S-adenosylmethionine mediates glutathione efficacy by increasing glutathione S-transferase activity: implications for S-adenosyl methionine as a neuroprotective dietary supplement.

When maintained on a folate-deficient, iron-rich diet, transgenic mice lacking in apolipoprotein E (ApoE-/- mice) demonstrate impaired activity of glutathione S-transferase (GST), resulting in increased oxidative species within brain tissue despite abnormally high levels of glutathione. These mice also exhibit reduced levels of S-adenosyl methionine (SAM) and increased levels of its hydrolysis product S-adenosyl homocysteine, which inhibits SAM usage. Supplementation of the above diet with SAM restored GST activity and eliminated reactive oxygen species at the expense of stockpiled glutathione, suggesting that one or more SAM-dependent reactions were required to maintain GST activity. We examined herein the impact of SAM on GST activity using a cell-free assay. SAM stimulated GST activity in a dose-response manner when added to homogenates derived from the above ApoE-/- mice. SAM also increased activity of purified rat liver GST and recombinant GST. Filtering of SAM through a 4 kDa cutoff and systematic withholding of reaction components eliminated the possibility of any additional contaminating enzyme. These findings confirm that SAM can exert a direct effect on GST activity. Since Alzheimer's disease is accompanied by reduced GST activity, diminished SAM and increased SAH, these findings underscore the critical role of SAM in maintenance of neuronal health.

Novel approaches to plant drug discovery based on high throughput pharmacological screening and genetic manipulation.

Plants are potentially important for novel therapeutic drug leads, but the slowness of conventional methods for investigation of plants limits enthusiasm in the pharmaceutical industry. To overcome some of the drawbacks, we have applied high throughput pharmacological screening (HTPS) to crude plant extracts. Using a "differential smart screen", (DSS) the spectrum of activity contained in a crude extract is measured at several closely related receptor subtypes. This spectrum is then compared to that of known compounds. A unique spectrum suggests that the extract merits further investigation. Evaluation of species and environmental libraries of whole plants has demonstrated the value of this approach for rapid prioritization of plants for investigation. In addition, genomic and genetic manipulation of plants and plant cell cultures can increase the value of DSS. For example, the whole genomic potential of a plant species for biodiversity can be accessed by using gain of function mutations to generate a "functional genomics library" of mutant clonal cultures, and the bioactivity of these cultures tested by DSS. Clones that overproduce activity differing from the wild-type plant can be identified in this way. This "Natural Products Genomics" (NPG) strategy is limited by the massive numbers of clonal cultures that are required to cover all possible gain-of-function mutations. The rapidity and efficiency of this process can be improved by using transgenic plants expressing appropriate mammalian proteins. These may be designed to make the plant cell resemble a human cell for a specific form of toxicity. Now, "unnatural selection" of resistant mutant clones can be used to provide a sub-population potentially enriched in useful compounds. Alternatively, transgenic plant cells can be used for "in situ screening" in which a mammalian receptor protein, linked to a reporter construct, such as green fluorescent protein, is expressed. Clonal cultures that produce ligands for this receptor can now be rapidly identified visually in an ultra-HTPS. Overall, our aim is to use pharmacological screening, together with functional genomic approaches, to make plant drug discovery competitive with combinatorial chemistry.