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Response of soybean cyst nematodes and soybeans (Glycine max) to herbicides

Published online by Cambridge University Press:  12 June 2017

Brian C. Levene
Affiliation:
Iowa State University, Ames, IA 50011
Gregory L. Tylka
Affiliation:
Iowa State University, Ames, IA 50011

Abstract

The effect of herbicides applied to V3 soybeans on race 3 soybean cyst nematode (SCN) reproduction and glyceollin production in roots was measured. Soybeans were treated postemergence with 1 × and 2 × rates of herbicides plus adjuvants or with adjuvants alone, and SCN development was measured. Acifluorfen, bentazon, lactofen, crop oil concentrate (COC), and nonionic surfactant (NIS) applications reduced SCN egg population densities 50 to 60% compared with the untreated control 4 and 8 wk after application. The SCN reproduction on plants treated with fluazifop-P, sethoxydim, and imazethapyr was similar to the untreated control. Crop oil concentrate or NIS applications alone were as effective as acifluorfen, bentazon, or lactofen applications for reducing SCN reproduction. However, no additive effect of adjuvant-herbicide combinations was observed, nor did herbicide rate affect SCN reproduction. Treatments reduced SCN reproduction only when applied to soybeans and had no effect on SCN reproduction when applied directly to the soil. No treatment stimulated SCN reproduction relative to the untreated control. Soybeans treated with COC, NIS, acifluorfen, and bentazon also had more glyceollin detected than the untreated control. Herbicide-induced glyceollin production may have increased the resistance of soybean to SCN.

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Copyright
Copyright © 1998 by the Weed Science Society of America 

