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W. Beversdorf, D. Hume, M. Daonnelly-Vanderloo (1988)
Agronomic Performance of Trianzine‐Resistant and Susceptible Reciprocal Spring Canola HybridsCrop Science, 28
H. Darmency, J. Pernès (1985)
Use of wild Setaria viridis (L.) Beauv. to improve triazine resistance in cultivated S. italica (L.) by hybridizationWeed Research, 25
Conard Conard, Radosevich Radosevich (1979)
Ecological fitness of Senecio vulgaris and Amaranthus retroflexus biotypes susceptible or resistant to atrazineJournal of Applied Ecology, 16
A. Mattoo, J. Marder, M. Edelman (1989)
Dynamics of the photosystem II reaction centerCell, 56
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Reduced growth, competitiveness, and photosynthetic efficiency of triazine-resistant Senecio vulgaris from California.Journal of Applied Ecology, 25
J. Gressel, G. Ben-Sinai (1985)
Low intraspecific competitive fitness in a triazine-resistant, nearly nuclear-isogenic line of Brassica napusPlant Science, 38
J. Hart, A. Stemler (1990)
Similar Photosynthetic Performance in Low Light-Grown Isonuclear Triazine-Resistant and -Susceptible Brassica napus L.Plant physiology, 94 3
J. Hart, A. Stemler (1990)
High Light-Induced Reduction and Low Light-Enhanced Recovery of Photon Yield in Triazine-Resistant Brassica napus L.Plant physiology, 94 3
J. Holt, S. Radosevich (1983)
Differential Growth of Two Common Groundsel (Senecio vulgaris) BiotypesWeed Science, 31
J. Bowes, A. Crofts, C. Arntzen (1980)
Redox Reactions on the reducing side of photosystem II in chloroplasts with altered herbicide binding properties.Archives of biochemistry and biophysics, 200 2
J. Hirschberg, L. Mcintosh (1983)
Molecular Basis of Herbicide Resistance in Amaranthus hybridusScience, 222
W. Beversdorf, J. Weiss-Lerman, L. Erickson, V. Machado (1980)
TRANSFER OF CYTOPLASMICALLY-INHERITED TRIAZINE RESISTANCE FROM BIRD'S RAPE TO CULTIVATED OILSEED RAPE (BRASSICA CAMPESTRIS AND B. NAPUS)Canadian journal of genetics and cytology, 22
W. Beversdorf, D. Hume (1984)
OAC TRITON SPRING RAPESEEDCanadian Journal of Plant Science, 64
W. Ahrens, E. Stoller (1983)
Competition, Growth Rate, and CO2 Fixation in Triazine-Susceptible and -Resistant Smooth Pigweed (Amaranthus hybridus)Weed Science, 31
E. Hanecker, J. Moll, H. Nöth (1984)
Metalltetrahydridoborate und Tetrahydridoborato-metallate, 12 [1] Zur Kenntnis von Calcium-bis(tetrahydridoborat)-bis(dimethylglykolether)/Metal Tetrahydroborates and Tetrahydroborato Metalates, 12 [1] On Calcium Bis(tetrahydroborate)-bis(dimethylglycolether)Zeitschrift für Naturforschung B, 39
Wolber Wolber, Steinback Steinback (1984)
Identification of the herbicide binding region of the O b protein by photoaffinity labeling with azidoatrazineZeitschrift für Naturforschung, 39c
M. Schönfeld, T. Yaacoby, O. Michael, B. Rubin (1987)
Triazine Resistance without Reduced Vigor in Phalaris paradoxa.Plant physiology, 83 2
Jansen Jansen, Hobe Hobe, Wesselius Wesselius, Rensen Rensen (1986)
Comparison of photosynthetic activity and growth performance in triazine‐resistant and susceptible biotypes of Chenopodium albumPhysiologic Végétale, 24
W. McCloskey, J. Holt (1990)
Triazine Resistance in Senecio vulgaris Parental and Nearly Isonuclear Backcrossed Biotypes Is Correlated with Reduced Productivity.Plant physiology, 92 4
A. Stowe, Jodie Holt (1988)
Comparison of Triazine-Resistant and -Susceptible Biotypes of Senecio vulgaris and Their F(1) Hybrids.Plant physiology, 87 1
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Souza Machado Souza Machado, Ali Ali, Shupe Shupe (1983)
