Crystallization of Escherichia coli enoyl reductase and its complex with diazaborine

Recent work has shown that the NADH-dependent enoyl acyl carrier protein reductase from Escherichia coli is the target for diazaborine, an antibacterial agent. This enzyme has been crystallized by the hanging-drop method of vapour diffusion complexed with NAD(+) and in the presence and absence of a thieno diazaborine. The crystals grown in the absence of diazaborine (form A) are in the space group P2(1) with unit-cell dimensions a = 74.0, b = 81.2, c = 79.0 A and beta = 92.9 degrees, and with a tetramer in the asymmetric unit, whilst those grown in the presence of diazaborine (form B) are in the space group P6(1)22 (or P6(5)22) with unit-cell dimensions a = b = 80.9 and c = 328.3 A, and with a dimer in the asymmetric unit. The structure determination of this enzyme in the presence of diazaborine will provide information on the nature of the drug binding site and contribute to a programme of rational drug design.

A study of the structure-activity relationship for diazaborine inhibition of Escherichia coli enoyl-ACP reductase

Enoyl acyl carrier protein (ACP) reductase catalyses the last reductive step of fatty acid biosynthesis, reducing the enoyl group of a growing fatty acid chain attached to ACP to its acyl product using NAD(P)H as the cofactor. This enzyme is the target for the diazaborine class of antibacterial agents, the biocide triclosan, and one of the targets for the front-line anti-tuberculosis drug isoniazid. The structures of complexes of Escherichia coli enoyl-ACP reductase (ENR) from crystals grown in the presence of NAD+ and a family of diazaborine compounds have been determined. Analysis of the structures has revealed that a mobile loop in the structure of the binary complex with NAD+ becomes ordered on binding diazaborine/NAD+ but displays a different conformation in the two subunits of the asymmetric unit. The work presented here reveals how, for one of the ordered conformations adopted by the mobile loop, the mode of diazaborine binding correlates well with the activity profiles of the diazaborine family. Additionally, diazaborine binding provides insights into the pocket on the enzyme surface occupied by the growing fatty acid chain.

The X-ray structure of Brassica napus beta-keto acyl carrier protein reductase and its implications for substrate binding and catalysis

BACKGROUND

beta-Keto acyl carrier protein reductase (BKR) catalyzes the pyridine-nucleotide-dependent reduction of a 3-oxoacyl form of acyl carrier protein (ACP), the first reductive step in de novo fatty acid biosynthesis and a reaction often performed in polyketide biosynthesis. The Brassica napus BKR enzyme is NADPH-dependent and forms part of a dissociable type II fatty acid synthetase (FAS). Significant sequence similarity is observed with enoyl acyl carrier protein reductase (ENR), the other reductase of FAS, and the short-chain alcohol dehydrogenase (SDR) family.

RESULTS

The first crystal structure of BKR has been determined at 2.3 A resolution in a binary complex with an NADP(+) cofactor. The structure reveals a homotetramer in which each subunit has a classical dinucleotide-binding fold. A triad of Ser154, Tyr167 and Lys171 residues is found at the active site, characteristic of the SDR family. Overall BKR has a very similar structure to ENR with good superimposition of catalytically important groups. Modelling of the substrate into the active site of BKR indicates the need for conformational changes in the enzyme.

CONCLUSIONS

A catalytic mechanism can be proposed involving the conserved triad. Helix alpha6 must shift its position to permit substrate binding to BKR and might act as a flexible lid on the active site. The similarities in fold, mechanism and substrate binding between BKR, which catalyzes a carbon-oxygen double-bond reduction, and ENR, the carbon-carbon double-bond oxidoreductase in FAS, suggest a close evolutionary link during the development of the fatty acid biosynthetic pathway.

Crystallographic analysis of triclosan bound to enoyl reductase

Molecular genetic studies with strains of Escherichia coli resistant to triclosan, an ingredient of many anti-bacterial household goods, have suggested that this compound works by acting as an inhibitor of enoyl reductase (ENR) and thereby blocking lipid biosynthesis. We present structural analyses correlated with inhibition data, on the complexes of E. coli and Brassica napus ENR with triclosan and NAD(+) which reveal how triclosan acts as a site-directed, picomolar inhibitor of the enzyme by mimicking its natural substrate. Elements of both the protein and the nucleotide cofactor play important roles in triclosan recognition, providing an explanation for the factors controlling its tight binding to the enzyme and for the emergence of triclosan resistance.

Inhibitor binding studies on enoyl reductase reveal conformational changes related to substrate recognition

Enoyl acyl carrier protein reductase (ENR) is involved in fatty acid biosynthesis. In Escherichia coli this enzyme is the target for the experimental family of antibacterial agents, the diazaborines, and for triclosan, a broad spectrum antimicrobial agent. Biochemical studies have suggested that the mechanism of diazaborine inhibition is dependent on NAD(+) and not NADH, and resistance of Brassica napus ENR to diazaborines is thought to be due to the replacement of a glycine in the active site of the E. coli enzyme by an alanine at position 138 in the plant homologue. We present here an x-ray analysis of crystals of B. napus ENR A138G grown in the presence of either NAD(+) or NADH and the structures of the corresponding ternary complexes with thienodiazaborine obtained either by soaking the drug into the crystals or by co-crystallization of the mutant with NAD(+) and diazaborine. Analysis of the ENR A138G complex with diazaborine and NAD(+) shows that the site of diazaborine binding is remarkably close to that reported for E. coli ENR. However, the structure of the ternary ENR A138G-NAD(+)-diazaborine complex obtained using co-crystallization reveals a previously unobserved conformational change affecting 11 residues that flank the active site and move closer to the nicotinamide moiety making extensive van der Waals contacts with diazaborine. Considerations of the mode of substrate binding suggest that this conformational change may reflect a structure of ENR that is important in catalysis.

