Origin, structure, and regulation of argK, encoding the phaseolotoxin-resistant ornithine carbamoyltransferase in Pseudomonas syringae pv. phaseolicola, and functional expression of argK in transgenic tobacco.

Pseudomonas syringae pv. phaseolicola produces the tripeptide N delta(N'-sulfo-diaminophosphinyl)-ornithylalanyl-homoarginin e (phaseolotoxin), which functions as a chlorosis-inducing toxin in the bean halo blight disease by inhibiting ornithine carbamoyltransferase (OCT). The bacterium possesses duplicate OCT genes, one of which, argK, encodes a toxin-resistant enzyme (ROCT) and imparts resistance to phaseolotoxin. We sequenced the argK gene from strain NPS3121, defined its promoter region, analyzed its regulation, and characterized its transcripts. The gene probably originated from another organism, since it is very distantly related to the argF gene encoding the housekeeping toxin-sensitive OCT and has low G+C content compared with the bacterial genome as a whole and with other protein-coding genes from P. syringae pv. phaseolicola. Optimized alignments of 13 OCT sequences allowed us to define key residues that may be responsible for toxin resistance and to identify a distinct prokaryotic amino acid signature, in ROCT, which argues for a prokaryotic origin of argK. An in-frame fusion of the argK coding region with the chloroplast transit peptide segment of the pea rbcS gene was introduced in Nicotiana tabacum by Agrobacterium-mediated transformation. The presence of an ROCT activity in transgenic plants was demonstrated by in vitro and in vivo assays. Some plants were toxin resistant, suggesting that pathogen-derived resistance to the toxin should be feasible in the pathogen's host

Kinetic constraints and features imposed by the immobilization of enzymes onto solid matrices: A key to advanced biotransformation

1045-1051The kinetics of immobilized enzymes can not be analyzed by means of the simple Michaelis-Menten concept, which generally fails to describe the immobilized state due to both its probable barriers, and because the active concentration of the enzyme approaches, or even exceeds this of its substrate(s). In such cases, the various experimental data are usually treated by complex rate equations comprising too many parameters acquiring different natures and meanings, depending on both the properties of the immobilization state and the experimental conditions; thus, more likely, only apparent values of the Michaelis-Menten kinetic parameters can be estimated experimentally. Likewise, immobilization is often a key method in optimizing the operational performance of enzymes, in both laboratory and industrial scale, and affects considerably the kinetics in non-aqueous and non-conventional media due to several issues as the structural changes of the enzyme molecule, the heterogeneity of the system, and the partial or total absence of water. In this work a theoretical approach is described on the formulation of simplified rate equations, reflecting also the actual mass balances of the reactants, in the case where esterification synthetic reactions are catalyzed by immobilized lipases, in either a non-aqueous organic solvent or in a non-solvent system