Hostname: page-component-cd9895bd7-gbm5v Total loading time: 0 Render date: 2024-12-26T05:40:41.923Z Has data issue: false hasContentIssue false

Nitrogen Assimilation Enzyme Activities in Witchweed (Striga) in Hosts Presence and Absence

Published online by Cambridge University Press:  12 June 2017

Imuetinyan Igbinnosa
Affiliation:
Université de Nantes, Faculté des Sciences et des Techniques, Groupe de Physiologie et Pathologie Végétale, Laboratorie de Cytopathologie Végétale, 2, rue de la Houssinière, F44072 NANTES Cedex 03, France
Patrick A. Thalouarn
Affiliation:
Université de Nantes, Faculté des Sciences et des Techniques, Groupe de Physiologie et Pathologie Végétale, Laboratorie de Cytopathologie Végétale, 2, rue de la Houssinière, F44072 NANTES Cedex 03, France

Abstract

N fertilizers suppress witchweed plant growth and development, thus reducing the severity of parasite attack and increasing host yield simultaneously. However, the underlying physiological mode of N action occurring within the parasite cells remains largely unknown. This study aims at screening for the effects of N forms and different growth conditions on some N assimilation enzymes in witchweed seedlings grown aseptically without host plant, and in pots with host plants. Results show that supply of N in NH4 + or urea forms resulted in 83 to 92% reduction in nitrate reductase activity (NRc), compared with control. Increasing NO3 concentrations from 0 mM to 100 mM, led to a corresponding increase in NRc in giant witchweed. NRc of giant witchweed seedlings grown under light and dark cycles were about 270 times higher than seedlings grown in continuous darkness. A combination of NH4 + and NO3 , resulted in increased giant witchweed NRc, compared with NH4 + or NO3 supplied singly. Highest shoot development and NRc was at NH4 + and NO3 ratio 1:1, followed by ratios 1:3, 3:1, 0:1, and 1:0, respectively. Addition of N in soils resulted in increased NRc, followed by rapid deterioration and death of giant witchweed plants. NRc, GSc, and GDHc in witchweed, maize, cowpea, and tobacco were affected by diurnal fluctuations with higher enzyme activities occurring during the day than at night. Higher GSc than GDHc suggests that NH4 + assimilation occurs mainly through the GS pathway in witchweed plants. NRc and GDHc were two and four times higher in giant witchweed grown in aseptic media without host plant, than that grown in potted soils with host plants. These findings provide insight into the physiological mode of N action and their implications on witchweed control.