Sequences surrounding the transcription initiation site of the Arabidopsis enoyl-acyl carrier protein reductase gene control seed expression in transgenic tobacco

The NADH-specific enoyl-acyl carrier protein (ACP) reductase, which catalyses the last reducing step during the fatty acid biosynthesis cycle, is encoded in Arabidopsis thaliana encoded by a single housekeeping gene (ENR-A) which is differentially expressed during plant development. To identify elements involved in its tissue-specific transcriptional control, a fragment comprising the 1470 bp region directly upstream of the ATG start codon of the ENR-A gene was fused to the uidA (GUS) reporter gene and analysed in transgenic Nicotiana tabacum plants. GUS activity found during development of the transgenic plants was similar to endogenous ENR protein levels found in both tobacco and Arabidopsis plants, except for developing flowers. In floral tissue the promoter fragment showed very little activity in contrast to the relatively high level of endogenous ENR expression. Successive deletions from the 5' and 3' regions of the promoter fragment revealed the presence of at least three elements which control GUS expression in different stages of development in the transgenic tobacco plants. First, expression in young developing leaves required both the presence of sequences between -329 to -201 relative to the transcription start and part of the untranslated leader comprising the first intron. Second, root-specific GUS expression was still observed after deletion of the 5'-upstream sequences up to 19 bp of the transcription initiation site. Further, the additional removal of the intron from the untranslated leader increased root-specific expression by ca. 4- to 5-fold. Third, high expression in seeds was still observed with the minimal upstream promoter segment of 19 bp. This seed expression level was found to be independent of the presence or absence of the intron in the untranslated leader. Finally, 3' deletion of the leader sequence up to 17 bp of the transcription start greatly impaired GUS activity during all stages of plant development, suggesting that the deleted sequence of the leader either functions as an enhancer for transcription initiation or stabilizes the mRNA.

Molecular genetic analysis of enoyl-acyl carrier protein reductase inhibition by diazaborine

Diazaborine and isoniazid are, at first sight, unrelated anti-bacterial agents that inhibit the enoyl-ACP reductase (ENR) of Escherichia coli and Mycobacterium tuberculosis respectively. The crystal structures of these enzymes including that of the diazaborine-inhibited E. coli ENR have been obtained at high resolution. Site-directed mutagenesis was used to study the importance of amino acid residues in diazaborine susceptibility and enzyme function. The results show that drug binding and inhibition require the presence of a glycine residue at position 93 of E. coli ENR or at the structurally equivalent position in the plant homologue, which is naturally resistant to the drug. The data confirm the hypothesis that any amino acid side-chain other than hydrogen at this position within the three-dimensional structure of these enzymes will affect diazaborine resistance by encroaching into the drug binding site. Substitutions of Gly-93 by amino acids with small side-chains, such as serine, alanine, cysteine and valine, hardly affected the catalytic parameters and rendered the bacterial host resistant to the drug. Larger amino acid side-chains, such as that of arginine, histidine, lysine and glutamine, completely inactivated the activity of the enzyme.

The X-ray structure of Escherichia coli enoyl reductase with bound NAD+ at 2.1 A resolution

Enoyl acyl carrier protein reductase catalyses the last reductive step of fatty acid biosynthesis, reducing an enoyl acyl carrier protein to an acyl-acyl carrier protein with NAD(P)H as the cofactor. The crystal structure of enoyl reductase (ENR) from Escherichia coli has been determined to 2.1 A resolution using a combination of molecular replacement and isomorphous replacement and refined using data from 10 A to 2.1 A to an R-factor of 0.16. The final model consists of the four subunits of the tetramer, wherein each subunit is composed of 247 of the expected 262 residues, and a NAD+ cofactor for each subunit of the tetramer contained in the asymmetric unit plus a total of 327 solvent molecules. There are ten disordered residues per subunit which form a loop near the nucleotide binding site which may become ordered upon substrate binding. Each monomer is composed of a seven-stranded parallel beta-sheet flanked on each side by three alpha-helices with a further helix lying at the C terminus of the beta-sheet. This fold is highly reminiscent of the Rossmann fold, found in many NAD(P)H-dependent enzymes. Analysis of the sequence and structure of ENR and comparisons with the family of short-chain alcohol dehydrogenases, identify a conserved tyrosine and lysine residue as important for catalytic activity. Modelling studies suggest that a region of the protein surface that contains a number of strongly conserved hydrophobic residues and lies adjacent to the nicotinamide ring, forms the binding site for the fatty acid substrate.

Mechanism of action of diazaborines

The diazaborine family of compounds have antibacterial properties against a range of gram-negative bacteria. Initially, this was thought to be due to the prevention of lipopolysaccharide synthesis. More recently, the molecular target of diazaborines has been identified as the NAD(P)H-dependent enoyl acyl carrier protein reductase (ENR), which catalyses the last reductive step of fatty acid synthase. ENR from Mycobacterium tuberculosis is the target for the front-line antituberculosis drug isoniazid. The emergence of isoniazid resistance strains of M. tuberculosis, a chronic infectious disease that already kills more people than any other infection, is currently causing great concern over the prospects for its future treatment, and it has reawakened interest in the mechanism of diazaborine action. Diazaborines only inhibit ENR in the presence of the nucleotide cofactor, and this has been explained through the analysis of the x-ray crystallographic structures of a number of Escherichia coli ENR-NAD+-diazaborine complexes that showed the formation of a covalent bond between the boron atom in the diazaborines and the 2'-hydroxyl of the nicotinamide ribose moiety that generates a noncovalently bound bisubstrate analogue. The similarities in catalytic chemistry and in the conformation of the nucleotide cofactor across the wider family of NAD(P)-dependent oxidoreductases suggest that there are generic opportunities to mimic the interactions seen here in the rational design of bisubstrate analogue inhibitors for other NAD(P)H-dependent oxidoreductases.

