Regulation of Expression of the Lactococcus lactis Histidine Operon

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Journal of Bacteriology, April 1999, p. 2026-2037, Vol. 181, No. 7
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Regulation of Expression of the Lactococcus lactis Histidine Operon

C. Delorme,^* S. D. Ehrlich, and P. Renault

Laboratoire de Génétique Microbienne, Institut National de Recherche Agronomique, 78352 Jouy-en-Josas Cedex, France

Received 14 October 1998/Accepted 15 January 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

In Lactococcus lactis, the his operon contains all the genes necessary for histidine biosynthesis. It is transcribed froma unique promoter, localized 300 bp upstream of the first gene.The region corresponding to the untranslated 5' end of the transcript,named the his leader region, displays the typical features ofthe T box transcriptional attenuation mechanism which is involvedin the regulation of many amino acid biosynthetic operons andtRNA synthetase genes in gram-positive bacteria. Here we describethe regulation of transcription of the his operon by the levelof histidine in the growth medium. In the absence of histidine,two transcripts are present. One covers the entire operon, whilethe other stops at a terminator situated about 250 bp downstreamof the transcription start point. DNA sequences implicated inregulation of the his operon were identified by transcriptionalfusion with luciferase genes and site-directed mutagenesis. Inaddition to the previously defined sequences necessary for effectiveT-box-mediated regulation, new essential regions were identified.Eighteen percent of the positions of the his leader region werefound to differ in seven distantly related strains of L. lactis.Analysis of the variable positions supports the folding modelof the central part of the his leader region. Lastly, in additionto the T-box-mediated regulation, the operon is regulated at thelevel of initiation of transcription, which is repressed in thepresence of histidine. An operator site, necessary for full repression,overlaps the terminator involved in the T box attenuation mechanism.The functionality of the operator is altered on plasmids withlow and high copy numbers, suggesting that supercoiling may playa role in the expression of the his operon. The extents of regulationat the levels of initiation and attenuation of transcription are6- to 8-fold and 14-fold, respectively. Together, the two levelsof control allow a 120-fold range of regulation of the L. lactisoperon byhistidine.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Extensive studies of amino acid biosynthetic genes in various bacteria have revealed a wide variety of models for gene organizationand regulation. Together with the lac and trp operons, the hisoperon was used as a model system to study the mechanisms governingexpression in enterobacteria and in many other microorganisms(reviewed in references 1, 2, and 47). As a result, thehis operon may be considered a paradigm for the study of the evolutionand the regulation of metabolic pathways. In this context, wehave initiated the study of the histidine biosynthesis operonof Lactococcus lactis. This lactic acid bacterium is commonlyused as a starter in the dairy industry and is becoming one ofthe best-characterized gram-positive bacteria. The his operoncontains 12 open reading frames (ORFs), of which 8 encode enzymesknown to be involved in histidine biosynthesis and 4 encode proteinsof unknown function (6).

In addition to the goal of generating information on the genetic organization of this bacterium, the his operon was chosenbecause most dairy strains are histidine auxotrophs while strainsisolated in the natural environment are prototrophs (7). Inactivationof the his operon is due to the accumulation of base substitutionsand small deletions in several genes. Gene transfer in this regionwas also documented (8). The inactivation of the his operonprobably confers a selective advantage to strains used in theindustrial dairy processes and may be considered to promote adaptationof lactococci to this new environment. A preliminary study, conductedwith L. lactis IL1403, which was obtained by plasmid curing ofan industrial dairy strain, showed that transcription of the operonis also partially inactivated (7). This suggested that expressionof the his operon may cause a selective disadvantage in L. lactisin milk and prompted further studies of the regulation of thehisoperon.

Based on sequence and potential mRNA secondary structure similarity, Grundy and Henkin (19) proposed that the L. lactishis operon was regulated by a mechanism of attenuation, involvinga signature sequence named the T box, frequently found for genesencoding aminoacyl-tRNA synthetases and amino acid biosynthesisenzymes in gram-positive bacteria. In the presence of limitingamounts of the appropriate amino acid, transcription antiterminationis mediated by uncharged tRNA, which acts as a positive regulator.Uncharged tRNA directly interacts with the leader mRNA at a specifier(the codon for the appropriate amino acid) and at the T box sequenceto stabilize the antiterminator stem and promote transcriptionantitermination. This mechanism allows a 10- to 30-fold regulationin Bacillus subtilis (17, 21, 33). This range is far belowthe 6,000-fold potential level of regulation of the Escherichiacoli his operon, resulting from the combination of the controlof initiation and elongation of transcription. In this bacterium,transcription initiation is under the control of ppGpp, the effectorof the stringent response, and its elongation is regulated byan attenuation mechanism. In addition, posttranscriptional regulationoccurs by mRNA processing and the activity of the first enzymeof the pathway (HisG) could be stimulated or inhibited by severalelements (1).

