Herbicides test method

[0001] The invention relates to plant enzymatic activity, and aspects thereof, involved in the biosynthesis of Coenzyme A. The invention particularly relates to the plant enzyme known either as pantoateo-β-alanine ligase (EC 6.3.2.1), pantoate activating enzyme or pantothenate synthetase (PS). PS catalyses the synthesis of pantothenate.

[0002] PS is an essential enzyme in the in planta biosynthesis of the vitamin and Coenzyme A precursor pantothenate. It is known to catalyse the following reaction:

ATP+(R)-pantoate+β-alanine→AMP+pyrophosphate+(R)-pantothenate.

[0003] PS genes have previously been isolated from Escherichia coli (GenBank accession number P31663), Bacillus subtilis (GenBank accession number P52998), and the cyanobacterium Synechocystis (GenBank accession number U44896). DNA sequences from Saccharomyces cerevisiae (GenBank accession number P40459) and Schizosaccharomyces pombe (GenBank accession number Q09673) having unknown functions have been proposed to code for PS enzymes based on DNA and deduced amino acid sequence similarities. To date, however, no gene has been reported which codes for the PS enzyme in any plant species. It is therefore an object of the invention to identify, isolate and sequence a gene coding for the PS enzyme present in plants.

[0004] A number of assays have been reported for measuring PS activity. One assay developed by Maas (1950a and 1950b) uses a microbiological assay of pantothenate based on the ability to promote growth of an E. coli pantothenate auxotroph (M99-1, panC). The assay developed by Pfleiderer et al (1960) measures the AMP liberated in the PS reaction. In this assay, myokinase catalyses the production of 2 moles of ADP for each mole of AMP released in pantothenate synthesis using ATP supplied in the assay mixture. Pyruvate kinase then generates 2 moles of pyruvate and ATP for 2 moles of phosphoenolpyruvate and ADP. Finally, lactate dehydrogenase reduces 2 moles of pyruvate to yield 2 moles of lactate concomitant with stoichiometric oxidation of NADH to NAD, which can be monitored spectrophotometrically by following the absorbance at 340 nm. A third assay, developed by Miyatake et al (1979), employs an assay mix containing 14C-β-alanine and unlabelled pantoate. In this assay any 14C-pantothenate formed is separated from unreacted 14C-β-alanine by cation exchange chromatography and subsequently quantified by liquid scintillation counting. These assays, however, are not suitable for use with high throughput biochemical screening and cannot be used for the large scale biochemical screening of compounds necessary to discover useful inhibitors of PS.

[0005] We have developed an invention which addresses the above-mentioned drawbacks associated with the prior art. Our invention covers a number of related aspects which encompass the same inventive concept.

[0006] According to a first aspect of the invention there is provided an isolated DNA molecule encoding a protein from a plant, which protein has PS activity. In preferred embodiments, the DNA is isolated from Lotus japonicus or Oryza sativa.

[0007] To support our invention we herein disclose the cDNA sequence from Lotus japonicus. In addition, we have shown that a previously unassigned expressed sequence tag of Oryza sativa (GenBank accession number D25017) is part of a cDNA coding sequence for a PS enzyme in Oryza sativa and disclose, as part of this invention, the full cDNA sequence of the PS gene from Oryza sativa. Furthermore, we have confirmed by sequence similarity, functional complementatibn of an Escherichia coli mutant devoid of PS enzyme activity, and by enzyme assays that the DNA sequence from Saccharomyces cerevisiae (GenBank accession number P40459) putatively ascribed as coding for a PS enzyme does code for the PS enzyme of Saccharomyces cerevisiae. A cDNA sequence coding for a PS enzyme in Lotus japonicus is provided in FIG. 1.2. A cDNA sequence coding for a PS enzyme in Oryza sativa is provided in FIG. 2.2. A DNA sequence coding for a PS enzyme in Saccharomyces cerevisiae is provided in FIG. 3.3. As a result of our invention it is now possible to obtain the DNA coding sequence for the PS, enzyme(s) from any plant source using methods available to those skilled in the art.

[0008] A further preferred embodiment of this aspect of our invention is an isolated DNA molecule encoding a protein from Lotus japonicus having PS activity wherein said protein comprises the amino acid sequence set forth in FIG. 1.2. A still further embodiment is an isolated DNA molecule encoding a protein from Oryza sativa having PS activity wherein said protein comprises the amino acid sequence in FIG. 2.2.

[0009] In addition, we have extended our invention to include a further aspect so as to provide a non-naturally occurring chimeric gene comprising a promoter operably linked to a DNA molecule encoding a protein from a plant having PS activity. Preferably, the protein is isolated from a dicotyledonous or a monocotyledonous plant, such as Lotus japonicus or Oryza sativa. Preferably the amino acid sequence is selected from the group, set forth in FIG. 1.2 (Lotus japonicus) and FIG. 2.2 (Oryza sativa).

[0010] We have developed our invention into another aspect which provides a recombinant vector comprising a chimeric gene, wherein the vector is capable of being stably transformed into a host cell. Also comprised in this aspect is the host cell stably transformed with the vector wherein the host cell is preferably a cell selected from the group consisting of a bacterial cell, a yeast cell, and an insect cell and is further capable of expressing the DNA molecule according to the invention.

[0011] In a still further aspect we have applied our invention to the recombinant production of the PS enzyme. In particular, the invention provides a method of producing a protein having PS activity in a host organism by firstly inserting a DNA sequence encoding a protein having PS activity into an expression cassette designed for the chosen host; inserting the resultant molecule, containing the individual elements linked in proper reading frame into a vector capable of being transformed into the host cell; growing the thus transformed host cell in a suitable culture medium; and isolating the protein product either from the transformed cell or the culture medium, or both, and purifying it.

[0012] In addition, we have developed our invention to provide methods for assaying a protein having pantothenate synthetase activity comprising; incubating pantothenate synthetase in a suitable reaction mixture in which pantothenate synthetase is capable of catalysing the conversion of pantoate, □-alanine and ATP to pantothenate, AMP and pyrophosphate; determining the amount of pyrophosphate formed by a calorimetric technique based on the assay for pyrophosphate developed by Chang et al. (1983); or converting the pyrophosphate formed by the catalytic activity of the pantothenate synthetase into inorganic phosphate by the catalytic activity of an inorganic pyrophosphatase, preferably yeast inorganic pyrophosphatase; and determining the amount of inorganic phosphate generated by the catalytic activity of said inorganic pyrophosphatase by colorimetric techniques, preferably by techniques based either on the assay for inorganic phosphate developed by Lanzetta et al. (1979) or on the assay for inorganic phosphate developed by Chifflet et al. (1988).

[0013] The production of PS, for example by using the recombinant methodology described hereinabove, has enabled us to develop methods of using purified PS to screen for novel inhibitors of PS activity which may be used as herbicides to control undesirable vegetation in fields where crops are grown, particularly agronomically important crops such as maize and other cereal crops such as wheat, oats, rye, sorghum, rice, barley, millet, turf and forage grasses, and the like, as well as cotton sugar cane, sugar beet, oilseed rape, and soybeans.

