We isolated two tomato (Lycopersicon esculentum) cDNA clones, tomPRO1 and tomPRO2, specifying ⌬ 1 -pyrroline-5-carboxylate synthetase (P5CS), the first enzyme of proline (Pro) biosynthesis. tomPRO1 is unusual because it resembles prokaryotic polycistronic operons (M.G. García-Ríos, T. Fujita, P.C. LaRosa, R.D. Locy, J.M. Clithero, R.A. Bressan, L.N. Csonka [1997] Proc Natl Acad Sci USA 94: 8249-8254), whereas tomPRO2 encodes a fulllength P5CS. We analyzed the accumulation of Pro and the tomPRO1 and tomPRO2 messages in response to NaCl stress and developmental signals. Treatment with 200 mM NaCl resulted in a >60-fold increase in Pro levels in roots and leaves. However, there was a <3-fold increase in the accumulation of the tomPRO2 message and no detectable induction in the level of the tomPRO1 message in response to NaCl stress. Although pollen contained approximately 100-fold higher levels of Pro than other plant tissues, there was no detectable increase in the level of either message in pollen. We conclude that transcriptional regulation of these genes for P5CS is probably not important for the osmotic or pollenspecific regulation of Pro synthesis in tomato. Using restriction fragment-length polymorphism mapping, we determined the locations of tomPRO1 and tomPRO2 loci in the tomato nuclear genome. Sequence comparison suggested that tomPRO1 is similar to prokaryotic P5CS loci, whereas tomPRO2 is closely related to other eukaryotic P5CS genes.
We isolated from a tomato cDNA library the tomPRO1 locus, which encodes ␥-glutamyl kinase (GK) and ␥-glutamyl phosphate reductase (GPR). This locus is unusual among eukaryotic genetic elements because it contains two open reading frames, and thus resembles prokaryotic polycistronic operons. The first open reading frame, specifying GK, is terminated by a TAA codon, which is followed by five nucleotides, an ATG translation initiation codon, and the second open reading frame, encoding GPR. DNA sequence analysis of fragments obtained by PCR amplification confirmed that the internal TAA and neighboring sequences are present in the endogenous tomPRO1 sequence in tomato. We demonstrated with RNase protection assays that the tomPRO1 locus is transcribed in tomato tissue culture cells, into a product that contains the internal stop codon. In Escherichia coli, tomPRO1 directed the synthesis of two proteins, a 33-kDa GK and a 44-kDa GPR. Antibodies against the 44-kDa GPR purified from E. coli recognized a 70-kDa product in tomato tissue culture cells and a 60-kDa product in leaves and roots. These results suggest that in tomato tissues, GPR is made as part of a longer polypeptide by some translational mechanism that enables bypass of the internal stop codon, such as frameshifting or ribosome hopping. The tomPRO1 locus may be the first example of a nuclear genetic element in plants that encodes two functional enzymes in two distinct open reading frames.
The first step of proline biosynthesis is catalyzed by ␥-glutamyl kinase (GK). To better understand the feedback inhibition properties of GK, we randomly mutagenized a plasmid carrying tomato tomPRO1 cDNA, which encodes proline-sensitive GK. A pool of mutagenized plasmids was transformed into an Escherichia coli GK mutant, and proline-overproducing derivatives were selected on minimal medium containing the toxic proline analog 3,4-dehydro-DL-proline. Thirty-two mutations that conferred 3,4-dehydro-DL-proline resistance were obtained. Thirteen different single amino acid substitutions were identified at nine different residues. The residues were distributed throughout the Nterminal two-thirds of the polypeptide, but 9 mutations affecting 6 residues were in a cluster of 16 residues. GK assays revealed that these amino acid substitutions caused varying degrees of diminished sensitivity to proline feedback inhibition and also resulted in a range of increased proline accumulation in vivo. GK belongs to a family of amino acid kinases, and a predicted threedimensional model of this enzyme was constructed on the basis of the crystal structures of three related kinases. In the model, residues that were identified as important for allosteric control were located close to each other, suggesting that they may contribute to the structure of a proline binding site. The putative allosteric binding site partially overlaps the dimerization and substrate binding domains, suggesting that the allosteric regulation of GK may involve a direct structural interaction between the proline binding site and the dimerization and catalytic domains.
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