Dormancy and Impotency of Cocklebur Seeds

Esashi, Yohji; Katoh, Hajime; Leopold, A. C.

doi:10.1104/pp.59.2.117

Cited by 22 publications

(7 citation statements)

References 15 publications

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“…We have suggested that the plant hormones may exert their primary actions by stimulating the growth of an embryonic axis rather than by supplying hydrolysates (11). The above mentioned facts obtained in the experiments about cocklebur seed germination suggest the plausibility of the latter view.…”

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confidence: 51%

“…Of the factors listed in Table III, enriched 02, high temperature, BA, and thiourea were effective to break cocklebur seed dormancy and to increase cotyledon enlargement, whereas GA3 and KNO3 were not effective to break the dormancy but promotive to the enlargement. IAA was ineffective on both (11).…”

Section: And Discussionmentioning

confidence: 98%

“…the cotyledons to restore the Chl formation. Therefore, several experiments were designed to examine the effects on the cotyledon greening of many diverse factors and reagents which accelerate the loss of the cocklebur seed dormancy and hence initiate the enlargement of the dormant cotyledons (11).…”

Section: And Discussionmentioning

confidence: 99%

“…Cytokinins and thiourea, besides C2H4, are able to release the dormancy of cocklebur seeds by restoring the growth of both the dormant embryonic axis and cotyledons (11). However, GA3 and KNO3, which were often effective to break dormancy in other seeds (2,29), failed to terminate the dormancy of cocklebur seeds, since they were incapable of causing the axial growth which played a leading role in rupturing the testa, although slightly capable of restoring the cotyledonary growth (11).…”

mentioning

confidence: 99%

“…However, GA3 and KNO3, which were often effective to break dormancy in other seeds (2,29), failed to terminate the dormancy of cocklebur seeds, since they were incapable of causing the axial growth which played a leading role in rupturing the testa, although slightly capable of restoring the cotyledonary growth (11).…”

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confidence: 99%

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Dormancy and Impotency of Cocklebur Seeds

Esashi¹,

Katoh²,

Hata³

et al. 1977

Plant Physiol.

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Dormant seeds of cocklebur (Xanthium pennsylvanicum Walir.) were characterized by the lack of ability to form chlorophyll. Such an inability of cotyledons of the dormant seeds was improved by the application of various factors and reagents which were capable of breaking the dormancy and of increasing cotyledon enlargement. Of these, ethylene, benzyladenine, and high temperature treatments were particularly effective, and, in turn, oxygen enrichment, gibbereHlic acid, thiourea, carbon doxide, and potassium nitrate were also promotive to the greening of the dormant cotyledons. The effects of benzyladenine, oxygen enrichment, and high temperature were reduced in the presence of absorbents for endogenously evolve carbon dioxide and ethylene. &-Aminolevulinic acid could not restore their greening ability.In dicotyledonous seeds, not only a growing embryonic axis but also a pair of enlarging cotyledons are responsible for rupture of testa on germination (8, 9). It has also been demonstrated that the dormancy of the seeds is due to the inability of both the axis and cotyledons to grow (8). The dormancy of cocklebur seeds is characterized by the lack of the aerobic C2H4 production in them (13,19) and is broken by C2H4 applied exogenously, which is capable of restoring their growth (8).Cytokinins and thiourea, besides C2H4, are able to release the dormancy of cocklebur seeds by restoring the growth of both the dormant embryonic axis and cotyledons (11). However, GA3 and KNO3, which were often effective to break dormancy in other seeds (2, 29), failed to terminate the dormancy of cocklebur seeds, since they were incapable of causing the axial growth which played a leading role in rupturing the testa, although slightly capable of restoring the cotyledonary growth (11).Concerning the possible actions of plant hormones in breaking seed dormancy or in accelerating seed germination, there have been the two views that, first, they may act by stimulating the biosynthesis of hydrolysis enzymes (2, 29); and second, the contrary is the case in which the primary action of GA3 may not be the activation of de novo synthesis of hydrolysis enzymes, such as amylase (7) and protease (6). We have suggested that the plant hormones may exert their primary actions by stimulating the growth of an embryonic axis rather than by supplying hydrolysates (11). The above mentioned facts obtained in the experiments about cocklebur seed germination suggest the plausibility of the latter view. Furthermore, the growth inability of the axis and cotyledons of dormant cocklebur seeds implies that seed dormancy is due to the arrest of activity not only of catabolic reaction processes in these tissues but also of anabolic reaction I Present address: Department of Biology, Miyagi University of Education, Aobayama, Sendai 980, Japan.processes. In the dormant cotyledons, the arrested anabolic processes may be symbolized by the failure of Chl biogenesis and chloroplast development, and the various factors which are capable of breaking seed dormancy may pe...

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confidence: 51%

Section: And Discussionmentioning

confidence: 98%

Section: And Discussionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Dormancy and Impotency of Cocklebur Seeds

Esashi¹,

Katoh²,

Hata³

et al. 1977

Plant Physiol.

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Plant Growth Hormones in Plants under Low-Temperature Stress: A Review

Bhattacharya

2022

Physiological Processes in Plants Under Low Temperature Stress

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Regulation of NH4 + uptake in wheat plants: Effect of root ammonium concentration and amino acids

Causin

Barneix

1993

Plant Soil

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When N deficient 10-day-old wheat plants were supplied with 1.5 mol m -3 NH 4, net NH 4 uptake rapidly decreased during the first 6h, while root free-NH4 and free amino acids concentration increased. However, after 24 h the NH~-uptake rate increased again, as the internal NH4 concentration decreased. When plants were pretreated during 40 h with different external NH 4 concentrations, net uptake measured on 1.0 mol m -3 NH 4 decreased with the increasing ion concentration during the + pretreatment. This decrement coincided with both root free-NH 4 and total free amino acids levels. When N-starved and NH 4 fed plants were treated during 0, 3 or 6 h with 1.0 molm -3 NH 4 in the presence of 1.0 mol m -3 MSX 2, net uptake (measured without MSX) decreased with the length of the inhibitor treatment. In both groups, MSX significantly increased root free-NH 4 concentration, while the level of total free amino acids was only increased in N-starved plants. When N-starved plants were externally supplied with 1.0 mol m -3 of different amino acids or amides, net NH~-uptake was only strongly inhibited in the presence of glutamine or asparagine. It is concluded that rapid changes in the concentration of certain amino acids during NH 4 nutrition might regulate the ion absorption, though at high endogenous levels of free NH 4 net uptake could be suppressed independently of the root concentration of free amino acids.Abbreviations: AUR, ammonium uptake rate; MSX, L-methionine sulphoximine

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Dormancy and Impotency of Cocklebur Seeds

Cited by 22 publications

References 15 publications

Dormancy and Impotency of Cocklebur Seeds

Dormancy and Impotency of Cocklebur Seeds

Plant Growth Hormones in Plants under Low-Temperature Stress: A Review

Regulation of NH4 + uptake in wheat plants: Effect of root ammonium concentration and amino acids

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