Type
Physiology, Chemistry, and Biochemistry
Copyright
Copyright © 1996 by the 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. Agabawi, K. A. and Younis, A. E. 1965. Effect of nitrogen application on growth and nitrogen content of Striga hermonthica Benth. and Sorghum vulgare Lur. grown for forage. Plant and Soil 23(3): 295304.Google Scholar
2. Agbobli, C. A. 1991. Effects of nitrogen rates on Striga asiatica emergence in maize culture in Togo. Pages 2829 in Ransom, J. K., Musselman, L. J., Worsham, A. D., and Parker, C., eds. Proceedings of the 5th International Symposium of Parasitic Weeds, Nairobi: CIMMYT.Google Scholar
3. Aslam, M., Oaks, A., and Huffaker, R. C. 1976. Effect of light and glucose on the induction of nitrate reductase and on the distribution of nitrate in etiolated barley leaves. Plant Physiol. 58: 588591.Google Scholar
4. Beevers, L. and Hageman, R. H. 1969. Nitrate reduction in higher plants. Ann. Rev. Plant Physiol. 20: 495522.CrossRefGoogle Scholar
5. Cutter, E. G. 1955. Anatomical studies in shoot apices of some parasitic and saprophytic angiosperms. Phytomorphology 5: 231247.Google Scholar
6. Galangau, F., Daniel-Vedele, F., Moureaux, T., Dorbe, M., Leydecker, M., and Caboche, M. 1988. Expression of leaf nitrate reductase genes from tomato and tobacco in relation to light-dark regimes and nitrate supply. Plant Physiol. 88: 383388.Google Scholar
7. Hunter, J. J. and Visser, J. H. 1986. Nitrate reductase activity (NRA) of cultivated Scrophulariacean root parasites. S. Afr. J. Bot. 52: 246248.Google Scholar
8. Igbinnosa, I. and Okonkwo, S.N.C. 1991. Screening of tropical legumes for the production of active germination stimulants and for resistance to Nigerian cowpea witchweed (Striga gesnerioides). Nig. J. Weed Science 4: 19.Google Scholar
9. Igbinnosa, I. 1993. The effect of nitrogen fertilizers on host/parasite relationships between Striga hermonthica Benth. and Zea mays. , University of Nigeria, Nsukka, Nigeria. 367 p.Google Scholar
10. Lagoke, S.T.O., Manzo, S. K., Emechebe, A. M., and Ajayi, O. 1986. Status of parasitic weed research in Nigerian savanna. Proceedings of the 15th Annual Conference of the Weed Science Society of Nigeria, University of Nigeria, Nsukka.Google Scholar
11. Macduff, J. H. and Trim, F. E. 1986. Effects of root temperature and form of nitrogen nutrition on nitrate reductase activity in oilseed rape (Brassica napus L.). Ann. Bot. 57: 345352.Google Scholar
12. Martinoia, E., Heck, V., and Wiemkem, A. 1981. Vacuoles as storage compartments for nitrate in barley leaves. Nature 289: 292294.Google Scholar
13. McNally, S. F. and Stewart, G. R. 1987. Inorganic nitrogen assimilation by parasitic angiosperms. Pages 539546 in Weber, H. C. and Forstreuter, W., eds. Proceedings on the 4th ISPFP, Marburg.Google Scholar
14. Mehta, P., Jain, A., and Srivastava, H. S. 1980. Light and ethylenediamine tetraacetic acid mediated differential effects of ammonium on nitrate reductase activity in maize seedlings. Physiol. Plant. 49: 417420.Google Scholar
15. Melzer, J. M., Kleinhofs, A., and Warner, R. L. 1989. Nitrate reductase regulation: Effects of nitrate and light on nitrate reductase mRNA accumulation. Mol. Gen. Genet. 217: 341346.Google Scholar
16. Miflin, B. J. and Lea, P. J. 1976. The pathway of nitrogen assimilation in plants. Phytochemistry 15: 873885.CrossRefGoogle Scholar
17. Murashige, T. and Skoog, F. 1962. A revised medium for rapid growth and bioassays with tobacco tissue cultures. Physiol. Plant. 15: 473497.Google Scholar
18. Musselman, L. J. 1980. The biology of Striga, Orobanche and other parasitic weeds. Ann. Rev. Phytopathol. 18: 463489.Google Scholar
19. Musselman, L. J. and Parker, C. 1981. Studies on indigo witchweed, the American strain of Striga gesnerioides (Scrophulariaceae). Weed Sci. 29: 594596.CrossRefGoogle Scholar
20. Ogborn, J.E.A. 1972. Control of Striga hermonthica in peasant farming. Pages 10681077 in Proceedings of the 11th British Weed Control Conference, Brighton, U.K.Google Scholar
21. Ogborn, J.E.A. 1987. Striga control under peasant farming conditions. Pages 145158 in Musselman, L. J., ed. Parasitic Weeds in Agriculture, Vol. 1. Striga, CRC Press, Boca Raton, Florida, U.S. Google Scholar
22. Okonkwo, S.N.C. 1991. In vitro growth response of cultured germinated seeds of witchweed (Striga asiatica). Pages 155163 in Ransom, J. K., Musselman, L.J., Worsham, A. D., and Parker, C., eds. Proceedings of the 5th International Symposium of Parasitic Weeds, Nairobi: CIMMYT.Google Scholar
