Adenosine, oxidation

Irreversible inhibition of ADP and CDP reduction in Ehrlich tumor cells was caused by ATP-, AMP- or adenosine oxidized with sodium periodate. The inhibition probably involves Schiff base formation between the 2, 3 -dialdehyde product and a lysine residue(s), because pyridoxal phosphate also inhibits ADP and CDP reduction (141, 142). 

Glucose [50-99-7] urea [57-13-6] (qv), and cholesterol [57-88-5] (see Steroids) are the substrates most frequentiy measured, although there are many more substrates or metaboUtes that are determined in clinical laboratories using enzymes. Co-enzymes such as adenosine triphosphate [56-65-5] (ATP) and nicotinamide adenine dinucleotide [53-84-9] in its oxidized (NAD" ) or reduced (NADH) [58-68-4] form can be considered substrates. Enzymatic analysis is covered in detail elsewhere (9). 

Phosphorus. Eighty-five percent of the phosphoms, the second most abundant element in the human body, is located in bones and teeth (24,35). Whereas there is constant exchange of calcium and phosphoms between bones and blood, there is very Httle turnover in teeth (25). The Ca P ratio in bones is constant at about 2 1. Every tissue and cell contains phosphoms, generally as a salt or ester of mono-, di-, or tribasic phosphoric acid, as phosphoHpids, or as phosphorylated sugars (24). Phosphoms is involved in a large number and wide variety of metaboHc functions. Examples are carbohydrate metaboHsm (36,37), adenosine triphosphate (ATP) from fatty acid metaboHsm (38), and oxidative phosphorylation (36,39). Common food sources rich in phosphoms are Hsted in Table 5 (see also Phosphorus compounds). 

The modes of action for niclosamide are interference with respiration and blockade of glucose uptake. It uncouples oxidative phosphorylation in both mammalian and taenioid mitochondria (22,23), inhibiting the anaerobic incorporation of inorganic phosphate into adenosine triphosphate (ATP). Tapeworms are very sensitive to niclosamide because they depend on the anaerobic metaboHsm of carbohydrates as their major source of energy. Niclosamide has selective toxicity for the parasites as compared with the host because Httle niclosamide is absorbed from the gastrointestinal tract. Adverse effects are uncommon, except for occasional gastrointestinal upset. 

ATP Adenosine triphosphate. Chemical energy generated by substrate oxidations is conserved by formation of high-energy compounds such as adenosine diphosphate (ADP) and adenosine triphosphate (ATP) or compounds containing the thioester bond. 

Several toxic compounds act by inhibiting the oxidation of carbohydrates or by inhibiting the formation of adenosine triphosphate (ATP), a molecule that... 

Jervis used porous silica coated with chemisorbed polyacrylhydrazide for immobilization of adenosine monophosphate (AMP) [117]. After periodate oxidation of its ribose residue the ligand was coupled to the carrier and used for isolation of lactate dehydrogenase from rabbit muscle. The specific capacity was 2 mg of protein/g adsorbent with a ligand content of 10 pmol/g, whereas recovery of enzymatic activity after elution was 85%. Hipwell et al. [118] found that for effective binding of lactate dehydrogenases on AMP-o-aminoalkyl-Sepharose the spacer arm length required at least 4 methylene links. Apparently, a macromolecule of polyacrylhydrazide acts itself like an extended spacer arm and thus allow AMP to bind the enzyme. 

Dipyridamole exerts its effect by inhibition of platelet phosphodiesterase E5, increasing cyclic guanosine monophosphate and cyclic adenosine monophosphate (cAMP). By inhibiting its uptake and metabolism by erythrocytes, dipyridamole also increases the availability of adenosine within blood vessels, promoting inhibition of platelet aggregation and local vasodilatation. " Dipyridamole may also inhibit cAMP phosphodiesterase in platelets, which further increases cAMP levels and may enhance endothelial nitric oxide production, contributing to its antithrombotic effect. Existing trials of dipyridamole in stroke have focused on secondary prevention and will be discussed briefly. 

A remarkable feature of the bioenergetic oxidation reactions of nutrients in cells is the fact that they are always coupled to another reaction, that of synthesis of the energy-rich chemical substance adenosine triphosphate (ATP) from adenosine diphosphate (ADP) and phosphate (oxidative phosphorylation Engelgardt and Ljubimova, 1939) ... 

The risk of developing colonic cancer is raised in UC, particularly in those with long-standing extensive disease (Lennard-Jones et al., 1990). The mechanism of this increased susceptibility is unknown, although it is tempting to speculate that it is related to inflammation and resulting oxidative damage to DNA. As yet there is little evidence to support this contention. Markowitz et al. (1988) have reported a decrease in constituent and oxidant-induced adenosine diphosphate ribosyl... 

P. Mitchell (Nobel Prize for Chemistry, 1978) explained these facts by his chemiosmotic theory. This theory is based on the ordering of successive oxidation processes into reaction sequences called loops. Each loop consists of two basic processes, one of which is oriented in the direction away from the matrix surface of the internal membrane into the intracristal space and connected with the transfer of electrons together with protons. The second process is oriented in the opposite direction and is connected with the transfer of electrons alone. Figure 6.27 depicts the first Mitchell loop, whose first step involves reduction of NAD+ (the oxidized form of nicotinamide adenosine dinucleotide) by the carbonaceous substrate, SH2. In this process, two electrons and two protons are transferred from the matrix space. The protons are accumulated in the intracristal space, while electrons are transferred in the opposite direction by the reduction of the oxidized form of the Fe-S protein. This reduces a further component of the electron transport chain on the matrix side of the membrane and the process is repeated. The final process is the reduction of molecular oxygen with the reduced form of cytochrome oxidase. It would appear that this reaction sequence includes not only loops but also a proton pump, i.e. an enzymatic system that can employ the energy of the redox step in the electron transfer chain for translocation of protons from the matrix space into the intracristal space. 

The process occurring in plants and algae by which water is oxidized to molecular oxygen and carbon dioxide is converted to carbohydrates in the presence of light is called photosynthesis. In addition to the products oxygen and carbohydrate, light energy is stored chemically in adenosine triphosphate (ATP) for later use for a variety of purposes. The production of... 

Monti, J. M., Jantos, H. Monti, D. (2001). Increase of waking and reduction of NREM and REM sleep after nitric oxide synthase inhibition prevention with GABAa or adenosine Ai receptor agonists. Behav. Brain Res. 123, 23-35. 

Energy depletion and nitric oxide as a cause of the rise in adenosine... 

Nitric oxide (NO) is an intercellular signaling molecule that can inhibit neuronal energy production (Brorson et al., 1999 Malefic et al., 2004). It has been found that NO donors cause large increases in extracellular adenosine in cultures of forebrain neurons (Rosenberg et al., 2000). These were shown to be caused by NO release, and the accumulation of adenosine was not blocked by probenecid (ENT blocker) or GMP (a blocker of AMP hydrolysis), suggesting that adenosine was likely of intracellular origin. Indeed, it was found that NO donors caused a decrease in intracellular ATP and the inhibition of adenosine kinase activity, possibly due to the rise in adenosine. 

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