Functional analysis of an interspecies chimera of acyl carrier proteins indicates a specialized domain for protein recognition

The nodulation protein NodF of Rhizobium shows 25% identity to acyl carrier protein (ACP) from Escherichia coli (encoded by the gene acpP). However, NodF cannot be functionally replaced by AcpP. We have investigated whether NodF is a substrate for various E. coli enzymes which are involved in the synthesis of fatty acids. NodF is a substrate for the addition of the 4'-phosphopantetheine prosthetic group by holo-ACP synthase. The Km value for NodF is 61 microM, as compared to 2 microM for AcpP. The resulting holo-NodF serves as a substrate for coupling of malonate by malonyl-CoA:ACP transacylase (MCAT) and for coupling of palmitic acid by acyl-ACP synthetase. NodF is not a substrate for beta-keto-acyl ACP synthase III (KASIII), which catalyses the initial condensation reaction in fatty acid biosynthesis. A chimeric gene was constructed comprising part of the E. coli acpP gene and part of the nodF gene. Circular dichroism studies of the chimeric AcpP-NodF (residues 1-33 of AcpP fused to amino acids 43-93 of NodF) protein encoded by this gene indicate a similar folding pattern to that of the parental proteins. Enzymatic analysis shows that AcpP-NodF is a substrate for the enzymes holo-ACP synthase, MCAT and acyl-ACP synthetase. Biological complementation studies show that the chimeric AcpP-NodF gene is able functionally to replace NodF in the root nodulation process in Vicia sativa. We therefore conclude that NodF is a specialized acyl carrier protein whose specific features are encoded in the C-terminal region of the protein. The ability to exchange domains between such distantly related proteins without affecting conformation opens exciting possibilities for further mapping of the functional domains of acyl carrier proteins (i. e., their recognition sites for many enzymes).

A mechanism of drug action revealed by structural studies of enoyl reductase

Enoyl reductase (ENR), an enzyme involved in fatty acid biosynthesis, is the target for antibacterial diazaborines and the front-line antituberculosis drug isoniazid. Analysis of the structures of complexes of Escherichia coli ENR with nicotinamide adenine dinucleotide and either thienodiazaborine or benzodiazaborine revealed the formation of a covalent bond between the 2' hydroxyl of the nicotinamide ribose and a boron atom in the drugs to generate a tight, noncovalently bound bisubstrate analog. This analysis has implications for the structure-based design of inhibitors of ENR, and similarities to other oxidoreductases suggest that mimicking this molecular linkage may have generic applications in other areas of medicinal chemistry.

Common themes in redox chemistry emerge from the X-ray structure of oilseed rape (Brassica napus) enoyl acyl carrier protein reductase

BACKGROUND

Enoyl acyl carrier protein reductase (ENR) catalyzes the NAD(P)H-dependent reduction of trans-delta 2-enoyl acyl carrier protein, an essential step in de novo fatty acid biosynthesis. Plants contain both NADH-dependent and separate NADPH-dependent ENR enzymes which form part of the dissociable type II fatty acid synthetase. Highly elevated levels of the NADH-dependent enzyme are found during lipid deposition in maturing seeds of oilseed rape (Brassica napus).

RESULTS

The crystal structure of an ENR-NAD binary complex has been determined at 1.9 A resolution and consists of a homotetramer in which each subunit forms a single domain comprising a seven-stranded parallel beta sheet flanked by seven alpha helices. The subunit has a topology highly reminiscent of a dinucleotide-binding fold. The active site has been located by difference Fourier analysis of data from crystals equilibrated in NADH.

CONCLUSIONS

The structure of ENR shows a striking similarity with the epimerases and short-chain alcohol dehydrogenases, in particular, 3 alpha,20 beta-hydroxysteroid dehydrogenase (HSD). The similarity with HSD extends to the conservation of a catalytically important lysine that stabilizes the transition state and to the use of a tyrosine as a base--with subtle modifications arising from differing requirements of the reduction chemistry.

The Escherichia coli malonyl-CoA:acyl carrier protein transacylase at 1.5-A resolution. Crystal structure of a fatty acid synthase component

Endogenous fatty acids are synthesized in all organisms in a pathway catalyzed by the fatty acid synthase complex. In bacteria, where the fatty acids are used primarily for incorporation into components of cell membranes, fatty acid synthase is made up of several independent cytoplasmic enzymes, each catalyzing one specific reaction. The initiation of the elongation step, which extends the length of the growing acyl chain by two carbons, requires the transfer of the malonyl moiety from malonyl-CoA onto the acyl carrier protein. We report here the crystal structure (refined at 1.5-A resolution to an R factor of 0.19) of the malonyl-CoA specific transferase from Escherichia coli. The protein has an alpha/beta type architecture, but its fold is unique. The active site inferred from the location of the catalytic Ser-92 contains a typical nucleophilic elbow as observed in alpha/beta hydrolases. Serine 92 is hydrogen bonded to His-201 in a fashion similar to various serine hydrolases. However, instead of a carboxyl acid typically found in catalytic triads, the main chain carbonyl of Gln-250 serves as a hydrogen bond acceptor in an interaction with His-201. Two other residues, Arg-117 and Glu-11, are also located in the active site, although their function is not clear.

