Abstract
Perennial (Lolium perenne L.) and annual (L. multiflorum) ryegrass are important species for landscape (e.g., turf) and agricultural (e.g., pasture systems) uses. Abiotic stresses limit the survival, growth, and/or appearance of these species. The synthesis and accumulation of quaternary ammonium compounds (QACs) such as glycinebetaine (GB) are an adaptive response to abiotic environmental stresses in some species. Both L. perenne and L. multiflorum are GB-accumulating species, and exogenous application of GB may enhance growth under less-than-optimal environmental conditions. We tested the effects of exogenous application of GB on growth and water relations of annual and perennial ryegrass growing under temperatures at the lower limits of their optimal growth. Osmotic stress resulted in increased GB accumulation in L. perenne, but exposure to cold temperatures did not result in increased GB accumulation in either species. Both species accumulated higher concentrations of GB in leaf and stem tissues when exogenous GB was supplied, regardless of growing temperature. Exogenous GB did contribute to lower osmotic potential in both species, but did not affect relative water content, although succulence was higher in some cases. Overall, exogenous GB did not affect growth under optimal growing temperatures, but did enhance growth of L. perenne growing under low temperatures.
Highlights
Annual (Lolium multiflorum) and perennial (Lolium perenne) ryegrass are important feed sources for a number of animals, and are important for their use in ornamental and sports turfs
To determine if GB is synthesized in response to abiotic stress, plants of L. multiflorum ‘Crusader’
Salinity of 100 and 150 mM NaCl and 10 d of water stress resulted in a lower relative water content (RWC)
Summary
Annual (Lolium multiflorum) and perennial (Lolium perenne) ryegrass are important feed sources for a number of animals, and are important for their use in ornamental and sports turfs. Both species are widely grown, but growth is often limited under cold spring temperatures [1]. Lolium perenne and L. multiflorum both produce proline, and production is increased in response to abiotic stresses such as drought [3,4]. Biosynthesis of the quaternary ammonium compound glycinebetaine (GB) has been reported in L. perenne [5], and GB is thought to play a role in drought tolerance in L. multiflorum [6]
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