Genetic Organization of the citCDEF Locus and Identification of mae and clyR Genes from Leuconostoc mesenteroides

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Journal of Bacteriology, July 1999, p. 4411-4416, Vol. 181, No. 14
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Genetic Organization of the citCDEF Locus and Identification of mae and clyR Genes from Leuconostoc mesenteroides

Sadjia Bekal-Si Ali, Charles Diviès, and Hervé Prévost^*

Laboratoire de Microbiologie, UA INRA, Université de Bourgogne ENS.BANA, F-21 000 Dijon, France

Received 8 February 1999/Accepted 12 May 1999

	ABSTRACT

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In this paper, we describe two open reading frames coding for a NAD-dependent malic enzyme (mae) and a putative regulatoryprotein (clyR) found in the upstream region of citCDEFG of Leuconostocmesenteroides subsp. cremoris 195. The transcriptional analysisof the citrate lyase locus revealed one polycistronic mRNA coveringthe mae and citCDEF genes. This transcript was detected only onRNA prepared from cells grown in the presence of citrate. Primerextension experiments suggest that clyR and the citrate lyaseoperon are expressed from a bidirectional A-T-rich promoter regionlocated between mae and clyR.

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Leuconostocs are heterofermentative lactic acid bacteria used as a starter in association with lactococci for the manufactureof fermented milks and cheeses. Leuconostocs contribute to cheeseflavor and texture due to the production of diacetyl, acetoin,acetate, and carbon dioxide from citrate metabolism. Conversionof citrate into pyruvate by lactic acid bacteria requires threeenzymes: a citrate permease (CitP), a citrate lyase (CL) thatcleaves intracellular citrate into acetate and oxaloacetate, andan oxaloacetate decarboxylase that catalyzes the oxaloacetatedecarboxylation into carbon dioxide and pyruvate. CitP catalyzesan electrogenic exchange of divalent citrate and monovalent organicacid, resulting in the generation of a membrane potential (17,18). The CL (EC 4.1.3.6) was shown to form a functional complex(M_r, 585,000) of three proteins: a $gamma$ subunit (acyl carrier protein[ACP]), a $beta$ subunit (citryl-S-ACP lyase; EC 4.1.3.34), and an $alpha$ subunit (citrate:acetyl-ACP transferase; EC 2.8.3.10) (1,7). This enzymatic complex is active only if the thioesterresidue of the prosthetic group linked to the $gamma$ subunit is acetylated.This activation is catalyzed by an SH-CL ligase (EC 6.2.1.22)which converts HS-ACP in the presence of ATP and acetate to acetyl-S-ACP(21, 22).

Recently, we used a reverse genetic strategy to clone and characterize five genes of the CL multienzymatic complex from agenomic library of Leuconostoc mesenteroides subsp. cremoris 195constructed by ligation into pJDC9 (1). Two clones containedin plasmids pCL9 and pCg5 were selected. Plasmid pCL9 was shownto contain an incomplete citC gene coding for CL ligase and thegenes citDEFG for ACP, the $beta$ and $alpha$ subunits, and CitG, respectively.The function of the citG product remains unknown. Plasmid pCg5was shown to contain DNA encoding the N terminus of CL ligase(citC). The citCDEFG genes are clustered on a 5.2-kb DNA fragment(Fig. 1). The absence of intergenic regions between citC, citD,citE, and citF suggested that all of these genes could be expressedin an large polycistronic mRNA.

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FIG. 1. (A) Organization of the CL genes in L. mesenteroides. Every gene is drawn to scale, and orientations of transcription are indicated by arrows. The Sau3A DNA fragments cloned in plasmids pCL9 and pCg5 are shown as thin lines at the bottom. Transcription initiation points are indicated by small open circles, and the transcripts are indicated by a double broken line. Probes used for Northern blotting are shown as solid bars. (B) Northern blot autoradiogram. Total RNAs prepared from L. mesenteroides cells grown in the presence of citrate (lanes 1, 3, and 5) or in its absence (lanes 2, 4, and 6) were analyzed by electrophoresis on agarose-formamide gels, blotted onto a nylon membrane, and hybridized with mae (lane 1 and 2), citF (lane 3 and 4), or citG (lane 5 and 6). Arrows indicate the migration positions of 23S and 16S rRNAs and the 5.2- and 4.0-kb transcripts. Sizes were determined by using an RNA ladder (9.5 to 0.25 kb; Gibco-BRL).

