Fat Utilization and Composition in Germinating Cotton Seeds.

White, Harold B.

doi:10.1104/pp.33.3.218

Cited by 13 publications

(4 citation statements)

References 15 publications

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“…This is clear from the data presented here where control of enzyme activity was achieved by raising the pH and by adding pCMB. White (19), and Crombie and Comber (6) accomplished the same purpose by boiling the seed before maceration. Ching (4) also shows a low FFA in Douglas fir seeds; in this instance it apparently was not necessary to destroy activity before maceration.…”

Section: Discussionmentioning

confidence: 99%

Lipolysis and the Free Fatty Acid Pool in Seedlings

Angelo¹,

Altschul²

1964

Plant Physiol.

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23. REUTHER, G. AND A. REICHARDT. 1963. The effects of temperature upon the bleeding and metabolism in Vitis vinifera. Planta 59: 391-410. 24. RIBEREAU-GAYON, G. AND P. RIBEREAu-GAYON. 1963. Utilisation de C1402 et de glucose U14C pour l'etude du metabolism des organiques de Vitis vinifera L. Comptes Rendus: 257: 778480. 25. RODOPULO, A. K. 1960. Oxidation-reduction transformations of the organic acids in the process of grape ripening. Biokhim. Vinodeliya 6:132-70. 26. STAFFORD, H. A. AND F. A. LOEWUS. 1958. The fixation of C1402 into tartaric and malic acids of excised grape leaves.

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Section: Discussionmentioning

confidence: 99%

Lipolysis and the Free Fatty Acid Pool in Seedlings

Angelo¹,

Altschul²

1964

Plant Physiol.

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“…During this dependency period, only about half of the seed's lipid content is used by the developing seedling. The long dependency and limited recycling of stored reserves contrasts markedly with the rapid depletion (4 to 14 d from germination) of reserve materials and the short dependency in many plants (Ching, 1963(Ching, , 1966Miller, 1938;Von Ohlen, 1931;Varner, 1965;White, 1958). During the dependency period, radicle (taproot) elongation is 20 to 25 cm before the epicotyl emerges, whereby conferring a competitive advantage in the acquisition of soil moisture during the critical germination period.…”

Section: Tree Growth and Pecan Adaptation To River Bottom Landmentioning

confidence: 99%

Adaptability of Pecan as a Species

Sparks¹

2005

HortSci

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Pecan [Carya illinoinensis (Wangenh.) C. Koch] is indigenous to the Mississippi River drainage system of the United States. Climate in the native pecan region ranges from humid to semiarid and from mild to harsh winters. Rainfall is bimodal with peaks in March to April and in August to September. Pecan is site specific and is the climax tree species on loamy, well drained, first bottom river land with a relatively high water table. Detrimental effects from pecan's shade intolerance from its more vigorous, sympatric species are minimized as these species are specific to differ sites. Pecan's deep and phreatophytic rooting habit ensures soil moisture during drought periods and facilitates pecan's survival in semiarid regions. Root development in the humus-surface layer ensures nutrient uptake from the most nutrient rich layer of the soil and, when the lower soil profile is saturated, aeration for the roots and water and nutrient uptake. The bimodal rain pattern replenishes soil profile moisture and its timing ensures seed germination, stand establishment, well-developed seed, and minimal drought stress. Natural selection for freeze tolerance and for minimum fruit development time allows survival in areas with harsh winters and short growing seasons. Regulation of seed germination and budbreak by heating and chilling results in pecan being native in cold and warm climates, greatly increasing the native range. The northern limit for pecan is dictated by heat units; the southern limit is restricted by lack of bimodal rains and vivipary. Reproductive stress is caused by the high lipid content of seed, but is counteracted by a long juvenile growth period of the seedling, by a small nut size and low percentage kernel, and by “off” production years of the tree. Nut and percentage kernel decrease as the growing season decreases which contributes to species survival in geographical regions with a short growing season. Selection for small nuts with low percentage kernel is enhanced by predators. Tree reserves are depleted by heavy production during “on” years and are replenished during “off”years. Perpetuation of pecan forests is apparently from sib/half sib seedlings following predator satiation while dissemination into new areas may be mainly by predators. Pecan and its pests successfully co-exist. Major defense against fruit feeders is escape in time, leaf feeders by biological associations and accommodation, and leaf diseases by confrontation. Heterozygous progenies from cross-pollination provide ample genetic diversity for continuous pecan selection to endure pressures imposed throughout a wide climatic range. Ecological adaptions within native pecan forests should be used in developing and maintaining commercial pecan orchards.

