Functional rescue of a bacterial dapA auxotroph with a plant cDNA library selects for mutant clones encoding a feedback-insensitive dihydrodipicolinate synthase.

Dihydrodipicolinate synthase (DHDPS; EC4.2.1.52) catalyses the first reaction of lysine biosynthesis in plants and bacteria. Plant DHDPS enzymes are strongly inhibited by lysine (I0.5 approximately 10 microM), whereas the bacterial enzymes are less (50-fold) or insensitive to lysine inhibition. We found that plant dhdps sequences expressing lysine-sensitive DHDPS enzymes are unable to complement a bacterial auxotroph, although a functional plant DHDPS enzyme is formed. As a consequence of this, plant dhdps cDNA clones which have been isolated through functional complementation using the DHDPS-deficient Escherichia coli strain encode mutated DHDPS enzymes impaired in lysine inhibition. The experiments outlined in this article emphasize that heterologous complementation can select for mutant clones when altered protein properties are requisite for functional rescue. In addition, the mutants rescued by heterologous complementation revealed a new critical amino acid substitution which renders lysine insensitivity to the plant DHDPS enzyme. An interpretation is given for the impaired inhibition mechanism of the mutant DHDPS enzyme by integrating the identified amino acid substitution in the DHDPS protein structure.

Arabidopsis loss-of-function mutant in the lysine pathway points out complex regulation mechanisms.

In plants, the amino acids lysine, threonine, methionine and isoleucine have L-aspartate-beta-semialdehyde (ASA) as a common precursor in their biosynthesis pathways. How this ASA precursor is dispersed among the different pathways remains vague knowledge. The proportional balances of free and/or protein-bound lysine, threonine, isoleucine and methionine are a function of protein synthesis, secondary metabolism and plant physiology. Some control points determining the flux through the distinct pathways are known, but an adequate explanation of how the competing pathways share ASA in a fine-tuned amino acid biosynthesis network is yet not available. In this article we discuss the influence of lysine biosynthesis on the adjacent pathways of threonine and methionine. We report the finding of an Arabidopsis thaliana dihydrodipicolinate synthase T-DNA insertion mutant displaying lower lysine synthesis, and, as a result of this, a strongly enhanced synthesis of threonine. Consequences of these cross-pathway regulations are discussed.

The Arabidopsis thaliana dhdps gene encoding dihydrodipicolinate synthase, key enzyme of lysine biosynthesis, is expressed in a cell-specific manner.

Lysine synthesis in prokaryotes, some phycomycetes and higher plants starts with the condensation of L-aspartate-beta-semialdehyde (L-ASA) and pyruvate into dihydrodipicolinic acid. The enzyme that catalyses this step, dihydrodipicolinate synthase (DHDPS), is inhibited by the end-product lysine and is therefore thought to have a regulatory control on lysine synthesis. We have cloned and sequenced an Arabidopsis thaliana DNA fragment containing 900 bases upstream of the dhdps coding sequence. A transcriptional fusion of this fragment with the beta-glucuronidase reporter gene (uidA. Gus) was used to study the transcription properties of this promoter fragment (DS). No lysine-induced repression on transcription could be detected. Expression of DS-Gus activity in transformed Arabidopsis thaliana and Nicotiana tabacum was found to be cell type-specific. In the vegetative parts of the plant, GUS activity was located in meristems and young vasculature of roots, in vasculature of stem and leaves and in the meristems of young shoots. In flowers, high expression was found in the carpels, style, stigma, developing embryos, tapetum of young anthers and pollen. We demonstrated that the Arabidopsis DS promoter can direct its cell type-specific expression in a heterologous plant, Nicotiana tuabacum. The importance of transcriptional regulation of the dhdps gene, and in more general genes involved in amino acid biosynthesis, is discussed.

Sequence diversity of the oprI gene, coding for major outer membrane lipoprotein I, among rRNA group I pseudomonads.

The sequence of oprI, the gene coding for the major outer membrane lipoprotein I, was determined by PCR sequencing for representatives of 17 species of rRNA group I pseudomonads, with a special emphasis on Pseudomonas aeruginosa and Pseudomonas fluorescens. Within the P. aeruginosa species, oprI sequences for 25 independent isolates were found to be identical, except for one silent substitution at position 96. The oprI sequences diverged more for the other rRNA group I pseudomonads (85 to 91% similarity with P. aeruginosa oprI). An accumulation of silent and also (but to a much lesser extent) nonsilent substitutions in the different sequences was found. A clustering according to the respective presence and/or positions of the HaeIII, PvuII, and SphI sites could also be obtained. A sequence cluster analysis showed a rather widespread distribution of P. fluorescens isolates. All other rRNA group I pseudomonads clustered in a manner that was in agreement with other studies, showing that the oprI gene can be useful as a complementary phylogenetic marker for classification of rRNA group I pseudomonads.

Molecular characterization of an Arabidopsis thaliana cDNA coding for a monofunctional aspartate kinase.

A cDNA clone encoding a monofunctional aspartate kinase (AK, ATP:L-aspartate 4-phosphotransferase, EC 2.7. 2.4) has been isolated from an Arabidopsis thaliana cell suspension cDNA library using a homologous PCR fragment as hybridizing probe. Amplification of the PCR fragment was done using a degenerate primer designed from a conserved region between bacterial monofunctional AK sequences and a primer identical to a region of the A. thaliana bifunctional aspartate kinase-homoserine dehydrogenase (AK-HSDH). By comparing the deduced amino acid sequence of the fragment with the bacterial and yeast corresponding gene products, the highest identity score was found with the Escherichia coli AKIII enzyme that is feedback-inhibited by lysine (encoded by lysC). The absence of HSDH-encoding sequence at the COOH end of the peptide further implies that this new cDNA is a plant lysC homologue. The presence of two homologous genes in A. thaliana is supported by PCR product sequences, Southern blot analysis and by the independent cloning of the corresponding second cDNA (see Tang et al., Plant Molecular Biology 34, pp. 287-294 [this issue]). This work is the first report of cloning a plant putative lysine-sensitive monofunctional AK cDNA. The presence of at least two genes is discussed in relation to possible different physiological roles of their respective product.

Isolation of a poplar and an Arabidopsis thaliana dihydrodipicolinate synthase cDNA clone.

A poplar DHDPS cDNA clone has been isolated by functional rescue of the dapA-deficient AT997 mutant of Escherichia coli. By sequence comparison between the poplar and maize DHDPS cDNAs, two oligonucleotides were designed to perform polymerase chain reaction (PCR) on Arabidopsis thaliana genomic DNA. The PCR fragment was subsequently used to isolate an Arabidopsis DHDPS genomic and cDNA clone.

Construction and characterisation of a yeast artificial chromosome library containing five haploid sugarbeet (Beta vulgaris L.) genome equivalents.

A yeast artificial chromosome (YAC) genomic library of Beta vulgaris was constructed in the pYAC4 vector. High-molecular-weight DNA was prepared from agarose-embedded leaf protoplasts from a triploid cultivar. The library was found to contain 33,500 clones in an ordered array of microtiter plates. Mean size of the inserts was estimated to be 135 kb, and the library should therefore represent the equivalent of five haploid genomes. The library was characterised for the presence of highly repetitive, chloroplast and single-copy sequences. In order to isolate single-copy sequences, 18 pools of DNA, each from 1920 individual YAC clones, were prepared for rapid screening of the library by the polymerase chain reaction. The results of these screenings showed that the number of isolated clones was at or near the frequency expected.