In this paper, we describe two open reading frames (ORFs) coding for an NAD-dependent malic enzyme (mae) and a putative regulatoryprotein (clyR) found in the upstream region of citCDEFG. One polycistronicmRNA covering the mae and citCDEF genes was detected only in RNAprepared from cells grown in the presence of citrate. The clyRgene and the CL operon are expressed from a bidirectional extraordinaryA-T-rich promoter region located between mae and clyR.

CL activity of L. mesenteroides is induced by citrate. CL activity was determined from cells growing in MRS medium (6) in the absence or presence of citrate or malate. When theoptical density at 600 nm of a culture of L. mesenteroides hadreached 0.4, citrate (10 g/liter) or malate at (5 g/liter) wasadded to the growth medium. CL activity was assayed at 25°C ina coupled spectrophotometric assay as described previously (1).Because CL could be inactivated by deacetylation of a prostheticgroup linked to its ACP, the enzyme sample was chemically acetylatedwith 5 mM acetic anhydride for 1 min at 25°C and then used immediatelyfor determination of CL activity. One unit of CL activity is definedas 1 mol of citrate converted to acetate and oxaloacetate permin. Malate enzyme activity was determined as described by Kobayashiet al. (14).

In the absence of citrate, no CL or malic enzyme activity was detected. Addition of citrate to the medium resulted in stronginduction of CL activity (2.5 U/mg of protein). When cells weregrown in malate medium, the CL activity was not induced. In thepresence of citrate or malate, no malic enzyme activity was detectedin L. mesenteroides subsp. cremoris (data notshown).

Sequence analysis of the upstream region of the citCDEFG gene cluster. The DNA sequence of the upstream region of citCDEFG was determined on both strands by oligonucleotide primer walking usingthe dideoxynucleotide chain termination method (Thermosequenasekit; Amersham) with pCg5 as a template. A 1,127-bp ORF in thesame orientation as citCDEFG was found (Fig. 1). This ORF encodeda 375-amino-acid protein (calculated molecular mass, 39,475 Da)preceded by a putative ribosome binding site (RBS) (5'-AAGGAG-3')which is complementary to the 3' end of the L. mesenteroides 16SrRNA sequence (26). The stop codon of this ORF was located 73nucleotides upstream of the start codon of citC. A comparisonof the primary structure of the putative protein with proteinsequences in the Swissprot and Pirprot sequence data banks revealedsimilarities to malic enzymes. Therefore, this gene was designatedmae and encodes a putative malate oxidoreductase. Malic enzymes[(s)-malate:NAD⁺ oxidoreductase (decarboxylating)] which catalyze malate oxidativedecarboxylation are classified into three groups (EC 1.1.1.38,EC 1.1.1.39, and EC 1.1.1.40) on the basis of coenzyme specificityand ability to catalyze the decarboxylation of oxaloacetate. Theputative mae gene product of L. mesenteroides showed a high levelof sequence identity (37 to 44%) to the NAD-dependent malic enzymes(EC 1.1.1.38) of Bacillus subtilis (16), Streptococcus bovis(11), Pyrococcus horikoshii (12), Archaeoglobus fulgidus (13),and Bacillus stearothermophilus (14). Two highly conserved sequences(box I and box II) were found (Fig. 2). Box I corresponds to anNAD-binding domain (24). The amino acid sequence from position153 to position 169 (box II) is described as the malic enzymesignature in the Prosite database {PS00331; F-x-[DV]-D-x(2)-G-T-[GSA]-x-[LIVMA]-[GAST](2)-[LIVMF](2)}.However, a phenylalanine residue, which is the first amino acidof the consensus pattern, is replaced in our sequence by a tyrosineat position 153. Replacement of the same phenylalanine residuewith a tryptophan is also observed in the sequence of the malicenzyme from A. fulgidus (Fig. 2).

