Purine auxotrophy: Possible applications beyond genetic marker

Exploring new drug candidates or drug targets against many illnesses is necessary as “traditional” treatments lose their effectivity. Cancer and sicknesses caused by protozoan parasites are among these diseases. Cell purine metabolism is an important drug target. Theoretically, inhibiting purine met...

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Published in:Yeast (Chichester, England) England), 2019-11, Vol.36 (11), p.649-656
Main Authors: Kokina, Agnese, Ozolina, Zane, Liepins, Janis
Format: Article
Language:English
Subjects:
Adenine
Auxotrophs
Auxotrophy
budding yeast
Cancer
Cell cycle
Cell proliferation
Drug development
Drug metabolism
Eukaryotes
evolution model
Genetic markers
Leishmaniasis
Malaria
Metabolism
Parasites
Protozoa
purine auxotrophy
Purines
Saccharomyces cerevisiae
Strains (organisms)
Supplements
Toxoplasmosis
Tropical diseases
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creator Kokina, Agnese
Ozolina, Zane
Liepins, Janis
description Exploring new drug candidates or drug targets against many illnesses is necessary as “traditional” treatments lose their effectivity. Cancer and sicknesses caused by protozoan parasites are among these diseases. Cell purine metabolism is an important drug target. Theoretically, inhibiting purine metabolism could stop the proliferation of unwanted cells. Purine metabolism is similar across all eukaryotes. However, some medically important organisms or cell lines rely on their host purine metabolism. Protozoans causing malaria, leishmaniasis, or toxoplasmosis are purine auxotrophs. Some cancer forms have also lost the ability to synthesize purines de novo. Budding yeast can serve as an effective model for eukaryotic purine metabolism, and thus, purine auxotrophic strains could be an important tool. In this review, we present the common principles of purine metabolism in eukaryotes, effects of purine starvation in eukaryotic cells, and purine‐starved Saccharomyces cerevisiae as a model for purine depletion‐elicited metabolic states with applications in evolution studies and pharmacology. Purine auxotrophic yeast strains behave differently when growing in media with sufficient supplementation with adenine or in media depleted of adenine (starvation). In the latter, they undergo cell cycle arrest at G1/G0 and become stress resistant. Importantly, similar effects have also been observed among parasitic protozoans or cancer cells. We consider that studies on metabolic changes caused by purine auxotrophy could reveal new options for parasite or cancer therapy. Further, knowledge on phenotypic changes will improve the use of auxotrophic strains in high‐throughput screening for primary drug candidates. Purine de novo synthesis pathway in all eukaryotes is functionally similar. Some medically important organisms or cell lines do not synthesize purines; forms of relapsing cancer, protozoans causing malaria, leishmaniasis, or toxoplasmosis are notorious examples. Budding yeast purine auxotrophic strains is model for purine auxotrophy in eukaryotes and can be used to screen for new drugs against cancer, protozoan infections, or instrument to find out how purine auxotrophy has emerged in the past.
doi_str_mv 10.1002/yea.3434
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Purine auxotrophic yeast strains behave differently when growing in media with sufficient supplementation with adenine or in media depleted of adenine (starvation). In the latter, they undergo cell cycle arrest at G1/G0 and become stress resistant. Importantly, similar effects have also been observed among parasitic protozoans or cancer cells. We consider that studies on metabolic changes caused by purine auxotrophy could reveal new options for parasite or cancer therapy. Further, knowledge on phenotypic changes will improve the use of auxotrophic strains in high‐throughput screening for primary drug candidates. Purine de novo synthesis pathway in all eukaryotes is functionally similar. Some medically important organisms or cell lines do not synthesize purines; forms of relapsing cancer, protozoans causing malaria, leishmaniasis, or toxoplasmosis are notorious examples. 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subjects Adenine
Auxotrophs
Auxotrophy
budding yeast
Cancer
Cell cycle
Cell proliferation
Drug development
Drug metabolism
Eukaryotes
evolution model
Genetic markers
Leishmaniasis
Malaria
Metabolism
Parasites
Protozoa
purine auxotrophy
Purines
Saccharomyces cerevisiae
Strains (organisms)
Supplements
Toxoplasmosis
Tropical diseases
title Purine auxotrophy: Possible applications beyond genetic marker
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