[0014] In particular, the present invention relates to a method for assaying a chemical entity for the ability to inhibit the activity of a PS enzyme from a plant by:

[0015] a) combining said PS enzyme in a suitable reaction mixture in which

[0016] i) said PS enzyme is capable of catalysing the conversion of pantoate, β-alanine and ATP to pantothenate, AMP and pyrophosphate;

[0017] ii) the pyrophosphate liberated in the PS reaction is determined by a calorimetric method, preferably by a method based on the assay for pyrophosphate developed by Chang et al. (1983);

[0018] iii) or the pyrophosphate liberated in the PS reaction is further converted to inorganic phosphate by the catalytic activity of an inorganic pyrophosphatase, preferably yeast inorganic pyrophosphatase; and

[0019] iv) the inorganic phosphate generated by the catalytic activity of inorganic pyrophosphatase is determined by a calorimetric method, preferably by a method based on the assay for inorganic phosphate developed by Lanzetta et al. (1979) or by a method based on the assay for inorganic phosphate developed by Chifflet et al. (1983);

[0020] b) combining said chemical and said PS enzyme together in a second reaction mixture under the same conditions as in said first reaction mixture; and

[0021] c) measuring the amount of pyrophosphate or inorganic phosphate produced in said first and said—second reaction mixture;

[0022] wherein said chemical is capable of inhibiting the activity of said PS enzyme if the amount of pyrophosphate or inorganic phosphate measured in said second reaction mixture is significantly less than the amount of pyrophosphate or in organic phosphate measured in said first reaction mixture.

[0023] The assay principle invented here is not limited to measuring PS activity but can be employed to measure any enzyme whose catalytic activity involves the formation of a substrate-nucleotidyl reaction intermediate by transfer of the nucleotidyl moiety from the corresponding nucleoside triphosphate to a suitable substrate, thereby generating inorganic pyrophosphate as one reaction product. Such enzymes include, but are not limited to, all aminoacyl-tRNA synthetases, asparagine synthetase, acetate thiokinase, dephosphocoenzyme-A-pyrophosphorylase and all enzymes catalysing the formation of nucleotide diphosphate sugars. The assays are preferably carried out on a microtiter scale and are preferably employed for the high-throughput biochemical screening of inhibitors of the enzymes.

[0024] The present invention is further directed to probes capable of specifically hybridising to a plant PS gene, cDNA or mRNA, wherein the probe comprises a contiguous portion of the coding sequence for a PS enzyme from a plant at least 10 nucleotides in length.

[0025] A further aspect the invention provides a method of producing a DNA molecule comprising a DNA portion encoding a protein having PS activity by,

[0026] a) preparing a nucleotide probe capable of specifically hybridising to a plant PS gene, cDNA or mRNA, wherein the probe comprises a contiguous portion of the coding sequence for a PS enzyme from a plant at least 10 nucleotides in length;

[0027] b) probing for other PS coding sequences in populations of cloned genomic DNA fragments or cDNA fragments from a chosen organism using the nucleotide probe prepared according to step a); and

[0028] c) isolating a DNA molecule comprising a DNA portion encoding a protein having PS activity.

[0029] DNA encoding the PS enzyme may be isolated from any desired plant species according to the invention. One method taught for isolating a plant PS coding sequence is represented by Example 1. In this method cDNA clones encoding a PS enzyme are identified from a library of cDNA clones derived from the plant of interest based on their ability to supply PS enzymatic activity to a mutant host organism deficient in this activity. Suitable host organisms for use in this method are those which can be used to screen cDNA expression libraries and for which mutants deficient in PS activity are either available or can be routinely generated. Such host organisms include, but are not limited to, E coli panC (strain AT1371).

[0030] Alternatively, plant PS coding sequences may be isolated according to well known techniques based on their sequence homology to the Lotus japonicus PS coding sequence set forth in FIG. 1.2 or to the Oryza sativa PS coding sequence set forth in FIG. 2.2. In these techniques all or part of the known PS coding sequence is used as a probe which selectively hybridises to other PS coding sequences present in populations of cloned genomic DNA fragments or cDNA fragments (i.e. genomic or cDNA libraries) from a chosen organism. Such state of the art techniques include hybridisation screening of plated DNA libraries and amplification by PCR using oligonucleotide primers corresponding to sequences conserved among known PS amino acid sequences.

[0031] For recombinant production of the PS enzyme in a host organism, the plant PS coding sequence may be inserted into an expression cassette designed for the chosen host and introduced into, the host where it is recombinantly produced. The choice of specific regulatory sequences such as promoter, signal sequence, 5′ and 3′ untranslated sequences, and enhancer appropriate for the chosen host is within the level of skill of those skilled in the art. The resultant molecule, containing the individual elements linked in proper reading frame, may be inserted into a vector capable of being transformed into the host cell. Suitable expression vectors and methods for recombinant production of proteins are well known for host organisms such as E. coli, yeast and insect cells. Specific examples include plasmids such as pBLUESCRIPT, pFLAG, pTrcHis, and baculovirus expression vectors, for example those derived from the genome of Autographica californica nuclear polyhedrus virus.

[0032] Recombinantly produced plant PS can be isolated and purified using a variety of standard techniques. The actual techniques which may be used will vary depending upon the host organism used, whether the PS enzyme is designed for secretion, and other such factors familiar to those skilled in the art.

[0033] Recombinantly produced plant PS is useful for a variety of purposes. For example, it may be used in an in vitro assay to screen known herbicidal chemicals whose target has not been identified to determine if they inhibit PS. Such an in vitro assay may also be used as a more general screen to identify chemicals which inhibit PS activity and which are therefore herbicide candidates. Alternatively, recombinantly produced plant PS may be used to elucidate the complex structure of this enzyme. Such information regarding the structure of the PS enzyme may be used, for example, in the rational design of new inhibitory herbicides.

[0034] Typically, the inhibitory effect on PS is determined by a significant reduction, a reduction that is greater than the margin of error inherent in the measurement technique, of pantothenate synthesis in the in vitro assay. Such a determination may be made simply by comparing the amount of pantothenate synthesised in the in vitro assay in the presence and absence of the candidate inhibitor.

[0035] The disclosures in British patent applications 97 11.1 63.7 and 97 134 77.9 from which this application claims priority, and in the abstract accompanying this application are incorporated herein by reference.

[0036] The invention will be further described by reference to the following detailed examples. These examples are provided for purposes of illustration only, and are not intended to be limiting unless otherwise specified.

EXAMPLES

[0037] A number of standard techniques have been used during development of our invention. These includes: cloning of plant genes by functional complementation (for example Senecoff and Meagher, 1993); the use of inverse PCR to recover fragments of genes not present in conventional libraries (Ocham et al, 1989) and the use of DNA sequence databases to discover PS genes cloned from other species which had unknown function at the time of their submission.