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References

Literature Cited

Abernathy, J. R. and Wax, L. M. 1973. Bentazon mobility and absorption in twelve Illinois soils. Weed Sci. 21: 224227.Google Scholar
Alphey, T.J.W., Bromilow, R. H., and Abdalla, A. M. 1985. Phloem translocation of foliar-applied oxamyl and its role in plant protection. Nematologica 31: 468477.Google Scholar
Alston, D. G. and Schmitt, D. P. 1988. Development of Heterodera glycines life stages as influenced by temperature. J. Nematol. 20: 366372.Google Scholar
Ayers, A. R., Ebel, J., Finelli, F., Berger, N., and Albersheim, P. 1976. Host—pathogen interactions: IX. Quantitative assays of elicitor activity and characterization of the elicitor present in the extracellular medium of cultures of Phytophthora megasperma var. sojae. Plant Physiol. 57: 751759.Google Scholar
Bhattacharyya, M. K. and Ward, E.W.B. 1986. Phenylalanine ammonialyase (PAL) activity in soybean hypocoryls and leaves following infection with Phytophthora megasperma f.sp. glycinea . Can. J. Bot. 66: 1823.Google Scholar
Bhattacharyya, M. K. and Ward, E.W.B. 1987. Biosynthesis and metabolism of glyceollin I in soybean hypocoryls following wounding or inoculation with Phytophthora megasperma f.sp. glycinea . Physiol. Mol. Plant Pathol. 31: 387405.Google Scholar
Browde, J. A., Pedigo, L. P., Owen, M.D.K., and Tylka, G. L. 1993. Soybean yield and pest management as influenced by nematodes, herbicides, and defoliating insects. Agron. J. 86: 601608.Google Scholar
Browde, J. A., Tylka, G. L., Pedigo, L. P., and Owen, M.D.K. 1994. Response of Heterodera glycines populations to a postemergence herbicide mixture and simulated insect defoliation. J. Nematol. 26: 498504.Google Scholar
Burden, R. S. and Bailey, J. A. 1975. Structure of the phytoalexin from soybean. Phytochemistry 14: 13891390.Google Scholar
Byrd, D. W. Jr., Barker, K. R., Ferris, H., Nusbaum, C. J., Griffin, W. E., Small, R. H., and Stone, C. A. 1976. Two semiautomatic elutriators for extracting nematodes and certain fungi from soil. J. Nematol. 8: 206212.Google Scholar
Byrd, D. W. Jr., Kirkpatrick, T., and Barker, K. R. 1983. An improved technique for cleaning and staining of nematodes. J. Nematol. 15: 142143.Google Scholar
Chakraboty, B. N. and Purkayastha, R. P. 1987. Alteration in glyceollin synthesis and antigenic patterns after chemical induction of resistance in soybean to Macrophomina phaseolina . Can. J. Microbiol. 33: 835840.Google Scholar
Darvil, A. G. and Albersheim, P. 1984. Phytoalexins and their elicitors - a defense against microbial infection in plants. Annu. Rev. Plant Physiol. 35: 243275.Google Scholar
Duke, S. O. 1985. Biosynthesis of phenolic compounds, chemical manipulation of higher plants. Pages 113131 in Thompson, A. C., ed. ACS Symposium Series 268. The Chemistry of Allelopathy Biochemical Interactions Among Plants. Salem, MA: American Chemical Society.Google Scholar
Fedorko, A., Kamionek, M., Kozlowska, J., and Mianowska, E. 1977. The effects of some carbamide herbicides on nematodes from different ecological groups. Pol. Ecol. Stud. 3: 2328.Google Scholar
Fehr, W. R., Caviness, C. E., Burmood, D. T., and Pennington, J. S. 1971. Stages of development descriptions for soybean, Glycine max (L.) Merrill. Crop Sci. 11: 929931.Google Scholar
Fischer, D. C., Kogan, M., and Paxton, J. 1990. Effect of glyceollin, a soybean phytoalexin, on feeding by three phytophagous beetles, dose versus response. Environ. Entomol. 19: 12781282.Google Scholar
Graham, T. L. and Graham, M. Y. 1991. Glyceollin elicitors induce major but distinctly different shifts in isoflavonoid metabolism in proximal and distal soybean cell populations. Mol. Plant-Microbe Interact. 4: 6068.Google Scholar
Graham, T. L., Kim, J. E., and Graham, M. Y. 1990. Role of constitutive conjugates in the accumulation of glyceollin in soybean infected with Phytophthora megasperma . Mol. Plant-Microbe Interact. 3: 157166.Google Scholar
Huang, J. S. and Barker, K. R. 1991. Glyceollin I in soybean-cyst nematode interactions: spatial and temporal distribution in roots of resistant and susceptible soybeans. Plant Physiol. 96: 13021307.Google Scholar
Humburg, N. E., ed. 1989. Herbicide Handbook of the Weed Science Society of America. 6th ed. Champaign, II.: Weed Science Society of America, pp. 164167.Google Scholar
Johnson, W. O., Kollman, G. E., Swithenbank, C., and Yih, R. Y. 1978. RH-6201 (Blazer): a new broad spectrum herbicide for postemergence use in soybeans. J. Agric. Food Chem. 26: 285286.Google Scholar
Keen, N. T. 1978. Phytoalexins: efficient extraction from leaves by a facilitated diffusion technique. Phytopathology 68: 12371239.Google Scholar
Komives, T. and Casida, J. E. 1983. Acifluorfen increases the leaf content of phytoalexins and stress metabolites in several crops. J. Agric. Food Chem. 31: 751755.Google Scholar
McLeod, R. W. and Khair, G. T. 1975. Effects of oximecarbamate, organophosphate and benzimidazole nematicides on life cycle stages of root-knot nematodes, Meloidogyne spp. Ann. Appl. Biol. 79: 329342.Google Scholar
Mine, A., Miyakado, M., and Matsunaka, S. 1975. The mechanism of bentazon selectivity. Pestic. Biochem. Physiol. 5: 566574.Google Scholar
Niblack, T. L., Baker, N. K., and Norton, D. C. 1992. Soybean yield losses due to Heterodera glycines in Iowa. Plant Dis. 76: 943948.Google Scholar
Payan, L. A., Johnson, A. W., and Littrell, R. H. 1987. Effects of nematicides and herbicides alone or combined on Meloidogyne incognita egg hatch and development. Ann. Appl. Nematol. 1: 6770.Google Scholar
Perry, R. N. and Beane, J. 1989. Effects of certain herbicides on the in vitro hatch of Globodera rostochiensis and Heterodera schachtii . Rev. Nematol. 12: 191196.Google Scholar
[SAS] Statistical Analysis Systems. 1987. SAS User's Guide: Statistics. Version 5. Cary, NC: Statistical Analysis Systems Institute, pp. 113138.Google Scholar
Schmitt, D. P., Corbin, F. T., and Nelson, L. A. 1983. Population dynamics of Heterodera glycines and soybean response in soils treated with selected nematicides and herbicides. J. Nematol. 15: 432437.Google Scholar
Schmitt, D. P. and Riggs, R. D. 1991. Influence of selected plant species on hatching of eggs and development of juveniles of Heterodera glycines . J. Nematol. 23: 16.Google Scholar
Sortland, M. E. and MacDonald, D. H. 1987. Effect of crop and weed species on development of a Minnesota population of Heterodera glycines race 5 after one to three growing periods. Plant Dis. 71: 2327.Google Scholar
Stossel, P. 1982. Glyceollin production in soybeans. Phytopathology 105: 109119.Google Scholar
Swisher, B. and Corbin, F. T. 1982. Behavior of BAS 9052 in soybeans (Glycine max) and johnsongrass (Sorghum halepense) plant and cell culture. Weed Sci. 30: 640650.Google Scholar
Taiz, L. and Zeiger, E. 1991. Surface protection and secondary defense compounds. Pages 318345 in Plant Physiology. Redwood City, CA: Benjamin/Cumming.Google Scholar
Welle, R. and Grisebach, H. 1988. Induction of phytoalexin synthesis in soybeans: enzymatic cyclization of prenylated pterocarpans to glyceollin isomers. Arch. Biochem. Biophys. 263: 191198.Google Scholar
Welle, R., Schroder, G., Schultz, E., Grisebach, H., and Schroder, J. 1990. Induced plant responses to pathogen attack. Analysis and heterologous expression of the key enzyme in the biosynthesis of phytoalexins in soybean. Eur. J. Biochem. 196: 423430.Google Scholar
Wong, A.T.S. and Tylka, G. L. 1994. Eight nonhost weed species of Heterodera glycines in Iowa. Plant Dis. 78: 365367.Google Scholar
Wong, A.T.S., Tylka, G. L., and Hartzler, R. G. 1993. Effect of eight herbicides on the in vitro hatching of Heterodera glycines . J. Nematol. 25: 578584.Google Scholar
Wrather, J. A. and Anand, S. C. 1988. Relationship between time of infection with Heterodera glycines and soybean yield. J. Nematol. 20: 439442.Google Scholar