Urokinase‐plasminogen activator protects periodontal ligament fibroblast from oxidative induced‐apoptosis and <scp>DNA</scp> damage

Akhoundi, Mohammad; Rokn, Amir Reza; Bagheri, Rezvan; Momeni, N.; Hodjat, Mahshid

doi:10.1111/jre.12576

Cited by 8 publications

(9 citation statements)

References 31 publications

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“…Amilorides hold a singular place in the history of cell physiology, providing a set of structurally-related analogs that can inhibit several different biological targets [28]. However, numerous studies have attributed pharmacological effects to a specific target of interest following treatment with amiloride or an analog without consideration of possible off-target effects [41][42][43]. In the cancer field alone, there are a several examples whereby effects have been ascribed to inhibition of either uPA [44][45][46] or NHE1 [47][48][49] without controlling for possible effects from the other target.…”

Section: Discussionmentioning

confidence: 99%

Screening of 5- and 6-Substituted Amiloride Libraries Identifies Dual-uPA/NHE1 Active and Single Target-Selective Inhibitors

Buckley

Kumar

Aboelela

et al. 2021

IJMS

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The K+-sparing diuretic amiloride shows off-target anti-cancer effects in multiple rodent models. These effects arise from the inhibition of two distinct cancer targets: the trypsin-like serine protease urokinase-type plasminogen activator (uPA), a cell-surface mediator of matrix degradation and tumor cell invasiveness, and the sodium-hydrogen exchanger isoform-1 (NHE1), a central regulator of transmembrane pH that supports carcinogenic progression. In this study, we co‑screened our library of 5- and 6-substituted amilorides against these two targets, aiming to identify single-target selective and dual-targeting inhibitors for use as complementary pharmacological probes. Closely related analogs substituted at the 6-position with pyrimidines were identified as dual-targeting (pyrimidine 24 uPA IC50 = 175 nM, NHE1 IC50 = 266 nM, uPA selectivity ratio = 1.5) and uPA-selective (methoxypyrimidine 26 uPA IC50 = 86 nM, NHE1 IC50 = 12,290 nM, uPA selectivity ratio = 143) inhibitors, while high NHE1 potency and selectivity was seen with 5-morpholino (29 NHE1 IC50 = 129 nM, uPA IC50 = 10,949 nM; NHE1 selectivity ratio = 85) and 5-(1,4-oxazepine) (30 NHE1 IC50 = 85 nM, uPA IC50 = 5,715 nM; NHE1 selectivity ratio = 67) analogs. Together, these amilorides comprise a new toolkit of chemotype-matched, non-cytotoxic probes for dissecting the pharmacological effects of selective uPA and NHE1 inhibition versus dual-uPA/NHE1 inhibition.

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Section: Discussionmentioning

confidence: 99%

Screening of 5- and 6-Substituted Amiloride Libraries Identifies Dual-uPA/NHE1 Active and Single Target-Selective Inhibitors

Buckley

Kumar

Aboelela

et al. 2021

IJMS

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“…IGF-II exerts neuroprotective effects by reducing oxidative stress through the acceleration of the Nrf2-nuclear translocation and by improving mitochondrial function 46 , 47 . Urokinase-plasminogen activator inhibits oxidative stress-induced apoptosis and DNA damage 48 . STC1 improves brain dysfunction after cerebral irradiation in rats by increasing CAT activity in the hippocampus 49 .…”

Section: Discussionmentioning

confidence: 99%

Therapeutic benefits of factors derived from stem cells from human exfoliated deciduous teeth for radiation-induced mouse xerostomia

Kano

Hashimoto

Liu

et al. 2023

Sci Rep

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Radiation therapy for head and neck cancers is frequently associated with adverse effects on the surrounding normal tissue. Irreversible damage to radiation-sensitive acinar cells in the salivary gland (SG) causes severe radiation-induced xerostomia (RIX). Currently, there are no effective drugs for treating RIX. We investigated the efficacy of treatment with conditioned medium derived from stem cells from human exfoliated deciduous teeth (SHED-CM) in a mouse RIX model. Intravenous administration of SHED-CM, but not fibroblast-CM (Fibro-CM), prevented radiation-induced cutaneous ulcer formation (p < 0.0001) and maintained SG function (p < 0.0001). SHED-CM treatment enhanced the expression of multiple antioxidant genes in mouse RIX and human acinar cells and strongly suppressed radiation-induced oxidative stress. The therapeutic effects of SHED-CM were abolished by the superoxide dismutase inhibitor diethyldithiocarbamate (p < 0.0001). Notably, quantitative liquid chromatography-tandem mass spectrometry shotgun proteomics of SHED-CM and Fibro-CM identified eight proteins activating the endogenous antioxidant system, which were more abundant in SHED-CM than in Fibro-CM (p < 0.0001). Neutralizing antibodies against those activators reduced antioxidant activity of SHED-CM (anti-PDGF-D; p = 0.0001, anti-HGF; p = 0.003). Our results suggest that SHED-CM may provide substantial therapeutic benefits for RIX primarily through the activation of multiple antioxidant enzyme genes in the target tissue.