Example 1

[0038] Isolation of a cDNA Clone Encoding Pantothenate Synthetase from Lotus japonicus

[0039] A L. japonicus PS clone was isolated by functional complementation of E. coli AT1371 (panC4, Δ(gpt-proA)62, lacY1, tsx-29, glnV44(AS), galK2, λ−, rac-0, hisG4(Oc), rfbD1, xylA5, mtl-1, argE3(Oc), thi-1, described by Cronan et al., 1982) from a cDNA library (from Corinna Tetzlaff, Department of Plant Sciences, University of Cambridge, Downing Street, Cambridge, C823EA, UK) The PS cDNA was found in a population of 50,000 ampicillin-resistant transformants of E. coli AT1371. The PS clone (pLC), was subcloned and sequenced as summarised in FIG. 1.1. The resulting nucleotide sequence (FIG. 1.2) revealed the presence of an open reading frame (ORF) encoding a polypeptide of 308 residues which is 61% similar to the protein sequence of PS from E coli. The open reading frame of PS was in frame with the lacZ on the pBLUESCRIPT vector which probably accounts for the expression of L. japonicus PS and hence complementation of E. coli AT1371.

Example 2

[0040] Isolation of a cDNA Clone Encoding Pantothenate Synthetase from Oryza sativa

[0041] A PS cDNA sequence from rice was found by nucleotide database searches as an expressed sequence tag (EST) of rice that had been submitted to GenBank (accession number D25017) on behalf of the Japanese Rice Genome Research Program. The full corresponding cDNA clone was obtained from Dr. Yuzo Minobe, National Institute of Agrobiological Resources, Kannondai, Tsukuba Ibaraki, Japan. This cDNA clone was called pRC1 and subcloned and sequenced as shown in FIG. 2.1. The nucleotide sequence of the 1.3 kb SalI-NotI insert of pRC1 and the predicted amino acid sequence of the PS gene are given in FIG. 2.2. When this sequence was compared to other PS sequences, the similarity originally seen within the 5′ EST region held for the entire open reading frame implying that the rice cDNA in pRC1 does code for PS. However, pRC1 did not complement the E. coli panC mutant. Thus, a fusion clone of lacZ and rice PS gene was derived from pRC2 (FIG. 2.3) that allowed both transcription of the rice cDNA and translation of the protein as a β-galactosidase fusion. Complementation of the E. coli panC mutant with the rice pantothenate synthase gene was achieved using this fusion one.

Example 3

[0042] Comparison of the Amino Acid Sequences of Known, or Predicted to be, Pantothenate Sythetases

[0043] When the amino acid sequences of known, or predicted to be, pantothenate-sythetases were aligned (FIG. 3.1), the putative PS protein sequences of Saccharomyces cerevisiae and Schizosaccharomyces pombe showed significant homology with E. coli PS. To confirm that the putative PS gene Of Saccharomyces cerevisiae did code for an enzyme with PS activity, a phage clone (PM4950) containing a 20 kb genomic fragment of the yeast chromosome IX which spans the putative PS gene was obtained from Dr. Carol Churcher, Sanger Centre, Hinxton Hall, Cambridge, UK. The open reading frame coding for the putative gene was subcloned in two steps for expression in E. coli as shown in FIG. 3.2. In the resulting plasmid, pYC1, the yeast PS gene was under transcriptional control of the lacZ promoter. However, PS was not in frame with lacZ and therefore was not expressed as a fusion protein. The nucleotide sequence and putative translation product of the 1.5 kb EcoRV-HindIII gnomic fragment in pYC1 are given in FIG. 3.3. Yeast PS functionally complemented the panC lesion in E coli AT1371, confirming that the gene did code for a functional PS.

Example 4

[0044] Isolation of the 5′ and the 3′ Ends of Pantothenate Synthetase from Lotus japonicus

[0045] We expected plant PS to be located in the chloroplast, but there was no evidence from the PS cDNA clones of L. japonicus and O. saliva of any chloroplast transit signals. Furthermore, both enzymes were predicted to be cytosolic proteins by pSORT (Molecular Biology Tools, ExPasy WWW Server).

[0046] To clone 5′ and 3′ sequences of the PS gene inverse PCR (iPCR) was used. Genomic DNA was isolated from L. japonicus leaf tissue and prepared as described by Dellaporta et al (1983). Aliquots of Lotus genomic DNA (8 μg) were digested overnight with the following restriction endonucleases: BamHI, EcoRI, HindIII, NotI, SalI, XbaI, XhoI. DNA fragments were precipitated with isopropanol and resuspended in TE buffer before loading onto an agarose gel. After electrophoresis, gel pieces corresponding to fragment sizes of between 2 kb and 15 kb were isolated from the agarose gel, and purified using the US BioClean MP kit (United States Biochemical, Cleveland, Ohio, USA). Each reaction was ligated overnight at 14° C. with 1.5 units of T4 DNA ligase in conditions which promote intra-molecular ligation. DNA was precipitated from the ligation mix with isopropanol, washed with ethanol, resuspended in sterile distilled water and used as templates in the following PCR step.

[0047] PCR amplification was carried out using the Expand High Fidelity PCR system from Boehringer Mannheim, FRG, adopting the manufacturers protocol for amplification of DNA of a size of up to 3 kb. The design of L. japonicus PS-specific primers Li5 and Li3 (Li5: dCGGGATCCATGGTGGGACGAGGGCGATGAG and Li3: dCATCAAGCTTATGTATCAAAGTGCCCCAGG) followed the general protocols for iPCR by Ochman et al. (1989). Restriction sites incorporated into the Li primers are HindIII in Li3 and BamHI in Li5 (underlined). Of all seven templates only the BamHI-derived circular Lotus library was effective in iPCR reactions. A single product of 750 bp was obtained with a minor contaminant at about 250 bp. This iPCR product was cleaved by BamHI as expected and was cloned into the pCRII vector using the PCR T/A cloning kit (Invitrogen, NV Leek, Netherlands following the manufacturer's instructions). The EcoRI insert of the resulting plasmid was sequenced at the Centre of Molecular Recognition, Department of Biochemistry, University of Cambridge (FIG. 4A). By comparison with the L. japonicus PS sequence, the genomic iPCR product matched the cDNA's 3′ and 5′ ends and was assumed to contain authentic PS flanking regions. The annotated nucleotide sequence is shown in FIG. 4B.

[0048] While primer and cDNA sequences were straightforwardly identified within the iPCR product, analysis of the flanking regions was more difficult, since intron-exon borders can only be identified with some confidence. Predicion of splice sites according to Hebsgaard et al. (1996) at the NetPlantGene Server (Center for Biological Sequence Analysis, Technical University of Denmark, Lyngby, Denmark) suggested possible donor splice sites at positions 258 and 281, and possible acceptor splice sites at positions 179, 316, 338 and 536 in the sequence given in FIG. 4B. These sites were found in the low probability threshold mode of the program to include nearly all true sites. Intriguingly, none of these splice sites are situated within regions corresponding to cDNA.

