Lithium chloride modulates chondrocyte primary cilia and inhibits Hedgehog signaling.

Lithium chloride (LiCl) exhibits significant therapeutic potential as a treatment for osteoarthritis. Hedgehog signaling is activated in osteoarthritis, where it promotes chondrocyte hypertrophy and cartilage matrix catabolism. Hedgehog signaling requires the primary cilium such that maintenance of this compartment is essential for pathway activity. Here we report that LiCl (50 mM) inhibits Hedgehog signaling in bovine articular chondrocytes such that the induction of GLI1 and PTCH1 expression is reduced ​ by 71 and 55%, respectively. Pathway inhibition is associated with a 97% increase in primary cilia length from 2.09 ± 0.7 µm in untreated cells to 4.06 ± 0.9 µm in LiCl-treated cells. We show that cilia elongation disrupts trafficking within the axoneme with a 38% reduction in Arl13b ciliary localization at the distal region of the cilium, consistent with the role of Arl13b in modulating Hedgehog signaling. In addition, we demonstrate similar increases in cilia length in human chondrocytes in vitro and after administration of dietary lithium to Wistar rats in vivo. Our data provide new insights into the effects of LiCl on chondrocyte primary cilia and Hedgehog signaling and shows for the first time that pharmaceutical targeting of the primary cilium may have therapeutic benefits in the treatment of osteoarthritis.

Primary cilia mediate mechanotransduction through control of ATP-induced Ca2+ signaling in compressed chondrocytes.

We investigated the role of the chondrocyte primary cilium in mechanotransduction events related to cartilage extracellular matrix synthesis. We generated conditionally immortalized wild-type (WT) and IFT88(orpk) (ORPK) mutant chondrocytes that lack primary cilia and assessed intracellular Ca(2+) signaling, extracellular matrix synthesis, and ATP release in response to physiologically relevant compressive strains in a 3-dimensional chondrocyte culture system. All conditions were compared to unloaded controls. We found that cilia were required for compression-induced Ca(2+) signaling mediated by ATP release, and an associated up-regulation of aggrecan mRNA and sulfated glycosaminosglycan secretion. However, chondrocyte cilia were not the initial mechanoreceptors, since both WT and ORPK cells showed mechanically induced ATP release. Rather, we found that primary cilia were required for downstream ATP reception, since ORPK cells did not elicit a Ca(2+) response to exogenous ATP even though WT and ORPK cells express similar levels of purine receptors. We suggest that purinergic Ca(2+) signaling may be regulated by polycystin-1, since ORPK cells only expressed the C-terminal tail. This is the first study to demonstrate that primary cilia are essential organelles for cartilage mechanotransduction, as well as identifying a novel role for primary cilia not previously reported in any other cell type, namely cilia-mediated control of ATP reception.

Localization of extracellular matrix receptors on the chondrocyte primary cilium.

A single primary cilium is found in chondrocytes and other connective tissue cells. We have previously shown that extracellular matrix (ECM) macromolecules such as collagen fibers closely associate with chondrocyte primary cilia, and their points of contact are characterized by electron-opaque plaques suggesting a direct link between the ECM and the cilium. This study examines the expression of receptors for ECM molecules on chondrocyte primary cilia. Embryonic chick sterna were fluorescently labeled with antibodies against alpha and beta integrins, NG2, CD44, and annexin V. Primary cilia were labeled using acetylated alpha-tubulin antibody. Expression of ECM receptors was examined on chondrocyte plasma membranes and their primary cilia using immunofluorescence and confocal microscopy. All receptors examined showed a punctate distribution on the plasma membrane. alpha2, alpha3, and beta1 integrins and NG2 were also present on primary cilia, whereas annexin V and CD44 were excluded. The number of receptor-positive cilia varied from 8/50 for NG2 to 43/50 for beta1 integrin. This is the first study to demonstrate the expression of integrins and NG2 on chondrocyte primary cilia. The data strongly suggest that chondrocyte primary cilia have the necessary machinery to act as mechanosensors, linking the ECM to cytoplasmic organelles responsible for matrix production and secretion.

Characterization of primary cilia distribution and morphology during lactation, stasis, and involution in the bovine mammary gland.

Primary cilia are small, sensory organelles projecting from virtually all cells and are vital for cellular and tissue function. Their distribution in bovine mammary tissue has not previously been assessed, despite the potential for these organelles to provide specialized perceptive and regulatory functions to this acutely responsive and adaptive gland. The research objectives were to assess ciliary distribution and morphology during active lactation, milk stasis, and early involution using tissue samples obtained following the abrupt cessation of milk removal in nonpregnant, Friesian dairy cows at mid-lactation. Routinely processed tissue sections were obtained at intervals from 6 to 192 hr after the last milking (N = 3 animals per group) and assigned to active lactation (6-12 hr), milk stasis (18-36 hr), and early involution (72-192 hr). Primary cilia were observed in luminal secretory epithelial cells (SECs), myoepithelial cells, and stromal cells following fluorescent immunohistochemistry and confocal microscopy. In SECs, some primary cilia appeared deflected against the apical cell membrane. The proportion of those deflected was greater during milk stasis than active lactation. Data show that primary cilia were suitably placed in three important cell types to potentially coordinate various forms of signal transduction relying on both mechanosensation and chemosensation, according to the physical and physiological state of the gland. Their cell-type distribution and morphology provide new directions in the study of mammary regulation to enhance the understanding of how various mammary-specific cellular responses may be initiated by biochemical or local biophysical factors.

Confocal imaging of the human keratocyte network using the vital dye 5-chloromethylfluorescein diacetate.

BACKGROUND: The human corneal stroma consists of intercalated layers of collagen and keratocytes. These cells are known to maintain the stroma and aid in repair but it is likely they have other crucial roles throughout the cornea. The complexity of their anatomy is revealed in this study by ex vivo in situ images of the human keratocyte covering a range of ages. METHODS: Human donor corneas of different ages were stained with 5-chloromethylfluorescein diacetate (CMFDA), a dye that is anchored and retained within the cell cytoplasm. The tissue was fixed, sectioned, mounted, and then imaged using a confocal laser scanning microscope at various magnifications and tissue planes. The digital image sets were transferred to multifunction image processing software for analysis and production of 3-D stereo images of keratocyte networks throughout the stroma. RESULTS: High quality images of CMFDA-stained cells revealed differences in the structure and orientation of keratocytes in the anterior, central and posterior stroma, which did not differ throughout the age-range studied. This method reveals very fine cell process ramifications not previously visualized, orientated in lateral and antero-posterior directions, and it confirms the potential for multidirectional communication between keratocyte networks. CONCLUSIONS: This qualitative study found consistency of keratocyte morphology in the normal human cornea throughout life. It confirmed differences in keratocyte anatomy, and the potential for rapid cellular communication by multiple interconnecting processes supporting cohesive keratocyte activity. This high-resolution 3-D microscopic study should assist in identifying gross deviant cellular behaviour in post-surgical and disease states.