Characterization of the collagen in the hexagonal lattice of Descemet's membrane: its relation to type VIII collagen.

Sawada, Hajime; Konomi, Hiroshi; Hirosawa, Kazushige

doi:10.1083/jcb.110.1.219

Cited by 172 publications

(94 citation statements)

References 37 publications

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“…When fully processed, these collagens retain the noncollagenous domains that flank their single, short collagenous domain. Monomers of these collagens assemble into covalently associated multimers, that then aggregate to form a three-dimensional, hexagonally arranged meshwork (25)(26)(27). The nodes of these meshworks are oligomerized noncollagenous globular domains and the internodal, fibrillar connections are oligomerized collagenous domains.…”

Section: Discussionmentioning

confidence: 99%

Identification of a structural constituent and one possible site of postembryonic formation of a teleost otolithic membrane

Davis

Burns

Navaratnam

et al. 1997

Proc. Natl. Acad. Sci. U.S.A.

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A gelatinous otolithic membrane (OM) couples a single calcified otolith to the sensory epithelium in the bluegill sunfish (Lepomis macrochirus) saccule, one of the otolithic organs in the inner ear. Though the OM is an integral part of the anatomic network of endorgan structures that result in vestibular function in the inner ear, the identity of the proteins that make up this sensory accessory membrane in teleosts, or in any vertebrate, is not fully known. Previously, we identified a cDNA from the sunfish saccular otolithic organ that encoded a new member of the collagen family of structural proteins. In this study, we examined biochemical features and the localization of the saccular collagen (SC) protein in vivo using polyclonal antisera that recognize the noncollagenous domains of the SC protein. The otolithic endorgans are part of the vestibular portion of the vertebrate inner ear and consist of a single or many calcified masses coupled to an underlying hair cell-containing sensory epithelium. A gelatinous otolithic͞otoconial membrane is attached to both the otolith and the underlying sensory epithelium and serves to couple the calcified mass(es) to the receptor epithelium. Displacement of the overlying otolith͞ otoconial mass(es) relative to the underlying receptor epithelium results in the displacement of hair cell stereociliary bundles that are critical to the mechanoelectrical transduction process in the inner ear (1).The teleost saccule is an otolithic organ involved in aspects of both vestibular (1) and acoustic function in certain fish (1, 2). The number of saccular sensory cells in certain teleosts (3) and cartilagenous fish (4) can be much larger than the number found in the human saccule (1). We took advantage of the large number of saccular hair cells found in certain teleosts to construct cDNA libraries in efforts to identify genes involved in vestibular function (5).Differential screening of the teleost saccular cDNA libraries led to the identification of candidate saccule-specific cDNAs. One of these was found to encode a unique form of collagen that was termed saccular collagen (SC). The 2.0-kb SC transcript was highly abundant in saccular RNA and appears unique to the saccule because it was not detected in several other sunfish tissues (6). A similar domain organization and homology of a conserved region within the carboxyl-terminal noncollagenous domain identified the SC as a new member of the family of collagens that includes collagens type VIII and type X (7-9). Expression of the SC gene was localized by in situ hybridization to secretory supporting cells located around the periphery of the saccular macula (6). In teleosts, supporting cells such as these have been correlated with the developmental appearance of the otolithic membrane (OM) (10) suggesting that the SC may be a component of the teleost OM. To date, the molecular identity of the proteins that comprise the teleost OM remains unknown.In this report, polyclonal SC-specific antisera were used to study the localization and...

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Section: Discussionmentioning

confidence: 99%

Identification of a structural constituent and one possible site of postembryonic formation of a teleost otolithic membrane

Davis

Burns

Navaratnam

et al. 1997

Proc. Natl. Acad. Sci. U.S.A.

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“…It was first identified in cell culture medium of bovine aortic endothelial cells [17] and is the principal component of the hexagonal lattice in Descemet's membrane of the eye [18]. It is also expressed in sclera and choroid, optic nerve sheath, periosteum, perichondrium, meninges, and the subendothelial layer of blood vessels [19][20][21].…”

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confidence: 99%

Mast cells and type VIII collagen in human diabetic nephropathy

Rüger¹,

Hasan²,

Greenhill³

et al. 1996

Diabetologia

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SummaryRenal injury in diabetes mellitus is associated with progressive interstitial fibrosis and extracellular matrix accumulation. However, the phenotypes of cells forming the interstitial infiltrate in diabetic nephropathy have not been precisely defined. There is increasing evidence for the association of mast cells with angiogenesis, chronic inflammatory conditions and fibrosis. We have recently shown that human mast cells can produce the non-fibrillar short chain type VIII collagen in vivo. Using immunohistochemistry, in situ hybridisation and reverse transcriptasepolymerase chain reaction, we examined the contribution of mast cells and type VIII collagen to the fibrotic changes occurring in biopsy-proven diabetic nephropathy. We observed that the number of interstitial mast cells was significantly increased in diabetic nephropathy compared with normal kidney tissue. In specimens from diabetic subjects, intense immunohistochemical staining for type VIII collagen was detected in mast cells, on periglomerular fibres and in perivascular and interstitial sites. The expression of type VIII collagen in periglomerular and interstitial sites coincided with that of alpha smooth muscle actin, a marker for myofibroblastic differentiation, mRNA for type VIII collagen was detected by reverse transcriptase-polymerase chain reaction in diabetic nephropathy and in a human mast cell line. By in situ hybridisation the transcripts for type VIII collagen were localised to renal mast cells. The increased number of mast cells and the elevated type VIII collagen deposition in human diabetic nephropathy provides a potential link between the extracellular matrix accumulation and the fibrosis observed in this condition. [Diabetologia (1996[Diabetologia ( ) 39: 1215[Diabetologia ( -1222

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“…Because of close packing, real arrays of cells in planar tissues often display hexagonal or near-hexagonal structure, e.g. in hepatic or retinal tissue [9,10,11].…”

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confidence: 99%

Repressor Lattice: Feedback, Commensurability, and Dynamical Frustration

Jensen¹,

Krishna²,

Pigolotti³

2009

Phys. Rev. Lett.

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We construct a hexagonal lattice of repressing genes, such that each node represses three of the neighbors, and use it as a model for genetic regulation in spatially extended systems. Using symmetry arguments and stability analysis we argue that the repressor-lattice can be in a nonfrustrated oscillating state with only three distinct phases. If the system size is not commensurate with three, oscillating solutions of several different phases are possible. As the strength of the interactions between the nodes increases, the system undergoes many transitions, breaking several symmetries. Eventually dynamical frustrated states appear, where the temporal evolution is chaotic, even though there are no built-in frustrations. Applications of the repressor-lattice to real biological systems are discussed.

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Characterization of the collagen in the hexagonal lattice of Descemet's membrane: its relation to type VIII collagen.

Cited by 172 publications

References 37 publications

Identification of a structural constituent and one possible site of postembryonic formation of a teleost otolithic membrane

Identification of a structural constituent and one possible site of postembryonic formation of a teleost otolithic membrane

Mast cells and type VIII collagen in human diabetic nephropathy

Repressor Lattice: Feedback, Commensurability, and Dynamical Frustration

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