In this paper, we show that transcription of the L. lactis his operon is also controlled at two levels, initiation and elongation,leading to a 120-fold modulation of transcription in vivo. Weconfirmed that elongation of transcription is subject to an attenuationmechanism related to the T box system. Elements involved in thissystem were identified. The initiation of transcription was shownto be controlled by a repression mechanism depending on an operatorsite present 250 bp downstream of the mRNA start. In addition,we suggest that a more general control of the operon may be exertedby modification of the supercoiling, a factor which appears tointerfere with the histidine-mediatedrepression.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains, media, oligonucleotides, and DNA manipulation procedures. The bacterial strains used in this study are listed in Table 1. E. coli TG1 and LLB1 were used for plasmid propagation (26).The pcn mutation of LLB1 reduces the copy number of pBS derivativesand was used to avoid the toxicity of some fragments when presentat a high copy number (HC). L. lactis strains were grown at 30°Con M17 medium (44), on chemically defined medium (CDM) containing0.1% histidine (CDM+H), or on CDM without histidine (CDM $-$ H) (34).E. coli cells were grown in Luria-Bertani medium at 37°C (31).When needed, erythromycin (5 µg/ml for L. lactis and 100 µg/mlfor E. coli) or ampicillin (50 µg/ml for E. coli) was added tothe culture medium. Plasmids and total DNA were prepared as previouslydescribed (29, 31, 40). Procedures for DNA manipulations,transformation of E. coli cells, and cloning were essentiallyas described by Maniatis et al. (31). Electrotransformationof L. lactis was performed as described by Holo and Nes (23).All enzymes for DNA technology were used according to the manufacturer'sspecifications. Oligonucleotides were synthesized on a DNA synthesizeroligo 1000M system (Beckman). The oligonucleotides used in thiswork are named as follows: the number indicates the position ofthe 5' end of the oligonucleotides in the direct (D) or reverse(R) orientation compared to the sequence given in Fig. 1A. Oligonucleotidesused for mutagenesis are listed in Table 1.

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TABLE 1. Bacterial strains, plasmids, and oligonucleotides

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FIG. 1. Organization and schematic representation of the histidine promoter region. (A) Nucleotide sequence and main features of the 5' end of the his operon. The end of orfX and beginning of hisC (first gene of the his operon) are underlined, and their stop and initiation codons are shown in bold characters. The start of the his mRNA characterized by primer extension is shown by a bent arrow and the $-$ 35 and $-$ 10 promoter sequences are boxed in grey. Specifier and T box sequences are boxed and shown in bold characters. Stem-loop structures I, II, III, and IV, the antiterminator, and the terminator are represented as inverted arrows. TATTAT repeated sequences are boxed. Numbers indicate positions relative to the previously reported sequence (GenBank sequence, U92974) (6). Mutations made in this work are indicated below the sequence; $Delta$ refers to deletion. (B) PCR-amplified DNA fragments used to analyze the regulation of the transcription. The bent arrow represents transcription start, and the horizontal arrows represent stem-loop structures of the his leader region. The numbers indicate the positions of the nucleotides at the 5' and 3' ends of the fragments and of the modifications. $Delta$ are deletions (positions of deleted nucleotides are shown in parentheses), and black boxes denote substitutions.

Northern blot analysis of his transcripts. RNA was isolated from L. lactis NCDO2118 grown in CDM to exponential phase (optical density at 600 nm [OD₆₀₀] of 0.5), washedtwo times, and transferred for 20 min to CDM+H or CDM $-$ H. TotalRNA was prepared as previously described for B. subtilis (14).After extraction and treatment with phenol/chloroform, RNA wasprecipitated with ethanol; 50 µg of glyoxalated RNA was subjectedto electrophoresis through a 1% agarose gel. Transfers and hybridizationswere performed as described by Maniatis et al. (31). DNA probeswere labeled with [ $alpha$ -³²P]dCTP by using a random primed DNA labeling kit (Boehringer,Mannheim, Germany), and oligonucleotide DNA probes were labeledwith [ $gamma$ -³²P]ATP with T₄ polynucleotidekinase.

Primer extension and DNA sequencing. Total RNA isolated from L. lactis NCDO2118 grown in CDM $-$ H and CDM+H was used as the template for primer extension with theprimer 848R. Fifty micrograms of RNA and 5 pmol of ³²P-labeled oligonucleotide were heated at 85°C for 10 min and cooledslowly to 42°C in 15 µl of annealing mix (10mM Tris-HCl [pH 8],1 mM EDTA, 1.25 M KCl). Elongation of the DNA strand was performedafter addition of 19.2 µl of a mixture containing 0.2 mM deoxynucleosidetriphosphates (0.2 mM each of dATP, dCTP, dTTP, and dGTP), RNaseinhibitor (Gibco), and 1.2 U of avian myeloblastosis virus reversetranscriptase (Boehringer). Samples were incubated at 42°C for1 h, precipitated, washed, dried, and suspended in 4 µl of Tris-EDTA(TE) and 6 µl of stop solution before loading on a denaturing6% polyacrylamide gel. The control sequence was determined onplasmid pBS-1 as a template with the same primer. Quantificationof the primer extension signals was performed on a PhosphorImager(Storm system; Molecular Dynamics). Double-stranded recombinantplasmid DNA was used as the template in dideoxy chain terminationsequencing reactions (6, 39).

Determination of luciferase activity in L. lactis. Luciferase assays were performed on a Bertold Lumat LB9501 apparatus. One milliliter of L. lactis culture was mixed with 5µl of nonaldehyde, and the light emission was immediately measured.The value of the peak obtained was standardized to the OD₆₀₀ ofthe culture. Luciferase activity was measured throughout the growthof the culture. Values reported in Tables 2 and 3 were measuredat OD₆₀₀ of 0.4.

