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Localization of Extracellular Matrix Receptors on the Chondrocyte Primary Cilium

Susan R. McGlashan, Cynthia G. Jensen and C. Anthony Poole

Department of Anatomy with Radiology, Faculty of Medical and Health Sciences, University of Auckland, Auckland, New Zealand (SRM,CGJ,CAP), and Section of Orthopaedic Surgery, Department of Medical and Surgical Sciences, Dunedin School of Medicine, University of Otago, Dunedin, New Zealand (CAP)

Correspondence to: Dr. Sue R. McGlashan, Department of Anatomy with Radiology, Faculty of Medical and Health Sciences, University of Auckland, Private Bag 92019, Auckland, New Zealand. E-mail: s.mcglashan{at}auckland.ac.nz

	Summary

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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 and ß integrins, NG2, CD44, and annexin V. Primary cilia were labeled using acetylated -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. 2, 3, and ß1 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 ß1 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. (J Histochem Cytochem 54:1005–1014, 2006)

Key Words: chondrocytes • primary cilia • integrins • NG2 • annexin V • CD44 • cartilage • collagen type II • fibronectin

	Introduction

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THE PRIMARY CILIUM is a single cytoplasmic organelle present in almost all eukaryotic cells including hyaline chondrocytes from both mammalian articular cartilage (Wilsman and Fletcher 1978; Wilsman 1979; Wilsman et al. 1980; Poole et al. 1985) and avian sternal sources (Poole et al. 1997,2001; Jensen et al. 2004). It is characterized by a 9 + 0 microtubular symmetry and is composed of two main parts: a basal body and a membrane-bound ciliary axoneme. The function of the primary cilium has remained elusive until recently when studies by Praetorius and Spring (2001) showed that the primary cilium of kidney epithelial cells acts as a ‘flow sensor’ and that bending of the cilium activates intracellular calcium signaling.

Intracellular calcium signaling is also initiated in chondrocytes subjected to dynamic mechanical load, but the transductory mechanisms are not fully understood (Roberts et al. 2001; Pingguan-Murphy et al. 2005). The interaction between chondrocytes and the extracellular matrix (ECM) that surrounds them is fundamental for normal development and for the maintenance of tissue architecture and function. Mechanical loading of the ECM results in the activation of mechanotransduction signaling pathways which, in turn, affects the metabolic activity of the chondrocytes (Muir et al. 1970; Hardingham and Fosang 1992; Lee et al. 1998,2000; Salter et al. 2001; Deschner et al. 2003; Chowdhury et al. 2004; Millward-Sadler and Salter 2004). In embryonic chick hyaline cartilage in situ, the chondrocyte ciliary axoneme projects into the ECM in a range of bent configurations, in contrast to the straight ciliary configuration observed in isolated chondrocytes (Poole et al. 1985,2001; Jensen et al. 2004). Our previous studies have led us to propose that deflection of the primary cilium by forces transmitted through the ECM allows it to act as a mechanosensor, detecting mechanical and physicochemical changes within its pericellular environment and transducing signals to the cell (Poole et al. 1997,2001; Jensen et al. 2004). It is well established that the activation of mechanotransduction signaling pathways is transmitted via cell surface receptors (Gray et al. 1988; Roberts et al. 2001; Chowdhury et al. 2004; Lucchinetti et al. 2004; Millward-Sadler and Salter 2004). Using electron tomography, we have demonstrated close associations between the ciliary membrane and the ECM (Jensen et al. 2004). These points of contact between the fibers of the ECM and the membrane are characterized by electron-opaque plaques, which may represent receptors for the collagens and proteoglycan aggregates of the ECM.

Chondrocytes express several classes of transmembrane ECM receptors. The most well-characterized of these are the integrins, which are heterodimeric transmembrane receptors that bind to many cartilage ECM molecules, including collagens, fibronectin, and laminin (Hynes 1992; Loeser 1993,2000; Loeser et al. 1995). Intracellularly, these receptors complex with the cortical actin cytoskeleton, activating intracellular signaling cascades and regulating gene expression of matrix molecules (Hynes 1992). NG2 is a transmembrane proteoglycan that contains chondroitin sulfate side chains, is expressed in developing and adult cartilage (Nishiyama et al. 1991; Midwood and Salter 1998,2001), and is a putative ligand for collagen types V and VI (Burg et al. 1996; Tillet et al. 1997,2002). This receptor plays a role in signal transduction, regulation of cell proliferation, adhesion, and cell spreading (Burg et al. 1996; Fukushi et al. 2004). Annexin V (anchorin CII) is a member of the large annexin family of proteins defined by their ability to bind phospholipids in a calcium-dependent manner and has been identified on the surface of chondrocytes (Mollenhauer et al. 1984,1999). A suggested role of annexin V within cartilage is binding of chondrocytes to type II collagen (von der Mark and Mollenhauer 1997; Lucic et al. 2003). CD44 is a cell surface glycoprotein that binds hyaluronan and is expressed in a variety of cell types including hyaline chondrocytes (Knudson 1993; Knudson et al. 1996; Jiang et al. 2002). Hyaluronan–CD44 binding retains proteoglycan aggregates in the chondrocyte pericellular matrix, and CD44 also functions to regulate matrix assembly and retention (Chow et al. 1995; Jiang et al. 2002).