[0049] There is one sequence feature of value regarding the question of the true translation start site within PS. This is a stop codon in the 5′ flanking region, 21 bases upstream from the putative initiation site, which is in frame with the PS ORF. If this stop codon forms part of the PS 5′-leader sequence as was implied in the splice site predictions, the ORF as encoded by the PS cDNA could safely be assumed to be complete. Specifically, this conclusion is conditional upon the absence of acceptor splice sites in between stop codon and cDNA start. The primary sequence information as such seems reliable firstly because a DNA-polymerase with proof reading activity was used in the PCR amplification and secondly because the chromatograms generated in two sequencing runs are both unambiguous.

Example 5

[0050] Cloning Pantothenate Synthetase from Lotus japonicus into an Expression Vector

[0051] An expression cassette was generated from the L. japonicus cDNA for PS using the PCR method of MacFerrin et al (1990) Lotus panC ORF was amplified from ca. 25 ng of plasmid pLC, using the primers LC5 and LC3. LC5 was designed to the start, ATG, codon of PS with an XbaI site highlighted in bold type and a ribsome binding site, underlined, included in the PCR primer dCGCGCTCTAGAA GGAGGAATTTAAAATGGCACCMTGGTGATATCTGAT. LC3 was designed to include the stop codon (TTA) of the ORF and an XhoI restriction site, in bold, in the PCR primer: dGCGCGCTCGAGTTACAAGTTGATTICTATGTT.

[0052] The PCR product was cloned into pBLUESCRIPT SK− (Stratagene Ltd. Cambridge Innovation Centre, 140 Cambridge Science Park, Milton Road, Cambridge, CB44GF, UK) using the XbaI and XhoI restriction sites incorporated in the primers, and the resulting clone was referred to as pSKL. The expression cassette was designed to contain the L. japonicus PS ORF as demonstrated FIG. 5. The correct construct was confirmed by DNA sequence analysis (data not shown).

Example 6

[0053] Expression of Pantothenate Synthetases from Lotus japonicus, Oryza saliva, and Saccharomyces cerevisiae in Escherichia coli

[0054]

L. japonicus
PS was expressed in an E coli panC mutant AT1371 because wild-type E. coli strains have considerable PS activity which would make purification of the recombinant enzyme more difficult. E. coli AT1371 (panC transformed with the Lotus panC overexpressing plasmid pSKL was grown from single colonies overnight in 10 ml LB cultures containing 100 μg/ml ampicillin. Four 500 ml aliquots of 2YT medium (1.6% (w/v) bactopeptone, 1.0% (w/v) yeast extract and 0.5% (w/v) NaCl in water) in 2 litre flasks containing 60 μg/ml ampicillin and 20 μg/ml IPTG were each inoculated with 5 ml of overnight culture and incubated at 37° C. with shaking (190 RPM) for 10 hours before harvesting. E coli cells were recovered by centrifugation (10 min, 5000 RPM) and immediately resuspended in 20 ml of buffer A (50 mM Tris.HCl, 1 mM EDTA, 0.1 mM DTT, pH 8.0). Cells were lysed by sonication. Two equal aliquots of the cell suspension were each sonicated 6 times for 30 seconds on ice, with a 30 second pause between each burst. Cell debris was removed by centrifugation (30 min, 12000 RPM) and the crude extract was assayed for enzymatic activity.

[0055] Along with the Lotus PS expression clone pSKL, expression of PS activity was examined with all other available PS clones, that is the lacZ-PS fusion clones of Lotus and rice (pLC and pRC, respectively), yeast panC (pYC1) and E. coli panC (pCL). However, unlike pSKL clones, no attempt was made to optimise expression. Crude extracts from E coli AT1371 transformed with these pantothenate synthase clones or with vector alone were assayed for pantothenate synthase activity using either pantoate or pantoyl-lactone as substrate. Crude extract from wild type E. coli was also assayed, and the results are shown in the appended table (Table 1) which includes previously reported PS activities. In all cases examined enzyme activities were much higher with pantoate than with pantoyl-lactone. Given that purified E. coli PS had no activity toward pantoyl-lactone (Miyatake et al., 1979), the residual activities seen here with the latter substrate are likely due to a hydrolysing activity present in the cell extracts. An activity that catalyses hydrolysis of pantoyl-lactone was previously implied by Maas (1952a and 1952b). Failure to detect activity in samples derived from the Lotus or rice panC-lacZ fusion clones indicates lack of expression of enzymatically active PS. However, these clones were successfully used to complement a panC lesion in E. coli and therefore must express at least low levels of PS activity. Activities found in wild type E. coli or AT1371 transformed with vector alone are in accordance with previously reported values.

Example 7

[0056] Purification of Recombinant Lotus japonicus Pantothenate Synthetase Expressed in Escherichia coli

[0057] A crude extract of E. coli AT1371 transformed with the Lotus panC expression clone pSKL was prepared as described in Example 6. Starting from this crude extract, PS was essentially purified in two steps, ammonium sulphate fractionation and anion exchange chromatography To the cleared extract (28 ml), a saturated solution of (NH4)2SO4 (12 ml) was added to reach a final concentration of 30% (NH4)2SO4. The solution was kept on ice for 1 hour with stirring to allow protein aggregates to form. Insoluble protein was removed by centrifugation (12,000 RPM, 30 minutes) at 4° C. The supernatant was recovered (36 ml) and brought to 40%0 (NH4)2SO4 saturation by addition of 6 ml of saturated (NH4)2SO4 solution. The solution was incubated and centrifuged as before. Pelleted protein aggregates were dissolved in 5 ml of buffer A and dialysed against 2 litres of buffer A overnight at −4 C. The dialysed solution was centrifuged at 12,000 RPM for 30 minutes, and the supernatant was directly used in the anion exchange chromatography step.

[0058] The sample (5 ml) was loaded onto a Pharmacia FPLC MonoQ HR10/10 column previously equilibrated in buffer A. The column was washed with equilibration buffer until A280 of the eluate was constant and below 0.1, and a constant flow rate of 2 ml/min was maintained throughout the run. Protein was eluted in a linear gradient (80 ml) of 0-250 mM KCl in buffer A, and 1 ml fractions were collected throughout the gradient and assayed for PS activity. FIG. 6 shows the PS activity (FIG. 6A) and protein (FIG. 6B) profiles of, this chromatographic step. The majority of PS activity eluted at ca. 100 mM KCl concentration. A second peak of PS activity eluted well separated from the first at just under 200 mM KCl along the gradient. This peak was broader than the first one and contained a much smaller but significant amount of activity. Since a homogenous overexpression product would principally be expected to elute in a single peak, separation of PS activity into two peaks was at first held to be an artifact. However, using a different column (MonoQ HR16/10) or changing gradient parameters including a solute change from KCl to ammonium acetate made no difference to the elution pattern. Physical differences in between the PS proteins in peaks one and two that could account for this behaviour may be due to differential folding or post-translational processing. The fractions with highest PS activities in either peak were pooled as indicated in FIG. 6A. Fractions 29 through 32 within the first peak gave sample PS-I (4 ml) which recovered 73% of PS activity loaded onto the column. Likewise, fractions 57 through 60 from the second peak were pooled to give PS-II (4 ml) containing 12% of the original PS activity. Samples PS-I and PS-II together contained 21.7 mg of PS.