Histidinol dehydrogenase assay and protein determination. In order to determine histidinol dehydrogenase activity, cells from 25-ml cultures at OD₆₀₀ of 0.4 to 0.5 were harvested bycentrifugation (5,000 × g; 15 min at 4°C) and stored at $-$ 20°C.The pellet was then resuspended in 300 µl of 0.05 M Tris buffer(pH 7.5) with 0.5 g of glass beads and shaken at maximum speedsetting on a Biospec homogenizer at room temperature 3 times,for 2 min each time, with a 1-min pause between each pair of pulses.After centrifugation at 30,000 × g for 15 min at 4°C, the supernatantwas passed through a G-50 Sephadex column that had been equilibratedand washed with 0.01 M Tris-HCl buffer (pH 7.3) at 4°C. Histidinoldehydrogenase from the crude bacterial extract was assayed bythe spectrophotometric method of Martin et al. (32). One unitof enzyme yields an absorbance of 1.0 U at 520 nm after 20 minat 37°C. The protein contents of cell extracts were determinedby using the Coomassie protein assay reagent (Pierce ChemicalCo., Rockford, Ill.).

Construction of truncated and mutagenized derivatives of the his promoter region in E. coli. Plasmids used for construction of the his promoter region derivatives in E. coli are listed in Table 1, and schematic drawingsof the final constructs are presented in Fig. 1B. The mutagenizedfragments were made in E. coli and recloned in promoter and terminatorprobe vectors in L. lactis. pJIM702 was used as the primary templateto generate the constructions pBS-1, pBS-2, pBS-3, pBS-4, pBS-5,pBS-6, and pBS-7 presented in this work. It carries a 1.4-kb EcoRIfragment that includes the promoter and the 5' end of the hisoperon in pBSKS⁺. Deletions and substitutions in the terminator and in the T boxsequence were generated from plasmid pBS-1 by PCR techniques.This plasmid contains a 1.3-kb PCR fragment amplified from pJIM702(with M13 primers [ $-$ 47] [Promega] in pBS and 1292R) and clonedafter double digestion with EcoRI and BamHI in pBSSK⁺. The oligonucleotide pairs 995R and 1001D, 1033R and 1053D, and1033R and 1042D were used to amplify pBS-1, producing pBS-1m1,pBS-1m3, and pBS-1m4, respectively. The NsiI restriction sitecarried by the primers was used to generate cohesive ends priorto ligation and transformation. In pBS-1m3 and pBS-1m4, the terminatorsequences were disabled at their 3' ends (1034-CGT₇ATATTATCTT-1052was replaced with ATGCA and 1034-CGT₆-1041 was replaced with ATGCATCC,respectively). In pBS-1m1, 5 bp in the T box sequence were changed(996-CCACG-1000 was replaced with TGCAT). In pBS-1m2, 46 bp (nucleotides[nt] 632 to 677) were deleted upstream of the promoter P_his.pBS-2, pBS-3, and pBS-4 contain 388-, 413-, and 294-bp PCR fragmentsobtained with oligonucleotide pairs 904D and 1292R, 879D and 1292R,and 791D and 1085R, respectively. These fragments were clonedin pBSSK⁺ digested with SmaI. pBS-4m1 and pBS-4m2 were constructed by PCRmutagenesis of pBS-4, with 1 bp (nt 972) and 8 bp (nt 972 to 979)deleted in the stem and loop of stem-loop IV of the his leader,respectively. pBS-6 and pBS-7 carry deletions, located at the3' end of the 1.4-kb fragment from pJIM702, that were producedby the action of DNase I. The cloned PCR products were sequencedto verify that no additional mutations hadoccurred.

Constructions of lux fusions in L. lactis replicative plasmid. Two types of transcriptional fusions were constructed, one each in a terminator and a promoter probe vector, named pTer andpProm, respectively. The pTer series contains derivatives of thehis leader region without the promoter cloned in pJIM2530 as theparental vector (35). In this plasmid, the fragments clonedin the multiple cloning sites (MCS) are followed by the luciferasereporter genes from Vibrio harveyi and transcribed from the constitutivepromoter P_orfD-repE present upstream of the MCS (27,35). This plasmid is a convenient vector to estimate the strengthof a terminator cloned in the MCS. It was used to study the regulationof the histidine operon by termination and antitermination. Theresulting plasmids, pTer-2, pTer-3, pTer-4, pTer-4m1, and pTer-4m2,are maintained at HC (Table 1).

The pProm series contains the lux genes under the control of the P_his promoter followed by a modified his leaderregion. The promoter probe vector pJIM2366 (a derivative of pJIM2530)contains a terminator that prevents transcription of the lux genesfrom the P_orfD-repE promoter (1.5 × 10³ ± 0.5 × 10³ lx/OD unit [35]). pProm-1 contains P_his and the completeand intact his leader region. pProm-1, pProm-1m3, and pProm-7were constructed as described in Table 1. These plasmids wereconstructed to have HC and then switched to low copy number (LC)by KpnI restriction as described previously (35). The KpnI restrictiondeletes a linker present in copF, the product of which is a repressorthat controls replication. After ligation, these plasmids weretransformed in L. lactis NCDO2118, which contains an intact hisoperon.

