Soybeans roots

Legocki, R. P., Legocki, M., Baldwin, T. O., and Szalay, A. A. (1986). Bioluminescence in soybean root nodules demonstration of a general approach to assay gene expression in vivo by using bacterial luciferase. Proc. Natl. Acad. Sci. USA 83 9080-9084. [Pg.414]

Lin, C.Y. Key, J.L. (1967). Dissociation and reassembly of polyribosomes in relation to protein synthesis in the soybean root. Journal of Molecular Biology, 26, 237-47. [Pg.178]

N. G. Juma and M. A. Tabatabai, Phosphata.se activity in corn and soybean roots condition for assay and effects of metals. Plant Soil 107 39 (1988). [Pg.191]

R. Rape, M. Pamiske, S. Brandt, and D. Werner, Isoliquiritigenin, a strong nod gene- and glyceollin resistance-inducing falvonoid from soybean root exudate. Appl. Environ. Microbiol. 5 1705 (1992). [Pg.218]

P. E. Schmidt, M. Pamiske, and D. Werner, Production of the phytoalexin glyceollin I by soybean root response to symbiotic and pathogenic infection. Bot. Acta. 105 18 (1992). [Pg.218]

D. Morandi, J. A. Bailey, and V. Gianinazzi-Pearson, Isoflavonoid accumulation in soybean root infected with vesicular-arbuscular mycorrhizal fungi. Physiol. Plant Pathol. 24 357 (1984). [Pg.290]

Soybean root exudates were inhibiting to okra, radish and tomato germination but not to carrot or beet germination. Although radish and tomato germination was significantly slowed, soybean root exudate activity in the tomato and radish... [Pg.227]

Developing soybean roots and hypocotyls Localization of respiratory oxidase in meristematic and xylematic tissues Hilal et al. (12)... [Pg.115]

Hilal M, Castagnaro A, Moreno H, Massa EM. Specific localization of the respiratory alternative oxidase in meristematic and xylematic tissues from developing soybean roots and hypocotyls. Plant Physiol 1997 115 1499-1503. [Pg.122]

Walker SJ, Llewellyn GC, Lillehoj EB, Dashek WV. Uptake and distribution of aflatoxin Bj in excised, soybean roots and toxin effects on root elongation. JEnviron ExperBot 1984 24 113-122. [Pg.178]

Recent examples of the use of SIMS in plant science include the measurement of metals in tree rings (23), aluminum in soybean roots (24), a variety of elements in soybean leaf (25), and nitrogen in yeast and soybean leaf (26). The latter paper also demonstrated the advantage of SIMS in distinguishing between different isotopes of the same element (15N and 14N). [Pg.280]

Lazof DB, Goldsmith JG, Rufty TW, Linton RW. The early entry of A1 into cells of intact soybean roots. A comparison of three developmental root regions using secondary ion mass spectrometry imaging. Plant Physiol 1996 112 1289-1300. [Pg.289]

Ferrarese MLL, Ferrarese-Filho O, Rodrigues D (2000) Ferulic acid uptake by soybean root in nutrient culture. Acta Physiol Plant 22 121-124... [Pg.411]

Hoch, G.E., K.C. Schneider and R.H. Burris. Hydrogen evolution and exchange and conversion of N20 to N2 by soybean root nodules. Biochim. Biophys. Acta 37, 273-279 (1960). [Pg.115]

Blum and Tingey found that ozone reduction in soybean root growth and nodulation was a function of foliar impact. They found no direct effect of ozone on the roots or soil systems surrounding the roots. [Pg.499]

Source Formic acid naturally occurs in carrots, soybean roots, carob, yarrow, aloe, Levant berries, bearberries, wormwood, ylang-ylang, celandine, jimsonweed, water mint, apples, tomatoes, bay leaves, common juniper, ginkgo, scented boronia, corn mint, European pennyroyal, and bananas (Duke, 1992). [Pg.603]

Example 2 Certain plant root exudates contain factors stimulating soybean root growth as well as nodule formation. These stimulating factors contain protein as well as several other chemical components. This research is still at a very early stage, and it will take additional effort to characterize these factors and enormous developmental work before they can be commercialized. It may become too expensive for a company to develop this type of minor special-use product. [Pg.453]

CORN COTTON ONION PEANUT PEANUT SOYBEAN ROOT ROOT ROOT ROOT CELL C. ROOT... [Pg.137]

Figure 11. Metabolism of propachlor to an Fi-malonylcysteine conjugate in soybean root. Soybeans treated with [ C-carbonyl] propachlor were harvested after 4 and 21 days. The glutathione and y-glutamylcysteine conjugates were identified by HPLC and the S-malonylcysteine conjugate was identified by the MS of the...

