Access the full text.
Sign up today, get DeepDyve free for 14 days.
W. Davies, Jianhua Zhang (1991)
Root Signals and the Regulation of Growth and Development of Plants in Drying Soil, 42
T. Wehner, E. Gritton (1981)
Horticultural Evaluation of Eight Foliage Types of Peas Near-isogenic for the Genes af, tl and st1Journal of the American Society for Horticultural Science
(2003)
Morphometry and Physiology of Near-Isogenic Lines of Pisum sativum L. with Different Leaf Morphology, Tr. V Mezhd. simp. “Novye i netraditsionnye rasteniya i perspektivy ikh ispol’zovaniya
(1950)
Regeneratsiya rastenii (Plant Regeneration)
E.M. Kof, I.V. Kondykov, E.S. Chuvasheva, M.A. Krasnova, I.A. Vinogradova, A.S. Oorzak (2001)
Genetic Collections, Isogenic and Alloplasmic Lines
V.V. Khangil’din (1990)
Genetika kul’turnykh rastenii: zernobobovye, ovoshchnye, bakh-chevye
(1989)
Ecology of Water Metabolism, Vodnyi obmen rastenii (Plant Water Relations)
E.M. Kof, A.S. Oorzhak, I.A. Vinogradova, Z.V. Kalibernaya, I.V. Kondykov, E.S. Chuvasheva (2003)
Tr. V Mezhd. simp. “Novye i netraditsionnye rasteniya I perspektivy ikh ispol’zovaniya”
E. Smolders, R. Merckx (1992)
Growth and shoot:root partitioning of spinach plants as affected by nitrogen supplyPlant Cell and Environment, 15
K. Gould, E. Cutter, J. Young (1986)
Morphogenesis of the compound leaf in three genotypes of the pea, Pisum sativumBotany, 64
(2004)
Genetics and Selection of Legumes–Rhizobia Symbiosis, Tez. 3go s”ezda “Genetika v XXI veke: sovremennoe sostoyanie i perspektivy razvitiya
D. Richards, R.N. Rowe (1977)
Effects of Root Restriction upon Peach SeedlingsAnn. Bot. (London), 41
T. Pustovoĭtova, I. Drozdova, N. Zhdanova, V. Zholkevich (2003)
Leaf Growth, Photosynthetic Rate, and Phytohormone Contents in Cucumis sativus Plants under Progressive Soil DroughtRussian Journal of Plant Physiology, 50
J. Hofer, T. Ellis (1998)
The genetic control of patterning in pea leavesTrends in Plant Science, 3
(1963)
Fiziologiya razvitiya rastenii (Physiology of Plant Development)
(2001)
Reproduction and Evaluation of Some Foliage Types of Peas Near-Isogenic for Genes Af and Tl, Genetic Collections, Isogenic and Alloplasmic Lines, Novosibirsk: Siberian Branch Russ
O. White
Studies of Inheritance in Pisum. II. The Present State of Knowledge of Heredity and Variation in Peas, 56
(1953)
Felderbse bei welcher die Ganz Blattspreite in Ralken Umbewandelt Ist
H. Lichtenthaler (1996)
Vegetation stress : an introduction to the stress concept in plantsJournal of Plant Physiology, 148
(1982)
Mekhanizmy regeneratsii rastenii (Mechanisms of Plant Regeneration), Rostov-on-Don: Rostov
J.B. Passioura (1988)
Root Signals Control Leaf Expansion in Wheat Seedlings in Drying SoilAust. J. Plant Physiol., 15
N.P. Krenke (1950)
Regeneratsiya rastenii
D. Richards, R. Rowe (1977)
Effects of Root Restriction, Root Pruning and 6-Benzylaminopurine on the Growth of Peach SeedlingsAnnals of Botany, 41
D.A. Sabinin (1963)
Fiziologiya razvitiya rastenii
P.S. Slavnyi (1989)
Vodnyi obmen rastenii
V. Polevoĭ (2001)
The Physiology of Plant IntegrityRussian Journal of Plant Physiology, 48
W. Jeschke, W. Hartung (2000)
Root-shoot interactions in mineral nutritionPlant and Soil, 226
I. Johnson, J. Melkonian, J. Thornley, S. Riha (1991)
A model of water flow through plants incorporating shoot/root ‘message’ control of stomatal conductancePlant Cell and Environment, 14
J. Passioura (1988)
Root signals control leaf expansion in wheat seedlings growing in drying soilAustralian Journal of Plant Physiology, 15
(1980)
Chailakhyan, M.Kh., Organism Integrity in the World of Vegetables, Fiziol
I. Goldman, E. Gritton, P. Flannery (1992)
Evaluation of the afila-tendriled acacia (afaf-tactac) pea foliage type under minimal competitionCrop Science, 32
(1958)
New Pea Cultivars
M.Kh. Chailakhyan (1980)
Organism Integrity in the World of VegetablesFiziol. Rast. (Moscow), 27
A.G. Yusufov (1982)
Mekhanizmy regeneratsii rastenii
N. Mishra, B. Mallick, S. Sopory (2001)
Electrical signal from root to shoot in Sorghum bicolor: induction of leaf opening and evidence for fast extracellular propagation.Plant science : an international journal of experimental plant biology, 160 2
L.B. Vysotskaya, L.N. Timergalina, T.N. Arkhipova, A.V. Dedov, G.R. Kudoyarova (2000)
Immunoanaliz regulyatorov rosta v reshenii problem fiziologii rastenii, rastenievodstva i biotekhnologii
(1990)
Genetic Features in Pea, Genetika kul’turnykh rastenii: zernobobovye, ovoshchnye, bakhchevye (Genetics of Crops: Leguminous Plants, Vegetables, and Cucurbitaceous)
Isogenic lines of pea (Pisum sativum L.) with the genetically determined changes in leaf morphology, afila (af) and tendril-less (tl), were used to study the relationship between shoot and root growth rates. The time-course of shoot and root growth was followed during the pre-floral period in the intact plants grown under similar conditions. The af mutation produced afila leaves without leaflets, whereas in the case of the tl mutations, tendrils were substituted with leaflets, and acacia-like leaves were developed. Due to the changes in leaf morphology caused by these mutations, pea genotypes differed in leaf area: starting from day 7, the leaf area was lower in the af plants and larger in the tl plants as compared to the wild-type plants. Such divergence was amplified in the course of plant development and reached its maximum immediately before the transition to flowering. Plants of isogenic lines did not notably differ in stem surface areas. In spite of significant difference in total leaf area, the wild type and tl plants did not differ in leaf dry weight. Starting from leaf 9, the af plants lagged behind two leaflet-bearing genotypes (wild type and tl) in leaf dry weight, whereas stem dry weight was similar in the wild type and tl forms and slightly lower in the af plants. Root dry weights were practically similar in the wild type and tl plants until flowering. The reduction of leaf area in the af plants drastically reduced root dry weight. In other words, the latter index was related to the total weight and total area of leaves and stems. The correlation analysis demonstrated an extremely low relationship between leaf and stem area and dry weight and those of roots early in plant development (when plants develop five to seven leaves). Later, immediately before flowering (nine to eleven leaves), root weight was positively related to leaf weight and area; however, stem area and root weight did not correlate. Thus, in three genotypes (wild type, af, and tl), at the end of their vegetative growth phase, leaf and root biomass accumulated in proportion, independently of leaf area expansion.
Russian Journal of Plant Physiology – Springer Journals
Published: Feb 24, 2006
Access the full text.
Sign up today, get DeepDyve free for 14 days.