Background: Trypanosomatids are early-diverging eukaryotes devoid of the major disulfide reductases - glutathione reductase and thioredoxin reductase - that control thiol-redox homeostasis in most organisms. These protozoans have evolved a unique thiol-redox system centered on trypanothione, a bis-glutathionyl conjugate of spermidine. Notably, the trypanothione system is capable to sustain several cellular functions mediated by thiol-dependent (redox) processes.
Scope of review: This review provides a summary of some historical and evolutionary aspects related to the discovery and appearance of trypanothione in trypanosomatids. It also addresses trypanothione's biosynthesis, physicochemical properties and reactivity towards biologically-relevant oxidants as well as its participation as a cofactor for metal binding. In addition, the role of the second most abundant thiol of trypanosomatids, glutathione, is revisited in light of the putative glutathione-dependent activities identified in these organisms.
Major conclusions: Based on biochemical and genome data, the occurrence of a thiol-redox system that is strictly dependent on trypanothione appears to be a feature unique to the order Kinetoplastida. The properties of trypanothione, a dithiol, are the basis for its unique reactivity towards a wide diversity of oxidized and/or electrophilic moieties in proteins and low molecular weight compounds from endogenous or exogenous sources. Novel functions have emerged for trypanothione as a potential cofactor in iron metabolism.
General significance: The minimalist thiol-redox system, developed by trypanosomatids, is an example of metabolic fitness driven by the remarkable physicochemical properties of a glutathione derivative. From a pharmacological point of view, such specialization is the Achilles' heel of these ancient and deadly parasites. This article is part of a Special Issue entitled Cellular functions of glutathione.
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