[0059] Both, PS-I and PS-II were dialysed against 1 litre of buffer A overnight at 4° C. and centrifuged to precipitate insoluble protein. 500 μl aliquots of both PS-I and PS-II were loaded onto a Pharmacia Superose 6 column equilibrated in buffer A, maintaining a constant flow rate of 0.5 ml per minute and collecting 1 ml fractions. PS activity from both samples eluted in single peaks at an equal retention volume after injection, indicating a similar native molecular weight for PS-I and PS-II. This step offers no further purification of PS. In fact, specific activity was slightly decreased in both cases as can be seen from the purification summary in Table 2. However, SDS-PAGE (Laemmli, 1970; Sambrook et al., 1989) analysis of these samples revealed removal of some protein contaminants through gel filtration. Fractions 16 and 17 were pooled in each case to give samples PS-I/GF and PS-II/GF. Physical characterisation of recombinant PS is dealt with in the next section and was carried out on both PS-I and PS-II while kinetic analysis (Example 9) was restricted to PS-I.

Example 8

[0060] Characterisation of the Recombinant Lotus japonicus Pantothenate Synthetase

[0061] In order to confirm the identity of the overexpressed Lotus PS, N-terminal protein sequencing (Table 3) and amino acid analysis (Table 4) was carried out at the Protein and Nucleic acid Chemistry Facility “in the Department of Biochemistry, University of Cambridge on an applied Biosystems 477A Protein Sequencer for both PS-I and PS-II.

[0062] Alignment of N-terminal sequences obtained for PS-I and PS-II to the theoretical N-terminus of L. japonicus PS in Table 3 demonstrated that the purified recombinant protein is PS from L. japonicus. The overexpressed protein was apparently processed at the N-terminus, and the majority of both PS-I and PS-II lacked two N-terminal residues (methionine and alanine). However, some of they protein only lacked methionine giving rise to the secondary sequences observed. PS-I and PS-II differ somewhat with respect to the proportions of these differentially processed species. This can be seen from the relative yields at which primary and secondary sequences were obtained. The less abundant protein species with N-terminal alanine sequenced at an average yield comprising 70% (PS-I) or 40% (PS-II) of that seen for the primary sequence.

[0063] The theoretical molecular weight of recombinant L. japonicus PS is 34.2 kD, and this value is in reasonable agreement with the subunit weight obtained by SDS-PAGE analysis of the purified overexpression product (ca. 37 kD). The native molecular weight of PS-I or PS-II was estimated by gel filtration to be 72.8 kD implying the native protein is a homodimer.

[0064] More accurate determination of the Lotus PS subunit molecular weight was achieved by electrospray mass spectroscopy ESMS (carried out on an electrospray ionisation (positive ion mode) quadrapole mass spectrometer (BioQ; VG, Manchester, UK) using software supplied by the manufacturer). The transformed mass data revealed the presence of two protein species both in PS-I and PS-II which differ by 72.3 Da and 70.3 Da, respectively. This corresponds well to the theoretically expected mass difference in between presence or absence of an N-terminal alanine, that is 71.0 Da. Protein sequencing of recombinant PS had already shown that the N-terminal methionine was missing from the overexpression product while the following alanine residue was only partially removed. The main ESMS signal (100%) belongs to the lighter species and does therefore in all likelihood correspond to PS with N-terminal proline. Likewise, the secondary signals obtained at 75% (PS-I) or 40% (PS-II) relative intensity are due to PS with N-terminal alanine. As was concluded from the N-terminal sequencing data, the relative proportions of lighter and heavier PS species obtained here indicate PS-II was more efficiently processed than PS-I.

[0065] The L. japonicus PS ORF encodes a polypeptide of 308 residues with a predicted molecular weight of 34.2 kDa, and the processed recombinant protein (3-proline through 308-leucine) has a theoretical mass of 34,037.7 Da.

[0066] This is only in rough accordance with the weights obtained for PS-I (33,969.0±12.3 Da) and PS-II (33,967.0±10.2 Da), that is these proteins are lighter than expected by 68.7 Da and 70.7 Da, respectively. Given the accuracy of ESMS mass determinations, this discrepancy is presumably not due to a machine artifact. A possible explanation for the mass differences would be a mutation in the overexpression clone that might have been introduced through the PCR amplification of the L. japonicus panC expression cassette. However, the PCR step in question was carried out using a polymerase mix including a proof-reading activity, and, as mentioned earlier, no nucleotide sequence changes were found in between panC cDNA and expression cassette. Alternatively, the overexpressed PS may have been further processed at the C-terminus, for example.

Example 9

[0067] A High-Throughput Assay for Pantothenate Synthetase Activity

[0068] Three different assays have been reported previously for measuring PS activity (see above). The assays described by Maas (1950a and 1950b) and Miyatake et al (1979) are either microbiological or radiometric, while the number of auxilary enzymes and substrates required for the assay developed by Pfleiderer et al (1960) makes this assay cumbersome, expensive, and limited in its application to low throughput screening only. Hence, all three assays are unsuitable for the large scale high throughput biochemical screening of compounds necessary to discover new inhibitors of PS.

[0069] The applicants have developed in vitro assays which can be employed for high throughput biochemical screening for detecting inhibitors of this enzyme, to the use of these assays in the development of novel herbicides and in determining their mode of action, and to biological active inhibitors of pantothenate biosynthesis and herbicides obtained thereby. The assays are designed to measure the pyrophosphate liberated in the PS reaction either directly with a modified version of the calorimetric assay for the determination of inorganic pyrophosphate originally described by Chang et al. (1983); or after its conversion with inorganic pyrophosphatase to inorganic phosphate, which is then determined with modified versions of the calorimetric assays for the determination of inorganic phosphate originally described by Lanzetta et al. (1979) or Chifflet et al. (1988). The assays are carried out at room temperature, preferably on a microtiter scale.

[0070] 1. The preferred assay mixture to colorimetrically measure the pyrophosphate liberated in the PS reaction comprises 100 μmol Tris.HCl SpH 8.0), 10 μmol MgSO4, 5 μmol ATP, 10 μmol β-alanine, 0.5 μmol pantoate and pantothenate synthetase in a total volume of 100 μl. After a suitable incubation period the PS reaction is terminated by the addition of 10 μl of a 0.8 M 2-mercaptoethanol in a 10% (w/v) solution of sodium dodecylsulfate followed by the addition of 50 μl of a 2.5% (w/v) solution of ammoniumheptamolybdate in 5 N sulfuric acid. After 20 minutes incubation at room temperature the intensity of the colour complex is determined by measuring the extinction at 620 nm. The amount of pyrophosphate liberated in the PS reaction is determined by reference to a standard curve generated from suitable amounts of pyrophosphate by using the difference of extinction at 620 nm between a complete PS assay mixture and a PS assay mixture lacking pantoate. One” unit of PS activity is defined as the amount of enzyme producing 1 mmole of pyrophosphate per minute, and specific activity is expressed as units per milligram of protein.

