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Mouse Submandibular Gland (mouse + submandibular_gland)

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Life Sciences60%

Selected Abstracts

Cellular dynamics of epithelial clefting during branching morphogenesis of the mouse submandibular gland

DEVELOPMENTAL DYNAMICS, Issue 6 2010
Yuichi Kadoya
Abstract We cultured the rudimental submandibular gland (SMG) of mice with a non,cell-permeable fluorescent tracer, and observed cell behavior during epithelial branching morphogenesis using confocal time-lapse microscopy. We traced movements of individual cells as shadowgraph movies. Individual epithelial cells migrated dynamically but erratically. The epithelial cleft extended by wiggling and separated a cluster of cells into two buds during branching. We examined the ultrastructure of the clefts in SMG rudiments treated with the laminin peptide A5G77f, which induces epithelial clefting. A short cytoplasmic shelf with a core of microfilaments was found at the deep end of the cleft. We propose that epithelial clefting involves a dynamic movement of cells at the base of the cleft, and the formation of a shelf within a cleft cell. The shelf might form a matrix attachment point at the base of the cleft with a core of microfilaments driving cleft elongation. Developmental Dynamics 239:1739,1747, 2010. © 2010 Wiley-Liss, Inc. [source]

Aquaporin 11 in the developing mouse submandibular gland

EUROPEAN JOURNAL OF ORAL SCIENCES, Issue 1 2010
Helga S. Larsen
Larsen HS, Ruus A-K, Schreurs O, Kanli Galtung H. Aquaporin 11 in the developing mouse submandibular gland. Eur J Oral Sci 2010; 118: 9,13. © 2010 The Authors. Journal compilation © 2010 Eur J Oral Sci Several aquaporins (AQPs) have been detected in mature and embryonic mammalian salivary glands (AQP1 and AQP3,AQP8). However, AQP11 has, to our knowledge, never before been described in salivary glands, but is known to be important in, for example, kidney development in mice. We therefore thought it relevant to investigate if AQP11 was present during salivary organogenesis. The submandibular salivary gland (SMG) from CD1 mice was studied during prenatal development and early postnatal development, and also in young adult male and female mice. The expression trend of the AQP11 transcript was detected using the reverse transcription,polymerase chain reaction (RT-PCR), and the temporal,spatial pattern was observed using in situ hybridization. The AQP11 transcript was first detected at embryonic day 13.5 and showed a more or less constitutive expression trend during the prenatal and early postnatal SMG development. Spatial studies demonstrated that the AQP11 transcript was present in the developing and mature duct structures at all stages studied. In the end pieces, the AQP11 transcript was reduced during glandular development. Our results point to an important role for AQP11 during salivary gland development. [source]

Histological and Ultrastructural Characterization of Developing Miniature Pig Salivary Glands,

THE ANATOMICAL RECORD : ADVANCES IN INTEGRATIVE ANATOMY AND EVOLUTIONARY BIOLOGY, Issue 7 2010
Jian Zhou
Abstract Salivary glands are a classic model of organ development and differentiation. Miniature pigs are considered as a unique animal model for salivary gland researchers in the fields of gene transfer, radiation damage, and functional reconstruction. However, there is little information about the development of miniature pig salivary glands. The present article was designed to study the developmental stages of salivary glands in miniature pigs using histological and ultrastructural methods. Sections from E40, E60, E80, E95 embryos, and P0 pups were stained with hematoxylin,eosin, Alcian blue, or periodic acid-schiff. Selected specimens were also processed for electron microscopy. The development of the miniature pig salivary glands can be divided into five different stages that refer to the stages of the developing mouse submandibular gland. The histological characteristics of the miniature pig salivary glands at different developmental stages were synchronously verified at the ultrastructural level. Interestingly, the development of the miniature pig parotid gland trailed that of the submandibular gland by ,15 days. Our study provides first-hand data regarding the morphological organogenesis of salivary glands in the miniature pig and provides a foundation for further research on this model. Anat Rec 293:1227,1239, 2010. © 2010 Wiley-Liss, Inc. [source]

Regulation of membrane potential and fluid secretion by Ca2+ -activated K+ channels in mouse submandibular glands

THE JOURNAL OF PHYSIOLOGY, Issue 2 2007
Victor G. Romanenko
We have recently shown that the IK1 and maxi-K channels in parotid salivary gland acinar cells are encoded by the KCa3.1 and KCa1.1 genes, respectively, and in vivo stimulated parotid secretion is severely reduced in double-null mice. The current study tested whether submandibular acinar cell function also relies on these channels. We found that the K+ currents in submandibular acinar cells have the biophysical and pharmacological footprints of IK1 and maxi-K channels and their molecular identities were confirmed by the loss of these currents in KCa3.1- and KCa1.1 -null mice. Unexpectedly, the pilocarpine-stimulated in vivo fluid secretion from submandibular glands was essentially normal in double-null mice. This result and the possibility of side-effects of pilocarpine on the nervous system, led us to develop an ex vivo fluid secretion assay. Fluid secretion from the ex vivo assay was substantially (about 75%) reduced in animals with both K+ channel genes ablated , strongly suggesting systemic complications with the in vivo assay. Additional experiments focusing on the membrane potential in isolated submandibular acinar cells revealed mechanistic details underlying fluid secretion in K+ channel-deficient mice. The membrane potential of submandibular acinar cells from wild-type mice remained strongly hyperpolarized (,55 ± 2 mV) relative to the Cl, equilibrium potential (,24 mV) during muscarinic stimulation. Similar hyperpolarizations were observed in KCa3.1- and KCa1.1 -null mice (,51 ± 3 and ,48 ± 3 mV, respectively), consistent with the normal fluid secretion produced ex vivo. In contrast, acinar cells from double KCa3.1/KCa1.1 -null mice were only slightly hyperpolarized (,35 ± 2 mV) also consistent with the ex vivo (but not in vivo) results. Finally, we found that the modest hyperpolarization of cells from the double-null mice was maintained by the electrogenic Na+,K+ -ATPase. [source]