Modification of Brassica napus seed oil by expression of the Escherichia coli fabH gene, encoding 3-ketoacyl-acyl carrier protein synthase III

The Escherichia coli fabH gene encoding 3-ketoacyl-acyl carrier protein synthase III (KAS III) was isolated and the effect of overproduction of bacterial KAS III was compared in both E. coli and Brassica napus. The change in fatty acid profile of E. coli was essentially the same as that reported by Tsay et al. (J Biol Chem 267 (1992) 6807-6814), namely higher C14:0 and lower C18:1 levels. In our study, however, an arrest of cell growth was also observed. This and other evidence suggests that in E. coli the accumulation of C14:0 may not be a direct effect of the KAS III overexpression, but a general metabolic consequence of the arrest of cell division. Bacterial KAS III was expressed in a seed- and developmentally specific manner in B. napus in either cytoplasm or plastid. Significant increases in KAS III activities were observed in both these transformation groups, up to 3.7 times the endogenous KAS III activity in mature seeds. Only the expression of the plastid-targeted KAS III gene, however, affected the fatty acid profile of the storage lipids, such that decreased amounts of C18:1 and increased amounts of C18:2 and C18:3 were observed as compared to control plants. Such changes in fatty acid composition reflect changes in the regulation and control of fatty acid biosynthesis. We propose that fatty acid biosynthesis is not controlled by one rate-limiting enzyme, such as acetyl-CoA carboxylase, but rather is shared by a number of component enzymes of the fatty acid biosynthetic machinery.

A Zea mays GTP-binding protein of the ARF family complements an Escherichia coli mutant with a temperature-sensitive malonyl-coenzyme A:acyl carrier protein transacylase

In an attempt to isolate a plant malonyl-coenzyme A:acyl carrier protein transacylase cDNA clone, by direct genetic selection in an Escherichia coli fabD mutant (LA2-89) with a maize cDNA expression library, a Zea mays cDNA clone encoding a GTP-binding protein of the ARF family was isolated. Complementation of a mutation affecting bacterial membrane lipid biosynthesis by a plant ARF protein, could indicate the existence of as yet unidentified bacterial equivalents of this ubiquitous eucaryotic GTP-binding protein.

Developmental specific expression and organelle targeting of the Escherichia coli fabD gene, encoding malonyl coenzyme A-acyl carrier protein transacylase in transgenic rape and tobacco seeds

In both plants and bacteria, de novo fatty acid biosynthesis is catalysed by a type II fatty acid synthetase (FAS) system which consists of a group of eight discrete enzyme components. The introduction of heterologous, i.e. bacterial, FAS genes in plants could provide an alternative way of modifying the plant lipid composition. In this study the Escherichia coli fabD gene, encoding malonyl CoA-ACP transacylase (MCAT), was used as a model gene to investigate the effects of over-producing a bacterial FAS component in the seeds of transgenic plants. Chimeric genes were designed, so as not to interfere with the household activities of fatty acid biosynthesis in the earlier stages of seed development, and introduced into tobacco and rapeseed using the Agrobacterium tumefaciens binary vector system. A napin promoter was used to express the E. coli MCAT in a seed-specific and developmentally specific manner. The rapeseed enoyl-ACP reductase transit peptide was used successfully, as confirmed by immunogold labelling studies, for plastid targeting of the bacterial protein. The activity of the bacterial enzyme reached its maximum (up to 55 times the maximum endogenous MCAT activity) at the end of seed development, and remained stable in mature transgenic seeds. Significant changes in fatty acid profiles of storage lipids and total seed lipid content of the transgenic plants were not found. These results are in support of the notion that MCAT does not catalyse a rate-limiting step in plant fatty acid biosynthesis.

Crystallization of the malonyl coenzyme A-acyl carrier protein transacylase from Escherichia coli

The malonyl coenzyme A-acyl carrier protein transacylase, a single polypeptide chain of 358 amino acid residues and a molecular mass of 32 kDa, is a key component of the fatty acid synthase multienzyme complex. The elucidation of its three-dimensional structure will help in the understanding of the molecular basis of the biosynthesis of fatty acids, as well as of polyketides and related biologically active molecules. Three X-ray-quality crystal forms of the Escherichia coli fabD gene product encoding for malonyl coenzyme A-acyl carrier protein transacylase have been obtained using the hanging-drop method and ammonium sulfate as precipitant. Two are tetragonal and each contains two molecules in the asymmetric unit (form I: space group P4(3(1))2(1)2 with a = b = 83.9 A, c = 166.5 A and form II: space group P4 with a = b = 132.64 A, c = 38.85 A), whereas the third form belongs to the hexagonal system and contains one molecule in the asymmetric unit (space group P6(1(5)) with a = b = 68.52 A, c = 117.71 A). In each case, the diffraction pattern extends to approximately 2.0 A resolution using CuK alpha radiation from a rotating anode source.

The use of a hybrid genetic system to study the functional relationship between prokaryotic and plant multi-enzyme fatty acid synthetase complexes

Fatty acid synthesis in bacteria and plants is catalysed by a multi-enzyme fatty acid synthetase complex (FAS II) which consists of separate monofunctional polypeptides. Here we present a comparative molecular genetic and biochemical study of the enoyl-ACP reductase FAS components of plant and bacterial origin. The putative bacterial enoyl-ACP reductase gene (envM) was identified on the basis of amino acid sequence similarities with the recently cloned plant enoyl-ACP reductase. Subsequently, it was unambiguously demonstrated by overexpression studies that the envM gene encodes the bacterial enoyl-ACP reductase. An anti-bacterial agent called diazaborine was shown to be a specific inhibitor of the bacterial enoyl-ACP reductase, whereas the plant enzyme was insensitive to this synthetic antibiotic. The close functional relationship between the plant and bacterial enoyl-ACP reductases was inferred from genetic complementation of an envM mutant of Escherichia coli. Ultimately, envM gene-replacement studies, facilitated by the use of diazaborine, demonstrated for the first time that a single component of the plant FAS system can functionally replace its counterpart within the bacterial multienzyme complex. Finally, lipid analysis of recombinant E. coli strains with the hybrid FAS system unexpectedly revealed that enoyl-ACP reductase catalyses a rate-limiting step in the elongation of unsaturated fatty acids.

