Effects of the antidepressant/antipanic drug phenelzine on alanine and alanine transaminase in rat brain.

1. Phenelzine (PLZ) is an antidepressant with anxiolytic properties. Acute and chronic PLZ administration increase brain GABA levels, an effect due, at least in part, to an inhibition of the activity of the GABA metabolizing enzyme, GABA transaminase (GABA-T). 2. Previous preliminary reports have indicated that acute PLZ treatment also elevates brain alanine levels. As with GABA, the metabolism of alanine involves a pyridoxal phosphate-dependent transaminase. 3. In the study reported here, the effects of acute PLZ treatment on the levels of various amino acids, some of which are also metabolized by pyridoxal phosphate-dependent transaminases were compared in rat whole brain. Of the 6 amino acids investigated, only GABA and alanine levels were elevated (in a time- and dose-dependent manner). 4. The elevation in brain alanine levels could be explained, at least in part, by a time- and dose-dependent inhibitory effect of PLZ on alanine transaminase (ALA-T), although as with GABA the increases are higher than expected from the degree of enzyme inhibition produced. In addition, we also showed that the elevation in alanine levels and the inhibition of alanine transaminase in the brain are retained after 14 days of PLZ treatment, and that PLZ produces a marked increase in extracellular levels of alanine. 5. These results are discussed in terms of their relevance to synaptic function and to the pharmacological profile of PLZ.

Effects of phenelzine and imipramine on the steady-state levels of mRNAs that encode glutamic acid decarboxylase (GAD67 and GAD65), the GABA transporter GAT-1 and GABA transaminase in rat cortex.

There is an increasing body of evidence suggesting that GABA plays an important role in the therapeutic effects of antidepressant/antipanic drugs. Phenelzine and imipramine are efficacious in the treatment of depression and panic disorder and phenelzine has been reported to elevate GABA levels while imipramine enhances GABA release in rat brains. In the present study, using a multiprobe quantitative solution hybridization assay, we measured the steady-state levels of mRNAs that encode glutamic acid decarboxylase (GAD67 and GAD65), the GABA transporter GAT-1 and GABA transaminase (GABA-T) in rat cortex after treatment with constant infusion (via osmotic minipumps) of phenelzine or imipramine for a short-term (3 days) or long-term (21 days) period. We found that none of the treatments gave rise to significant changes in the steady-state levels of mRNAs encoding GAD67, GAD65 or GABA-T at any time point. The steady-state levels of GAT-1 mRNA were increased significantly (23%) after long-term, but not by short-term, treatment with phenelzine. Imipramine treatment, short- or long-term, did not alter the steady-state levels of GAT-1 mRNA. These results suggest that the GABA enhancing effects of phenelzine or imipramine in rat cortex do not affect the steady-state levels of mRNAs that encode GAD67, GAD65 and GABA-T. Further, the previously observed increases in GABA levels or GABA release induced by these drugs are probably not a consequence of changes in the expression of these genes.

The quantitative analysis of multiple mRNA species using oligonucleotide probes in an S1 nuclease protection assay.

The quantitative measurement of steady-state mRNA levels is fundamental to the analysis of gene expression. A variety of techniques are widely used to achieve this including Northern blotting, RNase protection, and S1 nuclease protection. We describe here in detail a relatively recent extension of the S1 nuclease protection technique (1) in which radiolabeled oligonucleotides are used as probes in a solution hybridization assay (2). The principle advantage of this technique is that it allows, in a single RNA sample, the simultaneous measurement of the relative levels of at least six mRNA species, including that of a control mRNA. Further, a large number of RNA samples can be analyzed at one time.

Rapid, sensitive procedure to determine buspirone levels in rat brains using gas chromatography with nitrogen-phosphorus detection.

Reported here is a rapid, sensitive and relatively inexpensive procedure using gas chromatography with nitrogen-phosphorus detection (GC-NPD) to quantify buspirone levels in brains of rats. The analyte was directly extracted from brain homogenate with toluene after basification and then subjected to GC-NPD analysis using a capillary column. The calibration curves were linear over the range of 10 to 320 ng per 2 ml of brain homogenate, with typical r2 values >0.99. The assay was highly reproducible and gave peaks with excellent chromatographic properties.

Chronic administration of antipanic drugs alters rat brainstem GABAA receptor subunit mRNA levels.

Mental illness, such as panic disorder and depression, display comorbidity as well as common therapeutic treatments. These features point toward a common etiology and/or therapeutic pathway. There is evidence to suggest that some antipanic agents may mediate their effects by altering gamma-aminobutyric acid (GABA) levels or by modulating the activity of the GABAA receptor. Chronic stimulation of GABAA receptors by agonists or modulators results in changes in the pharmacological properties of the receptor concomitant with alterations in the expression of specific GABAA receptor subunits. Therefore, we investigated the hypothesis that long-term exposure to three antidepressant/antipanic drugs (imipramine, phenelzine and alprazolam) would produce changes in the steady-state levels of those subunit mRNAs that are believed to encode the major GABAA receptor subtype. Further, these changes in gene expression would be different to those produced by the non-antipanic anxiolytic (buspirone). We report here that, following a 21 day treatment, imipramine, phenelzine, alprazolam and buspirone differentially altered rat brainstem levels of GABAA receptor alpha 1-, beta 2- and gamma 2-subunit RNAs. These results demonstrate novel actions of antidepressant/antipanic drugs on GABAergic neurotransmission.