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Abstract

Periodontal disease (PD) is a polymicrobial chronic inflammatory condition of the supporting tissues around the teeth, leading to the destruction of surrounding connective tissue. During the progression of PD, osteoclasts play a crucial role in the resorption of alveolar bone that eventually leads to the loss of teeth if the PD is left untreated. Therefore, the development of antiresorptive therapies targeting bone-resorbing cells will significantly benefit the treatment of PD. Here, we demonstrate the inhibitory effect of CsinCPI-2, a novel cysteine peptidase inhibitor from the orange tree, on periodontitis-induced inflammation, alveolar bone loss, and osteoclast differentiation. Using the ligature-induced periodontitis model in mice, we show that treatment with CsinCPI-2 (0.8 µg/g of body weight) significantly reduced inflammatory cell infiltrate in the connective tissue and prevented the loss of alveolar bone mass (BV/TV) caused by PD, effects associated with diminished numbers of TRAP-positive multinucleated cells. Furthermore, CsinCPI-2 significantly downregulated the numbers of inflammatory cells expressing CD3, CD45, MAC387, and IL-1β. In vitro, CsinCPI-2 inhibited RANKL-induced TRAP+ multinucleated osteoclast formation in mouse bone marrow macrophage cultures in a concentration-dependent manner. This effect was not due to cytotoxicity, as demonstrated by the MTT assay. CsinCPI-2 inhibited RANKL-induced mRNA expression of Acp5, Calcr, and Ctsk, as well as the RANKL-induced upregulation of Nfatc1, a crucial transcription factor for osteoclast differentiation. Based on our findings, CsinCPI-2 prevents bone loss induced by PD by controlling the inflammatory process and acting directly on osteoclastogenesis, suggesting an interesting potential for CsinCPI-2 in the strategy for PD treatment.

Keywords

periodontal diseases periodontitis bone resorption osteoclasts inflammation cystatins

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References

Aral

Milward

Kapila

Berdeli

Cooper

. 2020. Inflammasomes and their regulation in periodontal disease: a review. J Periodontal Res. 55(4):473–487.

Backlund

Holmdahl

Mattsson

Hakansson

Lindstrom

Nandakumar

Grubb

Holmdahl

. 2011. Cystatin C influences the autoimmune but not inflammatory response to cartilage type II collagen leading to chronic arthritis development. Arthritis Res Ther. 13(2):R54.

Bokarewa

Abrahamson

Levshin

Egesten

Grubb

Dahlberg

Tarkowski

. 2007. Cystatin C binds serum amyloid A, downregulating its cytokine-generating properties. J Rheumatol. 34(6):1293–1301.

Brage

Lie

Ransjo

Kasprzykowski

Kasprzykowska

Abrahamson

Grubb

Lerner

. 2004. Osteoclastogenesis is decreased by cysteine proteinase inhibitors. Bone. 34(3):412–424.

Chen

Sun

Zhang

Yan

Xiao

. 2014. RANKL expression in periodontal disease: where does RANKL come from? Biomed Res Int. 2014:731039.

de Almeida Brandao

Spolidorio

Johnson

Golub

Guimaraes-Stabili

Rossa

Jr.

2019. Dose-response assessment of chemically modified curcumin in experimental periodontitis. J Periodontol. 90(5):535–545.

de Molon

Cheong

Bezouglaia

Dry

Pirih

Cirelli

Aghaloo

Tetradis

. 2014. Spontaneous osteonecrosis of the jaws in the maxilla of mice on antiresorptive treatment: a novel ONJ mouse model. Bone. 68:11–19.

de Molon

de Avila

Boas Nogueira

Chaves de Souza

Avila-Campos

de Andrade

Cirelli

. 2014. Evaluation of the host response in various models of induced periodontal disease in mice. J Periodontol. 85(3):465–477.

de Molon

Hsu

Bezouglaia

Dry

Pirih

Soundia

Cunha

Cirelli

Aghaloo

Tetradis

. 2016. Rheumatoid arthritis exacerbates the severity of osteonecrosis of the jaws (ONJ) in mice: a randomized, prospective, controlled animal study. J Bone Miner Res. 31(8):1596–1607.

