Effects of soluble corn bran hemicellulose on lipid metabolism

Organophosphorous and organochlorine pesticides affect human placental phosphoinositides metabolism and PI-4 kinase activity

The objective of this work was to describe the effect of organophosphorous and organochlorine pesticides on phosphoinositides metabolism in human placenta. Pesticides concentration (10 microM) was used for in vitro incubations of cell-free homogenates labelled with (32)P orthophosphate. Heptachlor (HC) and dichloro-diphenyl-trichloroethane (o-p' DDT) increased phosphatidyl-inositol, phosphatidylinositolphosphate, and phosphatidyl-inositolbiphosphate phosphorylation while azinphosmethyl (AM) increased phosphatidylinositolbiphosphate labeling. Decreased (32)P incorporation in phosphatidylinositol was found with phosmet (PM), AM, and chlorpyriphos (CHL). The effects of these xenobiotics on PI4-kinase activity using different subcellular fractions were also examined. Both type of pesticides affected the postmembrane supernatant enzyme activity. A biphasic effect on membrane and nuclear PI4-kinase activity was seen with HC. The strongest effect found was seen with o-p' DDT in nuclear kinase activity while substantial changes were also observed in membrane. These data demonstrate the sensitivity of human placental PI4-kinase to pesticides currently found in human tissues and suggest deleterious consequences in different processes regulated by 4-phosphoinositides.

Phosphoinositide metabolism and shape control in sheep red blood cells

Metabolic depletion of sheep red blood cells leads to decreased intracellular concentrations of ATP and reduced glutathione as well as degradation of phosphoinositides. In sheep red blood cells, depletion of ATP induced two types of shape transformation: one early phase involving formation of protrusions on the cell surface similar to those observed upon depletion of human red blood cells; and one late phase, in which the sheep red blood cells develop long, rod-shaped projections. During the initial stages of shape changes, degradation of the phosphoinositides parallels the discocyte-echinocyte transformation, thus giving further support to a shape-controlling mechanism based on the bilayer-couple hypothesis. However, formation of the long projections does not coincide with turnover of the phosphoinositides but rather with the level of reduced glutathione. This indicates that development of these rod-like extensions on the cell surface is induced by oxidative processes that may well involve cross-linking of membrane skeleton proteins.