Construction of lux transcriptional fusions in the chromosome. The plasmids used to produce lux transcriptional fusions in the chromosome were constructed by subcloning various fragmentscontaining the promoter into the L. lactis integrative vectorpJIM2374. This vector contains the origin of replication of pWV01but not the repA gene, the product of which is required for replication.This plasmid, a derivative of pORI28, is able to replicate ifthis protein is provided in trans (28) and contains the erythromycinresistance determinant of pIL253 as a marker, an MCS, and thelux genes as reporters. The construction of the integration plasmidspInt-1, pInt-1m1, pInt-1m2, pInt-1m3, pInt-1m4, pInt-5, pInt-6,and pInt-7 is described in Table 1. These plasmids were integratedat the his locus in the chromosome of L. lactis NCDO2118 by singlecrossover with pGhost4 as a helper as described by Godon et al.(15). The resulting strains contain the lux fusion with themodified promoters followed by the intact hisoperon.

	RESULTS

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Transcription of the his operon. RNA from L. lactis NCDO2118 grown in CDM+H or CDM $-$ H was analyzed by Northern blot, using as a probe the oligonucleotide 963R.No mRNA was detected in cells grown in the presence of histidine,suggesting that the initiation of transcription or mRNA stabilityis controlled by histidine (Fig. 2A). In cells grown in the absenceof histidine, two transcripts, of 10 and 0.25 kb, were detected(Fig. 2A). The use of probes consisting of several fragments ofthe his operon and flanking regions showed that the longer transcriptcovers the entire his operon while the shorter is located in itspromoter region (data not shown). The short transcript seems tobe the result of an early transcription elongation stop.

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FIG. 2. Transcription analysis of the histidine operon. (A) Northern blot. Total RNA was extracted from L. lactis NCDO2118 cells grown with (+) and without ( $-$ ) histidine and hybridized with oligonucleotide 963R. The size of the band is indicated. No transcript was detected in cells grown with histidine. (B) Primer extension analysis. Total RNA of L. lactis NCDO2118 cells grown with (+) and without ( $-$ ) histidine was used as a template for primer extension with the 848R oligonucleotide. The same oligonucleotide was used for the sequencing reaction with plasmid pBS-1 as a template. The asterisk indicates the nucleotide corresponding to the 5' end of the his mRNA found by primer extension.

Additional hybridization experiments with oligonucleotide probes were performed to localize the 5' ends of the two transcriptsand the 3' end of the small one more precisely. Oligonucleotide773R, upstream of the putative start point of transcription, didnot hybridize with either of the two messengers (data not shown).Oligonucleotides 848R and 1036R, between the potential start pointand the terminator, hybridized with the two transcripts (datanot shown). Oligonucleotide 1085R, downstream of the potentialterminator, hybridized only with the long transcript (data notshown). These observations indicate that both transcripts originatein a 75-bp region located between oligonucleotides 773R and 848Rand that the short transcript ends in the 49-bp fragment definedby oligonucleotides 1036R and 1085R. This region contains a rho-independentterminator structure (Fig. 1A). The precise start point of transcriptionwas mapped by primer extension at position 789 and is precededby the $-$ 10 and $-$ 35 consensus promoter sequences (Fig. 1A and Fig.2B).

The last step in histidine biosynthesis is carried out by the histidinol dehydrogenase encoded by the hisD gene, the fourthgene of the his operon. The measured HisD activity should reflectthe expression of the his operon. HisD activity varied 26-folddepending on whether histidine was present, as it was 7.8 ± 1and 0.3 ± 0.1 U/mg of protein in cells grown in CDM $-$ H and in CDM+H,respectively. As the basal level of HisD activity is near thelimit of detection, we investigated the regulation of the hisoperon using pInt-1. This is an integrative plasmid, carryinga transcriptional fusion of lux reporter genes with the entirehis promoter region up to the first gene, hisC (Fig. 1B). Theactivities of the lux genes under the control of the his promoterwere 335 × 10³ and 2.8 × 10³ activity lx/OD unit in the absence and in the presence of histidine,respectively, suggesting a 120-fold modulation of the transcriptionof the his operon (pInt-1, Table 2).

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TABLE 2. Expression of P_his and his leader region-lux fusions on LC plasmids or integrated on the chromosome

Structural features of the his leader region. The 438-bp region upstream of the start codon of hisC contains the promoter P_his and a 287-bp noncoding sequencethat was named the his leader region (Fig. 1A) (5). The hisleader region has the sequence features of the tRNA-mediated antiterminationsystems described by Grundy and Henkin (19). It contains thetypical T box sequence AAUUAAGGUGGAACCACG (nt 983 to 1000) (basesfitting with the consensus are underlined), a histidine specifierCAC (nt 885 to 887), and most of the other less conserved boxes(AGUA-I box [AGUA, nt 819 to 822], AG box [GAGAGA, nt 840 to 844],GNUG box [GCUG, nt 853 to 856], and F box [GCGUUA, nt 928 to 933])(Fig. 1A and 3 [19, 30]). The AGUA-II and GAAC boxes are notpresent. In addition to these conserved sequences, the his leaderregion may be folded into three stem and loop structures (17).To examine the validity of the proposed model of folding and todetect sequences important for histidine regulation, we have assessedthe genetic variability of this region in several L. lactis strains.Sequences important for the regulation as well as nucleotidesinvolved in the pairing of stems should be conserved or complementarychanges should maintain the proper folding of the leader. Forty-sixvariable nucleotides were found among the 252-bp sequences ofthree L. lactis subsp. lactis (IL1403, NCDO2118, and Co1) strainsand four L. lactis subsp. cremoris (NCDO763, Co2, Co4, and Co6)strains (Fig. 3A).

