200 activity, in order to promote taste bud cell type differentiation.

Published

2011

41. FGF signaling regulates the number of posterior taste papillae by controlling progenitor field size.

Author

Petersen CI, Jheon AH, Mostowfi P, Charles C, Ching S, Thirumangalathu S, Barlow LA, and Klein OD

Subjects

Adaptor Proteins, Signal Transducing, Animals, Embryo, Mammalian metabolism, Intracellular Signaling Peptides and Proteins, Membrane Proteins genetics, Membrane Proteins metabolism, Protein Serine-Threonine Kinases, Taste physiology, Taste Buds cytology, Fibroblast Growth Factor 10 genetics, Fibroblast Growth Factor 10 metabolism, Signal Transduction, Stem Cells cytology, Taste Buds embryology

Abstract

The sense of taste is fundamental to our ability to ingest nutritious substances and to detect and avoid potentially toxic ones. Sensory taste buds are housed in papillae that develop from epithelial placodes. Three distinct types of gustatory papillae reside on the rodent tongue: small fungiform papillae are found in the anterior tongue, whereas the posterior tongue contains the larger foliate papillae and a single midline circumvallate papilla (CVP). Despite the great variation in the number of CVPs in mammals, its importance in taste function, and its status as the largest of the taste papillae, very little is known about the development of this structure. Here, we report that a balance between Sprouty (Spry) genes and Fgf10, which respectively antagonize and activate receptor tyrosine kinase (RTK) signaling, regulates the number of CVPs. Deletion of Spry2 alone resulted in duplication of the CVP as a result of an increase in the size of the placode progenitor field, and Spry1(-/-);Spry2(-/-) embryos had multiple CVPs, demonstrating the redundancy of Sprouty genes in regulating the progenitor field size. By contrast, deletion of Fgf10 led to absence of the CVP, identifying FGF10 as the first inductive, mesenchyme-derived factor for taste papillae. Our results provide the first demonstration of the role of epithelial-mesenchymal FGF signaling in taste papilla development, indicate that regulation of the progenitor field size by FGF signaling is a critical determinant of papilla number, and suggest that the great variation in CVP number among mammalian species may be linked to levels of signaling by the FGF pathway., Competing Interests: The authors have declared that no competing interests exist.

Published

2011

42. Mash1 is required for the differentiation of AADC-positive type III cells in mouse taste buds.

Author

Seta Y, Oda M, Kataoka S, Toyono T, and Toyoshima K

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Cells, Cultured, Embryo, Mammalian, Epithelium embryology, Epithelium metabolism, Female, Gene Expression Regulation, Developmental, Mice, Mice, Knockout, Palate embryology, Palate metabolism, Pregnancy, Aromatic-L-Amino-Acid Decarboxylases metabolism, Basic Helix-Loop-Helix Transcription Factors physiology, Cell Differentiation genetics, Taste Buds embryology, Taste Buds metabolism

Abstract

Mash1 is expressed in subsets of neuronal precursors in both the central nervous system and the peripheral nervous system. However, involvement of Mash1 in taste cell differentiation has not previously been demonstrated. In this study, we investigated the role of Mash1 in regulating taste bud differentiation using Mash1 KO mice to begin to understand the mechanisms that regulate taste bud cell differentiation. We found that aromatic L-amino acid decarboxylase (AADC) cells were not evident in either the circumvallate papilla epithelia or in taste buds in the soft palates of Mash1 KO mice. However gustducin was expressed in taste buds in the soft palates of Mash1 KO mice. These results suggest that Mash1 plays an important role in regulating the expression of AADC in type III cells in taste buds, which supports the hypothesis that different taste bud cell types have progenitor cells that are specific to each cell type., (Copyright © 2011 Wiley-Liss, Inc.)

Published

2011

43. Epibranchial placode-derived neurons produce BDNF required for early sensory neuron development.

Author

Harlow DE, Yang H, Williams T, and Barlow LA

Subjects

Animals, Brain-Derived Neurotrophic Factor genetics, Epithelium embryology, Epithelium innervation, Female, Ganglia cytology, Ganglia physiology, Mice, Mice, Inbred C57BL, Mice, Knockout, Neurons cytology, Pregnancy, Receptor, trkB genetics, Receptor, trkB metabolism, Sensory Receptor Cells cytology, Taste Buds metabolism, Tongue embryology, Tongue innervation, Tongue physiology, Brain-Derived Neurotrophic Factor metabolism, Neurogenesis physiology, Neurons metabolism, Sensory Receptor Cells physiology, Taste Buds cytology, Taste Buds embryology