[0071] 2. The preferred assay mixture to measure the pyrophosphate liberated in the PS reaction after its conversion with inorganic pyrophosphatase to inorganic phosphate comp-rises 100 μmol Tris.HCl (pH 8.0), 10 μmol MgSO4, 5 μmol ATP, 10 μmol O-alanine, 0.5 μmol pantoate, 1.0 unit yeast inorganic pyrophosphatase and pantothenate synthetase in a total volume of 100 μl. After a suitable incubation period the PS reaction is terminated either

[0072] a) by the addition of 100 μl of a reagent mixture comprising 62.3 □g malachite green hydrochloride, 1.9 mg ammoniumheptamolybdate and 0.5% (v/v) of a suitable detergent (for example Triton X-100, Tween-80 or Tergitol NPX) in 1.88 N hydrochloric acid. The resulting colour complex is stabilised by the addition after 1 minute of 50 μl of a 26% (w/v) solution of trisodium citrate dihydrate in water and after an additional 45 minutes incubation at room temperature the intensity of the colour complex is determined by measuring, the extinction at 620 nm. The amount of inorganic phosphate liberated in the PS reaction is determined by reference to a standard curve generated from suitable amounts of inorganic phosphate by using the difference of extinction at 620 nm between a complete PS assay mixture and a PS assay mixture lacking pantoate. Since there are 2 molecules of inorganic phosphate liberated for every molecule of pyrophosphate formed in the PS reaction, one unit of PS activity is defined as the amount of enzyme producing 2 nmoles of inorganic phosphate per minute, and specific activity is expressed as units per milligram of protein; or

[0073] b) by the addition of 100 μl of a reagent mixture comprising 3 mg, ascorbic acid, 0.5 mg ammoniumheptamolybdate and 1 mg sodium dodecylsulfate in 0.7 N hydrochloric acid. The resulting colour complex is stabilised by the addition after 7 minutes of 50 μl of a 6% (w/v) solution of trisodium citrate dihydrate in water and after an additional 20 minutes incubation at room temperature the intensity of the colour complex is determined by measuring the extinction at 620 nm. The amount of inorganic phosphate liberated in the PS reaction is determined by reference to, a standard curve generated from suitable amounts of inorganic phosphate by using the difference of extinction at 620 nm between, a complete PS assay mixture and a PS assay mixture lacking pantoate. Since there are 2 molecules of inorganic phosphate liberated for every molecule of pyrophosphate formed in the PS reaction, one unit of PS activity is defined as the amount of enzyme producing 2 nmoles of inorganic phosphate per minute, and specific activity is expressed as units per milligram of protein.

[0074] In order to determine the linear range of the assay used here, recombinant PS purified through the anion exchange chromatography step was assayed by method 2a, using final β-alanine and pantoate concentrations of 10 mM and 0.5 mM, respectively. When various amounts of PS were assayed, a proportional relationship of inorganic phosphate formed and enzyme amount was obtained in between 1 and 4 μg of protein (FIG. 7A). Furthermore, when a given amount of PS was assayed for different time periods, a proportional relationship of inorganic phosphate formed and incubation time is obtained in between 0 and 20 minutes of incubation (FIG. 7B).

Example 10

[0075] Biochemical Properties of Recombinant Lotus japonicus Pantothenate Synthetase

[0076] The recombinant L. japonicus enzyme investigated here was found to require pantoate, β-alanine, ATP and Mg2+ for activity. The pantoate analogues pantoyl-lactone and ketopantoate were not active as substrates in the place of pantoate. When present at 10-fold excess over pantoate, these analogues did not effect significant inhibition (Table 5).

[0077] With 100 nM Tris.HCl buffer optimal PS activity was achieved at pH 8.0. Activity decreases sharply towards more acidic pH's and is nil at pH 7.0, while there is only a slight decrease towards higher pH's with ca. 75% activity left at pH 9.0.

[0078] Km and Vmax constants for pantoate and β-alanine were determined by measuring the effect of substrate concentration on the reaction rate. Either pantoate or β-alanine were kept at a constant concentration of either 0.5 or 20 mM, and activity assays were carried out using variable concentrations of the other. Plotting the PS activity as a function of substrate concentration according to Lineweaver and Burk (1934) and Eadie (1942) and Hofstee (1959) revealed the kinetic constants as listed in Table 6.

[0079] Lotus PS suffers from substrate inhibition by pantoate, which becomes significant at pantoate concentrations of 400 μM or higher. The effect of pantoate concentration on Km and Vmax for β-alanine was as, expected for pure uncompetitive inhibition, that is both constants decreased with increasing pantoate concentration while their ratio remained constant. Km over Vmax for β-alanine derived from Lineweaver-Burk analysis equalled 0.106 and 0.104 for pantoate concentrations of 20 mM and 0.5 mM, respectively. When the rate equation for uncompetitive substrate inhibition was fitted to the PS activity data for pantoate, values of 42±2 μM and 5.33±0.34 mM were derived for KS and K'S, respectively. Vmax is 11.03±0.19 units in this fit which is equal to a kcat value of 0.625±0.011 sec−1. The KS and kcat values are very similar to Km and kcat as derived from linearised plots of activity data.

[0080] Using the rate equation for uncompetitive substrate inhibition and the values for KS and K'S obtained in the fit, an optimal pantoate concentration of 470±30 μM was calculated.

[0081] PS was also assayed in the presence of various compounds that might be expected to possess regulatory properties towards the enzyme. Among these compounds are the intermediates of pantothenate biosynthesis as well as coenzyme A. As coenzyme A plays a prominent role in fatty acid synthesis and degradation, various acyl forms of coenzyme A and free fatty acids were also included. PS was not assayed at optimal substrate concentrations, but pantoate and β-alanine were present at concentrations close to the respective Km values (0.1 mM and 1 mM). Table 7 lists the compounds tried and their effect on PS activity which is expressed percentage of activity in an assay without additions.

REFERENCES

[0082] Bradford, M. M. (1976) Anal. Biochem. 72, 248-254.

[0083] Chang, G. G., Pan, F. Yeh, C., and Huang, T. M. (1983) Anal. Biochem. 130, 171.

[0084] Chifflet, S., Torriglia, A., Chiesa, R., and Tolosa, S. (1988) Anal. Biochem. 168, 1.

[0085] Cronan, J. E., Littel, K. J. and Jackowski, S. (1982) J. Bacterol.-149, 916-922.

[0086] Cronan, J. E. (1980) J. Bacteriol. 141, 1291-1297.

[0087] Dellaporta, S. L., Wood, J., and Hicks, J. B. (1983) Plant Mol. Biol. Rep. 1, 19-21.

[0088] Eadie, G. S. (1942) J. Biol. Chem. 146, 85.

[0089] Hebsgaard, S. M., Korning, P. G., Tolstrup, N., Engelbrecht, J., Rouze, P., and Brunak, S. (1996) Nucl. Acids Res. 24, 3439-3452.

[0090] Hofstee, B. H. J. (1959) Nature 184, 1296.

[0091] Lanzetta, P. A., Alvarez, L. J., Reinach, P. S. and Candia, O. A (1979) Anal. Biochem. 100, 95-97.

[0092] Laemmli, U. K (1970) Nature 227, 680-685.