Molecular characterization of an Escherichia coli mutant with a temperature-sensitive malonyl coenzyme A-acyl carrier protein transacylase

The temperature-sensitive malonyl CoA-ACP transacylase found in the Escherichia coli strain LA2-89, carrying the fabD89 allele, was shown to result from the presence of an amber mutation in the fabD gene, at codon position 257, in combination with the supE44 genotype of this strain. The truncated form of the protein produced as the result of the amber mutation was demonstrated to be enzymatically inactive, whereas amber suppression rendered the resulting enzyme temperature labile. Site-directed mutagenesis of codon 257 revealed a requirement for an aromatic amino acid at this position in the polypeptide chain, to assure temperature stability of the enzyme.

Crystallization of the NADH-specific enoyl acyl carrier protein reductase from Brassica napus

The tetrameric, NADH-dependent enoyl acyl carrier protein reductase from developing seeds of Brassica napus (oil seed rape) has been crystallized from solutions containing ammonium sulphate as the precipitant in the presence of NAD+ or NADH using the hanging drop method of vapour diffusion. The crystals belong to the tetragonal system and are in space group P4(2)2(1)2 with cell dimensions a = b = 70.5 A, c = 117.8 A. Considerations of the possible values of Vm indicate that the asymmetric unit contains a single subunit. The crystals are resistant to radiation damage and X-ray diffraction photographs taken with synchrotron radiation show measurable reflections to beyond 1.9 A resolution. Determination of the structure of this enzyme will advance the understanding of the mechanisms of lipid biosynthesis in plants and provide an opportunity to study the interactions between this enzyme and its acyl carrier protein substrate.

Cloning, nucleotide sequence, and expression of the Escherichia coli fabD gene, encoding malonyl coenzyme A-acyl carrier protein transacylase

The Escherichia coli fabD gene encoding malonyl coenzyme A-acyl carrier protein transacylase (MCT) was cloned by complementation of a thermosensitive E. coli fabD mutant (fabD89). Expression of the fabD gene in an appropriate E. coli expression vector resulted in an accumulation of the MCT protein of up to 10% of total soluble protein, which was accompanied by an approximately 1,000-fold increase in the MCT activity. DNA sequence analysis and expression studies revealed that the fabD gene is part of an operon consisting of at least three genes involved in fatty acid biosynthesis. Comparison with available DNA and protein data bases suggest that a 3-ketoacyl-acyl carrier protein synthase and a ketoacyl-acyl carrier protein reductase gene are located immediately upstream and downstream, respectively, of fabD within this fab operon. Western immunoblot analysis with antiserum raised against wild-type E. coli MCT showed that the fabD89 allele encodes a polypeptide with an apparent molecular weight of 27,000 in addition to the normal MCT protein of 32,000. The nature of the temperature-sensitive fabD89 gene product is discussed.

cDNA cloning and expression of Brassica napus enoyl-acyl carrier protein reductase in Escherichia coli

The onset of storage lipid biosynthesis during seed development in the oilseed crop Brassica napus (rape seed) coincides with a drastic qualitative and quantitative change in fatty acid composition. During this phase of storage lipid biosynthesis, the enzyme activities of the individual components of the fatty acid synthase system increase rapidly. We describe a rapid and simple purification procedure for the plastid-localized NADH-dependent enoyl-acyl carrier protein reductase from developing B. napus seed, based on its affinity towards the acyl carrier protein (ACP). The purified protein was N-terminally sequenced and used to raise a potent antibody preparation. Immuno-screening of a seed-specific lambda gt11 cDNA expression library resulted in the isolation of enoyl-ACP reductase cDNA clones. DNA sequence analysis of an apparently full-length cDNA clone revealed that the enoyl-ACP reductase mRNA is translated into a precursor protein with a putative 73 amino acid leader sequence which is removed during the translocation of the protein through the plastid membrane. Expression studies in Escherichia coli demonstrated that the full-length cDNA clone encodes the authentic B. napus NADH-dependent enoyl-ACP reductase. Characterization of the enoyl-ACP reductase genes by Southern blotting shows that the allo-tetraploid B. napus contains two pairs of related enoyl-ACP reductase genes derived from the two distinct genes found in both its ancestors, Brassica oleracea and B. campestris. Northern blot analysis of enoyl-ACP reductase mRNA steady-state levels during seed development suggests that the increase in enzyme activity during the phase of storage lipid accumulation is regulated at the level of gene expression.

Regulation of plant gene expression by antisense RNA

Regulation of gene expression by antisense RNA was first discovered as a naturally-occurring phenomenon in bacteria. Recently natural antisense RNAs have been found in a variety of eukaryotic organisms; their in vivo function is, however, obscure. Deliberate expression of antisense RNA in animal and plant systems has lead to successful down-regulation of specific genes. We will review the current status of antisense gene action in plant systems. The recent discovery that 'sense' genes are able to mimic the action of antisense genes indicates that (anti)sense genes must operate by mechanisms other than RNA-RNA interaction.

