Mannitol is the most abundant sugar alcohol in nature, occurring in bacteria, fungi, lichens, and many species of vascular plants. Celery (Apium graveolens L.), a plant that forms mannitol photosynthetically, has high photosynthetic rates thought to result from intrinsic differences in the biosynthesis of hexitols vs. sugars. Celery also exhibits high salt tolerance due to the function of mannitol as an osmoprotectant. A mannitol catabolic enzyme that oxidizes mannitol to mannose (mannitol dehydrogenase, MTD) has been identified. In celery plants, MTD Mannitol is a six-carbon noncyclic sugar alcohol found in diverse organisms ranging from bacteria to higher plants. Mannitol is present in more than 100 species of higher plants, where it can be a significant portion of the soluble carbohydrate (1-3). For instance, celery (Apium graveolens) translocates up to 50% of its photoassimilate as mannitol, with the remainder being sucrose (4). Both translocated carbohydrates are assimilated during growth of nonphotosynthetic heterotrophic (i.e., sink) tissues. Other postulated roles for mannitol include carbon storage, free radical scavenging, and osmoprotection (4-7).The use of mannitol as a photoassimilate and translocated carbohydrate is reported to be advantageous to the plant in several ways. Celery, a C3 plant, has carbon fixation rates equivalent to those of many C4 plants (8). This may result from both increased NADP/NADPH turnover compared to plants that exclusively form sugars and from the additional cytosolic sink for photosynthetically fixed CO2 provided by mannitol synthesis (7,9,10). In addition to the increased carbon fixation that accompanies mannitol biosynthesis, the initial step of mannitol utilization generates NADH, thus giving a higher net ATP yield than the catabolism of an equal amount of sucrose (7). Finally, mannitol-producing plants also exhibit a high degree of salt tolerance due to the function of mannitol as an osmoregulator and compatible solute (6,11,12). Celery plants grown in hydroponic culture with a salinity equivalent to 30% that of sea water show dry weight gains equal to plants grown at normal nutrient levels (12). In addition, tobacco that was genetically engineered to synthesize mannitol through the introduction of the Escherichia coli NAD-dependent mannitol-1-phosphate dehydrogenase acquired significant salt tolerance (6).Metabolite pool sizes in plants are usually determined by relative rates of synthesis and utilization. The isolation and characterization of a plant NAD-dependent mannitol dehydrogenase (MTD), the enzyme responsible for the oxidation of mannitol to mannose in celery, was reported by our laboratory (13). MTD is a monomeric mannitol:mannose 1-oxidoreductase with a molecular mass of "40 kDa (13,14). In celery plants, the expression of MTD is highly regulated. MTD activity is highest in young actively growing root tips, is also high in young rapidly growing (sink) leaves, but is not detected in mature photosynthetic (source) leaves. Extractable MTD activity ...