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FIG. 3. Structural model of the L. lactis NCDO2118 his leader region mRNA. The specifier (CAC), the T-box sequence, and other conserved boxes are indicated. The arrows indicate the base changes found in several distantly related strains of L. lactis. The absence of additional indication means that the change was found in all L. lactis subsp. cremoris strains (NCDO763, Co2, Co3, Co4, and Co6). Numbers in parentheses specify changes that are present only in IL1403 (1), in NCDO763 (2), in Co2, Co3, and Co4 (3), or in Co3 (4). Sequences of L. lactis subsp. lactis Co1 and NCDO2118 are identical. Other numbers indicate positions relative to those shown in Fig. 1. (A) Terminator conformation; (B) antitermination conformation; (C) and (D) alternative conformations of stem II and stem III.

The sequences of the boxes described earlier are not subject to variation except for that of the F box, where two positionschanged. The first change, G928A, is at a position which is conservedin less than 80% of the F boxes (36). The second, U931G, wasfound only in one strain and matches a position that was previouslyshown to be important for regulation of the tyrS gene (36).However, this base is not conserved in the leader of the L. lactistrp operon (45).

We also checked whether the changes would impair the folding of the three stem and loop structures described by Grundy andHenkin (19). Assuming that G-U base pairing is acceptable, thechanges found do not affect the folding of the first and laststems (stems I and IV, Fig. 3), the terminator, and the antiterminator.However, some changes are not compatible with the formation ofthe second stem-loop structure previously proposed (19). A newmodel of folding yielded four stem-loop structures instead ofthree (Fig. 3A). In this model, most base changes occur betweenthe stems or in the bulges of these structures (25 changes) andotherwise complementary changes maintain base pairing (12 changes)or the changes do not alter the pairing (G-C to G-U or G-U toA-U) (7 changes). Alternate structures for stems II and III mightalso be formed. The lower part of stem II could pair with thefirst bases of the F box to produce stem IIA as described by Rollinset al. (36) (Fig. 3C). Furthermore, these two stems can formstems IIB and IIIB (Fig. 3D). Stem IIB is similar to part of stemII proposed by Grundy and Henkin (19) but might be very unstablein the L. lactis subsp. cremoris strains because one change ispresent in the middle and two are present at the top of the stem.Interestingly, stem IIIB contains the F box in its loop (Fig.3C).

In the bottom left bulge of stem I and the top bulges of stems II and III, additions of 1 or 2 nt are observed, suggestingthat the size of these bulges is not important for regulation.The sequences of these three bulges were found to be highly variable.Changes occur in 4 of the 12 nt at the top bulge of stem II, in2 of 3 in stem III, and in 5 of 7 in the antiterminator. Moreover,several changes were found in the other bulges of stem I closeto the AGUA, AG, GNUC, and specifier boxes. This suggests that,outside of the conserved boxes, the primary sequences of the bulgesare not essential forregulation.

Interestingly, the unpaired nucleotides that form the bulge present in the middle of stem I have all changed in a way thatprevents any pairing in this region. This suggests that the flexibilitydue to the presence of this bulge is necessary for the functionalityof stem I. In contrast, some unpaired regions are not extensivelymodified in different strains, such as the first 20 nt of theleader, the sequence between stems III and IV, and the bulgesin the middle of stem I (between nt 881 and 892) and at the topof stem IV. This suggests that these sequences may be necessaryfor proper regulation of theoperon.

Mutational study of the his attenuation mechanism. Analysis of the mRNA and features of the his leader suggest that transcription of the his operon is regulated at two levels,initiation and elongation. In order to study the effect of attenuationon expression of the his genes, it was necessary to remove thenative promoter which is controlled by histidine at the levelof transcription initiation. We subcloned fragments containingthe his leader region without P_his into the terminatorprobe vector pJIM2530; the resulting plasmids belong to the pTerseries (Fig. 1B). Transcription of these fragments is under thecontrol of the constitutive promoter P_orfD-repE, andreadthrough is measured with the lux reporter gene present downstreamof the cloned fragment (35). In the presence of histidine, thehis leader region in pTer-4 caused a 42-fold decrease of the expressionof luciferase compared to that of the control pJIM2530 vector(Table 3). This confirmed the functionality of the terminatorin the cloned fragment. In the absence of histidine, the efficiencyof the termination was about 14-fold lower than in its presence,showing that the features necessary for antitermination are presenton the cloned fragment. Deletions at the 5' ends of the his leadersin pTer-3 and pTer-2 (deletions extending to nt 878 and 903, respectively)reduced significantly the control of the antitermination in theabsence of histidine (Table 3). These results confirmed the importanceof stem I in the attenuation mechanism. Moreover, these deletionsincreased termination activity in the presence of histidine two-and fourfold, respectively (Table 3). This result suggests animportant role of the 5'-end sequence of the his leader regionin termination of transcription, even in the presence of histidine.Similar results were also obtained with LC plasmids, suggestingthat no factor was titrated by HC plasmids (data not shown).

