Translocation and metabolism of glycine betaine in nodulated alfalfa plants subjected to salt stress

The fate of radioactive glycine betaine was investigated in 31-day-old alfalfa ( Medicago sativa L. cv Europe) plants nodulated by Rhizobium meliloti 102 F 34. Radioactive [methyl-¹⁴C]- or [1,2-¹⁴C]glycine betaine was fed for 6 h to plants subjected or not to stress by 0.2 M NaCl. A 36% decrease in glycine betaine uptake was observed in salinized plants. No loss of radioactivity in the gas phase or the growth medium was ever observed from either stressed or unstressed plants, even after a 4-day chase period. Glycine betaine catabolism was negligible in shoots of both control and salinized plants, but it was important in roots and even more significant in nodules of unstressed plants. In unstressed nodules, 52% of the labelled betaine was metabolized after 4 days, and the half-life of glycine betaine was estimated at ca 4 days. On the contrary, catabolism was dramatically reduced in stressed roots and, particularly, nodules in which the half-life of glycine betaine increased to at least 16 days. Analysis of the redistribution of radioactivity among plant organs during the chase period shows that glycine betaine was translocated from the roots to the nodules of salinized plants, so that during this period salinization resulted in a 91% increase in nodule radioactivity, whereas a 34% decrease was observed in control plants. Altogether, reduced catabolism and increased translocation of glycine betaine to stressed nodules favored its accumulation in these organs. The high level of glycine betaine might contribute to maintain a better water status in the nodule and, thus, protect the nitrogen fixation activity against the deleterious effects of elevated osmolarity in the nutrient solution.