Copper cells with complexing agents

Bleomycins and their analogues occur naturally as blue copper chelates. Removal of the copper by chemical reduction or complexing agents affords the antibiotics as white solid.s. Copper-free bleomycin is the active. species for chemotherapy, and it has lower toxicity. Bleomycin complexes readily with metal ion.s. which is a key factor in its mode of action. In.sidc the cell, bleomycin forms a chclatc with Fe(ll) that has square pyramidal gcomctiy. Nitrogen atoms from bleomycin occupy five of the po.sitions in this structure. The sixth position may be occupied by the carboxyl group of the carhamate function, but this group is... 

The transport of substances between the inside and outside of red cells can be monitored using NMR if the resonances from the two environments have different chemical shifts or intensities. Also, resonances outside the cell can be selectively broadened by the addition of paramagnetic species that do not cross the red cell membrane. Those used include the ferric complex of desferrioxamine, dysprosium-DTPA and the copper-cyclohexanediaminetetraacetic acid complex. To measure the rate of influx of a compound into red cells, the compound is added with the paramagnetic agent to a red cell suspension and the intensity of the resonance from the intracellular component is monitored as a function of time. This approach has been used to study the transport of glycerol, alanine lactate, choline and glycylglycine. The time scale that can be addressed covers the range of ms to hours. 

There are several such toxic agents that cause considerable medical, public and political concern. Two examples are discussed here the heavy metal ions (e.g. lead, mercury, copper, cadmium) and the fluorophosphonates. Heavy metal ions readily form complexes with organic compounds which are lipid soluble so that they readily enter cells, where the ions bind to amino acid groups in the active site of enzymes. These two types of inhibitors are discussed in Boxes 3.5 and 3.6. There is also concern that some chemicals in the environment, (e.g. those found in industrial effluents, rubbish tips and agricultural sprays), although present at very low levels, can react with enhanced reactivity groups in enzymes. Consequently, only minute amounts concentrations are effective inhibitors and therefore can be toxic. It is suggested that they are responsible for some non-specific or even specific diseases (e.g. breast tumours). 

Powell (1946) and Mason (1948) found that the 2 1 complex of 8-hydroxyquinoline with copper, oxine-copper, has a stronger fungicidal action than 8-hydroxyquinoline. Albert et al. (1953) attributed this to the fact that the organic part of the compound makes copper lipoid-soluble and thus accelerates its penetration into the cell. Inside the cell the 2 1 complex dissociates into a 1 1 complex and free 8-hydroxyquinoline. The active toxic agent is the ionised 1 1 complex of nonlipoid properties, which reacts with the enzymes in the fungus and blocks their function. This theory is also supported by the research work of McNew and Gershon (1969). 

However, Oberley and Buettner pointed out that all tumour cell lines have markedly decreased superoxide dismutase activity [355]. The marked decrease in manganese-dependent SOD activity is consistent with a decrease in aerobic metabolism and a decrease or only a modest increase in Cu-Zn SOD activity is consistent with an impaired response leading to transformation. As a result of the observed lowered SOD activities in tumour cells and an awareness of the SOD-mimetic activity of copper salicylate complexes, salicylate and other copper complexes were investigated as antitumour agents. 

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