BackgroundMicroparticles (MPs) are circulating membrane particles of less than a micrometer in diameter shed from endothelial and blood cells. Recent literature suggests that MPs are not just functionally inert cell debris but may possess biological functions and mediate the communication between vascular cells. As a significant proportion of MPs originate from platelets and endothelial cells, we hypothesized that MPs may harbor functional enzymes including an endothelial NO synthase (eNOS).Methods and ResultsUsing immunoprecipitation and Western blot analysis, we found that human circulating MPs carry an eNOS. Ca2+ and l‐arginine‐dependent NOS activity of crude enzyme extract from MPs was determined by measuring the conversion of [3H]‐L‐arginine to [3H]‐citrulline and NOS‐dependent nitrite production. NOS‐dependent NO production in intact MPs was assessed by the NO‐specific fluorescent probe MNIP‐Cu. In patients with cardiovascular disease, endothelial dysfunction was associated with an increase in the total number of circulating MPs as well as a significant decrease in the expression and activity of eNOS in MPs. No difference in reactive oxygen species was noted in MPs isolated from either group.ConclusionsOur data further support the concept that circulating MPs may not only retain phenotypic markers but also preserve the functionality of enzymes of the cells they originate from, including eNOS.
For the natural carotenoid 3,3'-dihydroxyisorenieratene (DHIR) and two synthetic derivatives, 3,3'-dihydroxy-16,17,18,16',17',18'-hexanor-Phi,Phi-carotene (DHHC) and Phi,Phi-carotene-3,3'-dione (DHIRQ, isorenieratene-3,3'-dione), steady state absorption experiments and combined density functional and multi-reference configuration interaction calculations were carried out. In addition, femtosecond transient absorption spectra were recorded for DHIR. Due to their marked out-of-plane distortion in DHIR, the phenolic end groups participate only partially in the conjugation system. In the low-energy regime its absorption spectrum with the maximum at 21 700 cm(-1) in acetone solution therefore closely resembles that of beta-carotene, the same as for the T1 energy. Further similarities are also found for the decay kinetics of the optically bright 1(1)Bu+ state of these compounds. After femtosecond excitation, the 1(1)Bu+ population of DHIR decays with a lifetime of 110 fs to the vibrationally hot 2(1)Ag-,v state which in turn relaxes to the 2(1)Ag-,0 state within 500 fs. Decay of the 2(1)Ag-,0 state to the S0 state occurs at a time scale of 12 ps. Demethylation of the phenolic end groups alleviates the steric repulsion by the polyene chain and causes a small red shift (1000 cm(-1)) comparing the absorption spectra of DHHC and DHIR. Oxidation of DHIR leads to drastic changes of the electronic and geometric properties. The quinoid end groups of DHIRQ are fully integrated into the conjugation system, shifting the absorption maximum to 17 800 cm(-1) in acetone solution which thus takes a blue color. The results of the quantum chemical calculations indicate that, in addition to the 2(1)Ag-(S1) state, two dark internal charge-transfer singlet states and the 1(1)Bu- state might be located energetically below the optically bright 1(1)Bu+ (S5) state of DHIRQ.
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