In the current study we have examined the specific expression of ECM receptors and their ligands in relation to the primary cilia of embryonic chick hyaline chondrocytes in situ, using immunofluorescent labeling and confocal microscopy. We present novel data showing the expression of receptors for ECM molecules on the chondrocyte primary cilium, strongly suggesting that the primary cilium has the molecular machinery necessary to act as a mechanosensory organelle.

	Materials and Methods

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Tissue Preparation
Fertile Shaver Brown eggs (Bromley Hatcheries; Tuakau, New Zealand) were sacrificed under approved ethical conditions between day 16 and day 17 following incubation at 39C. Fifty sterna were dissected free, the perichondrium was removed, sterna were divided into caudal and cephalic regions, and the cephalic regions were discarded. The caudal regions of sterna were either snap frozen in liquid nitrogen or fixed for 1 hr in 4% paraformaldehyde in 0.1 M PBS maintained at 37C.

Immunoblotting
Frozen sterna were rendered to a powder using a mortar and pestle in liquid nitrogen. The powder was extracted using RIPA buffer (1% NP-40, 0.5% sodium deoxycholate, 0.1% SDS in 50 mM Tris-HCl buffer, pH 8) containing protease inhibitors (10 mg/ml leupetin, 1 mM phenylmethylsulfonyl fluoride, and 2 mM sodium orthovanadate; Roche, Auckland, New Zealand) for 3 hr at 4C. Protein extract was centrifuged at 12,000 x g for 20 min at 4C. The supernatant was removed, and total protein was measured using the BioRad D_C Protein Assay (BioRad; Auckland, New Zealand). Supernatants were heated to 70C for 10 min, and equal amounts of protein (50 µg) were separated on 4–12% SDS polyacrylamide gels (Invitrogen; Auckland, New Zealand) at 200 V for 35 min. Proteins were subsequently transferred onto PVDF membranes (Hybond-P; Amersham Biosciences, Auckland, New Zealand) at 30 V for up to 90 min. Membranes were blocked with 5% non-fat milk powder in Tris-buffered saline containing 1% Tween-20 (TBS-T) for 1 hr at room temperature (RT) and incubated overnight at 4C with the appropriate primary antibody. Membranes were washed in TBS-T and incubated with species-specific horseradish peroxidase secondary antibody (1:2000; Chemicon, Auckland, New Zealand) for 2 hr at RT. Peroxidase activity was visualized using enhanced chemiluminescence (ECL; Amersham Biosciences) according to the manufacturer's instructions. Prestained protein standards and MagicMarker molecular mass standards (Invitrogen) were used to determine the apparent molecular masses of the blotted proteins.

Immunohistochemical Labeling
Sterna were embedded in optimal cutting temperature compound and frozen in the presence of methyl-butane, and 16-µm-thick cryosections were cut and air dried onto Superfrost Plus slides (Menzel Glazer; Braunschweig, Germany). Sections were predigested with testicular hyaluronidase (300 U/ml in 0.1 M Tris-buffered saline; pH 5.5) for 2 hr at RT to remove matrix proteoglycans and allow antibody penetration. Sections were subsequently permeabilized with 0.5% (v/v) Triton X-100 (Serva; Heidelberg, Germany) for 5 min at RT. Nonspecific binding was prevented by incubation with 2% (v/v) goat serum (Life Technologies; Auckland, New Zealand) for 30 min at RT. Primary antibodies (see Table 1 ) were diluted in PBS + 0.1% (w/v) BSA (Life Technologies) and added to the sections that were left overnight at 4C. Sections were incubated with the appropriate fluorescently conjugated secondary antibody—either goat anti-mouse or goat anti-rabbit FITC (1:200; Sigma-Aldrich, Auckland, New Zealand), diluted in PBS + 0.1% BSA, incubated at RT for 2 hr, and rinsed and mounted in Citifluor (Citifluor Ltd.; London, UK). For double-labeling experiments, sections were fixed in 4% paraformaldehyde for 5 min and nonspecific binding was blocked using 2% goat serum. The second primary antibody was added to the sections and incubated overnight at 4C. Sections were subsequently incubated with the appropriate secondary antibody—either goat anti-mouse or goat anti-rabbit Cy3 (1:500; Jackson ImmunoResearch Laboratories, West Grove, PA) for 2 hr at RT, rinsed, and mounted in Citifluor. In some experiments, the nucleus was also labeled with Hoechst 33258 (100 nM; Sigma-Aldrich) for 15 min at RT. For the labeling of ECM molecules, sections were not permeabilized with Triton X-100 prior to the addition of the primary antibody. For negative controls, sections were incubated with PBS + 0.1% BSA instead of the primary antibody. In addition, to test the specificity of integrin labeling, integrin antibodies were preadsorbed with active RGD-peptide (GRGDSP; 500 mg/ml, Calbiochem, Nottingham, UK) overnight at 4C prior to immunolabeling.

View larger version (37K): [in this window] [in a new window]   Figure 1 Distribution of primary cilia in chick hyaline cartilage. (A) Single confocal image (x100 magnification and optical zoom x1.5) of a chick sternal cartilage section labeled with an antibody against acetylated -tubulin, which stains the cytoplasm of the cell and the primary cilium. Unstained areas are nuclei. Arrows indicate cilia protruding at right angles to the incident light path that are suitable for receptor expression quantification; arrowheads show cilia that would be unsuitable. (B) Corresponding brightfield (pseudo phase contrast) image. The primary cilium is visible in the immunofluorescently labeled image (arrow, inset A) but cannot be seen in the corresponding light microscopic image (inset B). Bars: A = 20 µm; B = 2 µm.