Flavonoid genes in petunia: addition of a limited number of gene copies may lead to a suppression of gene expression

To evaluate the effect of increased expression of genes involved in flower pigmentation, additional dihydroflavonol-4-reductase (DFR) or chalcone synthase (CHS) genes were transferred to petunia. In most transformants, the increased expression had no measurable effect on floral pigmentation. Surprisingly, however, in up to 25% of the transformants, a reduced floral pigmentation, accompanied by a dramatic reduction of DFR or CHS gene expression, respectively, was observed. This phenomenon was obtained with both chimeric gene constructs and intact CHS genomic clones. The reduction in gene expression was independent of the promoter driving transcription of the transgene and involved both the endogenous gene and the homologous transgene. The gene-specific collapse in expression was obtained even after introduction of only a single gene copy. The similarity between the sense transformants and regulatory CHS mutants suggests that this mechanism of gene silencing may operate in naturally occurring regulatory circuits.

Flavonoid genes in petunia: addition of a limited number of gene copies may lead to a suppression of gene expression

To evaluate the effect of increased expression of genes involved in flower pigmentation, additional dihydroflavonol-4-reductase (DFR) or chalcone synthase (CHS) genes were transferred to petunia. In most transformants, the increased expression had no measurable effect on floral pigmentation. Surprisingly, however, in up to 25% of the transformants, a reduced floral pigmentation, accompanied by a dramatic reduction of DFR or CHS gene expression, respectively, was observed. This phenomenon was obtained with both chimeric gene constructs and intact CHS genomic clones. The reduction in gene expression was independent of the promoter driving transcription of the transgene and involved both the endogenous gene and the homologous transgene. The gene-specific collapse in expression was obtained even after introduction of only a single gene copy. The similarity between the sense transformants and regulatory CHS mutants suggests that this mechanism of gene silencing may operate in naturally occurring regulatory circuits.

Flavonoid synthesis in Petunia hybrida: partial characterization of dihydroflavonol-4-reductase genes

In this paper we describe the organization and expression of the genes encoding the flavonoid-biosynthetic enzyme dihydroflavonol-4-reductase (DFR) in Petunia hybrida. A nearly full-size DFR cDNA clone (1.5 kb), isolated from a corolla-specific cDNA library was compared at the nucleotide level with the pallida gene from Antirrhinum majus and at the amino acid level with enzymes encoded by the pallida gene and the A1 gene from Zea mays. The P. hybrida and A. majus DFR genes transcribed in flowers contain 5 introns, at identical positions; the three introns of the A1 gene from Z. mays coincide with the first three introns of the other two species. P. hybrida line V30 harbours three DFR genes (A, B, C) which were mapped by RFLP analysis on three different chromosomes (IV, II and VI respectively). Steady-state levels of DFR mRNA in the line V30 follow the same pattern during development as chalcone synthase (CHS) and chalcone flavanone isomerase (CHI) mRNA. Six mutants that accumulate dihydroflavonols in mature flowers were subjected to Northern blot analysis for the presence of DFR mRNA. Five of these mutants lack detectable levels of DFR mRNA. Four of these five also show drastically reduced levels of activity for the enzyme UDPG: flavonoid-3-O-glucosyltransferase (UFGT), which carries out the next step in flavonoid biosynthesis; these mutants might be considered as containing lesions in regulatory genes, controlling the expression of the structural genes in this part of the flavonoid biosynthetic pathway. Only the an6 mutant shows no detectable DFR mRNA but a wild-type level for UFGT activity. Since both an6 and DFR-A are located on chromosome IV and DFR-A is transcribed in floral tissues, it is postulated that the An6 locus contains the DFR structural gene. The an9 mutant shows a wild-type level of DFR mRNA and a wild-type UFGT activity.

Antisense genes in plants: an overview

Plants are the first multicellular higher eukaryotic organisms in which artificial antisense genes have been shown to down-regulate target gene expression. Manipulations with an antisense gene can serve as a tool to study the effect of a particular plant gene inactivation, the interaction of gene products whose genes are coordinately expressed, or the functional analysis of cryptic genes. Transgenic plants harbouring an antisense gene already gave rise to patentable new characteristics, showing that the technique has great scientific and economic value.

Cloning of the two chalcone flavanone isomerase genes from Petunia hybrida: coordinate, light-regulated and differential expression of flavonoid genes

In this paper we report the isolation of cDNA clones encoding the flavonoid-biosynthetic enzyme chalcone flavanone isomerase (CHI) from Petunia hybrida. A nearly full size cDNA clone, isolated from a corolla-specific expression library, was characterized by sequence analysis. Using this CHI cDNA and the previously cloned flavonoid-specific chalcone synthase (CHS) cDNA we show that CHI and CHS genes are coordinately and tissue-specifically expressed in a developmental and light-regulated manner. Furthermore, coordinate induction of both mRNAs is observed after continuous irradiation of Petunia plantlets with UV light, probably as part of the plants UV defence mechanism. The two CHI genes, denoted A and B, were isolated from a genomic library of the Petunia inbred line V30. Both genes are transcriptionally active: gene A is transcribed in corolla, tube and UV-irradiated plantlets (1.0 kb mRNA), whereas gene B is only transcribed in immature anthers (1.0 kb mRNA). In combination with Southern blot analysis these data implicate the presence of two distinct non-allelic CHI genes in the genome of the P. hybrida line V30. Unexpectedly, mature anthers accumulate a 0.3 kb larger CHI RNA. This RNA is transcribed from CHI gene A and has a 0.3 kb 5' extension relative to the gene A transcript found in corolla tissue. Furthermore it is neither coordinately expressed with CHS mRNA nor UV inducible. Its biological function is still obscure, since no active CHI enzyme could be demonstrated in the same tissue.