Abstract

In mice, BDNF provided by the developing taste epithelium is required for gustatory neuron survival following target innervation. However, we find that expression of BDNF, as detected by BDNF-driven β-galactosidase, begins in the cranial ganglia before its expression in the central (hindbrain) or peripheral (taste papillae) targets of these sensory neurons, and before gustatory ganglion cells innervate either target. To test early BDNF function, we examined the ganglia of bdnf null mice before target innervation, and found that while initial neuron survival is unaltered, early neuron development is disrupted. In addition, fate mapping analysis in mice demonstrates that murine cranial ganglia arise from two embryonic populations, i.e., epibranchial placodes and neural crest, as has been described for these ganglia in non-mammalian vertebrates. Only placodal neurons produce BDNF, however, which indicates that prior to innervation, early ganglionic BDNF produced by placode-derived cells promotes gustatory neuron development., (Copyright © 2011 Wiley-Liss, Inc.)

Published

2011

44. Expression of Six1 and Six4 in mouse taste buds.

Author

Suzuki Y, Ikeda K, and Kawakami K

Subjects

Animals, Cell Nucleus metabolism, Denervation, Gene Expression Regulation, Developmental, Homeodomain Proteins genetics, In Situ Hybridization, Mice, Mice, Inbred C57BL, Microscopy, Confocal, Submandibular Gland cytology, Submandibular Gland metabolism, Taste Buds cytology, Taste Buds embryology, Trans-Activators genetics, Homeodomain Proteins metabolism, Taste Buds metabolism, Trans-Activators metabolism

Abstract

Members of the Six gene family are expressed in various tissues including sensory organs, such as the inner ear and olfactory epithelium. We examined the expression of Six1 and Six4 mRNAs in mouse taste buds by using in situ hybridization. Six1 was detected immunohistochemically in the nuclei of taste bud cells, in a subset of type-II cells, as shown by double-immunolabeling with anti-Six1 together with anti-PLCβ2 or anti-IP(3)R3 antibodies. Six1-immunoreactive (IR) nuclei appeared at embryonic day 17.5 in the dorsal epithelium, and in the trench wall epithelium of circumvallate papillae at postnatal day 5. At this stage, Six1-IR nuclei were observed in all newly-formed type-II cells. During postnatal development, type-II cells increased in number, but those with Six1-IR nuclei showed no apparent increase. After transection of the bilateral glossopharyngeal nerve, type-II cells gradually disappeared; but some of them remained in the epithelium even at 11-17 days post-transection. The remaining type-II cells showed Six1-immunoreactivity. At 24 days after nerve transection, regenerating type-II cells appeared; and strong Six1-immunoreactivity was observed in them. Also, enhanced green fluorescent protein-immunoreactivity and β-galactosidase-immunoreactivity, which were indicators for Six1 transcripts and Six4 transcripts, respectively, overlapped. These results suggest that Six1 and Six4 genes are expressed in the taste bud cells, in newly formed or surviving type-II cells.

Published

2010

45. Brain-derived neurotrophic factor attracts geniculate ganglion neurites during embryonic targeting.

Author

Hoshino N, Vatterott P, Egwiekhor A, and Rochlin MW

Subjects

Animals, Brain-Derived Neurotrophic Factor genetics, Chemotactic Factors genetics, Epithelium embryology, Epithelium growth & development, Rats, Taste Buds cytology, Taste Buds embryology, Taste Buds growth & development, Tissue Culture Techniques, Tongue cytology, Tongue embryology, Tongue growth & development, Tongue innervation, Brain-Derived Neurotrophic Factor pharmacology, Chemotactic Factors pharmacology, Geniculate Ganglion cytology, Geniculate Ganglion drug effects, Geniculate Ganglion physiology, Neurites drug effects, Neurites metabolism, Neurites ultrastructure

Abstract

Geniculate axons are initially guided to discrete epithelial placodes in the lingual and palatal epithelium that subsequently differentiate into taste buds. In vivo approaches show that brain-derived neurotrophic factor (BDNF) mRNA is concentrated in these placodes, that BDNF is necessary for targeting taste afferents to these placodes, and that BDNF misexpression disrupts guidance. We used an in vitro approach to determine whether BDNF may act directly on geniculate axons as a trophic factor and as an attractant, and whether there is a critical period for responsiveness to BDNF. We show that BDNF promotes neurite outgrowth from geniculate ganglion explants dissected from embryonic day (E) 15, E18, infant, and adult rats cultured in collagen gels, and that there is a concentration optimum for neurite extension. Gradients of BDNF derived from slow-release beads caused the greatest bias in neurite outgrowth at E15, when axons approach the immature gustatory papillae. Further, neurites advanced faster toward the BDNF bead than away from it, even if the average amount of neurotrophic factor encountered was the same. We also found that neurites that contact BDNF beads did not advance beyond them. At E18, when axons would be penetrating pregustatory epithelium in vivo, BDNF continued to exert a tropic effect on geniculate neurites. However, at postnatal and adult stages, the influence of BDNF was predominantly trophic. Our data support a role for BDNF acting as an attractant for geniculate axons during a critical period that encompasses initial targeting but not at later stages., (Copyright 2010 S. Karger AG, Basel.)

