Identification of the two-phase mechanism of arachidonic acid regulating inflammatory prostaglandin E2 biosynthesis by targeting COX-2 and mPGES-1

Akasaka, Hironari; Ruan, Ke‐He

doi:10.1016/j.abb.2016.04.011

Cited by 17 publications

(11 citation statements)

References 34 publications

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“…Arachidonic acid, Thromboxane, 16(R)-HETE, Prostaglandin A1, Prostaglandin A2, and 8-Isoprostane are involved in arachidonic acid metabolism. Arachidonic acid and its metabolites, as the main inflammatory substances, are taking part in the process of immune and inflammatory actions6061. Thromboxane could promote cancer cell proliferation through enhancing the activity of cell mitosis6263.…”

Section: Discussionmentioning

confidence: 99%

Screening the active compounds of Phellodendri Amurensis cortex for treating prostate cancer by high-throughput chinmedomics

Zhang

Wang

et al. 2017

Sci Rep

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Screening the active compounds of herbal medicines is of importance to modern drug discovery. In this work, an integrative strategy was established to discover the effective compounds and their therapeutic targets using Phellodendri Amurensis cortex (PAC) aimed at inhibiting prostate cancer as a case study. We found that PAC could be inhibited the growth of xenograft tumours of prostate cancer. Global constituents and serum metabolites were analysed by UPLC-MS based on the established chinmedomics analysis method, a total of 54 peaks in the spectrum of PAC were characterised in vitro and 38 peaks were characterised in vivo. Among the 38 compounds characterised in vivo, 29 prototype components were absorbed in serum and nine metabolites were identified in vivo. Thirty-four metabolic biomarkers were related to prostate cancer, and PAC could observably reverse these metabolic biomarkers to their normal level and regulate the disturbed metabolic profile to a healthy state. A chinmedomics approach showed that ten absorbed constituents, as effective compounds, were associated with the therapeutic effect of PAC. In combination with bioactivity assays, the action targets were also predicted and discovered. As an illustrative case study, the strategy was successfully applied to high-throughput screening of active compounds from herbal medicine.

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Section: Discussionmentioning

confidence: 99%

Screening the active compounds of Phellodendri Amurensis cortex for treating prostate cancer by high-throughput chinmedomics

Zhang

Wang

et al. 2017

Sci Rep

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“…Platelets also have thromboxane A synthase 1, which has been confirmed by an inhibition experiment (19). Phospholipids in the cell membrane are rich in arachidonic acid so when the cells are stimulated by external stimuli, including bradykinin, thrombin, antigen-antibody complexes or other pathological factors, a number of which have not yet been characterized, the phospholipase A2 in cell membrane will be activated, consequently hydrolyzing the phospholipids and releasing arachidonic acid, which may then synthesize PGs under a series of enzymes including COX-2 and PGs synthetase (20). In the majority of normal tissues, PG is not expressed; however, under the stimuli of factors such as cytokines, growth factors, oncogenes or tumor-promoting agents, it may be upregulated and associated with the occurrence and development of tumors (21).…”

Section: Discussionmentioning

confidence: 90%

Effect of photodynamic therapy combined with Celecoxib on expression of cyclooxygenase-2 protein in HeLa cells

Mao

Wang

et al. 2018

Oncol Lett

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Abstract. The present study assessed the effect of photodynamic therapy (PDT) combined with Celecoxib (Cel) on cervical cancer HeLa cells. An MTT assay was performed to detect the inhibitory effects of Cel with different concentrations (10, 50, 100, 150, 200, 250 and 300 µg/ml) on the proliferation of HeLa cells. Subsequently, HeLa cells were divided into control group (group H), 50 g/ml Celecoxib group (group C), PDT group (group P), 50 g/ml Cel + PDT group (group P + C) and western blotting and immunohistochemistry were performed to detect the expression of cyclooxygenase-2 (COX-2) protein in the different groups. Cel inhibited HeLa cells proliferation 24 h following administration, among which 200 µg/ml induced a 50% inhibition rate; the relative expression level of COX-2 protein in group P + C was significantly decreased compared with that in either group C or group P (P<0.05). Cel inhibited the proliferation of human cervical cancer cells in a concentration-dependent manner, and combined PDT therapy may improve treatment outcomes.