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FIG. 2. Comparison of part of the deduced amino acid sequence of mae from L. mesenteroides (LEUCM) with parts of the sequences of the malic enzymes from B. stearothermophilus (BACST; protein sequence accession no. P16468), Streptococcus bovis (SBOV; accession no. U35659), B. subtilis (YTSJ; accession no. Z99118), A. fulgidus (ARFUL; accession no. AE000984), and P. horikoshii (PYHOR; accession no. 3257695). Identical amino acids are indicated by asterisks. The conserved region corresponding to an NAD-binding domain and the malic enzyme signature are enclosed in boxes I and II, respectively. The numbers on the right are amino acid positions in the protein sequences. The percentages on the right are the levels of identity between the entire protein sequence deduced from mae and the sequences of the previously described proteins.

Sequence analysis of the upstream region of mae revealed a 939-bp ORF transcribed divergently from the mae-citCDEFG genes(Fig. 1). This ORF encoded a putative protein of 312 amino acidswith a predicted molecular mass of 35,080 Da. A potential RBS(5'-GGAGG-3'), is localized 8 bp upstream of the translation startsite (ATG). A comparison of the primary structure of the putativeprotein with protein sequences in data banks revealed similaritiesto regulatory proteins belonging to the SorC family of transcriptionalregulators. The highest degree of identity (23.3%) was found withSorC, which positively and negatively regulates, in the presenceand absence of L-sorbose, respectively, the transcription of thesorbose operon of Klebsiella pneumoniae (23, 25). Significantidentity was also shown with YhjU, a hypothetical transcriptionalregulator of Escherichia coli (4), and DeoR, a deoxyribonucleotideregulator of B. subtilis (20). In the N-terminal part of the312-amino-acid polypeptide gene product, a helix-turn-helix motifwas identified (positions 21 to 34) by using the weight matrixof Dodd and Egan (8). This motif probably forms a DNA-bindingregion, suggesting that this gene product could act as an activatoror repressor of transcription. Because of its localization nearthe citrate lyase operon, we named this gene clyR. Alignment ofmultiple amino acid sequences performed with the Multalign program(5) showed that identity scores were particularly high in theN-terminal sequence in which the helix-turn-helix was presentand in the last 80 amino acids of the C terminus of the SorC familyof regulators (Fig. 3).

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FIG. 3. Multiple-sequence alignment of ClyR with proteins belonging to the SorC family of transcriptional regulators: SorC, from K. pneumoniae (protein sequence accession no. P37078); DeoR, a deoxyribonucleoside regulator from B. subtilis (accession no. P39140); YdeW, a hypothetical transcriptional regulator in the HipB-UxaB intergenic region of E. coli (accession no. P76141); YgaP, a hypothetical transcriptional regulator in the gap 5' region of Bacillus megaterium (accession no. P35168); YjhU, a hypothetical transcriptional regulator in the fecI-fimB intergenic region of E. coli (accession no. P39356). Sequence identities (percentages) between ClyR and the individual proteins are as follows: SorC, 23.3%; YjhU, 26.2% in a 221-amino-acid overlap; DeoR, 22.6%; YdeW, 20.7%; YgaP, 18.7%. The deduced primary sequences were aligned by the multiple-sequence alignment program Multalign (5). Amino acids conserved in at least three of the six sequences shown are shaded. The helix-turn-helix domains are white letters in black boxes. The derived consensus (Cons) sequence corresponding to amino acids conserved in at least four sequences is in the bottom row. All sequences are numbered from Met-1.

Transcriptional analysis of the CL locus. To determine the transcriptional organization and the nature of CL activity induction, in vivo transcripts of the CL locuswere detected by dot blotting and Northern hybridization analysis.RNA was prepared as previously described (15) from Leuconostoccells grown on MRS medium in the presence or absence of citrate.DNA probes specific for mae (273 bp), citF (700 bp) citG (720bp), and clyR (289 bp) were generated by PCR amplification usingpCL9 and pCg5 as templates (Fig. 1). For Northern blot analysis,30 µg of RNA was loaded on a denaturing 0.9% (wt/vol) agarose-6.6%(wt/vol) formaldehyde gel and, after electrophoresis, transferredto Nitran membranes (Amersham). DNA radiolabeling, transfer, andhybridization were performed as described previously (1).

