The Effects of Nitrogen Fertilization and the Growing Season on Carbon Partitioning in a Sward of Tall Fescue (Festuca arundinacea Schreb)

The effect of N fertilization on the relative carbon partitioningto the roots of tall fescue (Festuca arundinacea Schreb ), grownunder field conditions, was studied with a ¹⁴C-labelling techniqueon three regrowths representing contrasting growing seasonsUnder non-limiting N growing conditions, the relative carbonpartitioning to the roots averaged 17.0, 15 8, and 11 1% inthe summer, autumn, and spring regrowths, respectively The relativecarbon partitioning to the roots increased during the summerand autumn regrowths but decreased during the spring regrowthIn the absence of N fertilization, the relative carbon partitioningto the roots averaged 31 3, 26 5, and 26 7 in the summer, autumn,and spring regrowths, respectively The results were interpretedin terms of a functional equilibrium between the shoots andthe roots It was concluded that, for a dense canopy of a perennialgrass growing under fluctuating conditions of solar radiationand temperature, the relative growth of the roots compared tothe relative growth of the total biomass is primarily a functionof the shoot biomass Festuca arundinacea Schreb, carbon, partitioning, nitrogen, root growth, fertilization, grass     

Economy of Symbiotically Fixed Nitrogen in Red Clover (Trifolium pratenseL.)

The seasonal dynamics of symbiotic fixation, distribution andfate of nitrogen (N) were studied on two successive crops ofred clover (Trifolium pratenseL.) grown outdoors in soil containersunder the Mediterranean climate of southern France. Nitrogenaseactivity was followed throughout the growing season using acetylene(C₂H₂) reduction assays. The distribution and transfer of symbioticallyfixed N were followed by periodic measurements of¹⁵N distributionin plants after exposure of the root systems to labelled dinitrogen(¹⁵N₂). In both years there were two peaks of nitrogenase activity,one in spring and one in late summer, separated by a sharp decreaseduring the flowering period. Over the entire growth cycle, symbioticallyfixed N accounted for 61 to 96% of the total plant N. Once weekafter incorporation, 60 to 90% of N derived from the atmospherewas recovered in the aerial parts of the plants. More than 50%of this was in the leaves, but there were differences in distributionaccording to the stage of development. The maximum percentage(20–28%) recovered from nodulated roots occurred in May–June,during maximum growth of the vegetative organs, and in September.Above-ground symbiotically fixed N was highly mobile with time,moving from the rosette leaves to the leaves attached to theelongated stems and then to the seeds, where 25 to 50% of Nfixed in May and June was recovered in September. Because of:(1) the high turnover rate of leaves; and (2) the relativelyhigh N content of dead leaves, as much as 50% of the symbioticallyfixed N in a year was potentially available to the soil micro-organismsas litter. The maximum transfer was in spring and winter. Ofthe remainder, 20 to 35% was recovered in living plant partsduring regrowth in March of the second year. Transfers to andfrom the root system were less pronounced, but significant decreasesin N content of the roots occurred early in the second yearjust after foliage regrowth was initiated. It is concluded that,because of its high foliage productivity and turnover rate,and high yield of symbiotically fixed N, red clover is a goodcandidate to provide substantial amounts of N to the soil throughoutthe year and therefore restore N fertility. Red clover; Trifolium pratenseL.; forage legumes; labelled dinitrogen (¹⁵N₂) reduction; acetylene reduction; nitrogen fixation; nitrogen distribution; nitrogen transfer