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TABLE 3. Mutational analysis of the his leader region^a

Substitutions were introduced into the T box sequence to verify its importance in the attenuation mechanism of the his operon.In pInt-1m1, where part of the T box sequence 996-CCACG-1000 isreplaced by TGCAT (Fig. 1B), the level of expression of luciferaseis very low (<0.2 × 10³ lx/OD unit in CDM) irrespective of the histidine content of thegrowth medium. This value is similar to the background level foundin the absence of the reporter gene. We conclude that the antiterminationis abolished by this change and that the attenuation mechanismis T boxdependent.

T-box-dependent regulation has been studied extensively in B. subtilis, and the importance of several sequences in stems Iand II has already been demonstrated (16, 36). Our analysis,based on the variability of the his leader sequences, shows thatmany changes that conserve base pairing can occur in the stemand loop structures, suggesting that structural features mightbe more important than the primary sequence. Strikingly, in allstrains the bottom of stem-loop IV contains changes that maintainits structure, whereas no change occurred in the other 16 contiguousnucleotides, including the loop. This structure is thus a goodcandidate for involvement in the T box attenuation mechanism ofthe his operon. To verify the validity of this hypothesis, stem-loopIV was mutated by deletion of a single base at position 972 (pTer-4m1)or by an 8-bp deletion at positions 972 to 979 (pTer-4m2; Fig.1B). In both cases, the range of regulation by histidine decreaseddramatically to no more than twofold (Table 3). In the case ofpTer-4m1, this difference cannot be explained by a decrease inthe stability of stem-loop IV, as the free energy values are comparablein the wild-type and mutant strains (5.4 and 5.3 kJ, respectively).The latter results suggest that the sequence or integrity of stem-loopIV is required for the function of the attenuation mechanism.We did not find significant complementary sequence to stem-loopIV in the tRNA^His, the known diffusible partner that interacts with the mRNA leader,or in the his leader region. This suggests that another transfactor interacts with this region, and we decided to test forits presence by titration experiments conducted with mRNA fromthe leader region. The entire his leader region was overexpressedfrom the HC plasmid pProm-1 HC. The overexpression from pProm-1HC was as much as 15-fold compared to the expression from pInt-1.The histidinol dehydrogenase activity produced from the nativehis operon in the NCDO2118 strain decreased 4.6-fold in cellscontaining pProm-1 HC (the activities were 7.8 ± 1 and 1.7 ± 0.8U/mg of protein in NCDO2118 cells without and with pProm-1 HC,respectively). This observation supports the hypothesis that adiffusible factor partner, probably in addition to the tRNA^His, is required for attenuation of histranscription.

Transcription of the his operon is subject to repression of initiation. Northern analysis, previously described, showed that control of transcription of the his operon by attenuation is strengthenedby a second control at the level of initiation or of mRNA stability.The level of this control was quantified by reverse transcriptionof total RNA isolated after growth in the presence and in theabsence of histidine. The signal of the primer extension productwas sixfold lower under the former than under the latter condition(Fig. 2B). The expression of a fusion with the entire promoterand the his leader region on pInt-1 integrated on the chromosomeshould thus be controlled at two levels, initiation of transcription,or mRNA stability, and elongation of the transcription. Indeed,it is modulated 120-fold by histidine (Table 2). We demonstrated(see the preceding paragraph) that to the 120-fold modulationby histidine, attenuation appears to make a contribution responsiblefor a 14-fold modulation. A simple calculation suggests the presenceof a second control level modulated eightfold by histidine. Thiscalculated level accords with the data obtained by quantificationin the reverse transcriptionexperiment.

Absence of a terminator upstream histidine operon led us to check whether transcription starting upstream of the mapped P_hispromoter did not influence expression of the his operon. The fusionupstream of P_his in pInt-5 (Fig. 1B) displayed a lowactivity (5.8 × 10³ ± 1.3 × 10³ lx/OD unit), similar to that of the repressed P_his promoter,and was independent of the presence ofhistidine.