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“…21 In addition to direct damage and induced inflammation, oxidative stress can cause genetic mutations and PDLSC apoptosis through DNA damage. 22 Moreover, diabetes-induced oxidative stress can cause telomere dysfunction and PDLSCs senescence, which dampens periodontal bone tissue regeneration and reconstruction, and ultimately exacerbates bone loss in periodontitis. 23 Sun et al recently reported that increased mitochondrial ROS, impaired mitochondrial function, and compromised mitochondrial biogenesis in diabetes could aggravate the severity of periodontitis.…”

Section: Oxidative Stress and Mitochondrial Dysfunctionmentioning

confidence: 99%

“…Proved/potential mechanisms that mediate the detrimental effects of lipotoxicity on diabetes-associated periodontitis. M: Greater ROS levels and oxidative stress markers in crevicular fluid 20,23,26,27 M: Impaired mitochondrial function in periodontium cells 24 M: Lower Nrf2 level in periodontal tissues 24,25 O: Increased PDLSCs apoptosis, 24 senescence and telomere dysfunction 23 O: Increased bone resorption [23][24][25] Clinical 19,20,26,27 In vivo 21,22,24 In vitro 21,[23][24][25] ER stress M: Greater UPR-related gene expression and impaired ER function in periodontal tissues [36][37][38]108 In vivo 34,35,37,38,108 In vitro 34,36 Inflammation M: Inflammatory destruction of the supporting tissues around the teeth and an aberrant host response 39 M: Greater IL-1β and IL-18 in the gingival crevicular fluid and the activation of NLRP3 in gingival tissue 40 M: Greater expression of CD36 in macrophages and gingival fibroblasts a46-48 O: Increased osteoclast formation and inflammatory cytokine production a47-51 O: Increased bone resorption 47,48,50 Clinical 40,47 In vivo 39,46,49,…”

Section: Ta B L Ementioning

confidence: 99%

Lipotoxicity: The missing link between diabetes and periodontitis?

Sun,

Yin,

Yang

et al. 2024

J of Periodontal Research

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Lipotoxicity refers to the accumulation of lipids in tissues other than adipose tissue (body fat). It is one of the major pathophysiological mechanisms responsible for the progression of diabetes complications such as non‐alcoholic fatty liver disease and diabetic nephropathy. Accumulating evidence indicates that lipotoxicity also contributes significantly to the toxic effects of diabetes on periodontitis. Therefore, we reviewed the current in vivo, in vitro, and clinical evidence of the detrimental effects of lipotoxicity on periodontitis, focusing on its molecular mechanisms, especially oxidative and endoplasmic reticulum stress, inflammation, ceramides, adipokines, and programmed cell death pathways. By elucidating potential therapeutic strategies targeting lipotoxicity and describing their associated mechanisms and clinical outcomes, including metformin, statins, liraglutide, adiponectin, and omega‐3 PUFA, this review seeks to provide a more comprehensive and effective treatment framework against diabetes‐associated periodontitis. Furthermore, the challenges and future research directions are proposed, aiming to contribute to a more profound understanding of the impact of lipotoxicity on periodontitis.

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Urokinase‐plasminogen activator protects periodontal ligament fibroblast from oxidative induced‐apoptosis and DNA damage

Abstract: The present study brings support to the theory that uPA may have a protective role for periodontal tissue and could protect PDL fibroblasts from oxidative DNA damage and apoptosis.

Cited by 8 publications

References 31 publications

Screening of 5- and 6-Substituted Amiloride Libraries Identifies Dual-uPA/NHE1 Active and Single Target-Selective Inhibitors

Screening of 5- and 6-Substituted Amiloride Libraries Identifies Dual-uPA/NHE1 Active and Single Target-Selective Inhibitors

Therapeutic benefits of factors derived from stem cells from human exfoliated deciduous teeth for radiation-induced mouse xerostomia

Lipotoxicity: The missing link between diabetes and periodontitis?

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