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“…Therefore, a change in the distribution of PGH 2 to the particular isozyme is the key to control the metabolism of AA into the specific prostanoid. In recent years, using an enzymatic engineering approach to control the distribution of PGH 2 has been focused by our group to address this issue . In our previous studies, we have successfully created a single‐chain hybrid enzyme complex (SCHEC), COX‐1‐10aa‐PGIS, through the enzymatic engineering approach, which can force AA to be isomerized into PGI 2 , in order to rescue the deficiency of PGI 2 and to study the vascular protection effects of PGI 2 in cellular and animal models .…”

Section: Introductionmentioning

confidence: 99%

“…In our previous studies, we have successfully created a single‐chain hybrid enzyme complex (SCHEC), COX‐1‐10aa‐PGIS, through the enzymatic engineering approach, which can force AA to be isomerized into PGI 2 , in order to rescue the deficiency of PGI 2 and to study the vascular protection effects of PGI 2 in cellular and animal models . Another SCHEC, COX‐2‐10aa‐mPGES‐1, which can effectively pass PGH 2 to mPGES‐1, to convert AA to PGE 2 , has also been created as a model for understanding how PGE 2 is biosynthesized during inflammation . In this study, we created a novel SCHEC, linking the C‐terminus of COX‐1 to the N‐terminus of the TXAS, through a 10‐residue amino acid linker, to directly guide the metabolism of AA to TXA 2 by effectively passing the COX‐1 produced PGH 2 to TXAS.…”

Section: Introductionmentioning

confidence: 99%

“…In recent years, using an enzymatic engineering approach to control the distribution of PGH 2 has been focused by our group to address this issue. [10][11][12][13][14][15][16][17] In our previous studies, we have successfully created a single-chain hybrid enzyme complex (SCHEC), COX-1-10aa-PGIS, through the enzymatic engineering approach, which can force AA to be isomerized into PGI 2 , in order to rescue the deficiency of PGI 2 and to study the vascular protection effects of PGI 2 in cellular and animal models. [10][11][12][13] Another SCHEC, COX-2-10aa-mPGES-1, which can effectively pass PGH 2 to mPGES-1, to convert AA to PGE 2 , has also been created as a model for understanding how PGE 2 is biosynthesized during inflammation.…”

mentioning

confidence: 99%

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A novel single‐chain enzyme complex with chain reaction properties rapidly producing thromboxane A₂ and exhibiting powerful anti‐bleeding functions

Ling

et al. 2019

J Cellular Molecular Medi

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Uncontrollable bleeding is still a worldwide killer. In this study, we aimed to investigate a novel approach to exhibit effective haemostatic properties, which could possibly save lives in various bleeding emergencies. According to the structure‐based enzymatic design, we have engineered a novel single‐chain hybrid enzyme complex (SCHEC), COX‐1‐10aa‐TXAS. We linked the C‐terminus of cyclooxygenase‐1 (COX‐1) to the N‐terminus of the thromboxane A2 (TXA2) synthase (TXAS), through a 10‐amino acid residue linker. This recombinant COX‐1‐10aa‐TXAS can effectively pass COX‐1–derived intermediate prostaglandin (PG) H2 (PGH2) to the active site of TXAS, resulting in an effective chain reaction property to produce the haemostatic prostanoid, TXA2, rapidly. Advantageously, COX‐1‐10aa‐TXAS constrains the production of other pro‐bleeding prostanoids, such as prostacyclin (PGI2) and prostaglandin E2 (PGE2), through reducing the common substrate, PGH2 being passed to synthases which produce aforementioned prostanoids. Therefore, based on these multiple properties, this novel COX‐1‐10aa‐TXAS indicated a powerful anti‐bleeding ability, which could be used to treat a variety of bleeding situations and could even be useful for bleeding prone situations, including nonsteroidal anti‐inflammatory drugs (NSAIDs)‐resulted TXA2‐deficient and PGI2‐mediated bleeding disorders. This novel SCHEC has a great potential to be developed into a biological haemostatic agent to treat severe haemorrhage emergencies, which will prevent the complications of blood loss and save lives.

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Identification of the two-phase mechanism of arachidonic acid regulating inflammatory prostaglandin E2 biosynthesis by targeting COX-2 and mPGES-1

Cited by 17 publications

References 34 publications

Screening the active compounds of Phellodendri Amurensis cortex for treating prostate cancer by high-throughput chinmedomics

Screening the active compounds of Phellodendri Amurensis cortex for treating prostate cancer by high-throughput chinmedomics

Effect of photodynamic therapy combined with Celecoxib on expression of cyclooxygenase-2 protein in HeLa cells

A novel single‐chain enzyme complex with chain reaction properties rapidly producing thromboxane A₂ and exhibiting powerful anti‐bleeding functions

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Identification of the two-phase mechanism of arachidonic acid regulating inflammatory prostaglandin E2 biosynthesis by targeting COX-2 and mPGES-1

Cited by 17 publications

References 34 publications

Screening the active compounds of Phellodendri Amurensis cortex for treating prostate cancer by high-throughput chinmedomics

Screening the active compounds of Phellodendri Amurensis cortex for treating prostate cancer by high-throughput chinmedomics

Effect of photodynamic therapy combined with Celecoxib on expression of cyclooxygenase-2 protein in HeLa cells

A novel single‐chain enzyme complex with chain reaction properties rapidly producing thromboxane A2 and exhibiting powerful anti‐bleeding functions

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Product

Resources

About

A novel single‐chain enzyme complex with chain reaction properties rapidly producing thromboxane A₂ and exhibiting powerful anti‐bleeding functions