	Results

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Integrins and NG2 Are Expressed on the Chondrocyte Primary Cilium
Integrins 2, 3, and ß1 were present on the cell membrane as small plaques and showed a punctate distribution within the cytoplasm (Figures 2A –2C). There was no evidence of nuclear labeling with any of the three integrin antibodies. All three integrins localized as distinct puncta along the length of the primary cilium (see Figures 2D–2F). However, not all cilia examined were positive for integrin labeling. Fifty cilia were examined for each receptor protein, and the number of integrin-positive cilia ranged from 17 for 2 to 43 for ß1 (see Table 2 ). Fibronectin, a ligand for several integrins, was present in the ECM but showed no specific labeling on the cilium or within the cell (Figure 2A). Following incubation of the anti-integrin antibodies with active RGD peptides, there was no positive staining of integrins on or within either the cell or the cilium (Figure 2G). Negative controls for each antibody showed no positive labeling (Figure 2H).

View larger version (65K): [in this window] [in a new window]   Figure 2 Distribution of integrins in chick chondrocytes. Field views of (A) 2, (B) 3, and (C) ß1 integrin show a punctate distribution of each integrin (green) around the plasma membrane. (Inset A) Fibronectin (red) is distributed in the pericellular ECM surrounding the chondrocytes. Nuclei are identified with Hoechst labeling (blue). (Insets D–F) Primary cilia are identified using antibodies against -acetylated tubulin (red); (inset and D) 2-, (inset and E) 3-, and (inset and F) ß1-integrins (green) are present on the cilium as discrete puncta (yellow; arrows). (G,H) Negative control images treated as indicated. (I) Western blots obtained using antibodies against 2, 3, and ß1 integrins and ß-actin (loading control). Bars: A,B,C,G,H = 10 µm; inset A, D–F = 2 µm.

NG2 antibody showed a punctate distribution on the plasma membrane and occasionally in the cytoplasm (Figure 3A ). In the majority of cells examined, NG2 was not detected along the primary cilium (Figure 3B). However, in a small number of cells (8/50) (Table 2), NG2 was present on the cilium, appearing as puncta (Figures 3C and 3D). No labeling was observed in negative control sections (Figure 3E). Specificity of the NG2 antibody was tested by immunoblotting and a specific band was observed at 270 kDa (Figure 3F). Although several antibodies against mammalian type VI collagen, a putative ligand for NG2, were tested on both sternal and articular cartilage from chick (see Table 1), none showed consistently positive labeling. No antibodies against chick type VI collagen were available.

View larger version (40K): [in this window] [in a new window]   Figure 3 (A) NG2 distribution in chick chondrocytes. (B) In the majority of cells, NG2 antibody (green) is not detected on the primary cilium (red). (C,D) In a small number of cells, NG2 (green; arrows) localizes to regions along the cilium (red). (E) Control image; omission of primary antibody. (F) Western blot obtained with NG2 antibody showing a positive band at 270 kDa. Bars: A,E = 10 µm; B–D = 2 µm.

View larger version (52K): [in this window] [in a new window]   Figure 4 (A) Annexin V (red) distribution in chick chondrocytes shows a large punctate labeling around the plasma membrane with occasional staining in the ECM. Nuclei (blue) are labeled using Hoechst. (B) Type II collagen (green) is present throughout the ECM and shows a more intense labeling in the pericellular regions. (Inset B) Colocalization (yellow; arrows) of annexin V (red) and type II collagen (green). (C) Type II collagen (green) surrounds the chondrocyte and is closely associated (arrow) with the cilium (red). (D) Annexin V (green) is not detected on the primary cilium (red). (E) Negative control image; omission of annexin antibody. (F) Western blot obtained using annexin V antibody showing a positive band at 35 kDa. Bars: A,C,E = 10 µm; B–D = 2 µm.

	Discussion

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This study demonstrates for the first time that 2, 3, and ß1 integrins and NG2 are present on the chondrocyte primary cilium in situ. We have also shown that two matrix receptors, CD44 and annexin V, are excluded from the primary cilium. These results strengthen our previous findings that ECM macromolecules make contact with the ciliary membrane (Jensen et al. 2004) and indicate that integrins and NG2 are the likely receptors mediating this attachment.

Chick embryo sternal cartilage has proved an ideal model to investigate the structural relationship between the ECM and the primary cilium (Poole et al. 1985,2001). The majority of hyaline chondrocytes possess a primary cilium, which protrudes up to 5 µm into the ECM (Wilsman 1978; Wilsman et al. 1980). Although the cilia are unable to be identified with conventional light microscopy because of optical interference from the ECM, fluorescent immunohistochemical labeling has allowed us to visualize primary cilia and their interactions with the ECM (see Figure 1). Significantly, chick sternal cartilage, like articular cartilage, is influenced by mechanical load. It expresses cartilage-specific molecules such as type II collagen (see Figures 4B and 4C) and aggrecan to provide a mechanically functional load bearing ECM (Liu et al. 1999). Recent in ovo studies have shown that physical movement is necessary for successful development of the skeleton and that immobilization of chick embryos results in altered matrix composition and compromised material properties of cartilage (Mikic et al. 2004).