Evidence for the involvement of the 16kD gene promoter in initiation of chromosomal replication of Escherichia coli strains carrying a B/r-derived replication origin

Initiation of chromosomal DNA replication of several Escherichia coli dnaA (Ts) strains is diminished in cell harbouring pBR322 hybrid plasmids carrying both oriC and the adjacent 16kD gene promoter of E. coli K12. This perturbance, resulting in very slow growth, is caused both by the dnaA allele and the E. coli B/r-derived region of the replication origin of these strains. Cloning and DNA sequence analysis of the E. coli B/r replication origin revealed several base differences as compared to the E. coli K12 sequence. The replication origin of temperature sensitive fast growing mutants, originating from a homologous exchange between chromosomal and plasmid DNA sequences were also cloned. Sequence data showed that a single base change within the promoter of the 16kD gene of these dnaA (Ts) strains is able to suppress the inhibition of chromosomal DNA replication by the mentioned pBR322 hybrid plasmids. Our results strongly indicate a role of the 16kD gene promoter in control of initiation of chromosomal DNA replication.

Efficient isolation of the linear DNA killer plasmid of Kluyveromyces lactis: evidence for location and expression in the cytoplasm and characterization of their terminally bound proteins

Differential centrifugation of an osmotic lysate of K. lactis protoplasts showed that the linear DNA killer plasmids of K. lactis, pGKL1 and pGKL2, are almost exclusively present in the cytoplasmic fraction. This fractionation procedure allows the rapid isolation of large amounts of plasmid DNA without contamination by chromosomal and mitochondrial DNA. With these DNA preparations the size of the terminally bound proteins was estimated to be 28 and 36 kDal for pGKL1 and pGKL2, respectively. The entire pGKL1 sequence (except for 21 base pairs at the right terminus) was cloned in a shuttle vector that permits autonomous replication in the nucleus of K. lactis. However, killer gene expression could not be established in transformants. In connection with the observed cytoplasmic localization, this result suggests that gene expression of the killer DNA plasmids is entirely cytoplasmic.

The complete nucleotide sequence of the bacteriocinogenic plasmid CloDF13

The complete nucleotide sequence of the bacteriocinogenic plasmid CloDF13 has been determined. The plasmid consists of 9957 base pairs (molecular weight 6.64 X 10(6] with a GC content of 54.4%. At this moment 16 identified biological functions can be assigned to the primary structure of the CloDF13 DNA. The functions include those of eight protein encoding genes, two untranslated RNA species, and six DNA sites. We discuss these functions in relation to the structure of CloDF13 DNA. For convenience we have divided the CloDF13 genome into five defined regions: region I (origin of vegetative replication, priming and control of replication, type I incompatibility), region II (cloacin DF13, cloacin immunity, cloacin release, cloacin operon control), region III (double-stranded DNA-phage interaction, type II incompatibility, multimer resolution), region IV (inhibition of male specific RNA phages and transfer of Flac), and region V (mobility proteins, basis of mobility).

Dissection of promoter sequences involved in transcriptional activation of the Escherichia coli replication origin

The replication frequency of oriC plasmids in vivo is positively affected by specific transcripts running into oriC. These transcripts that activate oriC are initiated at a promoter of a gene coding for a 16kD protein. Genetic evidence is presented for binding of the initiation factor dnaA to a specific sequence (dnaA box) upstream of this promoter. Binding of the dnaA protein to this dnaA box regulates transcription initiation negatively. It was also demonstrated that binding of dnaA protein to the 16kD promoter region is essential to accomplish the actual activation event within the origin. Replication and incompatibility experiments suggest that dnaA protein is present within the activating transcription complex. The function of dnaA in this replication control mechanism is discussed.

Site-directed mutagenesis of the Escherichia coli chromosome near oriC: identification and characterization of asnC, a regulatory element in E. coli asparagine metabolism

We developed a new method for the specific mutagenization of the E. coli chromosome. This method takes advantage of the fact that a pBR322 plasmid containing chromosomal sequences is mobilizable during an Hfr-mediated conjugational transfer, due to an homologous recombination between the E. coli Hfr chromosome and the pBR322 derivative. Transconjugants are screened with a simple selection procedure for integration of mutant sequences in the chromosome and loss of pBR322 sequences. Using this method we specifically inactivated several genes near the E. coli replication origin oriC. We found that a gene coding for asparagine synthetase A. This regulatory mechanism was investigated in detail by determining in vivo regulation of asnA promoter activity by the 17kD protein under different growth conditions. Results obtained also suggest a general regulatory role of the 17kD protein in E. coli asparagine metabolism. Therefore the 17kD gene is proposed to be renamed asnC.

Initiation signals for complementary strand DNA synthesis in the region of the replication origin of the Escherichia coli chromosome

We have used an in vivo plasmid-phi X174 packaging system to detect replication initiation signals in the region of the replication origin (oriC) of the Escherichia coli chromosome. The results obtained are summarized as follows: (i) Neither within nor close to oriC effective signals for initiating complementary strand synthesis could be detected. We conclude that initiation mechanisms for leading and lagging strand synthesis at oriC are not identical to any known priming mechanism of DNA synthesis. (ii) At least five signals that can function as complementary strand origins on ss-plasmid DNA are located in a region about 2000-3300 base pairs away from oriC in the clockwise direction on the chromosome. We suggest that these signals are protein n' like recognition sequences since they are dependent for their activity on dnaB protein and show sequence similarities to other putative n' recognition sequences. Surprisingly, some of the signals are located on the template for leading strand synthesis.

