Abstract
Otoconia are bio-crystals anchored to the macular sensory epithelium of the utricle and saccule in the inner ear for motion sensing and bodily balance. Otoconia dislocation, degeneration and ectopic calcification can have detrimental effects on balance and vertigo/dizziness, yet the mechanism underlying otoconia formation is not fully understood. In this study, we show that selected matrix components are recruited to form the crystal matrix and sequester Ca2+ for spatial specific formation of otoconia. Specifically, otoconin-90 (Oc90) binds otolin through both domains (TH and C1q) of otolin, but full-length otolin shows the strongest interaction. These proteins have much higher expression levels in the utricle and saccule than other inner ear epithelial tissues in mice. In vivo, the presence of Oc90 in wildtype (wt) mice leads to an enrichment of Ca2+ in the luminal matrices of the utricle and saccule, whereas absence of Oc90 in the null mice leads to drastically reduced matrix-Ca2+. In vitro, either Oc90 or otolin can increase the propensity of extracellular matrix to calcify in cell culture, and co-expression has a synergistic effect on calcification. Molecular modeling and sequence analysis predict structural features that may underlie the interaction and Ca2+-sequestering ability of these proteins. Together, the data provide a mechanism for the otoconial matrix assembly and the role of this matrix in accumulating micro-environmental Ca2+ for efficient CaCO3 crystallization, thus uncover a critical process governing spatial specific otoconia formation.
Highlights
IntroductionLike bone, are a result of ordered deposition of inorganic calcium carbonate (calcium phosphate in bone) crystallites onto a pre-formed framework of organic matrix of glycoproteins
Otoconia, like bone, are a result of ordered deposition of inorganic calcium carbonate crystallites onto a pre-formed framework of organic matrix of glycoproteins
Oc90 interacts strongly with full-length otolin, and both domains of otolin participate synergistically in this interaction. The requirement of both otolin domains is consistent with the finding that the C1q domain of other related proteins is responsible for partner recognition and the triple helix (TH) domain for strengthening the interaction [22]
Summary
Like bone, are a result of ordered deposition of inorganic calcium carbonate (calcium phosphate in bone) crystallites onto a pre-formed framework of organic matrix of glycoproteins. The organic matrix of otoconia is composed of a predominant glycoprotein plus low-abundant glycoproteins (collectively called otoconins) and proteoglycans [1,2,3,4,5,6,7,8,9,10]. Oc90 is not related to the predominant bone matrix protein (collagen I in cortical bone and collagen II in cartilage) or any other known matrix protein, but rather, it has two domains resembling secretory phospholipase A2 (sPLA2) [7;8] with 31 and 35% amino acid identity (45% and 48%, respectively, with conservative variations counted). Experimental structure-function analysis has not been done to demonstrate the functional significance of conservation of the sPLA2 structure, but the critical features have been analyzed and modeled [9] and is re-capitulated in the Discussion section of this report
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