Integrins are heterodimeric transmembrane glycoproteins that are composed of an and ß subunit (Hynes 1992,2002). The ß1 subunit is a common feature of most matrix-binding integrins, whereas the type of subunit varies and determines the ligand specificity of the receptor. The punctate pattern of staining on the plasma membrane of all three subunits examined in the present study (2, 3, and ß1) was consistent with previous studies on the cellular distribution of integrins in both human articular and chick sternal cartilage (Durr et al. 1993; Hirsch et al. 1996). However, the number of cilia expressing these subunits varied from 17/50 for 2 integrin up to 43/50 for ß1. This variability in expression is not unique to cartilage. For example, Praetorius et al. (2004) have shown that ß1 integrin is present on the majority of, but not all, primary cilia in the collecting ducts of the kidney, and we have observed somatostatin receptor-3 expression targeted to 50% of kidney epithelial primary cilia (unpublished observations). It is unclear from the results of the current study whether this variation is a reflection of the temporal state of the primary cilium of a particular cell or variability among cilia, providing a potential mechanism for differentiating among cell subpopulations.

The two main functions of integrins are (a) to mediate cell adhesion to the ECM via their large extracellular globular domain and (b) to act as receptors that transduce signals from the cell surface into the cytoplasm (Hynes 1992,2002). ß1 integrins bind to many ligands present in cartilage, including collagen types II and VI, fibronectin, and laminin (Wurster and Lust 1984; Durr et al. 1993,1996; Loeser 1993,1997). We have also confirmed the expression in chick sterna of two ß1 integrin ligands: type II collagen (Figures 4B and 4C) and fibronectin (Figure 2A). Our present findings, coupled with our previous studies, strongly suggest that the integrins associated with the chondrocyte primary cilium play a role in anchoring the cilium to the mechanically functional collagen fibers within the ECM (Poole et al. 1985; Jensen et al. 2004).

Intracellularly, integrins possess a short cytoplasmic tail that interacts with adaptor proteins, signaling molecules, and the actin cytoskeleton (Humphries et al. 2004). To our knowledge, there is no evidence to suggest that an actin cytoskeleton or any of the adaptor proteins such as paxillin, talin, and -actinin are present within the cilium, although this has not been specifically examined. It is also unknown whether or ß integrins interact with polycystin 1, polycystin 2, fibrocystin, or other signaling and adaptor proteins (e.g., STAT6) that have recently been identified within primary cilia, although integrins and similar proteins are often associated at the cell–matrix interface of focal adhesions in epithelial cells (Wilson 2004). Therefore, we are currently unable to suggest what, if any, interactions are associated with the cytoplasmic tail of ciliary integrins.

The present study has shown for the first time that NG2 is expressed in chick sternal chondrocytes. More importantly, NG2 was also detected in a small proportion (8/50) of primary cilia (Figures 3C and 3D; Table 2). Interestingly, the NG2 molecule contains a chondroitin sulfate moiety and the sites for binding type V and VI collagen (Burg et al. 1996; Tillet et al. 1997). Although several different antibodies against mammalian collagen type VI were tested unsuccessfully in this study, the lack of species-specific antibodies meant that we were not able to identify this ligand in chick sterna. Because it is well established that collagen type VI is present in the pericellular microenvironment of hyaline chondrocytes from a number of species and is also present in developing epiphyseal cartilage (Poole et al. 1992; Sherwin et al. 1999), it is likely that type VI is also present in the developing chick sternum. We therefore suggest that NG2 in both the plasma membrane and the primary cilium is likely to interact with pericellular type VI collagen in chick sternal cartilage.

Type II collagen was abundantly expressed throughout the ECM, including the pericellular microenvironment (Figure 4B) where it completely surrounded the primary cilium (Figure 4C). These results strongly suggest that type II collagen is one of the fibrillar collagens that we have previously observed ultrastructurally in contact with the plasma and ciliary membranes (Jensen et al. 2004). One of the putative receptors for type II collagen is annexin V, which is located on the outer surface of chondrocytes (Koopman et al. 1994; Mollenhauer et al. 1999). The present study is the first to describe its localization in chick sternal cartilage in situ. Annexin V was distributed as large plaques on the plasma membrane (Figures 4A and 4C) and colocalized with pericellular type II collagen (Figure 4B), confirming reports of its role as a putative receptor for type II collagen (Lucic et al. 2003). However, annexin V was not present on the primary cilium. Therefore, although the current study shows an intimate relationship between type II collagen and the primary cilium (Figure 4C), this association is likely to be mediated via integrins rather than annexin V.

CD44 is a well-characterized plasma membrane glycoprotein and the principal hyaluronan receptor in chondrocytes (Chow et al. 1995; Knudson et al. 1996; Jiang et al. 2002). Hyaluronan complexes with aggrecan and link protein to form large proteoglycan aggregates with a substantial swelling potential (Knudson and Knudson 2001). Our own studies using ruthenium red staining have shown that aggrecan complexes are closely associated with the ciliary membrane (Jensen et al. 2004). However, although our results showed a punctate distribution of CD44 on the cell surface, this receptor was not present on the chondrocyte primary cilium. These results therefore suggest that there is no CD44–hyaluronan binding at the ciliary membrane.

