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Physiological gradients in citrus fruits
Authors
A. R. C. HaasL. J. Klotz
Authors Affiliations
A. R. C. Haas was Associate Plant Physiologist in the Experiment Station; L. J. Klotz was Associate Plant Pathologist in the Experiment Station.Publication Information
Hilgardia 9(3):179-217. DOI:10.3733/hilg.v09n03p179. January 1935.
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Abstract
Abstract does not appear. First page follows.
Introduction
The various portions of citrus fruits, particularly the regions near the calyx and stylar ends, differ not only in their morphology but also in their physical and chemical characters. The active acidity of various organs of plants forms a gradient that has been given considerable attention by Haas,(11) Gustafson,(9), (10) and Hurd-Karrer.(17),(18) The present paper presents evidence of the existence of physical and chemical differences and gradients in citrus and other fruits, and attempts to explain these differences in citrus fruits by a consideration of the structure and function of the parts concerned.
The functions of the vascular system of plants are support, and the conduction and distribution of solutes. Soluble materials that remain in the vascular stream after lateral absorption by the cells adjacent to the tracheal tubes, concentrate in the tissues near the terminals of the vascular strands. Cells in this region necessarily receive the surplus of the solutes. The location of these terminals is not always easily recognized because of branching and anastomosing, but the concentrations of ions as revealed by chemical analyses may indicate regions in which numerous vascular strands terminate. Ross(26) has described the analogy of the morphology of the fruit carpels and that of the citrus leaf. The main lateral veins of the leaf join at the margin and proceed to the leaf tip, which region, as shown by Haas, (13) becomes the principal place of deposition for soluble materials. It will be shown that similar regions are found in the citrus fruit, the structure of which is composed of a number of modified leaves coalesced to form the whole. Mature leaves on twigs will be considered only as they may affect the gradients in the fruits.
Susceptibility to abscission decreases as fruit matures, injuries due to malnutrition manifesting themselves by other symptoms. Localization of these injuries in certain parts of the fruit suggested a study of the physical and chemical composition of the susceptible and resistant parts.
Literature Cited
[1] Bartholomew E. T. Internal decline of lemons. II. Growth rate, water content, and acidity of lemons at different stages of maturity. Amer. Jour. Bot. 1923. 10:117-126.
[2] Chace E. M., Church C. G. Production of essential oils from citrus fruits. Citrus Leaves. 1923. 2:1-3.
[3] Chace E. M., Church C. G. Composition of Marsh seedless grapefruit grown in California and Arizona. California Citrograph. 1924. 9:122164- 220
[4] Chace E. M., Tolman L. M., Munson L. S. Chemical composition of some tropical fruits and their products. U. S. Dept. Agr. Bur. Chem. Bul. 1904. 87:1-38.
[5] Chace E. M., Wilson C. P., Church C. G. The composition of California lemons. U. S. Dept. Agr. Bul. 1921. 993:1-18.
[6] Collison S. E. Sugar and acid in oranges and grapefruit. Florida Agr. Exp. Sta. Bul. 1913. 115:1-23.
[7] Copeman P. R. van de R. Changes in the composition of oranges during ripening. Trans. Roy. Soc. S. Africa. 1931. 19:107-167.
[8] Fawcett H. S., Lee H. A. Citrus diseases and their control. 1926. New York: McGraw-Hill Co. 582p.
[9] Gustafson F. G. Studies on the hydrogen-ion concentration of plant juices. I. Preliminary studies on the changes in the hydrogen-ion concentration of plants during their development. Michigan Acad. Sci., Arts, and Letters, Papers. 1923. 2:49-52.
[10] Gustafson F. G. Diurnal changes in the acidity of Bryophyllum calycinum. Jour. General Physiol. 1925. 7:719-728.
[11] Haas A. R. C. Studies on the reaction of plant juices. Soil Sci. 1920. 9:341-369.
[12] Haas A. R. C. Relation between fruit size and abscission of young orange fruits. Bot. Gaz. 1927. 83:307-313.
[13] Haas A. R. C. Some nutritional aspects in mottle-leaf and other physiological diseases of citrus. Hilgardia. 1932. 6(15):483-559. DOI: 10.3733/hilg.v06n15p483 [CrossRef]
[14] Haas A. R. C., Halma F. F. Sap concentration and inorganic constituents of mature citrus leaves. Hilgardia. 1931. 5(13):407-424. DOI: 10.3733/hilg.v05n13p407 [CrossRef]
[15] Halma F. F., Haas A. R. C. Effect of sunlight on sap concentration of citrus leaves. Bot. Gaz. 1928. 86:102-106.
[16] Harris J. A., Gortner R. A. Notes on the calculation of the osmotic pressure of expressed vegetable saps from the depression of the freezing point, with a table for the values of P for ? = 0.001° to ? = 2.999°. Amer. Jour. Bot. 1914. 1:75-78.
[17] Hurd-Karrer Annie M. Changes in the buffer system of the wheat plant during its development. Plant Physiol. 1928. 3:131-153.
[18] Hurd-Karrer Annie M. Relation of leaf acidity to vigor in wheat grown at different temperatures. Jour. Agr. Research. 1929. 39:341-350.
[19] Janssen G., Bartholomew R. P. The translocation of potassium in tomato plants and its relation to their carbohydrate and nitrogen distribution. Jour. Agr. Research. 1929. 38:447-465.
[20] Joslyn M. A., Marsh G. L. The relation of deterioration of orange juice to its iodine reducing value. Science. 1932. 76:82-83.
[21] Klotz L. J. A possible vitality test for lemons. California Citrograph. 1933. 18:154-155.
[22] Lilleland O. Does potassium increase the sugar content of prunes?. Amer. Soc. Hort. Sci. Proc. 1930. 27:15-18.
[23] Markley K. S., Sando C. E. Permeability of the skin of apples as measured by evaporation loss. Plant Physiol. 1931. 6:541-547.
[24] Poore H. D. Analyses and composition of California lemon and orange oils. U. S. Dept. Agr. Tech. Bul. 1932. 241:1-30.
[25] Ranker E. R. A modification of the salicylic-thiosulfate method suitable for the determination of total nitrogen in plants, plant solution, and soil solutions. Jour. Assoc. Off. Agr. Chem. 1927. 10:230-251.
[26] Ross L. S. On the structure and development of the lemon. Bot. Gaz. 1890. 15:262-267.
[27] Shaffer P. A., Hartmann A. F. The iodometric determination of copper and its use in sugar analysis. II. Methods for the determination of reducing sugars in blood, urine, milk, and other solutions. Jour. Biol. Chem. 1921. 45:365-390.
[28] Takahashi Ikuro. On the effect of potassium upon citrus fruits. Studia Citrologica. 1931. 5:37-54.
[29] Wilson C. P., Young C. O. A method for the determination of the volatile oil content of citrus fruits. Jour. Ind. U. S. and Engin. Chem. 1917. 9:959-961.
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