Introduction
Cathepsin K, discovered and isolated from a rabbit osteoclast library in 1994 [
1], is an interesting cysteine protease which cleaves the triple helical domains of types I to II collagen [
1]. Research has shown that its collagenolytic action requires that chondroitin or keratin sulfate be bound to the protease [
2]. Cathepsin K is present in osteoclasts, human ovary, heart and skeletal muscle, lung, placenta, testis, small intestine and colon [
3]. Studies have identified upregulation of cathepsin K in fibroblast-like cells in synovial tissue of osteoarthritic and rheumatoid patients [
4‐
7]. A link to heightened expression in the presence of IL-1ß or TNFα was also shown by
in vitro culture of fibroblasts derived from rheumatoid patients in the work of Hou
et al. [
5]. In addition, an association with aging and increased cathepsin K levels has been suggested by Dejica
et al. since they found increased cathepsin K content in nonarthritic cartilage from older compared to younger subjects [
8]. Work by Ruettger
et al. showed that cathepsin K is regulated via activation of the classical protein kinase C and p38 MAP kinase in articular chondrocytes [
9].
Two interesting reports have shown spontaneous development of synovitis and cartilage degeneration in transgenic mice, which overexpress cathepsin K (transgenic UTU17 mice) [
10,
11]. In analysis of this model, transgenic animals showed osteoarthritis and increased levels of cathepsin K with aging. During growth and aging, cathepsin K was found to be the most abundant cysteine proteinase in the mouse knee joint, where cathepsin K was present near sites of matrix degeneration and destruction in articular cartilage.
Cathepsin K is a recognized component of osteoclasts, where it plays a central role in bone resorption [
7]. RANKL (receptor activator of nuclear factor κB ligand, also known as TRANCE, TNFSF11, OPGL, and ODF) is a member of the tumor necrosis factor family of signaling molecules, which functions in promoting osteoclast differentiation. RANKL, well known for its role in production of extracellular matrix remodeling enzymes, is one of the factors capable of inducing cathepsin K production. This aspect of the biology of cathepsin K has recently been studied by Combs and Yutzey in an analysis of the regulation of heart valve development which found that RANKL and cathepsin K are expressed by endocardial cushion endothelial cells; RANKL acted during valve remodeling to promote cathepsin K expression [
12].
Although there is not a large body of literature addressing cathepsin K and its role in disc degeneration, there are several previous interesting studies. The work of Ariga
et al. pointed to an association with endplate separation and disorganization of the annulus in spinal degenerative disorders [
13]. Neidhart
et al. found strong expression of cathepsin K in a number of regions of the spine in patients with ankylosing spondylitis [
14]. Mwale
et al. have studied the effect of a collagen type II collagen fragment (the 245-270 peptide) on disc cells [
15]. This work showed that the addition of this peptide fragment at levels of 1 μg/ml to cultured annulus cells resulted in a significant increase in cathepsin K expression by one day of culture; expression levels decreased over the following four days of culture and reached control levels. Nucleus cells exposed to this fragment also showed stimulated cathepsin K expression at one day of exposure.
In the present study, we hypothesized that cathepsin K might be an important component of matrix remodeling overlooked to date in the intervertebral disc. We tested this hypothesis by assessing gene expression of cathepsin K and RANKL in human disc tissue, and also applied immunohistochemistry analyses to disc tissues.
Materials and methods
Clinical study population
Experimental study of human disc specimens was approved prospectively by the authors' Human Subjects Institutional Review Board at Carolinas Medical Center. The need for informed consent was waived by the ethical board since disc tissue was removed as part of routine surgical practice. Scoring of disc degeneration utilized the Thompson scoring system; this system scores disc degeneration over the spectrum from a healthy disc (Thompson grade I) to discs with advanced degeneration (grade V, the most advanced stage of degeneration) [
16]. Patient specimens were derived from surgical disc procedures performed on individuals with herniated discs and degenerative disc disease. Surgical specimens were transported to the laboratory in sterile tissue culture medium. Care was taken to remove all granulation tissue and to sample only disc tissue. Non-surgical control donor disc specimens were obtained via the National Cancer Institute Cooperative Human Tissue Network (CHTN); they were shipped overnight to the laboratory in sterile tissue culture medium and processed as described below. Specimen procurement from the CHTN was included in our approved protocol by our human subjects Institutional Review board.