To localize the minimal region necessary for the regulation of initiation, deletions were generated in the promoter regionand fused with lux genes on an LC plasmid or integrated on thechromosome (Fig. 1). Deletion of 46 bp (nt 632 to 677) upstreamof P_his on the integrated pInt-1m2 had no effect on regulationof P_his, indicating that the region upstream of nt 677is not necessary for regulation (Table 2). Two other fusions,from which the 3' end of the his leader region is deleted, pInt-6and pInt-7, drive constitutive luciferase expression, indicatingthat the region downstream of nt 948 is necessary for the modulationof initiation (Table 2). As these deletions induce a high constitutivelevel of expression, these results suggest that initiation isregulated by a repressor. The requirement of sequences beyondnt 948 for the control of the initiation suggests that the operatorsite is distant from the promoter or is expanded over a largeregion. A search for repeated sequences in the promoter regionled to the discovery of five TATTAT sequences separated by 62,66, 135, and 135 bp (Fig. 1A). The fact that these repeats areregularly spaced and overlap the $-$ 10 box suggest that these sequencesare operators that allow the binding of DNA binding proteins andeventually the formation of a DNA loop. To test the involvementof these sequences in regulation, we deleted the first and thelast TATTAT boxes of the region on the integrative plasmids pInt-1m2and pInt-1m3, respectively (Table 2 and Fig. 1A and B). The centralsequences were not changed, since the his leader would have beenmodified, which could have interfered with the assessment of therole of the TATTAT boxes. The last TATTAT box and part of theterminator of the attenuation system were deleted in pInt-1m3,whereas the deletion was limited to the terminator in pInt-1m4,which was used as a control (Fig. 1B). Unexpectedly, the rangeof regulation by histidine in both of these fusions was foundto be less than twofold, indicating that the two deletions inthe terminator affect both the antitermination mechanism and initiationrepression (Table 2). This result suggests that an essentialoperator site overlaps the terminator. The absence of a differencein the levels of expression between pInt-1m3 and pInt-1m4 excludesa predominant role for TATTATsequences.

The experiments presented above were carried out with the lux fusions integrated in the chromosome. Similar experiments werealso performed with fusions on LC plasmids. Interestingly, theactivity of the entire promoter and leader region is modulatedonly 10-fold by histidine on an LC plasmid (five copies per chromosome;pProm-1) but is modulated 120-fold in the chromosome (pInt-1,Table 2). Similar levels of modulation were observed with plasmidswith moderate copy number and HC (30 and 80 copies per chromosome,respectively; data not shown). This result suggests that one ofthe transcription mechanisms is not operative on the plasmid.As we have shown above that the his leader region present in thisfragment was sufficient to exert the control by attenuation ona plasmid, it is likely that the control of initiation of transcriptiondoes not occur onplasmids.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Dual transcriptional control of the his operon. As we have shown previously, a 10-kb transcript covering the L. lactis histidine operon is induced in response to histidinestarvation (7). The levels of induction of the his operon asmeasured by an assay of histidinol dehydrogenase (hisD gene product)or by transcriptional fusion to lux reporter genes are 26- and120-fold, respectively. We attribute this difference to the highlevel of background of the dehydrogenase assay. A short transcriptof 250 nt starts at the same 5' end as the 10-kb transcript andstops at a rho-independent terminator structure upstream of thefirst his gene. This accords with an attenuation mechanism oftranscription control as suggested previously on the basis ofthe presence of conserved features in the his leader region (19).The dramatic decrease of the levels of all transcripts in thepresence of histidine suggests that the his operon is also regulatedat the level of initiation of transcription or of mRNA degradationand is thus subject to dualcontrol.

Accuracy of the model of the secondary structure of the his leader. Based on the presence of characteristic structural features in the his leader region, a general mechanism of transcriptionattenuation regulating the T box family gene was postulated togovern expression of the his operon (19). It involves the directinteraction of an uncharged tRNA with the leader region of themRNA, and a model of the leader-region folding was proposed byGrundy and Henkin (19). To test whether this model holds forthe his leader and to identify sequences important in the regulation,we first searched for the natural variation of the leader sequenceamong lactococci. Changes were observed for 18% of the nucleotides(46 of 252) of the his leader. Most changes are compatible withthe secondary structure proposed previously, but a different modelof folding of the central region of the his leader is presentedhere. It is based on the assumption that substitutions occur mainlyin the loops or in the unpaired regions, whereas in paired regionscomplementary changes occur, conserving the pairing. The new modelcontains four stem-loop structures (Fig. 3) and some of them aredifferent from those described in the recent model of T-box-regulatedgenes (36). Two previous reports also indicate that the secondarystructure of this region may vary more than was described in theoriginal model (19). Stem II is present upstream of stem I inthe leader region of the T-box-regulated gene encoding the isoleucine-tRNAsynthase of Staphylococcus aureus (18). The presence of an additionalstem in the trp operon was also proposed (45). These changesdo not challenge the general model but suggest that many variationscan occur around common features. It remains unknown if thesedifferences confer new properties to the T boxsystems.

The folding proposed here is compatible with the general model involving the interaction of tRNA with two bulges present instem I and the antiterminator. The specifier sequence, a CAC tripletin the bulge region present on the right of stem I, could interactwith the GUG anticodon of the his tRNA. However, the 5'UGGA3'sequence in the bulge of the antiterminator is not completelycomplementary to the 5'(C73)-CCA3' acceptor end of the L. lactistRNA^His (unpublished data). The explanation of this divergence with theother T-box-regulated genes might be due to the special featureof the acceptor end of the tRNA^His, which has an additional base at its 5' end that is paired withthe C73. The absence of a discriminator would thus be specificto the tRNA^His. Lastly, the his leader region contains, in the proper location,conserved sequences that are important for regulation but whichstill have unknown functions in the attenuation mechanism (22).In stem I, AGUA-I, AG, and GNUG boxes are present in the bottomleft, in the top left, and in the top bulges, respectively, witha single mismatch. The highly conserved sequence CCGUUA, namedthe F box, is located between stem-loop II and stem-loop III witha single mismatch. The AGUA-II and GAAC boxes are absent, as isthe case in some other leaders (36).