It is well established that, although the membrane of the primary cilium is continuous with the plasma membrane of the cell, it is a separate membrane domain with a unique complement of proteins (Bloodgood 1992). Numerous previous studies have shown the localization of specific receptors to the primary cilium in a variety of different cell types. These receptors include somatostatin receptor 3 and serotonin receptor 5-HT₆ on neuronal cilia (Handel et al. 1999; Brailov et al. 2000; Pan et al. 2005) and polycystins 1 and 2 on kidney epithelial cilia (Pazour and Rosenbaum 2002; Pazour et al. 2002; Yoder et al. 2002; Nauli et al. 2003). In the current study, the presence of NG2 and integrins on the chondrocyte cilium and the complete absence of ciliary annexin V and CD44 confirm that certain proteins are targeted to the ciliary membrane whereas others are excluded. Because primary cilia of chick sternal chondrocytes extend away from the cell surface, it is possible that receptors expressed in the plasma membrane are involved in cell attachment to the ECM and cell surface signaling, whereas receptor expression on the ciliary membrane may represent a mechanism for sensing changes in the wider pericellular microenvironment, several microns away from the immediate cell surface (Poole et al. 1985; Jensen et al. 2004).

Our finding that several matrix receptors are present on the chondrocyte primary cilium suggests that primary cilia are involved in the signaling processes related to the synthesis and maintenance of the ECM. Integrins have been directly implicated in mechanotransduction pathways in chondrocytes, and mechanical stimulation of chondrocytes results in an increase in intracellular calcium (reviewed in Loeser 2000; Roberts et al. 2001; Lee et al. 2002; Chowdhury et al. 2004; Millward-Sadler and Salter 2004). We have also reported ciliary bending in a wide range of connective tissue cells including chondrocytes, all of which are subjected to a variety of mechanical forces (Poole et al. 1985; Jensen et al. 2004). Previous studies of kidney epithelia have shown that the apical primary cilium acts as a mechanosensor, whereby flow-induced bending of the primary cilium results in an increase in intracellular calcium mediated through mechanosensitive ion channels localized along the cilium or at its base (Praetorius and Spring 2001; Praetorius et al. 2004). In addition, many recent studies in several connective tissue cell types including limb bud cells and fibroblasts also provide strong evidence supporting the hypothesis that primary cilia act as sensory organelles via hedgehog, Wnt, and PDGF signaling pathways during development and growth (Corbit et al. 2005; Germino 2005; Haycraft et al. 2005; May et al. 2005; Schneider et al. 2005; Teilmann et al. 2005; Low et al. 2006; Siroky et al. 2006). Therefore, we suggest that integrins on the chondrocyte primary cilium anchor mechanically functional collagen fibers to the ciliary membrane and, following ciliary bending induced by mechanical loading, transduce these signals via intracellular signaling cascades.

In conclusion, this is the first report that 2, 3, and ß1 integrins and NG2 are present on the chondrocyte primary cilium and that annexin V and CD44 are excluded from the cilium. We also demonstrate that type II collagen and fibronectin are expressed in the developing sternum, and that type II collagen is closely associated with the cilium. This relationship between the ECM, the receptors, and the primary cilium supports our hypothesis that a direct link exists between the ECM and the primary cilium and implicates integrins as the potential signal transduction molecules utilized by primary cilia of all connective tissue cells.

	Acknowledgments

 
This work was supported by The Royal Society of New Zealand Marsden Fund.

We thank Drs. Bill Stallcup, Jurgen Mollenhauer, Shirley Ayad, and Trevor Sherwin for the generous gifts of antibodies to NG2, annexin V, collagen type VI, and -acetylated tubulin, respectively. We acknowledge Drs. A.F. Horwitz, T.F. Linsenmayer, and D.M. Famborough for the use of V2E9, II-II6B3, and 39 antibodies supplied through the Developmental Studies Hybridoma Bank, University of Iowa, Ames, IA. We thank the Biomedical Imaging Research Unit, Department of Anatomy with Radiology, University of Auckland for technical support and advice, Dr. Sam S. Bowser for helpful discussions, and S. Swain for help with tissue preparation.

	Footnotes

 
Received for publication October 30, 2005; accepted April 14, 2006

	Literature Cited

Top Summary Introduction Materials and Methods Results Discussion Literature Cited

 

Bloodgood RA (1992) Directed movements of ciliary and flagellar membrane components: a review. Biol Cell 76:291–301[CrossRef][Medline]

Brailov I, Bancila M, Brisorgueil MJ, Miquel MC, Hamon M, Verge D (2000) Localization of 5-HT(6) receptors at the plasma membrane of neuronal cilia in the rat brain. Brain Res 872:271–275[CrossRef][Medline]

Burg MA, Tillet E, Timpl R, Stallcup WB (1996) Binding of the NG2 proteoglycan to type VI collagen and other extracellular matrix molecules. J Biol Chem 271:26110–26116[Abstract/Free Full Text]

Chow G, Knudson CB, Homandberg G, Knudson W (1995) Increased expression of CD44 in bovine articular chondrocytes by catabolic cellular mediators. J Biol Chem 270:27734–27741[Abstract/Free Full Text]

