Hostname: page-component-76fb5796d-22dnz Total loading time: 0 Render date: 2024-04-25T06:59:41.129Z Has data issue: false hasContentIssue false
  • English
  • Français

Penetration, Translocation, and Metabolism of 2,4-D and 2,4,5-T in Wild and Cultivated Cucumber Plants

Published online by Cambridge University Press:  12 June 2017

F. W. Slife ,
J. L. Key ,
S. Yamaguchi  and
A. S. Crafts
F. W. Slife
Affiliation:
Agronomy, University of Illinois, Urbana
J. L. Key
Affiliation:
Botany Department University of California, Davis
S. Yamaguchi
Affiliation:
Botany Department University of California, Davis
A. S. Crafts
Affiliation:
Botany Department University of California, Davis
Get access

Abstract

Wild cucumber (Sicyos angulatus) and cultivated cucumber (Cucumis sativus) were treated with carboxyl-labeled C142,4–D (2,4–D*) and 2,4,5–T (2,4,5–T*) and autoradiographs developed. The distribution pattern of 2,4–D* was achieved in 24 hours and changed little by the end of 4 or 8 days. The pattern of 2,4,5–T* translocation continued to change during an 8-day period, indicating a highly mobile compound. Metabolic studies indicated that considerably more 2,4–D* than 2,4,5–T* was absorbed by these species but 75% of the absorbed 2,4–D* was converted into two major metabolites within 24 hours. The absorbed 2,4,5–T* formed only traces of these metabolites even after 8 days. Evolution of C14O2 was approximately 10 times greater from 2,4–D*-treated plants than from 2,4,5–T*-treated plants. The greater phytotoxicity of 2,4,5–T on these species seems to be related to the inability of the plants to detoxify this compound as rapidly as 2,4–D.

Type
Research Article
Information
Weeds , Volume 10 , Issue 1 , January 1962 , pp. 29 - 35
Copyright
Copyright © 1962 Weed Science Society of America 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Literature Cited

1. Andreae, W. A., and Good, N. E. 1957. Studies on 3–indoleacetic acid metabolism. IV. Conjugation with aspartic acid and ammonia as processes in the metabolism of carboxylic acid. Plant Physiol. 32:566572.Google Scholar
2. Butts, J. S., and Fang, S. C. 1956. Tracer studies on the mechanism of action of hormonal herbicides. In Radioactive isotopes in agriculture. United States Atomic Energy Commission (TID 7512): 209214.Google Scholar
3. Crafts, A. S. 1956. The mechanism of translocation: Methods of study with C14 labeled 2,4–D. Hilgardia. Vol. 26. No. 6:287334.Google Scholar
4. Crafts, A. S. and Yamaguchi, S. 1958. Comparative tests on the uptake and distribution of labeled herbicides by Zebrina pendula and Tradescantia fluminensis . Hilgardia 27 (16): 421454.CrossRefGoogle Scholar
5. Crafts, A. S. and Yamaguchi, S. 1950. Absorption of herbicides by roots. Am. J. Bot. 47:248255.Google Scholar
6. Fang, S. C., and Butts, J. S. 1954. Studies in plant metabolism. III. Absorption, translocation, and metabolism of radioactive 2,4–D in corn and wheat plants. Plant Physiol. 29:5660.Google Scholar
7. Fang, S. C. 1958. Translocation and metabolism of 2,4–D–1–C14 in pea and tomato plants. Weeds 6:178186.Google Scholar
8. Galston, A. W., and Purves, W. K. 1960. The mechanism of action of auxin. Ann. Rev. Plant Physiol. 11:239276.Google Scholar
9. Holley, R. W., Boyle, F. P., and Hand, D. B. 1950. Studies on fate of radioactive 2,4–D in bean plants. Arch. Biochem. 27:143151.Google ScholarPubMed
10. Holley, R. W. 1952. Studies on the fate of radioactive 2,4–D in bean plants. II. A water soluble transformation product of 2,4–D. Arch. Biochem. Biophys. 35:171175.CrossRefGoogle Scholar
11. Jawarski, E. G., and Butts, J. S. 1952. Studies in plant metabolism. II. The metabolism of C14-labeled 2,4–D in bean plants. Arch. Biochem. Biophys. 38:207218.CrossRefGoogle Scholar
12. Radwan, M. A., Stocking, C. R., and Currier, H. B. 1960. Histo-autoradiographic studies of herbicidal translocation. Weeds 8:657665.Google Scholar
13. Stout, P. R., and Hoagland, D. R. 1939. Upward and lateral movement of salt in certain plants as indicated by radioactive isotopes of potassium, sodium, and phosphorus absorbed by roots. Am. J. Bot. 26:320324.CrossRefGoogle Scholar
14. Wain, R. L., and Wightman, F. 1954. The growth-regulating activity of certain w-substituted alkyl carboxylic acids in relation to beta-oxidation within the plant. Proc. Roy. Soc. (London). 142:525536.Google Scholar
15. Weintraub, R. L., Reinhart, J. H., Scherff, E. A., and Schisler, L. C. 1954. Metabolism of 2,4–D. III. Metabolism and persistence in dormant plant tissues. Plant Physiol. 29:303304.Google Scholar
16. Williams, M. C., Slife, F. W., and Hanson, J. B. 1960. Absorption and translocation of 2,4–D in several annual broadleaf weeds. Weeds 8:244255.CrossRefGoogle Scholar
17. Yamaguchi, S., and Crafts, A. S. 1958. Autoradiographic method for studying absorption and translocation of herbicides using C14 labeled compounds. Hilgardia 28 (6):161191.CrossRefGoogle Scholar