novel aspect of the structure of the avian thymic medulla

We provide evidence for the compartmentalization of the avian thymic medulla and identify the avian thymic dendritic cell. The thymic anlage develops from an epithelial cord of the branchial endoderm. Branches of the cord are separated by primary septae of neural crest origin. The dilation of the pr...

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Veröffentlicht in:	Cell and tissue research 2015-02, Vol.359 (2), p.489-501
Hauptverfasser:	Bódi, Ildikó, Minkó, Krisztina, Molnár, Dávid, Nagy, Nándor, Oláh, Imre
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Anatomy & physiology Animals Biomedical and Life Sciences Biomedicine Birds blood vessels Cellular biology Chick Embryo Chickens - anatomy & histology Collagen - metabolism Dendritic cells epithelial cells Extracellular Matrix - metabolism Human Genetics Immune system intermediate filaments Keratin Keratins - metabolism Molecular Medicine Morphology morphometry neural crest Proteomics Regular Article striated muscle Thymus Gland - anatomy & histology Thymus Gland - cytology Thymus Gland - ultrastructure vimentin
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container_title	Cell and tissue research
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creator	Bódi, Ildikó Minkó, Krisztina Molnár, Dávid Nagy, Nándor Oláh, Imre
description	We provide evidence for the compartmentalization of the avian thymic medulla and identify the avian thymic dendritic cell. The thymic anlage develops from an epithelial cord of the branchial endoderm. Branches of the cord are separated by primary septae of neural crest origin. The dilation of the primary septae produces the keratin-negative area (KNA) of the thymic medulla and fills the gaps of the keratin-positive network (KPN). Morphometric analysis indicates that the KNA takes up about half of the volume of the thymic medulla, which has reticular connective tissue, like peripheral lymphoid organs. The KNA receives blood vessels and in addition to pericytes, the myoid cells of striated muscle structure occupy this area. The myoid cells are of branchial arch or prechordal plate origin providing indirect evidence for the neural crest origin of the KNA. The marginal epithelial cells of the KPN co-express keratin and vimentin intermediate filaments, which indicate their functional peculiarity. The basal lamina of the primary septum is discontinuous on the surface of the KPN providing histological evidence for the loss of the blood-thymus barrier in the medulla. In the center of the KNA, the dendritic cells lie in close association with blood vessels, whereas the B-cells accumulate along the KPN. The organization of the KPN and KNA increases the “surface” of the so-called cortico-medullary border, thereby contributing to the efficacy of central tolerance.
doi_str_mv	10.1007/s00441-014-2027-1
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The basal lamina of the primary septum is discontinuous on the surface of the KPN providing histological evidence for the loss of the blood-thymus barrier in the medulla. In the center of the KNA, the dendritic cells lie in close association with blood vessels, whereas the B-cells accumulate along the KPN. 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The thymic anlage develops from an epithelial cord of the branchial endoderm. Branches of the cord are separated by primary septae of neural crest origin. The dilation of the primary septae produces the keratin-negative area (KNA) of the thymic medulla and fills the gaps of the keratin-positive network (KPN). Morphometric analysis indicates that the KNA takes up about half of the volume of the thymic medulla, which has reticular connective tissue, like peripheral lymphoid organs. The KNA receives blood vessels and in addition to pericytes, the myoid cells of striated muscle structure occupy this area. The myoid cells are of branchial arch or prechordal plate origin providing indirect evidence for the neural crest origin of the KNA. The marginal epithelial cells of the KPN co-express keratin and vimentin intermediate filaments, which indicate their functional peculiarity. The basal lamina of the primary septum is discontinuous on the surface of the KPN providing histological evidence for the loss of the blood-thymus barrier in the medulla. In the center of the KNA, the dendritic cells lie in close association with blood vessels, whereas the B-cells accumulate along the KPN. The organization of the KPN and KNA increases the “surface” of the so-called cortico-medullary border, thereby contributing to the efficacy of central tolerance.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer-Verlag</pub><pmid>25381569</pmid><doi>10.1007/s00441-014-2027-1</doi><tpages>13</tpages><oa>free_for_read</oa></addata></record>
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subjects	Analysis Anatomy & physiology Animals Biomedical and Life Sciences Biomedicine Birds blood vessels Cellular biology Chick Embryo Chickens - anatomy & histology Collagen - metabolism Dendritic cells epithelial cells Extracellular Matrix - metabolism Human Genetics Immune system intermediate filaments Keratin Keratins - metabolism Molecular Medicine Morphology morphometry neural crest Proteomics Regular Article striated muscle Thymus Gland - anatomy & histology Thymus Gland - cytology Thymus Gland - ultrastructure vimentin
title	novel aspect of the structure of the avian thymic medulla
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