Expression of legumin and vicilin genes in pea mutants and the production of legumin in transgenic plants.

Pea seeds contain two major storage proteins, legumin and vicilin, in proportions that are genetically and environmentally determined. They are synthesized from at least 40 genes and at least 10 different genetic loci. Mutant alleles at loci involved in starch synthesis, which result in perturbations in starch accumulation, also affect the expression of legumin genes, thereby influencing the legumin: vicilin ratio within the total seed protein. Examples of such alleles include r (starch-branching enzyme) and rb (ADP-glucose pyrophosphorylase), both of which result in a reduction in legumin synthesis; double mutants (rrb) show a particularly severe reduction in the amount of legumin. The effects of such mutations are specific to legumins. The amounts of vicilin are unaffected by mutations at r or rb. One of the consequences of the production of legumin from many genes is structural heterogeneity that is believed to preclude the purification of homogeneous legumin for crystallization and 3D-structure determination. Expression of cloned legumin cDNA in E. coli can result in sequence homogeneity, but E. coli is unable to carry out the normal proteolytic processing of legumin precursors and consequently such material is different from that produced in pea seeds. This paper describes the high-level synthesis, processing and assembly of pea legumin in transgenic wheat seeds, leading to the spontaneous in vitro formation of paracrystalline arrays of legumin, which may be attributed to the fact that the legumin consists of a single type of subunit. Such material might be used as a source of single-sequence, processed and assembled pea legumin for structural investigation.

Simultaneous reduction of the activity of two related enzymes, involved in early steps of the polyamine biosynthetic pathway, by a single antisense cDNA in transgenic rice.

Transgenic rice cell lines transformed with a heterologous cDNA derived from the arginine decarboxylase gene of oat, in an antisense orientation, exhibited significant (P < 0.05) down-regulation of the activity of the endogenous arginine and ornithine decarboxylases, compared to wild type and controls transformed only with the selectable marker (hpt). Changes in enzyme activity were reflected in a marked decrease in the level of putrescine (P < 0.001) and spermidine (P < 0.01) but not spermine (P > 0.05) in the majority of cell lines analyzed. In agreement with previous results, we confirmed that cell lines with low levels of polyamines exhibited normal morphogenic responses. In vegetative tissue at the whole plant level no significant variation (P > 0.05) in polyamine levels was observed. However, we measured significant reductions (P < 0.001) in putrescine levels in seeds derived from three out of five plants analyzed in detail. Thus, simultaneous reduction of the activity of the two alternative enzymes in the early steps of the polyamine pathway results in significant reduction in end-product accumulation in the seeds of transgenic plants.

Insertion of a casein kinase recognition sequence induces phosphorylation of ovine beta-lactoglobulin in transgenic mice.

We have shown that the cellular mechanisms of the mammary gland can be used to produce a phosphorylated form of a normally unphosphorylated milk protein. This was achieved by the insertion of a beta-casein DNA sequence coding for a group of mammary gland casein kinase recognition sites into ovine beta-lactoglobulin. Transgenic mice carrying this modified gene were generated and lactating females were shown to produce a novel beta-lactoglobulin in their milk. The infrared spectrum, reactivity to antiphosphoserine antibody and reduction of electrophoretic mobility on treatment with alkaline phosphatase showed that the novel protein recovered from the milk whey (serum) was phosphorylated and molecular mass determination by mass spectrometry was consistent with the phosphorylation of one or two residues. A similar level of phosphorylation was measured by quantitative infrared spectroscopy. Centrifugation of the milk to pellet the casein micelles showed that most of the phosphorylated beta-lactoglobulin was in the whey and hence not incorporated into casein micelles.

Bovine beta-casein expressed in transgenic mouse milk is phosphorylated and incorporated into micelles.

Transgenic mice carrying the bovine beta-casein gene linked to the promoter sequence of the sheep beta-lactoglobulin milk protein gene were produced. Four of seven lines expressed the transgene protein with mice from the two highest expressing lines producing 4 to 5 mg ml(-1) of this protein in their milk. The foreign protein was associated with the casein micelles and did not segregate into the whey fraction on centrifugation of milk samples. Following purification, the protein was characterized by amino acid analysis, gel electrophoresis, capillary zone electrophoresis, and trypsinolysis. The results showed that the transgene protein was authentic, phosphorylated bovine beta-casein A(1).

Gene-for-gene interactions between Pseudomonas syringae pv. phaseolicola and Phaseolus.

The gene for cultivar-specific avirulence to Phaseolus vulgaris cv. Tendergreen in races 3 and 4 of Pseudomonas syringae pv. phaseolicola was isolated and sequenced. Genomic clones from libraries of race 3 in pLAFR1 and race 4 in pLAFR3, which altered the phenotype of race 5 from virulent to avirulent in Tendergreen, were found to possess a common approximately 15-kb region of DNA that contained the determinant of avirulence. Subcloning and insertion mutagenesis with Tn1000 located an avirulence gene within a 1.4-kb BglII/HindIII DNA fragment in races 3 and 4. Comparison of the nucleotide sequences of regions of DNA that confer avirulence confirmed that both races have an identical gene for avirulence (designated avrPph3) comprising 801 base pairs (bp) and predicted to encode a cytoplasmic protein of 28,703 Da. A sequence, TGCAACCGAAT, 91% homologous to the motif found in promoter regions of avrB and avrD from P. s. pv. glycinea was located 89-99 bp upstream of the start of the open-reading frame 1. Hybridization experiments showed that avrPph3 was not plasmid-borne and was absent from isolates of P. s. pv. phaseolicola races 1, 2, 5, 6, 7, and 8, P. cichorii, P. s. pvs. coronafaciens, glycinea, maculicola, pisi, syringae, and tabaci. Cosegregation studies of crosses between cultivars resistant (Tendergreen) and susceptible (Canadian Wonder) to races 3 and 4 and transconjugants of race 5 confirmed that a gene-for-gene relationship controls specificity in the interaction between Tendergreen and races 3 and 4 of P. s. pv. phaseolicola.

Molecular cloning, expression and nucleotide sequence of the rcsA gene of Erwinia amylovora, encoding a positive regulator of capsule expression: evidence for a family of related capsule activator proteins.

A gene encoding a positive activator of the expression of extracellular polysaccharide (EPS) synthesis in the phytopathogen Erwinia amylovora has been isolated from a genomic library in Escherichia coli. The presence of the cloned gene in E. coli stimulated transcription of the genes encoding colanic acid biosynthesis and could complement rcsA mutations. Introduction of the gene on a multicopy plasmid into Er. amylovora caused a threefold increase in EPS expression. The nucleotide sequence of the gene (designated rcsA) was determined. This revealed a single open reading frame encoding an RcsA protein of 23-7 kDa. This was confirmed by minicell analysis in E. coli. The predicted amino acid sequence of this RcsA protein showed a high degree of homology to the RcsA protein of Klebsiella aerogenes, demonstrating the existence of a family of related RcsA activator proteins capable of stimulating EPS expression. The protein had no significant homology to known DNA-binding activator proteins, indicating, for the first time, that the RcsA family of activator proteins may stimulate expression of EPS synthesis indirectly by acting on other regulatory proteins.