The protocols presently established for optimum seed storage do not account for the chemical composition of different seed species, the physiological status of the seed, and the physical status of water within the seed. The physiological status of seeds from five species with varying chemical compositions was determined by measurements of rates of oxygen uptake and seed deterioration. The physical status of water was determined by water sorption characteristics. For each species studied, there was a specific moisture content for the onset of respiration, chemical reactions, and accelerated aging rates. The moisture contents at which these physiological levels were observed varied among the species and correlated with the lipid content of the seed. However, the changes in physiological activifies and the physical status of water occurred at specific relative humidities: 91% for the onset of respiration, 27% for the increased rates of thermal-chemical reactions, and 19% for optimum longevity. Based on these observations, we propose that equilibrating seeds between 19 and 27% relative humidity provides the optimum moisture level for maintaining seed longevity during longterm storage.mendations of the IBPGR (3). Based on limited empirical information, calculations from the viability equations, and practical considerations, the IBPGR recommends that seeds be stored at moisture contents between 3 and 7%, depending on the seed (10). For seeds with poor storage characteristics, further drying may be recommended (3, 5, 7). Unfortunately, these recommendations do not aid the gene bank operator in determining the optimal moisture content for storage of a particular seed species, cultivar, or lot.A more theoretical approach to the study of the effect of water content on seed deterioration would alleviate some of the intrinsic difficulties of a strictly empirical approach. Protocols developed from physical principles will obviate the need to determine optimal conditions for each species, varying cultivars within a species, and specific tissues within an individual seed.Intuitively While scientists have known for many years that dry, cold conditions will increase shelf life of biological material, the optimum moisture level and temperature are poorly understood. Since studies of the optimal environment for storage are intrinsically difficult because they take years, scientists have relied on experiments of seed aging under less optimal conditions and then extrapolated beyond their data. Based on these empirical data, equations have been derived to predict the rate of seed deterioration under various conditions (6,21). The assumption of these equations has been that the effect of water content on the rate ofseed deterioration is a logarithmic relationship and thus, the drier the tissue is, the longer it will maintain viability (5-7).The viability equations are the basis of the storage recom-1019 where k2 is proportional to the rate of a reaction, Z is a coefficient related to the rate of molecular collisions, Ea is the...