Using DNA probes for mae, citC, citF, and citG, the dot blot experiments revealed that transcripts were detected only in mRNAprepared from cells grown in the presence of citrate (data notshown). In the Northern blot analysis (Fig. 1), only one majormRNA transcript was detected by the mae, citF, and citG probes.No mRNA transcript was detected by dot blotting or Northern blottingusing the clyR probe. When probes for mae and citF were used,a single large transcript of approximately 5.2 kb was detected.The length of the transcript is consistent with the size expectedfrom the total nucleotide sequence of the mae-citCDEF genes (5kb). The transcript detected by the citG probe had a size of 4.0kb. Since this mRNA did not hybridize with the mae and citF probes,it presumably corresponds to an RNA starting downstream of theregion corresponding of the citF probe and ending downstream ofcitG or from processing of a larger transcript including the mae-citCDEFgenes. These transcripts were detected only from citrate-inducedcells (Fig. 1). Two bands corresponding in size to rRNAs (1,541and 2,904 bases) were detected in RNA from cells grown in thepresence of citrate. As previously reported by others (9, 10),these bands corresponded to citCDEF mRNA fragments that were presumablydegraded in the course of RNApurification.

These results establish that the mae-citCDEF genes are cotranscribed from a common citrate-regulated promoter-operator regionlocated upstream of mae. The physical arrangement of these genessuggested that they form anoperon.

Determination of the 5' terminus of the CL operon. To determine the transcription start site, primer extension experiments were performed. For this, 1 pmol of each primer wasannealed with 5 µg of total RNA, followed by synthesis of ³²P-labeled cDNA using reverse transcriptase as previously described(15). The radiolabeled products were then separated on a 6%polyacrylamide sequencing gel and visualized by autoradiography.The start site was determined with two different primers complementaryto the 407-to-441 (primer 3) and 480-to-500 (primer 4) nucleotidesequences (Fig. 4). RNA (30 µg) prepared from cells grown in thepresence or absence of citrate was used. Figure 4B shows the resultof a primer extension experiment using primer 4. Transcripts fromthe mae promoter were detected only in citrate-induced cells.No signal was detected in the absence of a primer (data not shown).Primer extension analysis gave unique signals for the two primersused. A comparison of the extension product with the DNA sequencingladder as a standard showed that the 5' end of the mRNA correspondedto a G nucleotide positioned at nucleotide 338, 50 bp upstreamof the putative translational initiation codon of the mae readingframe (Fig. 4). This finding suggests that the polycistronic mRNAstarts at this site. The sequence TTGACT-17 bp-TAGAAT locateda short distance upstream is a likely candidate for the operonpromoter.

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FIG. 4. Determination of the transcription start site of mae and clyR. (A) Primer extension performed with clyR primer 1. (B) Primer extension performed with mae primer 4. Primer extension reactions were performed as described in the text. Primer extension products were obtained by using RNA isolated from L. mesenteroides cells grown in the presence of citrate (lane 1) or in its absence (lane 2). The same oligonucleotide primer used for the primer extension analysis was used for sequencing by the dideoxy-chain termination method. G, guanine; A, adenosine; T, thymine; C, cytosine. A sequence complementary to that read from the ladder is shown, and the start site of the transcript is indicated by an arrow. (C) Nucleotide sequence of the mae-clyR intergenic region containing the bidirectional promoter region of the mae-citCDEF and clyR genes. The 239-bp intergenic region between translation codons of the mae and clyR genes is in boldface. The $-$ 10 and $-$ 35 regions and the transcription initiation sites (+1) are white letters in black boxes. The putative RBSs are shaded. The ATGs of the mae and clyR genes are underlined.

