Development of a binary vector system for plant transformation based on the supervirulent Agrobacterium tumefaciens strain Chry5.

This report describes the disarming of Agrobacterium tumefaciens Chry5, a strain highly tumorigenic on soybean. Disarming was achieved by removing an approximately 16.5-kb segment of the 285-kb Ti plasmid pTiChry5, including approximately 4 kb of the oncogenic T-DNA and an extended region right of the T-DNA, and replacing it with a gene for carbenicillin resistance, through homologous recombination. The deletion was confirmed with Southern analysis, and the loss of tumorigenicity was verified in tobacco and tomato plant stem inoculation assays. The deletion mutant, named KYRT1, successfully transferred the ß-glucuronidase (GUS) gene into tobacco leaf tissue, producing GUS-expressing callus which could be regenerated into viable plants. In a comparative study, the transformation efficiency of A. tumefaciens KYRT1, GV3850, and EHA105 was assayed by inoculating cotyledonary node explants. The results of this study revealed that, in a binary vector system, KYRT1 is equally or more effective than EHA105 or GV3850 at delivering DNA into soybean.

A single gene (Eu4) encodes the tissue-ubiquitous urease of soybean.

We sought to determine the genetic basis of expression of the ubiquitous (metabolic) urease of soybean. This isozyme is termed the metabolic urease because its loss, in eu4/eu4 mutants, leads to accumulation of urea, whereas loss of the embryo-specific urease isozyme does not. The eu4 lesion eliminated the expression of the ubiquitous urease in vegetative and embryonic tissues. RFLP analysis placed urease clone LC4 near, or within, the Eu4 locus. Sequence comparison of urease proteins (ubiquitous and embryo-specific) and clones (LC4 and LS1) indicated that LC4 and LS1 encode ubiquitous and embryo-specific ureases, respectively. That LC4 is transcribed into poly(A)+ RNA in all tissues was indicated by the amplification of its transcript by an LC4-specific PCR primer. (The LS1-specific primer, on the other hand, amplified poly(A)+ RNA only from developing embryos expressing the embryo-specific urease.) These observations are consistent with Eu4 being the ubiquitous urease structural gene contained in the LC4 clone. In agreement with this notion, the mutant phenotype of eu4/eu4 callus was partially corrected by the LC4 urease gene introduced by particle bombardment.

Soybean Roots Retain the Seed Urease Isozyme Synthesized during Embryo Development.

Roots of young soybean (Glycine max [L.] Merr.) plants (up to 25 days old) contain two distinct urease isozymes, which are separable by hydroxyapatite chromatography. These two urease species (URE1 and URE2) differ in: (a) electrophoretic mobility in native gels, (b) pH dependence, and (c) recognition by a monoclonal antibody specific for the seed ("embryo-specific") urease. By these parameters root URE1 urease is similar to the abundant embryo-specific urease isozyme, while root URE2 resembles the "ubiquitous" urease which has previously been found in all soybean tissues examined (leaf, embryo, seed coat, and cultured cells). The embryo-specific and ubiquitous urease isozymes are products of the Eu1 and Eu4 structural genes, respectively. Roots of the eu1-sun/eu1-sun genotype, which lacks the embryo-specific urease (i.e. ;seed urease-null'), contain no URE1 urease activity. Roots of eu4/eu4, which lacks ubiquitous urease, lack the URE2 (leaflike) urease activity. From these genetic and biochemical criteria, then, we conclude that URE1 and URE2 are the embryo-specific and ubiquitous ureases, respectively. Adventitious roots generated from cuttings of any urease genotype lack URE1 activity. In seedling roots the seedlike (URE1) activity declines during development. Roots of 3-week-old plants contain 5% of the total URE1 activity of the radicle of 4-day-old seedlings, which, in turn, has approximately the same urease activity level as the dormant embryonic axis. The embryo-specific urease incorporates label from [(35)S]methionine during embryo development but not during germination, indicating that there is no de novo synthesis of the embryo-specific (URE1) urease in the germinating root. We conclude that the seedlike urease (URE1) found in roots of young soybean plants is a remnant of the Eu1-encoded, abundant, embryo-specific urease which accumulates in the embryonic root axis during seed development.

Activation state of ribulose bisphosphate carboxylase in soybean leaves.

Conditions for extraction and assay of ribulose-1,5-bisphophate carboxylase present in an in vivo active form (initial activity) and an inactive form able to be activated by Mg(2+) and CO(2) (total activity) were examined in leaves of soybean, Glycine max (L.) Merr. cv Will. Total activity was highest after extracts had preincubated in NaHCO(3) (5 millimolar saturating) and Mg(2+) (5 millimolar optimal) for 5 minutes at 25 degrees C or 30 minutes at 0 degrees C before assay. Initial activity was about 70% of total activity. K(act) (Mg(2+)) and K(act) (CO(2)) were approximately 0.3 millimolar and 36 micromolar, respectively. The carry-over of endogenous Mg(2+) in the leaf extract was sufficient to support considerable catalytic activity. While Mg(2+) was essential for both activation and catalysis, Mg(2+) levels greater than 5 millimolar were increasingly inhibitory of catalysis. Similar inhibition by high Mg(2+) was also observed in filtered, centrifuged, or desalted extracts and partially purified enzyme. Activities did not change upon storage of leaves for up to 4 hours in ice water or liquid nitrogen before homogenization, but were about 20% higher in the latter. Activities were also stable for up to 2 hours in leaf extracts stored at 0 degrees C. Initial activity quickly deactivated at 25 degrees C in the absence of high CO(2). Total activity slowly declined irreversibly upon storage of leaf homogenate at 25 degrees C.

Effect of irradiance during growth of Glycine max on photosynthetic capacity and percent activation of ribulose 1,5-bisphosphate carboxylase.

The initial (in vivo) and total (activity present after preincubation with CO2 and Mg(2+)) activities of ribulose bisphosphate carboxylase were both assayed in extracts of leaves of soybean (Glycine max) plants which had been grown under 4 different irradiance levels. The total carboxylase activity per unit leaf area decreased with decreased irradiance during growth but was not different on a dry weight basis. The initial activity as a percentage of the total activity was unchanged (approximately 95%) except in leaves of plants grown at the lowest irradiance (74%). When the plants grown at the lowest irradiance were exposed to high irradiance, the initial activity was increased to 93% of the total. Light saturated rates of photosynthesis per unit leaf area were lower and saturated at lower irradiance for plants grown at lower irradiances. Initial carboxylase activity was correlated closely (r(2)=0.84) with leaf photosynthesis rate on a dry weight basis.