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B. Velthuys (1982)
1 – The Function of Plastoquinone in Electron Transfer
Summary: Résumé: Zusammenfassung Growth and biomass allocation of nearly isonuclear lines of triazine‐resistant and susceptible rapeseed (Brassica napus L.) were compared. Resistant and susceptible lines produced by reciprocal crossing were grown in a greenhouse and in growth chambers under high and low photon flux densities (PFD). Thirty to forty per cent greater average dry weight accumulation was observed in susceptible lines grown under high PFD. Higher leaf area ratio, lower root‐shoot ratio and lower specific leaf weight were observed in resistant lines grown in high PFD. These morphological modifications are consistent with a mechanism of compensation of lower photosynthetic performance. Little difference in dry weight and biomass allocation was seen in resistant and susceptible plants grown under low PFD. The similarity in growth response observed in susceptible and resistant plants grown under low PFD indicates the inefficient photochemistry in resistant plants does not necessarily result in lower productivity. Influence de l'intensite lumineuse sur la croissance de colza (Brassica napus L.) resistant aux triazines La croissance et la répartition de la biomasse de 2 lignées isonucléaires voisines de colza résistant et sensible aux triazines ont été comparées. Des lignées sensibles et résistantes produites par fertilisation croisée ont été cultivées dans une serre et en chambres climatiques sous des densités de flux de photon (PFD) hautes et faibles. Trente à quarante pour cent de plus dans 1'accumulation de la matière sèche ont été observées chez les lignées sensibles cultivées sous hauts PFD. Un ratio plus important de la surface foliaire, un ratio plus bas racine/tige et un poids spécifique foliaire plus faible ont été observées chez les lignées résistantes cultivées sous hauts PFD. Ces modifications morphologiques sont liées avec un mécanisme de compensation du rendement photosynthétique plus faible. Une faible différence dans le poids sec, et la répartition de la biomasse a été observed entre les plantes sensibles et résistantes cultivées sous faibles PFD. La similitude de la croissance observée chez les plantes sensibles cultivées sous faibles PFD montre que la déficience photochimique chez les plantes résistantes ne résulte pas nécessairement en une productivité plus faible. Einfluß der Lichtintensität auf das Wachstum von Triazin‐resistentem Raps (Brassica napus L.) Das Wachstum und die Biomassebildung von fast reinen Linien von Triazin‐resistentem und von ‐empfindlichem Raps wurden vergleichen. Durch Kreuzbefruchtung wurden resistente und empfindliche Linien gewonnen, die im Gewächshaus und Phytotron unter hoher und niedriger Lichtintensität gezogen wurden. 30–40% höhere mittlere Trockenmasse wurden bei hoher Lichtintensität bei den empfindlichen Linien festgestellt. Ein höherer Blattflächenindex, ein kleineres Wurzel/Sproß‐Verhältnis und ein geringeres spezifisches Blattgewicht wurden bei hoher Lichtintensitaät bei den resistenten Linien gefunden. Diese morpholo‐gischen Veränderungen stimmen mit einem Mechanismus zur Kompensation geringerer Photosynthese überein. Bei niedriger Lichtintensität gab es nur kleine Unterschiede in der Trockenmasse‐ und Biomassebildung zwischen den resistenten und den empfindlichen Pflanzen, worin sich zeigt, daß der ineffiziente Photochemismus der resistenten Pflanzen nicht notwendigerweise zu einer geringeren Produktivität führen muß.
Weed Research – Wiley
Published: Oct 1, 1992
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