The clinical impact of ABCB1 polymorphisms on the treatment of psychiatric diseases.

Polymorphisms in the drug transporter gene ABCB1 account for differences in the clinically efficacy of the most drugs, most likely by influencing their access to the brain. The majority proportion of depressed patients, given a regular dose, do not respond properly or experience severe side effects. One explanation may be the polymorphisms in the drug transporter gene ABCB1, which account for differences in the clinical efficacy of antidepressants, neuroleptics or mood stabilizers most likely by influencing their access to the brain. If patients are treated with a substrate of P-gp, functionally relevant genetic variants in the ABCB1 transporter could influence intracerebral drug concentrations and, thereby, clinical response. The review shows recently investigated clinical impact of ABCB1 variants including the three most important SNPs rs1045642, rs2032582, and rs2032583. In the paper, with respect not to go beyond the scope of this review, we will focus on these three SNPs. The final goal of pharmacogenetics is to help clinicians to choose the best treatment for each individual patient. >From the evidence reviewed in this publication, it is likely that combination of metabolizing and drug target polymorphisms will produce the best prediction for the selection of the optimal dose and optimal drug as a function of the individual` s genetic profile.

The anti-Parkinson drug budipine is exported actively out of the brain by P-glycoprotein in mice.

P-glycoprotein, a product of the ABCB1 gene, is a plasma membrane transporter that exports certain drugs as well as endogenous substances against a concentration gradient in the intestines, kidney and testes. It also constitutes an important part of the blood-brain barrier, where it exports its substrates out of the brain back into the circulation. To investigate whether the uptake of the anti-Parkinson drug budipine into the brain is mediated by P-glycoprotein, abcb1ab(-/-) double knock-out mice and wild-type control mice received budipine continuously over 11 days via implanted osmotic infusion pumps at the rate of 30ug over 24h. Concentrations of the drug in plasma, brain, and organs were measured with HPLC. Budipine concentrations in the abcb1ab knock-out animals were 3.1 times higher than in control mice. This study confirms the important role P-gp plays at the blood-brain barrier and shows that budipine is a substrate of P-gp.

The heat shock protein 90-targeting drug cisplatin selectively inhibits steroid receptor activation.

Cisplatin is an antineoplastic drug that binds to DNA, thereby inhibiting cell division and tumor growth. Cisplatin may also disrupt the function of some proteins, including heat shock protein 90 (Hsp90). We report that cisplatin dose-dependently inhibited transcriptional activity of the androgen receptor and the glucocorticoid receptor (GR) in transient reporter assays. A truncated, hormone-independent GR was only partially inhibited at significantly higher doses of cisplatin. Cisplatin treatment of neuroblastoma cells led to an immediate inhibition of hormone binding by GR, followed by proteasome-dependent degradation of the receptor. Other Hsp90-regulated proteins, i.e. the phosphokinases raf-1, lck, and c-src, were not affected, indicating a specific functional interference of cisplatin with the steroid receptors GR and androgen receptor. Cisplatin did not elicit a stress response, in contrast to geldanamycin. Immunoprecipitation revealed that cisplatin disrupts binding of GR to Hsp90. Moreover, cisplatin-treated Hsp90 was unable to associate with untreated ligand binding domain of GR. Reticulocyte lysate was able to restore hormone binding of GR in vitro, but not when the lysate was pretreated with geldanamycin. Our data reveal that cisplatin influences steroid receptors also independently of its DNA-mediated effects and, thus, suggest a novel modes of action for this cytostatic drug.

Essential role of the unusual DNA-binding motif of BAG-1 for inhibition of the glucocorticoid receptor.

The co-chaperone BAG-1 is involved in the regulation of steroid hormone receptors, including the glucocorticoid receptor (GR). More recently, BAG-1 was found in the nucleus where it decreases GR transactivation. Moreover, nonspecific DNA binding of BAG-1 has been reported. We discovered that of the N-terminal part of BAG-1M, the first 8 amino acids are sufficient for DNA binding, containing a stretch of three lysines and a stretch of three arginines. Changing the spacing between these stretches had no effect on DNA binding. Surprisingly, this small, nonsequence-specific DNA binding domain was nonetheless necessary for the inhibitory function of BAG-1 for GR-dependent transcription, whereas the following serine- and threonine-rich E(2)X(4) repeat domain was not. Mutational analysis of these two domains revealed that only mutants retaining DNA binding capability were able to down-regulate GR-mediated transactivation. Intriguingly, lack of DNA binding could not be functionally rescued by BAG-1M harboring a point mutation abolishing interaction with hsp70. Thus, DNA binding and hsp70 interaction are required in cis. We propose that the nonsequence-specific DNA-binding protein BAG-1 acts at specific chromosomal loci by interacting with other proteins.