Festuca pratensis

G. Johansson, Carbon distribution in grass (Festuca pratensis L.) during regrowth after cutting-utilization of. stored and newly a.ssimilated carbon. Plant Soil I5I I (1993). [Pg.189]

P level cue (Festuca pratensis) Snowgum (Eucalyptus pauciflora) 94... [Pg.382]

G. Johansson, Relea.se of organic C from growing roots of meadow fescue (Festuca pratensis L.), Soil Biol. Biochem. 24 421 (1992). [Pg.400]

Gams W, Petrini O, Schmidt D. Acremonium uncinatum, a new endophyte in Festuca pratensis. Mycotaxon 37 67-71, 1990. [Pg.312]

Meadow fescue (Festuca pratensis) N. uncinatum Bitylenchus maximus, Flelicotylenchus sp., Trichodorus primitivus, Merlinius brevidens, Pratylenchus pratensis, P. goodeyi, P. thornei, Tylenchorhynchus dubius,... [Pg.554]

Schoberlein W, Pfannmoller M, Eggestein S, Szabova M. Investigation of interactions between Acremonium uncinatum in Festuca pratensis and various nematodes species in the soil. In Bacon CW, Hill NS, eds. Neotyphodium/Qr ss Interactions. New York Plenum Press, 1997, pp 201-203. [Pg.570]

Thomas H, Bortlik K, Rentsch D, Schellenberg M, Matile P (1989) Catabolism of Chlorophyll in vivo - Significance of Polar Chlorophyll Catabolites in a Non-Yellowing Senescence Mutant of Festuca pratensis Huds. New Phytol 111 3... [Pg.38]

Vicentini F, Hortensteiner S, Schellenberg M, Thomas H, Matile P (1995) Chlorophyll Breakdown in Senescent Leaves - Identification of the Biochemical Lesion in a Stay-Green Genotype of Festuca pratensis Huds. New Phytol 129 247... [Pg.41]

VICENTINI F, HORTENSTEINER S, SCHELLENBERG M, THOMAS H and MATTT.F. P. 1995. Chlorophyll breakdown in senescent leaves identification of the biochemical lesion on a stay-green genotype of Festuca pratensis Huds. New Phytologist 111 3-8. [Pg.282]

Bylin AG, Hume DE, Card SD, Mace WJ, Lloyd-West CM, Huss-Danell K. Influence of nitrogen fertilization on growth and loline alkaloid production of meadow fescue (Festuca pratensis) associated with the fungal symbiont Neotyphodium unci-natum. Botany—Botanique 2014 92(5) 370-5. [Pg.283]

Takai T, Sanada Y, Yamada T (2010) Influence of the fungal endophyte Neotyphodium uncinatum on the persistency and competitive ability of meadow fescue Festuca pratensis Huds.). Grassland Sci 56 59-64. doi 10.1111/j.l744-697X.2010.00175.x... [Pg.172]

Shoots of a range of grass species were toxic to other grasses and clover when decomposed anaerobically (Table VII). Ttie phytotoxicity seemed to be caused by organic acids and was less after 20 days of decomposition than after 10. Festuca rubra > Agrostis stolonifera/ and Alopecurus pratensis residues were the most toxic which to an extent is consistent with field observations that residues of the former two species are particularly difficult to seed into. When the shoots were decomposed aerobically, some were toxic after 10 days but this toxicity disappeared after 20 days when some residues could stimulate plant growth (Table VII). [Pg.50]

Christensen MJ, Leuchtmann A, Rowan DD, Tapper BA. Taxonomy of Acremonium endophytes of tall fescue (Festuca arundinacea), meadow fescue (F. pratensis), and perennial rye-grass (Lolium perenne). Mycol Res 97 1083-1092, 1993. [Pg.312]

Alopecurus pratensis, Ammophila arenaria, Arrhenatherum elatior, Dactylis sp., Festuca ovina, F. rubra, Phleurn sp., and Poa pratensis could be naturally colonized by isolates of both Gl and G2. The habitat seems to be more important, as the common occurrence of different groups in the same locality is rare. [Pg.352]

Christensen MJ. Variation in the ability of Acremonium endophytes of Lolium perenne, Festuca arundinacea and F. pratensis to form compatible associations in the three grasses. Mycol Res 99 466-470, 1995. [Pg.443]

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