In common with other zwitterionic quaternary ammonium compounds (QACs), glycine betaine acts as an osmoprotectant in plants, bacteria, and animals, with its accumulation in the cytoplasm reducing adverse effects of salinity and drought. For this reason, the glycine betaine biosynthesis pathway has become a target for genetic engineering of stress tolerance in crop plants. Besides glycine betaine, several other QAC osmoprotectants have been reported to accumulate among flowering plants, although little is known about their distribution, evolution, or adaptive value. We show here that various taxa of the highly stress-tolerant family Plumbaginaceae have evolved four QACs, which supplement or replace glycine betaine-namely, choline 0-sulfate and the betaines of (-alanine, proline, and hydroxyproline. Evidence from bacterial bioassays demonstrates that these QACs function no better than glycine betaine as osmoprotectants. However, the distribution of QACs among diverse members of the Plumbaginaceae adapted to different types of habitat indicates that different QACs could have selective advantages in particular stress environments. Specifically, choline 0-sulfate can function in sulfate detoxification as well as in osmoprotection, 13-alanine betaine may be superior to glycine betaine in hypoxic saline conditions, and proline-derived betaines may be beneficial in chronically dry environments. We conclude that the evolution of osmoprotectant diversity within the Plumbaginaceae suggests additional possibilities to explore in the metabolic engineering of stress tolerance in crops.Abiotic stresses such as drought and salinity are the major constraints to crop yield (1), and more sources of genes for tolerance to them are needed (2-4). When such genes occur in crops or in closely related wild species, they can be exploited by traditional breeding techniques (3, 4). A much wider potential pool of genes is now available: genetic engineering makes it possible to use any organism as a source of simple adaptations to abiotic stresses (5, 6). This has led to much interest in stress adaptations that may be controlled by one or a few genes.One such adaptation to dry and saline conditions is the accumulation of osmoprotectants (7). Unlike most solutes, osmoprotectants stabilize proteins and membranes when present at high concentrations and so can be used to raise cytoplasmic osmotic pressure in stressed cells without deleterious effects (7, 8). Betaines and other zwitterionic quaternary ammonium compounds (QACs) are very effective osmoprotectants, and several occur in diverse taxa of flowering plants (Table 1 and ref. 9). Glycine betaine is the most widespread of these; it is the only one for which biosynthetic enzymes and genes have been isolated (10, 11) and the onlyThe publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact. one so far targeted for metabolic engineering (1...