Chowdhury TT, Salter DM, Bader DL, Lee DA (2004) Integrin-mediated mechanotransduction processes in TGFß-stimulated monolayer-expanded chondrocytes. Biochem Biophys Res Commun 318:873–881[CrossRef][Medline]

Corbit KC, Aanstad P, Singla V, Norman AR, Stainier DY, Reiter JF (2005) Vertebrate smoothened functions at the primary cilium. Nature 437:1018–1021[CrossRef][Medline]

de Melker AA, Sterk LM, Delwel GO, Fles DL, Daams H, Weening JJ, Sonnenberg A (1997) The A and B variants of the alpha 3 integrin subunit: tissue distribution and functional characterization. Lab Invest 76:547–563[Medline]

Deschner J, Hofman CR, Piesco NP, Agarwal S (2003) Signal transduction by mechanical strain in chondrocytes. Curr Opin Clin Nutr Metab Care 6:289–293[CrossRef][Medline]

DiPersio CM, Trevithick JE, Hynes RO (2001) Functional comparison of the alpha3A and alpha3B cytoplasmic domain variants of the chicken alpha3 integrin subunit. Exp Cell Res 268:45–60[CrossRef][Medline]

Durr J, Goodman S, Potocnik A, von der Mark H, von der Mark K (1993) Localization of beta1-integrins in human cartilage and their role in chondrocyte adhesion to collagen and fibronectin. Exp Cell Res 207:235–244[CrossRef][Medline]

Durr J, Lammi P, Goodman SL, Aigner T, von der Mark K (1996) Identification and immunolocalization of laminin in cartilage. Exp Cell Res 222:225–233[CrossRef][Medline]

Fukushi J, Makagiansar IT, Stallcup WB (2004) NG2 proteoglycan promotes endothelial cell motility and angiogenesis via engagement of galectin-3 and alpha3beta1 integrin. Mol Biol Cell 15:3580–3590[Abstract/Free Full Text]

Germino GG (2005) Linking cilia to Wnts. Nat Genet 37:455–457[CrossRef][Medline]

Gray ML, Pizzanelli AM, Grodzinsky AJ, Lee RC (1988) Mechanical and physicochemical determinants of the chondrocyte biosynthetic response. J Orthop Res 6:777–792[CrossRef][Medline]

Handel M, Schulz S, Stanarius A, Schreff M, Erdtmann-Vourliotis M, Schmidt H, Wolf G, et al. (1999) Selective targeting of somatostatin receptor 3 to neuronal cilia. Neuroscience 89:909–926[CrossRef][Medline]

Hardingham TE, Fosang AJ (1992) Proteoglycans: many forms and many functions. FASEB J 6:861–870[Abstract]

Haycraft CJ, Banizs B, Aydin-Son Y, Zhang Q, Michaud EJ, Yoder BK (2005) Gli2 and Gli3 localize to cilia and require the intraflagellar transport protein polaris for processing and function. PLoS Genet 1:e53[CrossRef][Medline]

Hirsch MS, Cook SC, Killiany R, Hartford Svoboda KK (1996) Increased cell diameter precedes chondrocyte terminal differentiation, whereas cell-matrix attachment complex proteins appear constant. Anat Rec 244:284–296[CrossRef][Medline]

Humphries MJ, Travis MA, Clark K, Mould AP (2004) Mechanisms of integration of cells and extracellular matrices by integrins. Biochem Soc Trans 32:822–825[CrossRef][Medline]

Hynes RO (1992) Integrins: versatility, modulation, and signaling in cell adhesion. Cell 69:11–25[CrossRef][Medline]

Hynes RO (2002) Integrins: bidirectional, allosteric signaling machines. Cell 110:673–687[CrossRef][Medline]

Jensen CG, Poole CA, McGlashan SR, Marko M, Issa ZI, Vujcich KV, Bowser SS (2004) Ultrastructural, tomographic and confocal imaging of the chondrocyte primary cilium in situ. Cell Biol Int 28:101–110[CrossRef][Medline]

Jiang H, Peterson RS, Wang W, Bartnik E, Knudson CB, Knudson W (2002) A requirement for the CD44 cytoplasmic domain for hyaluronan binding, pericellular matrix assembly, and receptor-mediated endocytosis in COS-7 cells. J Biol Chem 277:10531–10538[Abstract/Free Full Text]

Knudson CB (1993) Hyaluronan receptor-directed assembly of chondrocyte pericellular matrix. J Cell Biol 120:825–834[Abstract/Free Full Text]

Knudson CB, Knudson W (2001) Cartilage proteoglycans. Semin Cell Dev Biol 12:69–78[CrossRef][Medline]

Knudson W, Aguiar DJ, Hua Q, Knudson CB (1996) CD44-anchored hyaluronan-rich pericellular matrices: an ultrastructural and biochemical analysis. Exp Cell Res 228:216–228[CrossRef][Medline]

Koopman G, Reutelingsperger CP, Kuijten GA, Keehnen RM, Pals ST, van Oers MH (1994) Annexin V for flow cytometric detection of phosphatidylserine expression on B cells undergoing apoptosis. Blood 84:1415–1420[Abstract/Free Full Text]