Primer extension analysis of the transcriptional start point of clyR. Regulatory proteins are weakly synthesized in cells. If the clyR gene product is a regulatory protein, the difficulty in detectingmRNA from it was not surprising. However, the transcriptionalstart site of clyR was successfully determined by primer extensionexperiments using two different oligonucleotides extending fromnucleotide 4 to nucleotide 44 (primer 1) and from nucleotide 59to nucleotide 93 (primer 2) (Fig. 4). RNA (30 µg) from cells grownin the presence or absence of citrate was used. An extension productwas detected only when RNA prepared from citrate-induced cellswas used. Primer extension analysis gave unique signals for thetwo primers used. No signal was detected in the absence of a primer.Figure 4A show the result of a primer extension experiment usingprimer 1. The extension product indicated that the 5' end of themRNA corresponded to nucleotide A located 24 bp upstream of thestart codon of the clyR gene. This transcription start point allowedlocalization of the putative promoter to the sequence TTGATA-17bp-TACAAT (Fig. 4).

Conclusion. In this paper, we describe two ORFs potentially coding for an NAD-dependent malic enzyme (mae) and a putative regulatory protein(clyR) found in the upstream region of citCDEFG of L. mesenteroides.This is the first report of genes coding for a putative malicenzyme and a regulator protein belonging to the SorC family ina lactic acid bacterium. The mae product showed a high level ofsequence similarity to malic enzymes of B. stearothermophilusthat, in addition to the NAD-dependent oxidative decarboxylationof L-malate, catalyzes the decarboxylation of oxaloacetate. TheCL activity of L. mesenteroides was induced by citrate, and atranscript from mae-citCDEFG was detected only in RNA preparedfrom cells grown in the presence of citrate. However, no significantmalic enzyme activity could be detected in cells grown in thepresence of citrate, showing that the malic enzyme is not inducedby citrate while transcription of mae is citrate dependent. Therole of the mae gene product in citrate metabolism remains tobe determined. This gene could code for an inactive malic enzymeor does not encode a malic enzyme. The mae gene in the CL operonis not present in the other CL operon previously described inK. pneumoniae (2). The transcription of the citS-oadGAB andcitC operons encoding citrate carrier, oxaloacetate decarboxylase,and CL, respectively, is citrate dependent in K. pneumoniae cellsgrown anaerobically. In this organism, expression of the citratefermentation genes was shown to be positively controlled by atwo-component signal transduction system encoded by the promoter-distalgene of the citS operon, citA (sensor kinase) and citB (responseregulator) (3, 19).

In L. mesenteroides, the DNA region (189 nucleotides) between the transcription starts of clyR and mae containing the twoidentified putative promoters showed an extraordinarily high A+Tcontent (82.1%) (Fig. 4). These promoters showed close similarityto the consensus found in promoters from gram-positive bacteriaand E. coli. Divergent promoter regions in bacteria are frequentlytargets for the control of gene expression at the transcriptionallevel. The divergent promoter region between the clyR and maegenes is likely to be a putative target for recognition by a regulatoryprotein involved in the control of the CL activity of L. mesenteroides.The fact that the extension product obtained with the clyR primerswas only obtained with RNA from citrate-grown cells provides theonly experimental evidence that ClyR could regulate the mae-citCEDFgenes. The disruption of clyR certainly will allow us to elucidateits function in the expression of the CL operon. Unfortunately,no useful techniques are available at this time for this typeof genetic approach to L. mesenteroides.

Nucleotide sequence accession number. The nucleotide sequence data reported herein has been combined with sequences from previous GenBank submissions (accessionno. Y10621).

	ACKNOWLEDGMENTS

S.B. was the recipient of a fellowship from the Programme Intergouvernemental Franco-Algérien. This work was supported bya grant from the Conseil Régional deBourgogne.

	FOOTNOTES

^* Corresponding author. Mailing address: Laboratoire de Microbiologie, UA INRA, Université de Bourgogne ENS.BANA, 1 EsplanadeErasme, F-21 000 Dijon, France. Phone and Fax: 33 3 80 39 66 40.E-mail: hprevost{at}u-bourgogne.fr.

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	Articles by Bekal-Si Ali, S.
	Articles by Prévost, H.

Appl. Environ. Microbiol.	Infect. Immun.	Eukaryot. Cell
Mol. Cell. Biol.	J. Virol.	Microbiol. Mol. Biol. Rev.
	ALL ASM JOURNALS

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