Expression of cathepsin K and RANKL in vivo
Analysis of human disc tissue was carried out as previously described using laser capture microdissection methods [
17]. Total RNA was extracted from cells using the TRIzol reagent (Gibco, Carlsbad, CA, USA), reverse transcribed to double-stranded cDNA, subjected to two rounds of transcription, and hybridized to the DNA microarray in the Affymetrix Fluidics Station 400. Affymetrix human U133 X3P arrays were used. The GCOS Affymetrix GeneChip Operating System (version 1.2, Affymetrix, Santa Clara, CA, USA) was used for determining gene expression levels of RANKL and cathepsin K (Affymetrix gene identifications AF053712.1 for RANKL, and NM_000396.1 for cathepsin K).
Gene array data related to human disc tissue reported here have been uploaded to the Gene Expression Omnibus (GEO) website [GEO:GSE23130] and may be accessed at sample numbers GSM569830 - GSM569848.
Immunolocalization of RANKL
Disc specimens were fixed in 10% neutral buffered formalin for no longer than 24 hours and changed to 70% ethanol. Undecalcified specimens were embedded in paraffin and sections cut at 4 μm, collected on PLUS slides (Allegiance, McGaw Park, IL, USA) and dried at 60°C. Sections were deparaffinized in xylene (Allegiance) and rehydrated through graded alcohols (AAPER, Shelbyville, KY, USA) to distilled water. Antigen retrieval was performed using Dako Target Retrieval Solution, pH 6.0 (Dako, Carpenteria, CA, USA) for 20 minutes at 95°C followed by cooling for 20 minutes. The remainder of the procedure was performed using the Dako Autostainer Plus (Dako) automated stainer. Endogenous peroxidase was blocked using 3% H202 (Humco, Texarcana, TX, USA). Slides were incubated for one hour with anti-RANKL (Santa Cruz Biotechnology, Santa Cruz, CA, USA) at a 1:50 dilution. Secondary antibody was 4+Biotinylated Universal Goat Link (Biocare Medical, Concord, CA, USA) for 10 minutes followed by 4+ streptavidin HRP Label (Biocare) for 10 minutes and Vector NovaRed (Vector Laboratories, Burlingame, CA, USA) for 5 minutes. Slides were removed from the stainer, rinsed in water, counterstained with light green, dehydrated, cleared and mounted with resinous mounting media. Mouse IgG (Dako) was used as a negative control. Human tonsil was utilized as a positive control.
Immunolocalization of cathepsin K
Following fixation and embedding as described above, paraffin sections were cut at 4 μm, collected on PLUS slides (Allegiance) and dried at 60°C. Sections were deparaffinized in xylene (Allegiance) and rehydrated through graded alcohols (AAPER) to distilled water. The remainder of the procedure was performed using the Dako Autostainer Plus (Dako) automated stainer. Endogenous peroxidase was blocked using 3% H202 (Humco). Slides were incubated for one hour with anti-cathepsin K (Abcam, Cambridge, MA, USA) at a 1:100 dilution. Mouse IgG (Dako) was used as a negative control. A secondary antibody was 4+Biotinylated Universal Goat Link (Biocare Medical,) for 10 minutes followed by 4+ streptavidin HRP Label (Biocare) for 10 minutes and DAB (Biocare)) for 5 minutes. Slides were removed from the stainer, rinsed in water, counterstained with light green, dehydrated, cleared and mounted with resinous mounting media. Rat physeal tissue was used as a positive control.
Statistical analyses
Standard statistical analyses were performed utilizing InStat (GraphPad Software, Inc., San Diego, CA, USA). Unpaired t-tests and linear regression analyses were performed; means ± s.e.m. were calculated. P = 0.05 was considered to be the level of significant.