10.

de Molon

Rossa

Jr Thurlings

Cirelli

Koenders

. 2019. Linkage of periodontitis and rheumatoid arthritis: current evidence and potential biological interactions. Int J Mol Sci. 20(18):4541.

11.

Drake

Clarke

Oursler

Khosla

. 2017. Cathepsin K inhibitors for osteoporosis: biology, potential clinical utility, and lessons learned. Endocr Rev. 38(4):325–350.

12.

Elburki

Rossa

Jr Guimaraes-Stabili

Lee

Curylofo-Zotti

Johnson

Golub

. 2017. A chemically modified curcumin (CMC 2.24) inhibits nuclear factor κB activation and inflammatory bone loss in murine models of LPS-induced experimental periodontitis and diabetes-associated natural periodontitis. Inflammation. 40(4):1436–1449.

13.

Gianotti

Sommer

Carmona

Henrique-Silva

. 2008. Inhibitory effect of the sugarcane cystatin CaneCPI-4 on cathepsins B and L and human breast cancer cell invasion. Biol Chem. 389(4):447–453.

14.

Guimaraes

Coimbra

de Aquino

Spolidorio

Kirkwood

Rossa

Jr.

2011. Potent anti-inflammatory effects of systemically administered curcumin modulate periodontal disease in vivo. J Periodontal Res. 46(2):269–279.

15.

Hajishengallis

. 2015. Periodontitis: from microbial immune subversion to systemic inflammation. Nat Rev Immunol. 15(1):30–44.

16.

Jacome-Galarza

Percin

Muller

Mass

Lazarov

Eitler

Rauner

Yadav

Crozet

Bohm

, et al. 2019. Developmental origin, functional maintenance and genetic rescue of osteoclasts. Nature. 568(7753):541–545.

17.

Johansson

Grubb

Abrahamson

Kasprzykowski

Kasprzykowska

Grzonka

Lerner

. 2000. A peptidyl derivative structurally based on the inhibitory center of cystatin C inhibits bone resorption in vitro. Bone. 26(5):451–459.

18.

Kim

Pokhrel

Lee

Kim

Lee

. 2019. 6-Shogaol, an active ingredient of ginger, inhibits osteoclastogenesis and alveolar bone resorption in ligature-induced periodontitis in mice. J Periodontol. 91(6):809–818.

19.

Kinane

Stathopoulou

Papapanou

. 2017. Periodontal diseases. Nat Rev Dis Primers. 3:17038.

20.

Kuo

Lin

Chiang

Chiu

. 2019. Ameliorative effect of hesperidin on ligation-induced periodontitis in rats. J Periodontol. 90(3):271–280.

21.

Lee

Kim

. 2003. Signal transduction by receptor activator of nuclear factor kappa B in osteoclasts. Biochem Biophys Res Commun. 305(2):211–214.

22.

Leguizamon

NDP

Rodrigues

de Campos

Nogueira

AVB

Viola

Schneider

Neo-Justino

Tanomaru-Filho

Zambuzzi

Henrique-Silva

, et al. 2019. In vivo and in vitro anti-inflammatory and pro-osteogenic effects of citrus cystatin CsinCPI-2. Cytokine. 123:154760.

23.

Lerner

. 2020a. Role of interleukins on physiological and pathological bone resorption and bone formation: I. Effects by cytokines in the IL-1 and IL-2 families. In: Zaidi

, editor. Encyclopedia of bone. Oxford (UK): Academic Press. p. 45–66.

24.

Lerner

. 2020b. Role of interleukins on physiological and pathological bone resorption and bone formation: II. Effects by cytokines in the IL-6 and IL-10 families. In: Zaidi

, editor. Encyclopedia of bone. Oxford (UK): Academic Press. p. 67–87.

25.