Isolation and characterization of plasmids carrying a partially defective Escherichia coli replication origin

The replication origin (oriC) of the Escherichia coli chromosome has been cloned and the region essential for chromosomal replication has been delimited to 245 base pairs. In previous studies the ability of recombinants between oriC and ColE1-type vectors, to transform E. coli polA- strains was used to determine which nucleotides in oriC are essential for replication. In this paper we have used a different approach by isolating partial defective replication mutants of a minichromosome (pCM959) that contains oriC as the single replication origin. Our results demonstrate that many mutations are allowed within oriC that do not affect oriC function as measured by the ability to transform E. coli polA- strains. In the minimal oriC region we detected 8 mutations at positions that are conserved in the sequence of six bacterial origins. The implications of these results on previous work will be discussed. Our data also demonstrate that a mutation producing an oriC- phenotype may be suppressed by secondary mutations. An E. coli strain was found that facilitates the isolation of partially defective minichromosomes. The results with this strain indicate a specific function of the sequence surrounding the base pair at position 138.

Maintenance and incompatibility of plasmids carrying the replication origin of the Escherichia coli chromosome: evidence for a control region of replication between oriC and asnA

Plasmids that replicate only by means of the cloned Escherichia coli replication origin (oriC) are called minichromosomes or oriC-plasmids. In this paper it is shown that sequences located between oriC and asnA are involved in maintenance and incompatibility of minichromosomes. These sequences include part of the 16kD and 17kD genes, previously allocated within this region (1,2). Transcription towards oriC that is initiated at the 16kD promoter, specifically enhances the stability and copy-number of minichromosomes. Three regions are involved in minichromosome incompatibility. One region, incA, includes the minimal oriC sequence. A second, incB, maps within a 210 base pairs fragment that overlaps the 16kD promoter. The third, incC, encompasses the 17kD gene. Neither one of the regions expresses incompatibility on its own, but the additional presence of one of the others is required. The data presented indicate that sequences of the 16kD and 17kD genes are part of the replication control system of oriC-plasmids.

Identification of mutations affecting replication control of plasmid Clo DF13

The bacteriocinogenic plasmid Clo DF13, originally isolated from Escherichia cloacae, is stably maintained in Escherichia coli to the extent of about 10 copies per cell. Its replication resembles that of many other small, multicopy plasmids; plasmid-encoded protein is not required but plasmid-specific genetic information is involved in regulation of replication as both conditional and nonconditional copy-number mutants of Clo DF13, and transcomplementable copy-number mutants of plasmid Col E1 have been described. The sequences essential for replication of Col E1 (refs 16, 17) and Clo DF13 (refs 18, 19) have been identified within a region surrounding the replication origin. Initiation of Col E1 replication is preceded by transcription of the origin region, providing the RNA primer at the origin. However, transcription in the opposite direction results in a small transcript of approximately 100 nucleotides (RNA-100) for both Col E1 (refs 21, 22) and Clo DF13 (ref. 23). Data suggest that Col E1 RNA-100 acts as a negative control element for the initiation of replication. We show here that single base transitions in the RNA-100 cistron of Clo DF13 can result in a nonconditional increase in plasmid copy-number. Also, sequence analysis has revealed that a specific base transition in a DNA region, apparently involved in both termination and initiation of transcription towards the replication origin, results in a thermosensitive plasmid copy-number.

The nucleotide sequence surrounding the replication origin of the cop3 mutant of the bacteriocinogenic plasmid Clo DF13

The nucleotide sequence from about 100 base-pairs downstream to about 600 base pairs upstream the CloDF13 replication origin has been determined. A comparison of this sequence with the corresponding ColE1 origin sequence reveals that: The sequence at the origin of replication is conserved. There are large differences in the nucleotide sequence downstream the replication origin, whereas there is a large homology in the region of about 410 base-pairs upstream the replication origin. This conserved region might code for a largely homologous basic, arginine rich polypeptide of about 45 amino-acids, for both ColE1 and CloDF13. Although there are large differences in the primary structure of the region coding for the 100 nucleotide RNA, the secondary structure of this region seems to be conserved.

Origin and direction of replication of the bacteriocinogenic plasmid Clo DF13

Cairn's type replicative intermediates of both the wildtype Clo DF13 plasmid and the copy mutant CLO DF13 cop3 were isolated by dye-buoyant density centrifugation. Replicative intermediates were linearized at the HpaI or Sa1I cleavage site, and examined with the electron-microscope. The data show that replication of both the Clo DF13 wild type plasmid and the Clo DF13 cop3 plasmid, initiates at about 2.8% on the physical map. Replication proceeds unindirectionally and counterclockwise on this map.

In vitro construction of deletion mutants of the bacteriocinogenic plasmid Clo DF13

The isolation and characterization of deletion mutants of the bacteriocinogenic plasmid Clo DF13 is described. To construct these deletion mutants, DNA of Clo DF13::Tn901 and Clo DF13-rep3::Tn901 plasmids was digested with restriction endonucleases, ligated with T4 ligase and introduced by transformation into Escherichia coli. The presence of the ampicilline transposon Tn901 facilitated the selection of plasmids. The resulting Clo DF13::Tn901 deletion mutants were analyzed by digestion with restriction endonucleases and electron microscopy. From the properties of the various deletion mutants it was concluded that a Clo DF13 DNA region, extending from 5 to 11.5% on the physical map, is essential for the replication of Clo DF13. This region, comprising about 600 base pairs, contains in addition to an origin of replication, DNA sequences which are involved in the regulation of Clo DF13 DNA replication. Furthermore it was observed that in case of the Clo DF13 copy mutant, Clo DF13-rep3, deletion of the 43% to 63% part of the plasmid genome, resulted in the generation of multimeric plasmid structures, accompanied with an impaired segregation of the plasmids to daughter cells.