Lee DA, Noguchi T, Frean SP, Lees P, Bader DL (2000) The influence of mechanical loading on isolated chondrocytes seeded in agarose constructs. Biorheology 37:149–161[Medline]

Lee DA, Noguchi T, Knight MM, O'Donnell L, Bentley G, Bader DL (1998) Response of chondrocyte subpopulations cultured within unloaded and loaded agarose. J Orthop Res 16:726–733[CrossRef][Medline]

Lee HS, Millward-Sadler SJ, Wright MO, Nuki G, Al-Jamal R, Salter DM (2002) Activation of integrin—RACK1/PKCalpha signalling in human articular chondrocyte mechanotransduction. Osteoarthritis Cartilage 10:890–897[CrossRef][Medline]

Liu H, Bee JA, Lees P (1999) Metabolic kinetics of proteoglycans by embryonic chick sternal cartilage in culture. Arch Biochem Biophys 367:225–232[Medline]

Loeser RF (1993) Integrin-mediated attachment of articular chondrocytes to extracellular matrix proteins. Arthritis Rheum 36:1103–1110[Medline]

Loeser RF (1997) Growth factor regulation of chondrocyte integrins. Differential effects of insulin-like growth factor 1 and transforming growth factor beta on alpha 1 beta 1 integrin expression and chondrocyte adhesion to type VI collagen. Arthritis Rheum 40:270–276[Medline]

Loeser RF (2000) Chondrocyte integrin expression and function. Biorheology 37:109–116[Medline]

Loeser RF, Carlson CS, McGee MP (1995) Expression of ß1 integrins by cultured articular chondrocytes and in osteoarthritic cartilage. Exp Cell Res 217:248–257[CrossRef][Medline]

Low SH, Vasanth S, Larson CH, Mukherjee S, Sharma N, Kinter MT, Kane ME, et al. (2006) Polycystin-1, STAT6, and P100 function in a pathway that transduces ciliary mechanosensation and is activated in polycystic kidney disease. Dev Cell 10:57–69[CrossRef][Medline]

Lucchinetti E, Bhargava MM, Torzilli PA (2004) The effect of mechanical load on integrin subunits alpha5 and beta1 in chondrocytes from mature and immature cartilage explants. Cell Tissue Res 315:385–391[CrossRef][Medline]

Lucic D, Mollenhauer J, Kilpatrick KE, Cole AA (2003) N-telopeptide of type II collagen interacts with annexin V on human chondrocytes. Connect Tissue Res 44:225–239[Medline]

May SR, Ashique AM, Karlen M, Wang B, Shen Y, Zarbalis K, Reiter J, et al. (2005) Loss of the retrograde motor for IFT disrupts localization of Smo to cilia and prevents the expression of both activator and repressor functions of Gli. Dev Biol 287:378–389[Medline]

Midwood KS, Salter DM (1998) Expression of NG2/human melanoma proteoglycan in human adult articular chondrocytes. Osteoarthritis Cartilage 6:297–305[CrossRef][Medline]

Midwood KS, Salter DM (2001) NG2/HMPG modulation of human articular chondrocyte adhesion to type VI collagen is lost in osteoarthritis. J Pathol 195:631–635[CrossRef][Medline]

Mikic B, Isenstein AL, Chhabra A (2004) Mechanical modulation of cartilage structure and function during embryogenesis in the chick. Ann Biomed Eng 32:18–25[CrossRef][Medline]

Millward-Sadler SJ, Salter DM (2004) Integrin-dependent signal cascades in chondrocyte mechanotransduction. Ann Biomed Eng 32:435–446[CrossRef][Medline]

Mollenhauer J, Bee JA, Lizarbe MA, von der Mark K (1984) Role of anchorin CII, a 31,000-mol-wt membrane protein, in the interaction of chondrocytes with type II collagen. J Cell Biol 98:1572–1579[Abstract/Free Full Text]

Mollenhauer J, Mok MT, King KB, Gupta M, Chubinskaya S, Koepp H, Cole A (1999) Expression of Anchorin CII (cartilage annexin V) in human young, normal adult, and osteoarthritic cartilage. J Histochem Cytochem 47:209–220[Abstract/Free Full Text]

Muir H, Bullough P, Maroudas A (1970) The distribution of collagen in human articular cartilage with some of its physiological implications. J Bone Joint Surg 52:554–563

Nauli SM, Alenghat FJ, Luo Y, Williams E, Vassilev P, Li X, Elia AE, et al. (2003) Polycystins 1 and 2 mediate mechanosensation in the primary cilium of kidney cells. Nat Genet 33:129–137[CrossRef][Medline]

Nishiyama A, Dahlin KJ, Stallcup WB (1991) The expression of NG2 proteoglycan in the developing rat limb. Development 111:933–944[Abstract/Free Full Text]

Pan J, Wang Q, Snell WJ (2005) Cilium-generated signaling and cilia-related disorders. Lab Invest 85:452–463[CrossRef][Medline]

Pazour GJ, Rosenbaum JL (2002) Intraflagellar transport and cilia-dependent diseases. Trends Cell Biol 12:551–555[CrossRef][Medline]

Pazour GJ, San Agustin JT, Follit JA, Rosenbaum JL, Witman GB (2002) Polycystin-2 localizes to kidney cilia and the ciliary level is elevated in orpk mice with polycystic kidney disease. Curr Biol 12:R378–R380[CrossRef][Medline]

