Thromboxane A2 (TXA2)

The concentration-dependent effects of U-46619 (1 nM–10 μM) on platelet aggregation and shape alterations have EC50s of 0.58 μM and 0.013 μM, respectively [1]. U-46619 (10 nM–10 μM) stimulates phosphoinositide (PI) hydrolysis in a concentration-dependent manner with a comparable concentration dependence and raises internal Ca2+ concentration ([Ca2+]i [1]. GTPase in platelet membranes can similarly be activated by U-46619 (3 nM–10 μM) in a concentration-dependent way[1]. Through the activation of the p38MAPK and ERK1/2 signaling pathways, U-46619 enhances the differentiation efficiency of human induced pluripotent stem cells into endothelial cells [2].

Male spontaneously hypertensive rats (SHR) exhibit elevated blood pressure in response to U-46619 (5 μg/kg; i.v.) [3].

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The effect of U 46619 (5 micrograms/kg i.v.) alone or in combination with acetylsalicylic acid (ASA) (100 mg/kg po.) on mean arterial blood pressure (MABP) was investigated in male and female spontaneously hypertensive rats (SHR). In male SHR, a significant increase of MABP was observed 1 min after administration of U 46619. Pretreatment of male SHR with ASA delayed the increase of MABP after intravenous injection of U 46619 compared to U 46619 alone. Whereas in control animals the elevated MABP returned to baseline values 5 min after intravenous application of U 46619, the MABP of ASA-pretreated male SHR remained significantly increased by about 30 mmHg. In contrast, the MABP of female SHR did not respond to U 46619 alone or to the combination of U 46619 and ASA. Sex differences were further shown by the vascular formation of thromboxane B2 (TXB2). Whereas in male SHR the vascular formation of TXB2 was increased by U 46619, the TXB2 formation of female SHR was decreased. The vascular formation of 6-keto-PGF1 alpha of male and female SHR was not influenced by U 46619 alone or a combination of U 46619 and ASA. In conclusion, our results demonstrate that the blood pressure of SHR respond differently to the TXA2 mimetic U 46619 in the two sexes. Furthermore, by modulating blood pressure response to TXA2, vasoactive prostanoids may be significantly involved in the maintenance of hypertension with male SHR.[3]

1. Thromboxane A2 (TXA2) receptor-mediated signal transduction was investigated in washed rabbit platelets to clarify the mechanisms of induction of shape change and aggregation. 2. The TXA2 agonist, U46619 (1 nM to 10 microM) caused shape change and aggregation in a concentration-dependent manner. A forty-times higher concentration of U46619 was needed for aggregation (EC50 of 0.58 microM) than shape change (EC50 of 0.013 microM). The aggregation occurred only when external 1 mM Ca2+ was present, but the shape change could occur in the absence of Ca2+. 3. SQ29548 at 30 nM and GR32191B at 0.3 microM (TXA2 receptor antagonists) competitively inhibited U46619-induced shape change and aggregation with similar potency, showing that both aggregation and shape change induced by U46619 were TXA2 receptor-mediated events. However, ONO NT-126 at 1 nM, another TXA2 receptor antagonist, inhibited U46619-induced aggregation much more potently than the shape change, suggesting the possible existence of TXA2 receptor subtypes. 4. ONO NT-126 (2 nM to 3 microM) by itself caused a shape change without aggregation in a concentration-dependent manner, independent of external Ca2+. Therefore, ONO NT-126 is a partial agonist at the TXA2 receptor in rabbit platelets. 5. U46619 (10 nM to 10 microM) increased internal Ca2+ concentration ([Ca2+]i) and activated phosphoinositide (PI) hydrolysis in a concentration-dependent manner with a similar concentration-dependency. 6. U46619 (3 nM to 10 microM) also activated GTPase concentration-dependently in the membranes derived from platelets. U46619-induced activation of GTPase was partly inhibited by treatment of membranes with QL, an antibody against Gq/11. 7. The EC50 values of U46619 in Ca2+ mobilization (0.15 microM), PI hydrolysis (0.20 microM) and increase in GTPase activity (0.12 microM) were similar, but different from the EC50 value in shape change (0.013 microM), suggesting that activation of TXA2 receptors might cause shape change via an unknown mechanism. 8. U46619-induced shape change was unaffected by W-7 (30 microM), a calmodulin antagonist or ML-7 (30 microM), a myosin light-chain kinase inhibitor, indicating that an increase in [Ca2+]i might not be involved in the shape change. In fact, U46619 (10 nM) could cause shape change without affecting [Ca2+]i level, determined by simultaneous recordings. 9. [3H]-SQ29548 and [3H]-U46619 bound to platelets at a single site with a Kd value of 14.88 nM and Bmax of 106.1 fmol/10(8) platelets and a Kd value of 129.8 nM and Bmax of 170.4 fmol/10(8) platelets, respectively. The inhibitory constant Ki value for U46619 as an inhibitor of 3H-ligand binding was similar to the EC50 value of U46619 in GTPase activity, phosphoinositide hydrolysis and Ca2+ mobilization, but significantly different (P < 0.001 by Student's t test) from the effect on shape change. 10. Neither U46619 nor ONO NT-126 affected the adenosine 3',5'-cyclic monophosphate (cyclic AMP) level in the presence or absence of external Ca2+ and/or isobutyl methylxanthine. 11. The results indicate that TXA2 receptor stimulation causes phospholipase C activation and increase in [Ca2+]i via a G protein of the Gq/11 family leading to aggregation in the presence of external Ca2+, and that shape change induced by TXA2 receptor stimulation might occur without involvement of the Gq-phospholipase C-Ca2+ pathway[1].

