Structural characterization of Tobacco etch virus coat protein mutants.

The assembly of Tobacco etch potyvirus (TEV) coat protein (CP) and truncated mutants in Escherichia coli was studied. CP from which 28, 63 or 112 amino acids were deleted from the N-terminus polymerized into potyvirus-like particles (PVLPs). These structures were more rigid and progressively smaller in diameter than those produced by full length TEV-CP. CP from which 175 N-terminal amino acids were removed, failed to polymerize. A fragment containing amino acids 131 to 206 of TEV-CP is sufficient for PVLP assembly in E. coli. To determine the function of the highly conserved amino acids Ser152, Arg154, and Asp198 point mutants were generated. The mutant CPDelta63(Asp198Glu) exhibited different spectral properties following circular dichroism analysis showing a lower amount of alpha-helix compared to the wild type molecule. No differences were observed in spectra obtained from fluorescence spectroscopy. The point mutants bind RNA in vitro to the same degree as the wild type protein. However, while the wild type and the Arg154Gln mutant CP were each able to form PVLPs in E. coli, the Asp198Glu and the double mutant Ser152Pro/Arg154Gln mutants did not. These results suggest that the Asp198Glu mutation has an altered secondary structure which affects the capacity of the protein to polymerize but did not affect in vitro protein-RNA interactions.

Genetic analysis of a region of the Rhizobium meliloti pSym plasmid specifying catabolism of trigonelline, a secondary metabolite present in legumes.

Genes controlling the catabolism of trigonelline, a secondary metabolite that is often present in legumes, are located on the pSym megaplasmid of Rhizobium meliloti. To investigate the role of bacterial trigonelline catabolism in the Rhizobium-legume symbiosis, we identified and characterized the R. meliloti RCR2011 genetic loci (trc) controlling trigonelline catabolism. Tn5-B20 mutagenesis showed that the trc region is a continuous DNA segment of 9 kb located 4 kb downstream of the nifAB and fdxN genes. Trc mutants fell into two classes according to their phenotype and location: (i) mutants carrying Tn5-B20 insertions in the right-hand part of the trc region were incapable of growing on trigonelline as the sole carbon and/or nitrogen source, and (ii) insertions in the left-hand part of the trc region resulted in delayed growth on trigonelline as the sole carbon and/or nitrogen source. No significant defect in nodule formation or nitrogen fixation was detected for mutants of either class. Screening of a set of R. meliloti strains from various geographical origins showed that all of these strains are able to catabolize trigonelline and show sequence homology between their megaplasmids and a trc probe.

Rhizobium meliloti Genes Encoding Catabolism of Trigonelline Are Induced under Symbiotic Conditions.

Rhizobium meliloti trc genes controlling the catabolism of trigonelline, a plant secondary metabolite often abundant in legumes, are closely linked to nif-nod genes on the symbiotic megaplasmid pSym [Boivin, C., Malpica, C., Rosenberg, C., Denarie, J., Goldman, A., Fleury, V., Maille, M., Message, B., and Tepfer, D. (1989). In Molecular Signals in the Microbe-Plant Symbiotic and Pathogenic Systems. (Berlin: Springer-Verlag), pp. 401-407]. To investigate the role of trigonelline catabolism in the Rhizobium-legume interaction, we studied the regulation of trc gene expression in free-living and in endosymbiotic bacteria using Escherichia coli lacZ as a reporter gene. Experiments performed with free-living bacteria indicated that trc genes were organized in at least four transcription units and that the substrate trigonelline was a specific inducer for three of them. Noninducing trigonelline-related compounds such as betaines appeared to antagonize the inducing effect of trigonelline. None of the general or symbiotic regulatory genes ntrA, dctB/D, or nodD seemed to be involved in trigonelline catabolism. trc fusions exhibiting a low basal and a high induced [beta]-galactosidase activity when present on pSym were used to monitor trc gene expression in alfalfa tissue under symbiotic conditions. Results showed that trc genes are induced during all the symbiotic steps, i.e., in the rhizosphere, infection threads, and bacteroids of alfalfa, suggesting that trigonelline is a nutrient source throughout the Rhizobium-legume association.