The isolation and characterization of a family of maize glutathione-S-transferases (GST's) has been described previously. These enzymes are designated GSTs I, II and III based on size, substrate specificity and responsiveness to safeners. GST III has been shown to act on the herbicide alachlor as well as the commonly used substrate 1-chloro-2,4-dinitrobenzene (CDNB). Clones were isolated from a maize cDNA library in lambda gt10. Three clones contained the entire coding region for GST III. The sequences of these clones were consistent with the known amino terminal GST III protein sequence. Moreover, expression of one of these clones in E. coli resulted in a GST activity as measured with both CDNB and alachlor, proving that at least one of the clones encodes an active GST III species. With the enzyme expressed in E. coli it will become possible to study enzyme structure-function relationships ex planta. While a number of different GST proteins are present in maize tissue the GST III gene is present in single or low copy in the genome.
A chimeric gene encoding the alfalfa mosaic virus (AlMV) coat protein was constructed and introduced into tobacco and tomato plants using Ti plasmid-derived plant transformation vectors. The progeny of the self-fertilized transgenic plants were significantly delayed in symptom development and in some cases completely escaped infection after inoculated with AIMV. The inoculated leaves of the transgenic plants had significantly reduced numbers of lesions and accumulated substantially lower amounts of coat protein due to virus replication than the control plants. These results show that high level expression of the chineric viral coat protein gene confers protection against AIMV, which differs from other plant viruses in morphology, genome structure, gene expression strategy and early steps in viral replication. Based on our results with AIMV and those reported earlier for tobacco mosaic virus, it appears that genetically engineered crossprotection may be a general method for preventing viral disease in plants.
ABSTRACrThe in vivo rates of uptake and detoxification of alachlor and metolachlor were determined using Pioneer corn 3320 seedlings. Equal amounts of the radiolabeled herbicides were applied to etiolated coleoptiles and, at various intervals after treatment, the unabsorbed radioactivity was removed and quantified. Analysis of 80% methanol extracts by reverse phase liquid chromatography showed no significant differences in the rate of uptake of metolachlor and alachlor. However, the rate of glutathione conjugation of alachlor in vivo was two-to threefold greater than the rate for metolachlor at 2 and 4 hours after herbicide application.Since the initial step in detoxification is conjuption of the chloroacetanilide to glutathione, the activities of the enzymes responsible for conjuption, the glutathione-S-transferases (GST) were also analyzed in vitro, using crude extracts and the purified GST enzymes. The specific activities of the extracts were consistent with the results in vivo. Using alachlor as a substrate, the specific activity for glutathione conjugation was almost threefold higher than that for metolachlor. Kinetic analysis of purified GST III indicates that the enzyme has a higher affinity for alachlor (K,,,app = 1.69 millimolar) than for metolachlor (K",app = 8.9 millimolar).
When rat brain myelin was examined by sodium dodecyl sulphate/polyacrylamideslab-gel electrophoresis followed by fluorography of the stained gel, it was found that a host of proteins of rat brain myelin were labelled 2, 4 and 24h after the intracerebral injection of H(3) (32)PO(4). Among those labelled were proteins migrating to the positions of myelin-associated glycoprotein, Wolfgram proteins, proteolipid protein, DM-20 and basic proteins. The four basic proteins with mol.wts. 21000, 18000 (large basic protein), 17000 and 14000 (small basic protein) were shown to be phosphorylated after electrophoresis in both acid-urea- and sodium dodecyl sulphate-containing gel systems followed by fluorography. The four basic proteins imparted bluish-green colour, after staining with Amido Black, which is characteristic of myelin basic proteins. The four basic proteins were purified to homogeneity. Fluorography of the purified basic proteins after re-electrophoresis revealed the presence of phosphorylated high-molecular-weight ;polymers' associated with each basic protein. The amino acid compositions of the phosphorylated large basic protein and small basic proteins are compatible with the amino acid sequences. Proteins with mol.wts. 21000 and 17000 gave the expected amino acid composition of myelin basic proteins. Radiolabelled phosphoserine and phosphothreonine were identified after partial acid hydrolysis of the four purified basic proteins. The [(32)P]phosphate-protein bond in the basic protein was stable at an acidic pH but was readily hydrolysed at alkaline pH, as would be expected of phosphoester bonds involving both serine and threonine residues. Double-immunodiffusion analysis demonstrated that the four phosphorylated proteins showed complete homology when diffused against antiserum to a mixture of small and large basic proteins. Since the four basic proteins of rat brain myelin were phosphorylated both in vivo and in vitro it is postulated that the same protein kinase is responsible for their phosphorylation in both conditions.
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