We modified our 3D protocol by using U-46619 to upregulate both p38 mitogen-activated protein kinase (p38MAPK) and extracellular signal-regulated kinase 1/2 (ERK1/2) signaling, which increased the differentiation efficiency (as measured by CD31 expression) to as high as 89% in two established hiPSC lines. The differentiated cells expressed arteriovenous, but not lymphatic, markers; formed tubular structures and EC lumen in vitro; had significantly shorter population-doubling times than monolayer-differentiated hiPSC-ECs; and restored perfusion and vascularity in a murine hind limb ischemia model. The differentiation efficiency was also > 85% in three hiPSC lines that had been derived from patients with diseases or disease symptoms that have been linked to endothelial dysfunction[2].

Animal/Disease Models: 12-15 weeks old male and female SHR [2]
Doses: 5 μg/kg
Route of Administration: intravenous (iv) (iv)injection
Experimental Results: A significant increase in MABP was induced in male SHR after 1 minute.

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Pressure Myography [4]
Vasodilation was determined using a pressure myography system as previously described.20,46 Briefly, rats were sacrificed under anesthesia, and the brains were rapidly harvested and placed in precooled physiological salt dissolution (PSS, composition in mmol/L: NaCl 118, KCl 4.7, CaCl2 1.6, KH2PO4 1.2, MgSO4 1.2, NaHCO3 25, EDTA 0.026, glucose 5.5, pH 7.4) bubbled with 95% O2 + 5% CO2. CBA was carefully isolated from the brain and cut into an unbranched artery segment of 3 mm in length. The artery segment was inserted with glass micropipettes at both ends and fixed in a perfusion chamber of a DMT-114P Pressure Myograph System, which was filled with PSS aerated with 95% O2 + 5% CO2 at 37 °C. The lumen of the segment was perfused with the same aerated PPS. After 60 min of equilibrium, 100 nmol/L U46619 or 30 mmol/L KCl was added to the luminal superfusate to induce stable vasocontraction. Vasodilation was subsequently caused by cumulatively adding ACh or NaHS. The diameter of the artery segment was continually measured by Pressure Myograph System software. Vasodilation was expressed as the percentage of the maximum diameter using the following formula:
where Dmax is the initial diameter of the artery segment at equilibration for 60 min, Dmin is the stable diameter after adding KCl or U46619, and D is the diameter after adding ACh or NaHS. [4]

[1]. Thromboxane A2-mediated shape change: independent of Gq-phospholipase C--Ca2+ pathway in rabbit platelets. Br J Pharmacol. 1996 Mar;117(6):1095-104.