Subramanian, S. et al., The promoters of the isoflavone synthase genes respond differentially to nodulation and defense signals in transgenic soybean roots. Plant Mol. Biol, 54, 623, 2004. [Pg.215]

Vidal, J., Nguyen, J., Perrot-Rechenmann, C. Gadal, P. (1986). Phosphoeno/pyruvate carboxylase in soybean root nodules an immunochemical study. Planta 169, 198-201. [Pg.137]

Newcomb, E.H. Tandon, S.R. (1981). Uninfected cells of soybean root nodules Ultrastructure suggests key role in ureide production. Science 212, 1394-6. [Pg.200]

Sangwan, I. O Brian, M.R. (1991). Evidence for an inter-organismic heme biosynthetic pathway in symbiotic soybean root nodules. Science 251, 1220-2. [Pg.201]

Suganuma, N.M., Kitou, M. Yamamoto, Y. (1987). Carbon metabolism in relation to cellular organization of soybean root nodules and respiration of mitochrondria aided by leghemoglobin. Plant Cell Physiology 28, 113-22. [Pg.201]

Van de Weil, C., Scheres, B., Franssen, H., Van Lierop, M.-J., Van Lammeren, A., Van Kammen, A. Bisseling, T. (1990). The early nodulin transcript ENOD2 is located in the nodule parenchyma (inner cortex) of pea and soybean root nodules. The EMBO Journal 9,1-7. [Pg.202]

Verma, D.P.S., Kazazian, V., Zogbi, V. Bal, A.K. (1978). Isolation and characterization of the membrane envelope enclosing the bac-teroids in soybean root nodules. Journal of Cell Biology 78, 919-36. [Pg.203]

Werner, D., Mellor, R.B., Hahn, M.G. Grisebach, H. (1985). Soybean root response to symbiotic infection Glyceollin I accumula-... [Pg.203]

Werner, D., Morschel, E., Garbers, C., Bassarab, S. Mellor, R.B. (1988). Particle density and protein composition of the peribacteroid membrane from soybean root nodule is affected by mutations in the microsymbiont Bradyrhizobium japonicum. Planta 174, 263-70. [Pg.204]

A study was conducted to determine the effects of combinations of organic amendments and benzaldehyde on plant-parasitic and non-parasitic nematode populations, soil microbial activity, and plant growth (Chavarria-Carvajal et al., 2001). Pine bark, velvetbean and kudzu were applied to soil at rates of 30 g/kg and paper waste at 40 g/kg alone and in combination with benzaldehyde (300 mul/kg), for control of plant-parasitic nematodes. Pre-plant and post-harvest soil and soybean root samples were analyzed, and the number of parasitic and non-parasitic nematodes associated with soil and roots were determined. Soil samples were taken at 0, 2, and 10 weeks after treatment to determine population densities of bacteria and fungi. Treatment... [Pg.67]

Morandi D. Isoflavonoid accumulation in soybean roots infected with vesicular-arbuscular mycorrhizal fungus. Physiol PI Pathol 1984 24 357-364. [Pg.190]

Baziramakenga, R., Leroux, G. D., and Simard, R. R. 1995. Effects of benzoic and cinnamic acids on membrane permeability of soybean roots. J. Chem. Ecol. 21,1271-1285... [Pg.246]

Yathavakilla, S.K.V. and Caruso, J.A. Study of Se-Hg antagonism in Glycine max (soybean) roots by size exclusion and reversed phase HPLC-ICPMS. Anal. Bioanal. Chem. 2007, 389, 715-723. [Pg.159]

Iqbal, M.J., Afzal, A.J., Yaegashi, S., Ruben, E., Triartayakorn, K., Njiti, VN., Ahsan, R., Wood, A.J., and Lightfoot, D.A., 2002, A Pyramid of loci for partial resistance to Fusarium solani f. sp. Glycines maintains Myo-i nositol-1 -phosphate synthase expression in soybean roots. Theor. Appl. Genet. 105 1115-1123. [Pg.337]

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