Lerner

. 2020c. Role of interleukins on physiological and pathological bone resorption and bone formation: III. Effects by cytokines in the IL-12 and IL-17 families, and by IL-3, IL-32 and IL-34. In: Zaidi

, editor. Encyclopedia of bone. Oxford (UK): Academic Press. p. 88–102.

26.

Lerner

Grubb

. 1992. Human cystatin C, a cysteine proteinase inhibitor, inhibits bone resorption in vitro stimulated by parathyroid hormone and parathyroid hormone–related peptide of malignancy. J Bone Miner Res. 7(4):433–440.

27.

Liu

Figliomeni

Huang

Pavlos

Rogers

Tan

Price

Zheng

. 2003. Expression of RANKL and OPG mRNA in periodontal disease: possible involvement in bone destruction. Int J Mol Med. 11(1):17–21.

28.

Liu

Lerner

Teng

. 2010. Cytokine responses against periodontal infection: protective and destructive roles. Periodontology 2000. 52(1):163–206.

29.

Nakashima

Takayanagi

. 2009. Osteoimmunology: crosstalk between the immune and bone systems. J Clin Immunol. 29(5):555–567.

30.

Nogueira

de Molon

Nokhbehsaim

Deschner

Cirelli

. 2017. Contribution of biomechanical forces to inflammation-induced bone resorption. J Clin Periodontol. 44(1):31–41.

31.

Okamoto

Nakashima

Shinohara

Negishi-Koga

Komatsu

Terashima

Sawa

Nitta

Takayanagi

. 2017. Osteoimmunology: the conceptual framework unifying the immune and skeletal systems. Physiol Rev. 97(4):1295–1349.

32.

Santiago

Khan

Miguel

Gironda

Soares-Costa

Pela

Leite

Edwardson

Buzalaf

MAR

Henrique-Silva

. 2017. A new sugarcane cystatin strongly binds to dental enamel and reduces erosion. J Dent Res. 96(9):1051–1057.

33.

Schett

. 2011. Effects of inflammatory and anti-inflammatory cytokines on the bone. Eur J Clin Invest. 41(12):1361–1366.

34.

Soares-Costa

Beltramini

Thiemann

Henrique-Silva

. 2002. A sugarcane cystatin: recombinant expression, purification, and antifungal activity. Biochem Biophys Res Commun. 296(5):1194–1199.

35.

Souza

Lerner

. 2013. The role of cytokines in inflammatory bone loss. Immunol Invest. 42(7):555–622.

36.

Souza

PPC

Lerner

. 2019. Finding a toll on the route: the fate of osteoclast progenitors after toll-like receptor activation. Front Immunol. 10:1663.

37.

Stralberg

Henning

Gjertsson

Kindlund

Souza

Persson

Abrahamson

Kasprzykowski

Grubb

Lerner

. 2013. Cysteine proteinase inhibitors regulate human and mouse osteoclastogenesis by interfering with rank signaling. FASEB J. 27(7):2687–2701.

38.

Stralberg

Kassem

Kasprzykowski

Abrahamson

Grubb

Lindholm

Lerner

. 2017. Inhibition of lipopolysaccharide-induced osteoclast formation and bone resorption in vitro and in vivo by cysteine proteinase inhibitors. J Leukoc Biol. 101(5):1233–1243.

39.

Takayanagi

Kim

Koga

Nishina

Isshiki

Yoshida

Saiura

Isobe

Yokochi

Inoue

, et al. 2002. Induction and activation of the transcription factor NFATc1 (NFAT2) integrate RANKL signaling in terminal differentiation of osteoclasts. Dev Cell. 3(6):889–901.

40.

Tompkins

. 2016. The osteoimmunology of alveolar bone loss. Connect Tissue Res. 57(2):69–90.

41.

Wei

Kitaura

Zhou

Ross

Teitelbaum

. 2005. IL-1 mediates TNF-induced osteoclastogenesis. J Clin Invest. 115(2):282–290.

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Phytocystatin CsinCPI-2 Reduces Osteoclastogenesis and Alveolar Bone Loss

Abstract

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