Conversion of versiconal acetate to versiconal and versicolorin C in extracts from Aspergillus parasiticus

The primary product of hydrolysis of versiconal acetate catalyzed by porcine liver esterase and the 35–70% ammonium sulfate fraction from a soluble extract from mycelia of Aspergillus parasiticus was versiconal. Versiconal was stable at neutral pH for several hours and was rapidly converted to versi-colorin C by treatment with 0.4 M HCl. The addition of NADPH to the 35–70% ammonium sulfate fraction resulted in conversion of versiconal acetate to both versiconal and versicolorin C. The conversion of versiconal acetate to versicolorin C in the cell-free system is proposed to involve an esterase and an NADPH-dependent cyclase.     

Phosphorylation influences the binding of the yeast RAP1 protein to the upstream activating sequence of the PGK gene.

Yeast repressor activator protein 1 (RAP1) binds in vitro to specific DNA sequences that are found in diverse genetic elements. Expression of the yeast phosphoglycerate kinase gene (PGK) requires the binding of RAP1 to the activator core sequence within the upstream activating sequence (UAS) of PGK. A DNA fragment Z+ which contains the activator core sequence of the PGK(UAS) has been shown to bind RAP1. Here we report that phosphatase treatment of RAP1 affected its binding to the PGK(UAS) but that this depended on the nature of the sequence flanking the 5' end of the activator core sequence. When the sequence flanking the 5' end of the activator core sequence was different from the PGK RAP1-binding site, phosphatase treatment of RAP1 decreased its binding to the DNA. When the 5' end of the binding site was a match to the PGK RAP1-binding site dephosphorylation of RAP1 increased RAP1 binding to the DNA. These observations were reproduced when the minimal functional DNA-binding domain of the RAP1 protein was used, implicating a phosphorylation-dependent binding of RAP1. This is the first evidence for phosphorylation-dependent binding of RAP1.     

Absorption, translocation, and metabolism of14C-clomazone in soybean (Glycine max) and threeAmaranthus weed species

The patterns of clomazone (2-[(2-chlorophenyl) methyl-4,4-dimethyl-3-isoxazolidinone) absorption, translocation, and metabolism and their contribution to the plant selectivity of this herbicide were studied in tolerant soybean [Glycine max (L.) Merr.] andAmaranthus hybridus and in susceptibleA. retroflexus andA. lividus. Differential root absorption appeared to play a significant role in the differential response of these four plant species to clomazone. Absorption of root-applied¹⁴C-clomazone was greater by the two sensitiveAmaranthus weeds than by the tolerant soybean andA. hybri-dus. Following application of¹⁴C-clomazone to roots, most of the absorbed radioactivity was translocated to the leaves of all four species. Approximately 50% of the absorbed¹⁴C-clomazone was metabolized by all four plant species as early as 12 h after treatment. Thin layer Chromatographic (TLC) analysis of plant tissue extracts from all four species revealed the formation of two major metabolites of clomazone. These unidentified metabolites had Rf values of 0.4 and 0.8, respectively, in a butanolacetic acidwater (1235, vol/vol/vol) developing system. The Rf value of unaltered clomazone in this system was 0.95. Differential metabolism or differential rate of metabolism of clomazone was not observed in this study and did not seem to account for the tolerance of soybean andA. hybridus or the suceptibility ofA. retroflexus andA. lividus to this herbicide.Plant Pathology, Physiology, and Weed Science Department, Contribution No. 600.     

Gene splicing by overlap extension: tailor-made genes using the polymerase chain reaction

Gene Splicing by Overlap Extension or "gene SOEing" is a PCR-based method of recombining DNA sequences without reliance on restriction sites and of directly generating mutated DNA fragments in vitro. By modifying the sequences incorporated into the 5'-ends of the primers, any pair of polymerase chain reaction products can be made to share a common sequence at one end. Under polymerase chain reaction conditions, the common sequence allows strands from two different fragments to hybridize to one another, forming an overlap. Extension of this overlap by DNA polymerase yields a recombinant molecule. This powerful and technically simple approach offers many advantages over conventional approaches for manipulating gene sequences.     

Primary Infection of Barley by Erysiphe graminis f. sp. hordei in Relation to Leaf-Age Dependent Resistance and the Roles of the Epidermis and Mesophyll in this Resistance

Abstract The infection frequency of both compatible and incompatible races of Erysiphe graminis f. sp. hordei decreased gradually with increasing leaf age on undetached primary barley leaves. The length of secondary hyphae of the compatible race was approximately the same regardless of age, but secondary hyphae were slightly longer on younger seedlings than on older seedlings in the case of the incompatible race. Both the infection frequency and length of secondary hyphae of the two races weredistinctly different. On composite sections produced by exchanging the epidermal layers of young and relatively mature primary leaves, the infection frequency of the compatible race was higher on the epidermis of young leaves than on the epidermis of older, leaves, regardless of which mesophyll was under the epidermis. The epidermis appears to play a major role in age-dependent resistance, while the mesophyll may act disparately by providing a factor promotive to mildew infection in addition to supporting the resistance function of the epidermis.