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Root Reserves and Susceptibility to Systemic Herbicides in two Phreatophytes

Published online by Cambridge University Press:  12 June 2017

H. P. Cords  and
Amir A. Badiei
H. P. Cords
Affiliation:
Nevada Agricultural Experiment Station
Amir A. Badiei
Affiliation:
Nevada Agricultural Experiment Station
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Abstract

Saltcedar (Tamarix pentandra Pall.) and Woods rose (Rosa woodsii Lindl. var. ultramontana [Wats.] Jeps.) were sprayed with systemic herbicides at frequent intervals over a 2-year period. Root samples were collected at each spray date and analyzed for “total available carbohydrates.” Food reserve levels in the roots and response to herbicides were not correlated.

Type
Research Article
Information
Weeds , Volume 12 , Issue 4 , October 1964 , pp. 299 - 301
Copyright
Copyright © 1964 Weed Science Society of America 

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References

1. Arle, , Fred, H., Bowser, C. E., and McRae, G. N. 1962. Chemical control of saltcedar (Tamarix pentandra). Res. Prog. Rep. WWCC:18.Google Scholar
2. Bartley, T. R. and Otto, N. E. 1961. Carbohydrate reserves in tamarisk (saltcedar). Prog. Rep. No. 4, August 1960 through July 1961. Chem. Eng. Lab. Rep. No. W-3, USDI, Bur. Recl., Division Eng. Laboratories.Google Scholar
3. Fisher, C. E., Meadors, C. E., and Behrens, Richard. 1956. Some factors that influence the effectiveness of 2,4,5-trichlorophenoxyacetice acid in killing mesquite. Weeds 4:139147.CrossRefGoogle Scholar
4. Hyder, D. N., Sneva, Forrest A., and Freed, Virgil H. 1962. Susceptibility of big sagebrush and green rabbitbrush to 2,4-D as related to certain environmental, phenological, and physiological conditions. Weeds 10:288295.CrossRefGoogle Scholar
5. Klingman, G. C. and Ahlgren, G. H. 1951. Effects of 2,4-D on dry weight, reducing sugar, total sugars, polysaccharides, nitrogen and alkyl sulfide in wild garlic. Bot. Gaz. 113:119134.CrossRefGoogle Scholar
6. Leonard, Oliver A. and Crafts, Alden S. 1956. Translocation of herbicides III. Uptake and distribution of radioactive 2,4-D by brush species. Hilgardia 26:366415.CrossRefGoogle Scholar
7. Lindahl, Ivan, Davis, R. E., and Shepherd, W. O. 1949. The application of the total available carbohydrate method to the study of carbohydrate reserves of switch cane (Arundinacea tecta). Plant Physiol. 24:285295.CrossRefGoogle Scholar
8. Robertson, Joseph H. and Cords, H. P. 1957. Survival of rabbitbrush (Chrysothamnus Spp.) following chemical, burning and mechanical treatments. J. Range Mgt. 10:8389.CrossRefGoogle Scholar
9. Smith, F. G., Hamner, C. L., and Carlson, A. F. 1947. Changes in food reserves and respiratory capacity of bindweed tissues accompanying herbicidal action of 2,4-dichlorophenoxyacetic acid. Plant Physiol. 22:5865.CrossRefGoogle Scholar
10. Tschirley, Fred H. and Hull, Herbert M. 1951. Susceptibility of velvet mesquite to an amine and an ester of 2,4,5-T as related to various biological and meteorological factors. Weeds 7:427435.CrossRefGoogle Scholar
11. Weaver, Robert J. and Robert DeRose, H. 1946. Absorption and translocation of 2,4-dichlorophenoxyacetic acid. Bot. Gaz. 107:509521.CrossRefGoogle Scholar
12. Welton, F. A., Morris, V. H., and Hartzler, A. J. 1929. Organic food reserves in relation to the eradication of Canada thistle. Ohio Agr. Expt. Sta. Bull. 441.Google Scholar
13. Wiese, A. F. and Rea, H. E. 1962. Factors affecting the toxicity of phenoxy herbicides to field bindweed. Weeds 10:5861.CrossRefGoogle Scholar