Published

2010

46. BDNF is required for the survival of differentiated geniculate ganglion neurons.

Author

Patel AV and Krimm RF

Subjects

Animals, Brain-Derived Neurotrophic Factor genetics, Caspase 3 genetics, Caspase 3 metabolism, Cell Differentiation genetics, Cell Survival physiology, Embryo, Mammalian, Enzyme Activation, Heterozygote, Homozygote, Immunohistochemistry, Mice, Mice, Inbred C57BL, Mice, Knockout, Taste Buds embryology, bcl-2-Associated X Protein genetics, Brain-Derived Neurotrophic Factor metabolism, Geniculate Ganglion metabolism, Neurons cytology, Neurons metabolism

Abstract

In mice lacking functional brain-derived neurotrophic factor (BDNF), the number of geniculate ganglion neurons, which innervate taste buds, is reduced by one-half. Here, we determined how and when BDNF regulates the number of neurons in the developing geniculate ganglion. The loss of geniculate neurons begins at embryonic day 13.5 (E13.5) and continues until E18.5 in BDNF-null mice. Neuronal loss in BDNF-null mice was prevented by the removal of the pro-apoptotic gene Bax. Thus, BDNF regulates embryonic geniculate neuronal number by preventing cell death rather than promoting cell proliferation. The number of neurofilament positive neurons expressing activated caspase-3 increased on E13.5 in bdnf(-/-) mice, compared to wild-type mice, demonstrating that differentiated neurons were dying. The axons of geniculate neurons approach their target cells, the fungiform papillae, beginning on E13.5, at which time we found robust BDNF(LacZ) expression in these targets. Altogether, our findings establish that BDNF produced in peripheral target cells regulates the survival of early geniculate neurons by inhibiting cell death of differentiated neurons on E13.5 of development. Thus, BDNF acts as a classic target-derived growth factor in the developing taste system., (Copyright (c) 2010 Elsevier Inc. All rights reserved.)

Published

2010

47. Taste cell formation does not require gustatory and somatosensory innervation.

Author

Ito A, Nosrat IV, and Nosrat CA

Subjects

Animals, Animals, Newborn, Brain-Derived Neurotrophic Factor genetics, Mice, Mice, Knockout, Neurotrophin 3 genetics, Taste Buds embryology, Taste Buds growth & development, Tongue embryology, Tongue growth & development, Tongue innervation, Nerve Fibers physiology, Taste Buds physiology

Abstract

Dependency of taste buds and taste papillae on innervation has been debated for a long time. Previous research showed neurotrophins, brain-derived neurotrophic factor (BDNF) and neurotrophin-3 (NT-3), play an important role for the establishment of the lingual gustatory and somatosensory innervation. BDNF null mutant mice showed severe deficits in gustatory innervation and loss of taste buds while NT-3 null mutation reduced lingual somatosensory innervation to tongue papillae. These results proved BDNF or NT-3 null mutations affected different sensory modalities (i.e. gustatory and somatosensory, respectively). In this study, we analyzed taste bud development in BDNFxNT-3 double knockout mice to examine the relationship between taste bud development and gustatory/somatosensory innervation. Our results demonstrate that, at the initial stage, before nerve fibers reached the appropriate areas in the papilla, taste bud formation did not require innervation. However, at the synaptogenic stage, after nerve fibers ramified into the apical epithelium, innervation was required and played an essential role in the development of taste buds/papillae.