Discussion
Improved understanding of the regulation of extracellular matrix turnover during normal homeostasis and during advancing disc degeneration is an important topic in disc research [
18]. As noted by Millward-Sadler
et al., matrix turnover has implications for the pathogenesis of human disc degeneration [
19]. Historically, the matrix metalloproteinases, including MMP-1, -2, -3, -7, -8, -9, -13, -19 and -28 [
20‐
31], have been considered the key players in disc matrix destruction during disc degeneration.
In the present work we confirm that cathepsin K is constitutively expressed in the human disc. Our analysis showed that there was significantly greater expression of cathepsin K in degenerated discs compared to healthier ones (Figure
1). This finding suggests a role for cathepsin K in disc degeneration, and is in agreement with the findings of Konttinen
et al. that cathepsin K expression increased with the severity of osteoarthritis [
6].
We now know that the degenerating disc has increased expression of a number of important genes related to the extracellular matrix [
32] and proteoglycans [
33], inflammatory cytokines, and matrix-degrading agents, neurotrophins, and cytokines (for reviews and studies see [
26,
33‐
41]).
In vitro studies have been especially helpful in advancing our understanding of inflammatory cytokine production [
42‐
45]. Hou
et al. have shown that IL-1ß or TNFα
in vitro stimulation of synovial fibroblasts derived from rheumatoid or osteoarthritic subjects produced increased cathepsin K expression. These two proinflammatory cytokines have well-recognized roles in intervertebral disc degeneration [
46]. We hypothesize that in the cytokine rich milieu of the degenerating disc cathepsin K plays a significant role in disc matrix degeneration.
RANKL is recognized as a factor capable of inducing cathepsin K production, and is known to be regulated by IL-1ß and TNFα (see [
7] for a recent review). In addition to its acknowledged role in osteoclast development and function [
7], RANKL signaling activates a number of pathways important in a number of cell types including bone marrow stromal cells, fibroblasts, mammary endothelial cells, epithelial cells, osteoblasts, osteoclasts and T lymphocytes (see [
47,
48] for reviews). In 2009, Mackiewicz
et al. showed the immunohistochemical presence of RANKL in human annulus tissue [
49].
In the present work, we identified significantly increased RANKL gene expression in more degenerated discs compared to healthier discs (Figure
3). Our analyses of gene expression data from disc tissue also showed a significant, positive linear relationship between cathepsin K and RANKL expression which accounted for a high proportion of the variability in this relationship (92.2%, Figure
2). This finding is also consistent with regulation of cathepsin K expression during disc degeneration; we note, however, that future mechanistic studies should be undertaken to further explore this control mechanism. Other aspects of RANKL function in the disc merit future studies to determine whether it acts to inhibit proliferation and to induce apoptosis as was seen by McGonigle
et al. in endothelial cells [
50].
It should be noted that the present analyses utilized only annulus cells in the microarray expression studies; we currently are adding nucleus specimens so that future work can explore expression patterns in nucleus cells as well as the annulus. We look forward to data from other disc research labs on this topic. Important future studies should include
in vivo analyses to determine the exact relationship between cathepsin K and RANKL expression, correlations of cathepsin K levels to collagen fragments within the disc (as pioneered in the important work of Neidart
et al. [
14] and Mwale
et al. [
15], and expanded
in vitro studies with annulus and nucleus cells.
In closing, a note should also be made concerning the current clinical interest in development of cathepsin K inhibitors because of their ability to inhibit bone resorption [
3,
7,
51,
52]. As we continue to move towards the application of biologic therapies for human disc degeneration, it may be efficacious to consider inclusion of selective, specific approaches to inhibit cathepsin K. Yasuca
et al. reported in 2005 that some cathepsin K inhibitors are now in clinical trials for osteoporosis therapy, and noted that cathepsin K is a preferable drug target for non-inflammatory osteoarthritis with positive pre-clinical data [
3].
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
HEG, in collaboration with ENH, conceived and planned the study. GLH performed microarray analyses, while JAI and NZ performed histology and immunohistochemistry. HEG wrote the manuscript and performed statistical analyses with HJN. Co-authors agreed with the finalized submission. All authors read and approved the final manuscript.