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“…acids produced may vary during, for example, aging of potato tuber tissue (Willemot and Stumpf [43]) or alteration of oxygen available to plants (Harris and James [14]). White (42) found that cotton seeds deplete stored linoleic and saturated acids faster than oleic whereas germinating watermelon studied by Hardman and Crombie (13) showed a relatively unspecific breakdown of stored fat.…”

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Fat Metabolism in Higher Plants

Harwood¹,

Stumpf²

1970

Plant Physiol.

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To understand more fully organelle membrane assemblage, the synthesis of the first fatty acids by the germinating pea, Pisum sativum, was studied by the incorporation of either tritiated water or acetate-1_'4C into lipids by the intact, initially dry seed. After a lag phase, labeling proceeded linearly. This lag phase ended when uptake of water had increased the seed weight to 185% of its original weight. The first fatty acids synthesized were palmitic and stearic followed shortly after by long chain saturated fatty acids (C20-C26). The synthesis of very long chain acids was consistently characteristic of several other seeds in early stages of germination. The majority of the radioactive acids were present in phospholipids and were localized in particulate fractions. The acyl components of phosphatidyl glycerol were highly labeled. (13) showed a relatively unspecific breakdown of stored fat.The use of tritiated water as a source of label for newly synthesized fatty acids provides a good alternative to the commonly used acetate. Spedding and Wilson (39) have used this isotope to study amino acid metabolism at very early stages of germination of mustard, and Foster and Katz (9) studied its incorporation into fatty acids by rat adipose tissue. Since water is intimately involved with the natural germination process, use of tritium oxide does not suffer from the criticism of using an artificial substrate. The results of its use can then be compared to the use of acetate, in case of differences.Since pea seeds are readily germinated with concomitant lipid synthesis (32), they were chosen to study the synthesis of fatty acids at very early times of germination. It is at this stage that reorganization of cell components occurs, directed to organelle formation. Thus this paper attempts to define the nature of the fatty acids and complex lipids which are synthesized by the seed as germination begins.Germination of a plant seed involves a complex series of metabolic processes such as water imbibition, respiration, nucleic acid and protein synthesis, mobilization of food reserves as well as cell differentiation and growth (33). Plant fatty acid synthesis has been studied with peas by Macey and Stumpf (32). These low lipid, high starch-containing seeds were found to incorporate acetate-1-14C into fatty acids from C16 to C28. The enzyme systems responsible for these syntheses were further studied and evidence was presented that the microsomal fraction participated in the synthesis of the very long chain fatty acids, probably from malonyl-acyl carrier protein. Either green or etiolated barley leaves also synthesized fatty acids of chain length up to C24 (17). The same authors (18) found that these acids were located in a particulate cellular fraction. Kolattukudy (28), using Brassica leaf tissue, found very long chain fatty acids produced from acetate.Partially purified enzyme preparations of fatty acid synthetase usually produced a pattern of fatty acids different from the pattern found with the endogenous fatty acid...

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Fat Utilization and Composition in Germinating Cotton Seeds.

Cited by 13 publications

References 15 publications

Lipolysis and the Free Fatty Acid Pool in Seedlings

Lipolysis and the Free Fatty Acid Pool in Seedlings

Adaptability of Pecan as a Species

Fat Metabolism in Higher Plants

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