Published

2010

48. Regulatory role of Six1 in the development of taste papillae.

Author

Suzuki Y, Ikeda K, and Kawakami K

Subjects

Animals, Cell Count, Gene Expression Regulation, Developmental, Hedgehog Proteins genetics, Hedgehog Proteins metabolism, Homeodomain Proteins genetics, Mice, Morphogenesis, Taste Buds pathology, Taste Buds ultrastructure, Homeodomain Proteins metabolism, Taste Buds embryology, Taste Buds metabolism

Abstract

The Six family genes encode homeobox transcription factors, and their deficiency leads to abnormal sensory organ structures. We analyzed the expression patterns of Six1 and its role in the morphogenesis of taste bud-bearing lingual papillae during mouse embryonic development. Six1 was expressed in the mesenchyme of the lateral lingual swellings at embryonic day (E) 11.5 and in the epithelium of fungiform papillae during E14.5-E17.5. In the posterior region of the tongue, Six1 expression appeared in the epithelial thickenings in the center of the dorsal surface at E13.5-E14.5 and was observed in the trench wall of circumvallate and foliate papillae at E15.5-postnatal day 0. Six1-deficient mice (Six1 (-/-)) showed distinct morphological changes: the fungiform papillae increased in size and number, and their distribution in the tongue differed from that of wild-type mice. The number of primordia of fungiform papillae marked by Shh and Wnt10b appeared to increase in Six1 ( -/- ). With regard to circumvallate papillae, more extensive invagination of epithelial thickenings, earlier formation of papillae, and stunted trenches were noted in Six1 ( -/- ); the expression of Shh was altered, consistent with these anomalies. The foliate papillae were elevated initially and showed stunted trenches in Six1 ( -/- ). Thus, the modulation of signaling events in Six1 ( -/- ) leads to the earlier formation of the gustatory papillae, the abnormal distribution of fungiform papillae, and malformed trenches in circumvallate and foliate papillae.

Published

2010

49. Sox-2 in taste bud and lateral line system of zebrafish during development.

Author

Germanà A, Montalbano G, Guerrera MC, Laura R, Levanti M, Abbate F, de Carlos F, Vega JA, and Ciriaco E

Subjects

Animals, Blotting, Western, Chemoreceptor Cells metabolism, Epithelial Cells metabolism, Female, Immunohistochemistry, Lateral Line System embryology, Male, Mechanoreceptors metabolism, Taste Buds embryology, Zebrafish, Lateral Line System growth & development, Lateral Line System metabolism, SOX Transcription Factors metabolism, Taste Buds growth & development, Taste Buds metabolism, Zebrafish Proteins metabolism

Abstract

The Sox-2 is a transcription factor involved in adult neurogenesis in different vertebrate species, including fishes. Sox-2 also participates in growth and renewal on sensory cells in neuromasts of the fish lateral line system, and it is essential for development of taste buds in mammals. Using immunohistochemistry and Western blot we have investigated the occurrence and localization of Sox-2 taste buds and neuromast of zebrafish from 10 days post-fertilization to adult stage (1 year). The antibody used identifies two protein bands with estimated molecular weights of 34 and 37kDa which are consistent with those predicted for Sox-2. Sensory cells in taste buds displayed Sox-2 immunoreactivity at all the ages sampled, whereas in the neuromasts Sox-2 expression was restricted to the basal non-sensory cells. Interestingly Sox-2 immunoreactivity was observed in epithelial cells associated with both taste buds and neuromasts. Present results demonstrate that Sox-2 expressed in taste buds and neuromasts of zebrafish during the whole lifespan. Nevertheless, whereas the role of Sox-2 in taste buds of zebrafish remains to be established, the results in neuromast suggest that Sox-2 could participate in cell renewal of the mechanosensory cells.

Published

2009

50. Taste bud development and patterning in sighted and blind morphs of Astyanax mexicanus.

Author

Varatharasan N, Croll RP, and Franz-Odendaal T

Subjects

Animals, Embryo, Nonmammalian, Eye embryology, Eye growth & development, Fishes physiology, Jaw cytology, Jaw embryology, Models, Biological, Taste Buds growth & development, Blindness embryology, Blindness veterinary, Body Patterning physiology, Fishes embryology, Taste Buds embryology

Abstract

In the blind cave-dwelling morph of A. mexicanus, the eye degenerates while other sensory systems, such as gustation, are expanded compared to their sighted (surface-dwelling) ancestor. This study compares the development of taste buds along the jaws of each morph. To determine whether cavefish have an altered onset or rate of taste bud development, we fluorescently labeled basal and receptor cells within taste buds over a developmental series. Our results show that taste bud number increases during development in both morphs. The rate of development is, however, accelerated in cavefish; a small difference in taste bud number exists at 5 dpf reaching threefold by 22 dpf. The expansion of taste buds in cavefish is, therefore, detectable after the onset of eye degeneration. This study provides important insights into the timing of taste bud expansion in cavefish as well as enhances our understanding of taste bud development in teleosts in general., ((c) 2009 Wiley-Liss, Inc.)

Published

2009