Cathepsin k
From Proteopedia
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<Structure load='1atk' size='350' frame='true' align='right' caption='Insert caption here' scene='72/727885/Mainpage/2' /> | <Structure load='1atk' size='350' frame='true' align='right' caption='Insert caption here' scene='72/727885/Mainpage/2' /> | ||
| - | Cathepsin K is initially synthesized in its inactive form, pre-procathepsin k, a 37-kDa protein made up of a single peptide chain 329 amino acids in length (9,11,12). The pre-procathepsin k sequence has three distinct features: a signal peptide, consisting of the first 15 amino acids at the N-terminus; a propeptide, comprising amino acids 16-114; and the main chain, which makes up the final 215 amino acids ending at the C-Terminus (10). When the enzyme is activated, the signal peptide and propeptide portions are cleaved to produce the mature Cathepsin K protein weighing 27-kDa (11,12). | + | Cathepsin K is initially synthesized in its inactive form, pre-procathepsin k, a 37-kDa protein made up of a single peptide chain 329 amino acids in length (9,11,12). The pre-procathepsin k sequence has three distinct features: a signal peptide, consisting of the first 15 amino acids at the N-terminus; a propeptide, comprising amino acids 16-114; and the main chain, which makes up the final 215 amino acids ending at the C-Terminus (9,10). When the enzyme is activated, the signal peptide and propeptide portions are cleaved to produce the mature Cathepsin K protein weighing 27-kDa (11,12). |
The <scene name='72/727885/Cathepsin_k_active_site/1'>active site</scene> of Cathepsin K consists of three residues: CYS25, HIS162, and ASN182 (8). | The <scene name='72/727885/Cathepsin_k_active_site/1'>active site</scene> of Cathepsin K consists of three residues: CYS25, HIS162, and ASN182 (8). | ||
Revision as of 22:56, 31 March 2016
Contents |
Structure
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Cathepsin K is initially synthesized in its inactive form, pre-procathepsin k, a 37-kDa protein made up of a single peptide chain 329 amino acids in length (9,11,12). The pre-procathepsin k sequence has three distinct features: a signal peptide, consisting of the first 15 amino acids at the N-terminus; a propeptide, comprising amino acids 16-114; and the main chain, which makes up the final 215 amino acids ending at the C-Terminus (9,10). When the enzyme is activated, the signal peptide and propeptide portions are cleaved to produce the mature Cathepsin K protein weighing 27-kDa (11,12).
The of Cathepsin K consists of three residues: CYS25, HIS162, and ASN182 (8).
Function
Cathepsin K is the most abundant cysteine protease produced by osteoclasts, the multinuclear cells responsible for bone resorption (6,7). Osteoclasts implement bone resorption by secreting acid onto the bone surface which demineralizes bone tissue, followed by proteases – including cathepsins – which degrade the bone matrix (6,8). Cathepsin K can cleave type I and type II collagen, major components of bone and cartilage matrices (4,5). This enzyme is unique among other cysteine proteases in that it can cleave collagen at multiple sites and in its triple helix (2).
Disease
Deficiencies in Cathepsin K have been shown to cause pycnodysostosis, caused by reduced bone resorption and characterized by increased bone density and short stature (3). Cathepsin K inhibitors have been thus thought potential treatments for diseases involving excessive bone or cartilage resorption, such as osteoporosis and autoimmue arthritis (1,4,6). However, as demineralization of bone can continue without Cathepsin k, the inhibition of Cathespin K may merely result in the accumulation of weakened bone tissue (7).
Relevance
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References
1. Asagiri, M., Hirai, T., Kunigami, T., et.al. (2008). Cathepsin K-dependent toll-like receptor 9 signaling revealed in experimental arthritis. Science, 319(5863), 624-627.
2. Garnero, P., Borel, O., Byrjalsen, I., et.al. (1998). The collagenolytic activity of cathepsin K is unique among mammalian proteinases. Journal of Biological Chemistry,273(48), 32347-32352.
3. Gelb, B. D., Shi, G. P., Chapman, H. A., & Desnick, R. J. (1996). Pycnodysostosis, a lysosomal disease caused by cathepsin K deficiency.Science, 273(5279), 1236-1238.
4. Hou, W. S., Li, Z., Gordon, R. E., et.al. (2001). Cathepsin K is a critical protease in synovial fibroblast-mediated collagen degradation. The American journal of pathology, 159(6), 2167-2177.
5. Kafienah, W. E., Bromme, D., Buttle, D. J., et.al. (1998). Human cathepsin K cleaves native type I and II collagens at the N-terminal end of the triple helix. Biochemical Journal,331(3), 727-732.
6. Stoch, S. A., & Wagner, J. A. (2008). Cathepsin K inhibitors: a novel target for osteoporosis therapy. Clinical Pharmacology & Therapeutics, 83(1), 172-176.
7. Väänänen, K. (2005). Mechanism of osteoclast mediated bone resorption—rationale for the design of new therapeutics. Advanced drug delivery reviews,57(7), 959-971.
8. Zhao, B., Janson, C. A., Amegadzie, B. Y., et.al. (1997). Crystal structure of human osteoclast cathepsin K complex with E-64. Nature Structural & Molecular Biology, 4(2), 109-111.
9. "UniProtKB - P43235 (CATK_HUMAN)." Uniprot.org.
10. "CATK_HUMAN (P43235)." ExPasy.org/cgi-bin/protparam
11. McQueney, M. S., Amegadzie, B. Y., D’Alessio, K., et.al. (1997). Autocatalytic activation of human cathepsin K. Journal of Biological Chemistry, 272(21), 13955-13960.
12. Bossard, M. J., Tomaszek, T. A., Thompson, S. K., et.al. (1996). Proteolytic activity of human osteoclast cathepsin K expression, purification, activation, and substrate identification. Journal of Biological Chemistry, 271(21), 12517-12524.