[0093] Lineweaver, H., and Burk, D. (1934) J. Am. Chem. Soc. 56, 658.

[0094] Maas, W. K. (1952a) J. Biol. Chem. 198, 23-32.

[0095] Maas, W. K. (1952b) J. Bact. 63, 227-232.

[0096] MacFerrin, K D., Terranova, M. P., Schreiber, S. L., and Verdine, G. L. (1990) Proc. Natl. Acad. Sci. USA 87,1937-1941.

[0097] Miyatake, K., Nakano, Y., and Kitaoka, S. (1979) Methods Enzymol. 62, 215-219.

[0098] Ochman, H, Ajioka, J. W., Garza, D., and Harti, D. L. (1989) Inverse PCR in PCR Technology, pp. 105-112, Erlich, H. A. ed., Stockton Press, New York.

[0099] Pfleiderer, G., Kreiling, A., and Wieland, T. (1960) Biochem. Z. 333, 302-307.

[0100] Sambrook, J., Fritsch, E. F., and Maniatis, T. (1989) Molecular Cloning: A Laboratory Manual, 2nd Ed., Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

[0101] Senecoff, J. F. and Meagher, R. B. (1993). Plant Physiol. 102: 387-399

1TABLE 1Expression of pantothenate synthetases in E. coliAT1371 (panC) and wild type strainsE. coliSpecific Activity [U/mg] usingstrainVectorPantoateORPantoyl-lactoneReferenceAT1371pSKL8.7not detected(panC)Lotus PSAT1371pLCnot detectednot detected(panC)Lotus PS-lacZAT1371pRCnot detectednot detected(panC)rice PS-lacZAT1371pYC188.03.1this study(panC)yeast PSAT1371pCL957.46.0(panC)E. coli PSAT1371pBluescriptnot detectednot detected(panC)K12—13.4—(wildtype)K12—8.1-8.7—Cronan(wildet al.type)(1982)AT1371—< 0.001—(panC)(notdetected)B—4.1—Miyatake(wildet al.type)(1979)W (wild—1.3—Pfleiderertype)et al.(1961)

[0102]

2

TABLE 2

Summary of the purification procedure for recombinant Lotus japonicus

pantothenate synthetase.

PS was assayed using pantoate and β-alanine at final concentrations of

1 mM and 10 mM, respectively. Protein was assayed according to the method

of Bradford (1976), using the Bio-Rad Protein reagent and microprotein

assay in accordance with the manufacturer's instructions. Bovine serum

albumine was used to calibrate the assay.

Specific-

total protein
total Units
Activity
recovery

Sample
(mg)
(nmoles/min)
(U/mg)
(%)
purification

Cleared
908.6
27410.2
30.2
(100)
(1)

extract

(NH4)2SO4
209.7
33030.6
157.5
121
5.2

30-40%

MonoQ - PS-I
17.8
24160.8
1357.3
88
44.9

MonoQ - PS-II
3.9
4070.7
1038.5
15
34.1

Superose6 -
2.16
2386.6
1104.9
79(b)
36.3

PS-I(a)

Superose6 -
0.44
400.8
911.0
79(b)
29.9

PS-II(a)

(a)
Aliquots of the MonoQ - PS-I - pool (2.2 mgs of protein in 0.5 ml) or the MonoQ - PS-II - pool (0.5 mgs of protein in 0.5 ml) were purified further by Superose 6 gelfiltration. PS activity from both PS-I and PS-II eluted in a single peak at identical retention volumes.

(b)
The recovery is expressed with respect to the activity loaded onto the gelfiltration column.

[0103]

3

TABLE 3

N-terminal protein sequences of PS-I and PS-II proteins

and predicted sequence

for Lotus japonicus pantothenate synthetase

Predicted sequence (a):

M A P M V I S D
K D E M R K W S R -

1° sequence (b):
P M V I S D K D E M R K W S R

20° sequence (b):
A P M V I S D K D E M R K W S R

(a) N-terminal protein sequence predicted from the Lotus japonicus ORF for PS (cf. FIG. 1.2). The residues underlined correspond to the nucleotide sequence of the PCR primer used in the production of the overexpression clone.

(b) Identical N-terminal protein sequences were obtained for PS-I and PS-II. The molar yield of secondary sequence as compared to primary sequence was ca. 70% in case of PS-I and ca. 30% for PS-II

[0104]

4

TABLE 4

Amino acid compositions obtained by amino

acid analysis for PS-I and PS-II.

integer fit of measured mole

ratios to expected values

Amino acid
expected value
PS-I
PS-II

Cys
5
5.64
not determined

Asp
33
35.24
33.67

Thr
6
6.14
6.71

Ser
23
18.79
19.96

Glu
30
24.78
25.19

Gly
26
28.50
26.20

Ala
19
20.02
19.76

Val
33
30.70
32.76

Met
7
7.03
not determined

Ile
20
20.37
19.84

Leu
22
24.56
23.78

Tyr
7
7.01
6.5

Phe
13
15.07
13.01

His
8
7.64
12.11

Lys
20
20.89
22.52

Arg
17
16.97
16.17

Pro
12
11.67
10.82

Trp
5
not determined
not determined

306 residues

[0105]

5

TABLE 5

Substrate specificity of the recombinant Lotus japonicus

pantothenate synthetase.

change from

Pantoate
β-alanine
standard assay
activity (units)
yield (%)

0.1 mM
1 mM
—
12.51
(100)

0.1 mM
—
—
0
0

—
1 mM
—
0
0

—
1 mM
pantoyl-lactone
<0.1
<1

(1.0 mM)

—
1 mM
pantoyl-lactone
0.15
1

(10 mM)

—
1 mM
ketopantoate
0
0

(1.0 mM)

—
1 mM
ketopantoate
0
0

(10 mM)

0.1 mM
1 mM
pantoyl-lactone
11.53
92

(1.0 mM)

0.1 mM
1 mM
ketopantoate
12.18
97

(1.0 mM)

[0106]

6

TABLE 6

Steady state kinetic constants for the recombinant

Lotus pantothenate synthetase.

Substrate
Km(a) [μM]
Vmax(a) [units]
kcat(b) [sec−1]

Pantoate
45 (LB)
11.36 (LB)
0.63

(β-alanine at 20 mM
44 (EH)
10.98 (EH)

const.)

β-alanine
990 (LB)
9.52 (LB)
0.54

(pantoate at 0.5 mM
986 (EH)
9.51 (EH)

const.)

(a)
Kinetic constants were derived according to Lineweaver-Burk (LB) and Eadie-Hofstee (EH).

(b)
Calculation of kcat is based on the Vmax-mean from LB- and EH-determinations using the known enzyme amount per assay and a molecular weight of 34 kD.

[0107]

7

TABLE 7

Activity of recombinant Lotus pantothenate synthetase in

the presence of various potential effectors.

Pantothenate synthetase activity obtained with individual

compounds is expressed as a percentage of activity in an

assay without effector. The assay was carried out using

pantoate and β-alanine at concentrations of 0.1 mM and

1.0 mM, respectively.

