A Multi-Species Phenotypic Screening Assay for Leishmaniasis Drug Discovery Shows That Active Compounds Display a High Degree of Species-Specificity.

High genetic and phenotypic variability between Leishmania species and strains within species make the development of broad-spectrum antileishmanial drugs challenging. Thus, screening panels consisting of several diverse Leishmania species can be useful in enabling compound prioritization based on their spectrum of activity. In this study, a robust and reproducible high content assay was developed, and 1280 small molecules were simultaneously screened against clinically relevant cutaneous and visceral species: L. amazonensis, L. braziliensis, and L. donovani. The assay is based on THP-1 macrophages infected with stationary phase promastigotes and posterior evaluation of both compound antileishmanial activity and host cell toxicity. The profile of compound activity was species-specific, and out of 51 active compounds, only 14 presented broad-spectrum activity against the three species, with activities ranging from 52% to 100%. Notably, the compounds CB1954, Clomipramine, Maprotiline, Protriptyline, and ML-9 presented pan-leishmanial activity, with efficacy greater than 70%. The results highlight the reduced number of compound classes with pan-leishmanial activity that might be available from diversity libraries, emphasizing the need to screen active compounds against a panel of species and strains. The assay reported here can be adapted to virtually any Leishmania species without the need for genetic modification of parasites, providing the basis for the discovery of broad spectrum anti-leishmanial agents.

In vitro studies of DNA damage caused by tricyclic antidepressants: a role of peroxidase in the side effects of the drugs.

Studies show that tricyclic antidepressants prescribed for migraines, anxiety, and child enuresis have numerous adverse effects in living cells. One of the undesired outcomes observed under treatment with these drugs is DNA damage. However, the mechanisms underlying damage have yet to be elucidated. We performed in vitro studies of the DNA damage caused by four tricyclic antidepressants: imipramine, amitriptyline, opipramol, and protriptyline. We focused particularly on the DNA damage aided by peroxidases. As a model of a peroxidase, we used horseradish peroxidase (HRP). At pH 7, reactions of HRP with excess hydrogen peroxide and imipramine yielded an intense purple color and a broad absorption spectrum with the maximum intensity at 522 nm. Reactions performed between DNA and imipramine in the presence of H(2)O(2) and HRP resulted in the disappearance of the DNA band. In the case of the other three drugs, this effect was not observed. Extraction of the DNA from the reaction mixture indicated that DNA is degraded in the reaction between imipramine and H(2)O(2) catalyzed by HRP. The final product of imipramine oxidation was identified as iminodibenzyl. We hypothesize that the damage to DNA was caused by an imipramine reactive intermediate.

Biotransformation of protriptyline by filamentous fungi and yeasts.

1. The potential of various fungi to metabolize protriptyline (an extensively used antidepressant) was studied to investigate similarities between mammalian and microbial metabolism. 2. Metabolites produced by each organism were isolated by high-pressure liquid chromatography and identified by nuclear magnetic resonance and mass spectrometry. The metabolites identified in one or more fungi were 2-hydroxyprotriptyline, N-desmethylprotriptyline, N-acetylprotriptyline, N-acetoxyprotriptyline, 14-oxo-N-desmethylprotriptyline, 2-hydroxy-acetoxyprotriptyline and 3-(5-hydrodibenzo[bf][7]annulen-5-yl)propanoic acid. 3. Among 27 filamentous fungi and yeast species screened, Fusarium oxysporum f. sp. pini 2380 metabolized 97% of the protriptyline added. Several other fungi screened gave significant metabolism of protriptyline, including Cunninghamella echinulata ATCC 42616 (67%), C. elegans ATCC 9245 (17%), C. elegans ATCC 36112 (22%), C. phaeospora ATCC 22110 (50%), F. moniliforme MRC-826 (33%) and F. solani 3179 (12%). 4. F. oxysporum f. sp. pini produced phase I and phase II metabolites and thus is a suitable microbial model for protriptyline metabolism.

In pursuit of drugs for American trypanosomiasis: evaluation of some "standards" in a mouse model.

Forty-nine "standard" compounds known to be useful in the treatment of other diseases were tested for their suppressive activity against the trypomastigotes of Trypanosoma cruzi-infected mice. The most active was the antidepressant protriptyline, which was almost three times as effective as the reference drug, nifurtimox. A major value of the present data is to demonstrate the refractoriness of the T. cruzi parasite against many of the drug standards that have known biological activity.

Potent block of potassium currents in rat isolated sympathetic neurones by the uncharged form of amitriptyline and related tricyclic compounds.

1. The block of K+ currents by amitriptyline and the related tricyclic compounds cyproheptadine and dizocilpine was studied in dissociated rat sympathetic neurones by whole-cell voltage-clamp recording. 2. Cyproheptadine (30 microM) inhibited the delayed-rectifier current (Kv) by 92% and the transient current (KA) by 43%. For inhibition of Kv, cyproheptaidine had a KD of 2.2 microM. Dizocilpine (30 microM) inhibited Kv by 26% and KA by 22%. The stereoisomers of dizocilpine were equally potent at blocking Kv and KA. 3. Amitriptyline, a weak base, was significantly more effective in blocking Kv at pH 9.4 (KD = 0.46 microM) where the ratio of charged to uncharged drug was 50:50 compared with pH 7.4 (KD = 11.9 microM) where the ratio was 99:1. 4. N-methylamitriptyline (10 microM), the permanently charged analogue of amitriptyline, inhibited Kv by only 2% whereas in the same cells amitriptyline (10 microM) inhibited Kv by 36%. 5. Neither amitriptyline nor N-methylamitriptyline had a detectable effect on Kv when added to the intracellular solution. 6. It is concluded that the uncharged form of amitriptyline is approximately one hundred times more potent in blocking Kv than the charged form. However, this does not seem to be due to uncharged amitriptyline having better access to an intracellular binding site.