Pingguan-Murphy B, Lee DA, Bader DL, Knight MM (2005) Activation of chondrocytes calcium signalling by dynamic compression is independent of number of cycles. Arch Biochem Biophys 444:45–51[Medline]

Poole CA, Ayad S, Gilbert RT (1992) Chondrons from articular cartilage.V. Immunohistochemical evaluation of type VI collagen organisation in isolated chondrons by light, confocal and electron microscopy. J Cell Sci 103:1101–1110[Abstract/Free Full Text]

Poole CA, Flint MH, Beaumont BW (1985) Analysis of the morphology and function of primary cilia in connective tissues: a cellular cybernetic probe? Cell Motil 5:175–193[CrossRef][Medline]

Poole CA, Jensen CG, Snyder JA, Gray CG, Hermanutz VL, Wheatley DN (1997) Confocal analysis of primary cilia structure and colocalization with the Golgi apparatus in chondrocytes and aortic smooth muscle cells. Cell Biol Int 21:483–494[CrossRef][Medline]

Poole CA, Zhang ZJ, Ross JM (2001) The differential distribution of acetylated and detyrosinated alpha-tubulin in the microtubular cytoskeleton and primary cilia of hyaline cartilage chondrocytes. J Anat 199:393–405[CrossRef][Medline]

Praetorius HA, Praetorius J, Nielsen S, Frokiaer J, Spring KR (2004) ß₁-integrins in the primary cilium of MDCK cells potentiate fibronectin-induced Ca²⁺ signaling. Am J Physiol Renal Physiol 287:F969–978

Praetorius HA, Spring KR (2001) Bending the MDCK cell primary cilium increases intracellular calcium. J Membr Biol 184:71–79[CrossRef][Medline]

Roberts SR, Knight MM, Lee DA, Bader DL (2001) Mechanical compression influences intracellular Ca²⁺ signaling in chondrocytes seeded in agarose constructs. J Appl Physiol 90:1385–1391[Abstract/Free Full Text]

Salter DM, Millward-Sadler SJ, Nuki G, Wright MO (2001) Integrin-interleukin-4 mechanotransduction pathways in human chondrocytes. Clin Orthop Relat Res 391(suppl):49–60

Schneider L, Clement CA, Teilmann SC, Pazour GJ, Hoffmann EK, Satir P, Christensen ST (2005) PDGFRalphaalpha signaling is regulated through the primary cilium in fibroblasts. Curr Biol 15:1861–1866[CrossRef][Medline]

Sherwin AF, Carter DH, Poole CA, Hoyland JA, Ayad S (1999) The distribution of type VI collagen in the developing tissues of the bovine femoral head. Histochem J 31:623–632[CrossRef][Medline]

Siroky BJ, Ferguson WB, Fuson AL, Xie Y, Fintha A, Komlosi P, Yoder BK, et al. (2006) Loss of primary cilia results in deregulated and unabated apical calcium entry in ARPKD collecting duct cells. Am J Physiol Renal Physiol 290:F1320–1328[Abstract/Free Full Text]

Teilmann SC, Byskov AG, Pedersen PA, Wheatley DN, Pazour GJ, Christensen ST (2005) Localization of transient receptor potential ion channels in primary and motile cilia of the female murine reproductive organs. Mol Reprod Dev 71:444–452[CrossRef][Medline]

Tillet E, Gential B, Garrone R, Stallcup WB (2002) NG2 proteoglycan mediates beta1 integrin-independent cell adhesion and spreading on collagen VI. J Cell Biochem 86:726–736[CrossRef][Medline]

Tillet E, Ruggiero F, Nishiyama A, Stallcup WB (1997) The membrane-spanning proteoglycan NG2 binds to collagens V and VI through the central nonglobular domain of its core protein. J Biol Chem 272:10769–10776[Abstract/Free Full Text]

von der Mark K, Mollenhauer J (1997) Annexin V interactions with collagen. Cell Mol Life Sci 53:539–545[CrossRef][Medline]

Wilsman NJ (1978) Cilia of adult canine articular chondrocytes. J Ultrastruct Res 64:270–281[CrossRef][Medline]

Wilsman NJ (1979) Numerical density of convex, nonbranching organelles in anisotropically oriented cells. Cilia in tangential chondrocytes. J Histochem Cytochem 27:1551–1553[Abstract]

Wilsman NJ, Farnum CE, Reed-Aksamit DK (1980) Incidence and morphology of equine and murine chondrocytic cilia. Anat Rec 197:355–361[Medline]

Wilsman NJ, Fletcher TF (1978) Cilia of neonatal articular chondrocytes. Incidence and morphology. Anat Rec 190:871–890[Medline]

Wilson PD (2004) Polycystic kidney disease. N Engl J Med 350:151–164[Free Full Text]

Wurster NB, Lust G (1984) Synthesis of fibronectin in normal and osteoarthritic articular cartilage. Biochim Biophys Acta 800:52–58[Medline]

Yoder BK, Hou X, Guay-Woodford LM (2002) The polycystic kidney disease proteins, polycystin-1, polycystin-2, polaris, and cystin, are co-localized in renal cilia. J Am Soc Nephrol 13:2508–2516[Abstract/Free Full Text]

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