[2]. The prostaglandin H2 analog U-46619 improves the differentiation efficiency of human induced pluripotent stem cells into endothelial cells by activating both p38MAPK and ERK1/2 signaling pathways. Stem Cell Res Ther. 2018 Nov 15;9(1):313.

[3]. U 46619 induces different blood pressure effects in male and female spontaneously hypertensive rats (SHR). Prostaglandins Leukot Essent Fatty Acids. 1993 Jun;48(6):469-73.

[4]. Roles of the RhoA-ROCK Signaling Pathway in the Endothelial H2S Production and Vasodilation in Rat Cerebral Arteries. ACS Omega. 2022 May 20;7(22):18498-18508.

[5]. Thromboxane A2 receptors in prostate carcinoma: expression and its role in regulating cell motility via small GTPase Rho. Cancer Res. 2008 Jan 1;68(1):115-21.

A stable prostaglandin endoperoxide analog which serves as a thromboxane mimetic. Its actions include mimicking the hydro-osmotic effect of VASOPRESSIN and activation of TYPE C PHOSPHOLIPASES. (From J Pharmacol Exp Ther 1983;224(1): 108-117; Biochem J 1984;222(1):103-110)

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Background: We have shown that the differentiation of human-induced pluripotent stem cells (hiPSCs) into endothelial cells (ECs) is more efficient when performed with a 3-dimensional (3D) scaffold of biomaterial than in monolayers. The current study aims to further increase hiPSC-EC differentiation efficiency by deciphering the signaling pathways in 3D scaffolds. Methods and results: We modified our 3D protocol by using U-46619 to upregulate both p38 mitogen-activated protein kinase (p38MAPK) and extracellular signal-regulated kinase 1/2 (ERK1/2) signaling, which increased the differentiation efficiency (as measured by CD31 expression) to as high as 89% in two established hiPSC lines. The differentiated cells expressed arteriovenous, but not lymphatic, markers; formed tubular structures and EC lumen in vitro; had significantly shorter population-doubling times than monolayer-differentiated hiPSC-ECs; and restored perfusion and vascularity in a murine hind limb ischemia model. The differentiation efficiency was also > 85% in three hiPSC lines that had been derived from patients with diseases or disease symptoms that have been linked to endothelial dysfunction. Conclusions: These observations demonstrate that activating both p38MAPK and ERK1/2 signaling pathways with U-46619 improves the efficiency of arteriovenous hiPSC-EC differentiation and produces cells with greater proliferative capacity. Keywords: Endothelial differentiation; Human-induced pluripotent stem cells; Signaling pathways. PubMed Disclaimer[2]

C21H34O4

350.49226

350.245

C, 71.96; H, 9.78; O, 18.26

56985-40-1

56985-40-1;

5311493

Colorless to light yellow liquids

1.1±0.1 g/cm3

519.7±30.0 °C at 760 mmHg

176.1±18.1 °C

0.0±3.1 mmHg at 25°C

1.548

3.9

2

4

12

25

457

5

CCCCC[C@@H](/C=C/[C@H]1C2OCC(C2)[C@@H]1C/C=C/CCCC(=O)O)O

LQANGKSBLPMBTJ-BRSNVKEHSA-N

InChI=1S/C21H34O4/c1-2-3-6-9-17(22)12-13-19-18(16-14-20(19)25-15-16)10-7-4-5-8-11-21(23)24/h4,7,12-13,16-20,22H,2-3,5-6,8-11,14-15H2,1H3,(H,23,24)/b7-4-,13-12+/t16-,17+,18+,19-,20-/m1/s1

(Z)-7-[(1R,4S,5S,6R)-6-[(E,3S)-3-hydroxyoct-1-enyl]-2-oxabicyclo[2.2.1]heptan-5-yl]hept-5-enoic acid

U-46619; U46619; U 46619; 9,11-Methanoepoxy PGH2; 11alpha,9alpha-epoxymethano-PGH2; MLS000028857; CHEMBL521784;

2934.99.9001

Powder      -20°C    3 years

                     4°C     2 years

In solvent   -80°C    6 months

                  -20°C    1 month

Room temperature (This product is stable at ambient temperature for a few days during ordinary shipping and time spent in Customs)

May dissolve in DMSO (in most cases), if not, try other solvents such as H2O, Ethanol, or DMF with a minute amount of products to avoid loss of samples

Note: Listed below are some common formulations that may be used to formulate products with low water solubility (e.g. < 1 mg/mL), you may test these formulations using a minute amount of products to avoid loss of samples.