Concentration
Final activity

Compound
[mM]
[%]

—
—
(100)

a-KIVA
1
89

Ketopantoate
1
97

Pantoyl-lactone
1
92

Pantothenate
1
98

Pyrophosphate
1
78

CoenzymeA
1
109

0.2
106

0.1
100

Acetyl-coA
0.100
93

Malonyl-coA
0.100
92

Palmitoleoyl-coA
0.022
114

Oleoyl-coA
0.024
108

Palmitic acid
0.060
115

0.015
135

0.002
133

Palmitoleic acid
0.100
100

0.020
116

FIGURES

[0108] Referring to FIG. 1.1 there is shown a partial restriction map (A), subcloning (B) and nucleotide sequencing (C) of pLC, a Lotus japonicus cDNA for pantotheate synthetase. A: The L. japonicus pantotheate synthetase cDNA (pLC) was isolated by functional complementation of E. coli AT1371 (panC). B represents the sub-clones needed for the DNA sequencing strategy which is summarised in C.

[0109] Referring to FIG. 1.2 there is shown the nucleotide sequence of the Lotus japonicus cDNA for pantothenate synthetase and its predicted amino acid sequence. FIG. 1.2 shows the DNA sequence of the 1.33 kb EcoRI to XhoI insert of pLC (described in FIG. 1.1). The open reading frame codes for a polypeptide of 308 amino acids with a predicted molecular mass of 34.2 kDa and with 61% similarity to PS from E. coli. The indicated translation start site is putative and the stop codon (TAA) is is translated as “*”. This ORF on pLC is in frame with lacZ which accounts for expression of functional enzyme in E. coli and hence the observed complementation effect

[0110] Referring to FIG. 2.1 there is shown partial restriction map (A), subcloning (B), and nucleotide sequencing (C) of the rice pantothenate synthetase cDNA. The original cDNA for rice gene, pRC1, was subcloned in order to obtain its complete nucleotide sequence. The arrows indicate the position, direction, and length of individual sequencing runs. The open arrow indicates the EST sequence (GenBank accession no. D25017).

[0111] Referring to FIG. 2.2 there is shown the nucleotide sequence of the rice cDNA for pantothenate synthetase and its predicted amino acid sequence. The figure shows the DNA sequence of the 1.26 kb SalI to NotI insert of pRC1 (FIG. 2.1). The ORF encodes a polypeptide of 313 residues with a predicted molecular mass of 33.9 kD. The indicated translation start site is putative, and the stop codon is translated as “*”.

[0112] Referring to FIG. 2.3 there is depicted a method for generating the lacZ-pantothenate synthetase fusion clone for the expression of rice pantothenate synthetase in E. coli. The orientation of the cDNA in pRC1 was changed to yield pRC2 where the open reading frame is under transcriptional control of the lacZ promoter. The lacZ-PS fusion was generated by deleting four base pairs from pRC2, and the resulting plasmid, pRC, was sequenced to confirm the deletion (data not shown).

[0113] Referring to FIG. 3.1, the alignment of pantothenate synthetase protein sequences is shown. The PS protein sequences predicted from known (Lotus japonicus, Oryza saliva, Escherichia coli, Bacillus subtilis, Synechocystis sp.) or putative (Saccharomyces cerevisiae, Schizosaccharomyces pombe) genes were aligned using CLUSTAL W(1.5) within the GCG software package. Fully conserved residues are marked “*”, functionally conserved ones are marked “.”. lotus: Lotus japonicus, rice Oryza saliva, coli: Escherichia coli (GenBank P31663), subt: Bacillus subtilis (GenBank P52998), syne: Synechocystis sp. (GenBank U44896), yeast: Saccharomyces cerevisiae (GenBank P40459), pombe: Schizosaccharomyces pombe (GenBank Q09673).

[0114] Referring to FIG. 3.2, the subcloning of yeast pantothenate synthetase for expression in E. coli is depicted. A: The λ bacteriophage clone IPM4950 was obtained from the Sanger Centre, Hinxton Hall, Cambridge, UK, where the yeast PS sequence had been generated. B+C: Yeast panC was subcloned in two steps to yield plasmid clone pYC1 where the gene is placed under transcriptional control of the lac promoter. The position of the ORF is indicated by arrows. A T3-primed sequencing reaction using pYC1 as template confirmed the identity of the EcoRV-HindIII insert of the plasmid.

[0115] Referring to FIG. 3.3, there is shown the nucleotide sequence of the: Saccharomyces cerevisiae genomic DNA fragment for pantothenate synthetase and its predicted amino acid sequence. FIG. 3.3 shows the nucleotide sequence of the 1.5 kb EcoRV to HindIII genomic DNA fragment of S. cerevisiae that forms the insert of pYC1. The predicted amino acid sequence of yeast PS appears below the open reading frame. A Shine-Dalgarno-like sequence upstream of the translation initiation codon that may fortuitously serve as a RBS in E. coli is underlined. §—EcoRV; ¶—HindIII.

[0116] Referring to FIG. 4 there is shown the inverse PCR product of Lotus japonicus genomic regions flanking panC. A: Schematic representation of the iPCR product cloned into pCRII. The EcoRI.EcoRI insert was sequenced using T7 and M13 reverse primers. Both sequence runs were performed in duplicate and spanned ca. 600 bases each. B: Nucleotide sequence of the cloned iPCR product. The indicated matches with panC cDNA mean identical sequences. Positions corresponding to the first base (5′-¶) or the last base (3′-§) of the panC cDNA are marked. Within the 5′ flanking genomic sequence, there is a stop-codon in frame with the panC ORF.

[0117] Referring to FIG. 5, the expression cassette PCR of Lotus japonicus pantothenate synthetase is shown.

[0118] Referring to FIG. 6, there is shown the anion exchange chromatographs of recombinant Lotus japonicus pantothenate synthetase is shown. A sample of ammonium sulphate precipitated and dialysed PS was subjected to anion exchange chromatography on a MonoQ HR10/10 column as described in Example 7. A: PS activity profile. Fractions 29 through 32 were pooled to give sample PS-I, and fractions 57 through 60 were pooled to give sample PS-II. B: Protein elution profile followed by continous measurement of A280 and potassium chloride gradient employed.

[0119] Referring to FIG. 7 the results of a high-throughput assay for recombinant Lotus japonicus pantothenate synthetase is depicted graphically. Graph A shows the effect of enzyme concentration on the reaction rate. Specific amounts of MonoQ purified PS-I were assayed as described in Example 9, method 2a. The activity-response is proportional in a range from 1 to 4 μg PS per assay. Graph B shows the time course of inorganic phosphate formation. 1.2 mg (&Circlesolid;), 2.4 mg (▪), and 3.0 mg (▴) of MonoQ purified PS-I were assayed as described in Example 9, method 2a. The activity-response is proportional in a range from 0 to 20 minutes of incubation.

Number	Date	Country	Kind
9713477.9	Jun 1997	GB
9711163.7	May 1997	GB

	Number	Date	Country
Parent	09424378	Nov 1999	US
Child	10456684	Jun 2003	US

Herbicides test method

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