23. Okonkwo, S.N.C. 1992. Micropropagation of some parasitic weeds. Pages 448470 in Bajaj, Y.P.S., ed. Biotechnology in Agriculture and Forestry, Vol. 20, High-Tech and Micropropagation IV, Springer-Verlag Berlin Heidelberg.Google Scholar
24. Parker, C. 1983. Factors influencing Striga seed germination and host-parasite specificity. Pages 3138 in Proceedings of the 2nd International Workshop on Striga, Upper Volta: ICRISAT.Google Scholar
25. Rajasekhar, V. K. and Mohr, H. 1986. Effect of ammonium and nitrate on growth and appearance of nitrate reductase and nitrite reductase in dark- and light-grown mustard seedlings. Planta 169: 594599.Google Scholar
26. Raju, P. S., Osman, M. A., Souman, P., and Peacock, J. M. 1990. Effects of N, P and K on Striga asiatica (L.) Kuntze seed germination and infestation of sorghum. Weed Res. 30: 139144.Google Scholar
27. Rey, L., Thalouarn, P., Fer, A., and Renaudin, S. 1990. About the capacity of achlorophyllous parasitic flowering plants to assimilate inorganic forms of carbon and nitrogen. Beitr. Biol. Pflanzen. 65: 429441.Google Scholar
28. Salsac, L., Chaillou, S., Morot-Gaudry, J-F., Lesaint, C., and Jolivet, E. 1987. Nitrate and ammonium nutrition in plants. Plant Physiol. 25: 805812.Google Scholar
29. Sauerborn, J. 1991. The economic importance of phytoparasites Orobanche and Striga . Pages 137146 in Ransom, J. K., Musselman, L. J., Worsham, A. D., and Parker, C., eds. Proceedings of the 5th International Symposium of Parasitic Weeds, Nairobi: CIMMYT.Google Scholar
30. Schuster, C., Schmidt, S., and Mohr, H. 1989. Effect of nitrate, ammonium, light and a plastidic factor on the appearance of multiple forms of nitrate reductase in mustard (Sinapsis alba L.) cotyledons. Planta 177: 7483.Google Scholar
31. Shapiro, B. M. and Stadtman, E. R. 1970. Glutamine synthetase (Escherichia coli). Pages 910922 in Colowick, S. P., Kaplan, N. O., Tabor, H., and Tabor, C. W., eds. Methods in enzymology, Vol. 17, Metabolism of amino acids and amines, Academic press, N.Y. CrossRefGoogle Scholar
32. Singh, R. P. and Srivastava, H. S. 1983. Regulation of glutamine dehydrogenase activity by amino acids in maize seedlings. Physiol. Plant. 57: 549554.CrossRefGoogle Scholar
33. Smaling, E.M.A., Stein, A., and Sloot, P.H.M. 1991. Statistical analysis of the influence of Striga hermonthica on maize yields in fertilizer trials in Southwestern Kenya. Plant and Soil 138: 18.Google Scholar
34. Smith, S. E., St John, B. J., Smith, F. A., and Nicholas, D.J.D. 1985. Activity of glutamine synthetase and glutamate dehydrogenase in Trifolium subterraneum L. and Alium cepa L: Effects of mycorrhizal infection and phosphate nutrition. New Phytol. 99: 211227.Google Scholar
35. Stewart, G. R. and Orebamjo, T. O. 1980. Nitrogen status and nitrate reductase activity of the parasitic angiosperm Tapinanthus bangwensis (Engl. et K. Krause) Danser growing on different hosts. Ann. Bot. 45: 587589.Google Scholar
36. Stewart, G. R., Nour, J., MacQueen, M., and Shah, N. 1984. Aspects of the biochemistry of Striga . Pages 161178 in Ayensu, E. S., Doggett, R. D., Keynes, J., Marton-Lefevre, J., Musselman, L. J., Parker, C., and Pickering, A., eds. Striga—Biology and Control, Paris: ICSU.Google Scholar
37. Thalouarn, P., Rey, L., Hirel, B., Renaudin, S., and fer, A. 1987. Activity and immunocytochemical localization of glutamine synthetase in Lathraea clandestina L. Protoplasma 141: 95100.CrossRefGoogle Scholar
38. Thalouarn, P., Philouze, V., and Renaudin, S. 1988. Nitrogen metabolism key enzyme activities in a Scrophulariaceae holoparasite Lathraea clandestina L. J. Plant Physiol. 132: 6366.Google Scholar
39. Thalouarn, P., Canevet, S., and Renaudin, S. 1990. Carbon and nitrogen metabolism in a holoparasitic plant, Lathraea clandestina L, with respect to the main phenologic stages. J. Plant Physiol. 136: 193197.Google Scholar
40. Vairinhos, F., Bhandari, B., and Nicholas, D.J.D. 1983. Glutamine synthetase, glutamine synthase and glutamine dehydrogenase in Rhizobium japonicum strains grown in culture and in bacteroids from root nodules of Glycine max . Planta 159: 207215.Google Scholar
41. Vaucheret, H., Kronenberger, J., Rouze, P., and Caboche, M. 1989. Complete nucleotide sequence of the two homeologous tobacco nitrate reductase genes. Plant Mol. Biol. 12: 597600.CrossRefGoogle ScholarPubMed