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Injection Formulation 1: DMSO : Tween 80： Saline = 10 : 5 : 85 (i.e. 100 μL DMSO stock solution → 50 μL Tween 80 → 850 μL Saline)
*Preparation of saline: Dissolve 0.9 g of sodium chloride in 100 mL ddH ₂ O to obtain a clear solution.
Injection Formulation 2: DMSO : PEG300 ：Tween 80 : Saline = 10 : 40 : 5 : 45 (i.e. 100 μL DMSO → 400 μLPEG300 → 50 μL Tween 80 → 450 μL Saline)
Injection Formulation 3: DMSO : Corn oil = 10 : 90 (i.e. 100 μL DMSO → 900 μL Corn oil)
Example: Take the Injection Formulation 3 (DMSO : Corn oil = 10 : 90) as an example, if 1 mL of 2.5 mg/mL working solution is to be prepared, you can take 100 μL 25 mg/mL DMSO stock solution and add to 900 μL corn oil, mix well to obtain a clear or suspension solution (2.5 mg/mL, ready for use in animals).

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Injection Formulation 4: DMSO : 20% SBE-β-CD in saline = 10 : 90 [i.e. 100 μL DMSO → 900 μL (20% SBE-β-CD in saline)]
*Preparation of 20% SBE-β-CD in Saline (4°C，1 week): Dissolve 2 g SBE-β-CD in 10 mL saline to obtain a clear solution.
Injection Formulation 5: 2-Hydroxypropyl-β-cyclodextrin : Saline = 50 : 50 (i.e. 500 μL 2-Hydroxypropyl-β-cyclodextrin → 500 μL Saline)
Injection Formulation 6: DMSO : PEG300 : castor oil : Saline = 5 : 10 : 20 : 65 (i.e. 50 μL DMSO → 100 μLPEG300 → 200 μL castor oil → 650 μL Saline)
Injection Formulation 7: Ethanol : Cremophor : Saline = 10： 10 : 80 (i.e. 100 μL Ethanol → 100 μL Cremophor → 800 μL Saline)
Injection Formulation 8: Dissolve in Cremophor/Ethanol (50 : 50), then diluted by Saline
Injection Formulation 9: EtOH : Corn oil = 10 : 90 (i.e. 100 μL EtOH → 900 μL Corn oil)
Injection Formulation 10: EtOH : PEG300：Tween 80 : Saline = 10 : 40 : 5 : 45 (i.e. 100 μL EtOH → 400 μLPEG300 → 50 μL Tween 80 → 450 μL Saline)

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Oral Formulation 1: Suspend in 0.5% CMC Na (carboxymethylcellulose sodium)
Oral Formulation 2: Suspend in 0.5% Carboxymethyl cellulose
Example: Take the Oral Formulation 1 (Suspend in 0.5% CMC Na) as an example, if 100 mL of 2.5 mg/mL working solution is to be prepared, you can first prepare 0.5% CMC Na solution by measuring 0.5 g CMC Na and dissolve it in 100 mL ddH2O to obtain a clear solution; then add 250 mg of the product to 100 mL 0.5% CMC Na solution, to make the suspension solution (2.5 mg/mL, ready for use in animals).

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Oral Formulation 3: Dissolved in PEG400
Oral Formulation 4: Suspend in 0.2% Carboxymethyl cellulose
Oral Formulation 5: Dissolve in 0.25% Tween 80 and 0.5% Carboxymethyl cellulose
Oral Formulation 6: Mixing with food powders

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Note: Please be aware that the above formulations are for reference only. InvivoChem strongly recommends customers to read literature methods/protocols carefully before determining which formulation you should use for in vivo studies, as different compounds have different solubility properties and have to be formulated differently.

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 (Please use freshly prepared in vivo formulations for optimal results.)