1.Molecular Analysis of Salivary Gland Branching Morphogenesis
Takayoshi Sakai ; Melinda Larsen ; Mikihiko Kogo ; Kenneth M. Yamada
Oral Science International 2004;1(1):16-21
Recently, clinicians and scientists have focused on tissue engineering for regenerative medical therapy. This approach promises to provide remarkable clinical breakthroughs for the future. In oral and craniofacial medicine, most scientific approaches to tissue engineering currently involve tooth and bone, while little progress has been made toward regenerating organs such as salivary gland. To develop strategies for salivary gland regeneration, it will be important to understand the molecular mechanisms of normal salivary development. This mini-review describes a recently developed and tested set of approaches for identifying and characterizing molecules essential for branching morphogenesis and other developmental processes. It shows the value of using laser microdissection and the new process of T7-SAGE for gene discovery of putative candidate molecules that may be crucial regulators or mediators. We describe a stepwise series of associated strategies for reliable identification and functional testing of a candidate molecule, as well as its successful application to a specific candidate molecule originally identified by T7-SAGE.
2.Salivary gland branching morphogenesis--recent progress and future opportunities.
Jeff Chi-feng HSU ; Kenneth M YAMADA
International Journal of Oral Science 2010;2(3):117-126
Salivary glands provide saliva to maintain oral health, and a loss of salivary gland function substantially decreases quality-of-life. Understanding the biological mechanisms that generate salivary glands during embryonic development may identify novel ways to regenerate function or design artificial salivary glands. This review article summarizes current research on the process of branching morphogenesis of salivary glands, which creates gland structure during development. We highlight exciting new advances and opportunities in studies of cell-cell interactions, mechanical forces, growth factors, and gene expression patterns to improve our understanding of this important process.
Animals
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Cell Communication
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physiology
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Embryonic Development
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physiology
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Epithelium
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embryology
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Extracellular Matrix
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physiology
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Humans
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Intercellular Signaling Peptides and Proteins
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physiology
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Morphogenesis
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physiology
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Salivary Glands
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embryology