Abstract
Nucleotides are synthesized through two distinct pathways: de novo synthesis and nucleoside salvage. Whereas the de novo pathway synthesizes nucleotides from amino acids and glucose, the salvage pathway recovers nucleosides or bases formed during DNA or RNA degradation. In contrast to high proliferating non-malignant cells, which are highly dependent on the de novo synthesis, cancer cells can switch to the nucleoside salvage pathways to maintain efficient DNA replication. Pyrimidine de novo synthesis remains the target of interest in cancer therapy and several inhibitors showed promising results in cancer cells and in vivo models. In the 1980s and 1990s, poor responses were however observed in clinical trials with several of the currently existing pyrimidine synthesis inhibitors. To overcome the observed limitations in clinical trials, targeting pyrimidine salvage alone or in combination with pyrimidine de novo inhibitors was suggested. Even though this approach showed initially promising results, it received fresh attention only recently. Here we discuss the re-discovery of targeting pyrimidine salvage pathways for DNA replication alone or in combination with inhibitors of pyrimidine de novo synthesis to overcome limitations of commonly used antimetabolites in various preclinical cancer models and clinical trials. We also highlight newly emerged targets in pyrimidine synthesis as well as pyrimidine salvage as a promising target in immunotherapy.
Highlights
Academic Editors: Laura Carrassa, The essential building blocks of DNA, as well as RNA, consist of two classes of nucleotides, purines, and pyrimidines
In contrast to deoxycytidine triphosphate (dCTP) synthesis directly via ribonucleotide reductase (RNR), deoxythymidine triphosphate (dTTP) synthesis is dependent on the formation of deoxythymidine diphosphate via deoxyuridine monophosphate
DNA synthesis remains the backbone of cancer therapy besides its limitations caused by the ability of cancer cells to adapt to nucleoside salvage pathways to maintain successful DNA replication
Summary
Academic Editors: Laura Carrassa, The essential building blocks of DNA, as well as RNA, consist of two classes of nucleotides, purines, and pyrimidines. Cancer 2cells of 19 can escape pyrimidine de novo synthesis inhibition by adapting the nucleoside salvage pathways leading to unsuccessful market approval of novel compounds as well as limitations of currently used anti-cancer agents [11–13]. Discovery of targeting pyrimidine salvage to overcome observed limitations of currently Here we focus on pyrimidine synthesis in cancer therapy and discuss the recent reused anti-cancer agents and pyrimidine analogs. We highlight co-targeting discovery of targeting pyrimidine salvage to overcome observed limitations of currently of pyrimidine de novo synthesis and salvage pathways as a novel strategy in cancer therused anti-cancer agents and pyrimidine analogs. Cancer cells have frequently undergone metabolic rewiring to exploit the more energy-efficient pyrimidine salvage pathway to maintain faithful DNA replication in highly proliferating cells and, support genome integrity [1,15]
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