Soybean (Glycine max [L.] Merrill) mutant aj6 carries a single recessive lesion, aj6, that eliminates ubiquitous urease activity in leaves and callus while retaining normal embryo-specific urease activity. Consistently, aj6/aj6 plants accumulated urea in leaves. In crosses of aj6/aj6 by urease mutants at the Eu1, Eu2, and Eu3 loci, F 1 individuals exhibited wild-type leaf urease activity, and the F 2 segregated urease-negative individuals, demonstrating that aj6 is not an allele at these loci. F 2 of aj6/aj6 crossed with a null mutant lacking the Eu1-encoded embryo-specific urease showed that ubiquitous urease was also inactive in seeds of aj6/aj6. The cross of aj6/aj6 to eu4/eu4, a mutant previously assigned to the ubiquitous urease structural gene (R.S. Torisky, J.D. Griffin, R.L. Yenofsky, J.C. Polacco [1994] Mol Gen Genet 242: 404-414), yielded an F 1 having 22% Ϯ 11% of wild-type leaf urease activity. Coding sequences for ubiquitous urease were cloned by reverse transcriptase-polymerase chain reaction from wild-type, aj6/aj6, and eu4/eu4 leaf RNA. The ubiquitous urease had an 837-amino acid open reading frame (ORF), 87% identical to the embryo-specific urease. The aj6/aj6 ORF showed an R201C change that cosegregated with the lack of leaf urease activity in a cross against a urease-positive line, whereas the eu4/eu4 ORF showed a G468E change. Heteroallelic interaction in F 2 progeny of aj6/aj6 ϫ eu4/eu4 resulted in partially restored leaf urease activity. These results confirm that aj6/aj6 and eu4/eu4 are mutants affected in the ubiquitous urease structural gene. They also indicate that radical amino acid changes in distinct domains can be partially compensated in the urease heterotrimer.The main function of urease in plants is to recycle N from urea. In soybean (Glycine max [L.] Merrill), this is particularly important during germination when storage proteins are mobilized to nourish the seedling. Most of the large endogenously generated urea pool comes from Arg (Stebbins and Polacco, 1995), which constitutes 18% of storage protein N (Micallef and Shelp, 1989) and is actively degraded to urea and Orn upon germination (Goldraij and Polacco, 1999). Urease catalyzes N reconversion from urea to ammonia, which is subsequently assimilated via Gln synthetase (Lam et al., 1996). Urease also recycles N derived from urea exogenously applied as a foliar fertilizer (Witte et al., 2002). A potential urease role in maintaining N 2 fixation under water stress was posited in a model by Purcell et al. (2000) and Vadez and Sinclair (2001), whereby urea is generated directly from ureides in soybean cultivars (e.g. Maple arrow) able to fix N 2 under water deficit. Ureides are converted to urea in reactions that are not affected by water deficit thus avoiding ureide buildup and its inhibition of N fixation (Serraj et al., 1999). In this model, urease is essential to N use in soybean cultivars adapted to dry areas where fixed N is the sole or major N source. Drought-sensitive cultivars, however, are purported to bypass urea p...