In addition to the conservation of stems, our analysis revealed hypervariable regions in the loops of stem-loops II and III,suggesting they have no role in the formation of the folding ofthe his leader. Moreover, we have found a hypervariable unpairedregion in the middle of stem I. In this region, most of the simplechanges observed would allow additional pairing. Interestingly,compensatory changes that prevent pairing are always present.Such unpaired regions at the same location are present in mostof the T-box-regulated leaders. They might confer increased flexibilityto the upper part of stem I, which contains the AG and GNUGboxes.

Mutational analysis of the his leader region. The his operon of L. lactis is effectively controlled by a T-box-dependent mechanism of attenuation. The region necessaryfor full regulation was demonstrated to be present on a 294-bpfragment, and this region induces a 14-fold modulation of theterminator readthrough (pTer-4; Table 3). It contains all thestem and loop structures described previously, including the attenuatorand the terminator. The terminator, together with stems III andIV, terminates the transcription by a factor of about 185, independentlyof the presence of histidine (pTer-2; Table 3). The precise locationof the terminator was determined by several mutations which abolishtermination (e.g., pInt-1m4 and pInt-1m3, Table 2). The replacementof 5 bp in the T box sequence suppresses regulation by attenuation(pInt-1m1). This confirms that, in the his leader, the T box isinvolved in the formation of theantiterminator.

The role of stem I was assessed by deletions at the 5' end of the his leader. The truncation of part of stem I, removing boxesAGUA, AG, and GNUG but not the specifier, results in a 10-folddecrease of the antitermination activity (pTer-3 and pTer-2, Table3). These deletions also increase two- and fourfold, respectively,the basal level of termination in the his leader in the presenceof histidine. Several elements of stem I were shown previouslyto be involved in the regulation of the ilv-leu operon and tyrSgene of B. subtilis (16, 36). Deletion of stem I of the ilv-leuoperon and point mutations affecting GNUG and AG boxes in thetyrS gene dramatically increased the basal level of terminationand abolished the tRNAcontrol.

In addition to the features conserved among T box family genes, we have found that sequences specific for the his leader arenecessary for the antitermination. Deletion of a single nucleotidein the loop of stem-loop IV, as well as complete deletion of theloop, dramatically decreased the histidine-dependent level ofantitermination (pTer-4m1 and pTer-4m2, Table 3). These resultsshow the importance of this region in the attenuation mechanism.However, we do not know whether the region interacts directlywith the tRNA^His or plays another role. For example, it could allow secondarycontacts important for the global conformation of the mRNA orinteract with a trans-acting factor. The interactions of the anticodonand the acceptor stem of the tRNA with the leader are necessarybut might not be sufficient to stabilize the antiterminator structure.The presence of trans-acting factors or extended contact betweenthe leaders and their cognate tRNAs has been postulated but notdemonstrated (22, 33). Although RNA-RNA interactions may bevery complex and difficult to predict, the apparent lack of pairinglonger than 4 bp between the tRNA^His and the his leader does not support the hypothesis of a simpleextended contact between these two partners. In particular, theloop of stem-loop IV, where the deletion of a single nucleotideabolishes most of the histidine regulation, has no complementarysequence in the tRNA^His. This suggests the existence of a trans-acting activator differentfrom the tRNA. Overexpression of the entire his leader decreasesthe expression of the his operon, suggesting that the excess ofsegments of the his leader mRNA in the cell titrates a positiveeffector involved in the attenuation mechanism. In the generalmodel for the T box system, uncharged tRNA was demonstrated toact as a positive effector (12, 20, 33). However, duringhistidine starvation the titration of the uncharged tRNA^His by the overexpression of the his leader region is doubtful. Theseresults suggest that an unknown factor, one different from thetRNA^His, may be involved in the antiterminationmechanism.

Second transcription control of the his operon. Histidine is one of the most energy-requiring amino acids to synthesize, but it is not abundant in the cell. Its biosynthesisshould thus be tightly controlled. For example, the E. coli orSalmonella typhimurium his operon is controlled by a combinationof metabolic regulation (range, 30-fold) and attenuation (range,200-fold) which gives a potential range of regulation of 6,000-fold(46). However, the T box attenuation system allows no more than14-fold modulation of the transcription of the his operon in L.lactis. This range is of the same order as the 10- to 30-foldmodulation observed for the other T-box-regulated genes studieduntil now, including the regulation of tRNA synthetases and ofthe ilv-leu operon of B. subtilis (17, 21, 33). It couldbe expected that the transcription of synthetase genes is nevercompletely repressed, as their products are necessary for thelife of the cell independent of the environmental conditions.However, operons for amino acid biosynthesis (members of the Tbox gene family), like the ilv-leu operon of B. subtilis (17)and the trp operon of L. lactis (34), have multiple levels ofcontrol. In addition to the T-box-directed regulation of the transcriptionof the his operon, initiation of transcription or mRNA stabilityis modulated 6- to 8-fold in the presence of histidine, allowinga global range of control over 120-fold. Previous reports showedthat the leaders of several mRNAs of the T box family genes areprocessed (4, 45). A processing event that might stabilizethe mRNA of the thrS gene (4) or participate in the regulationof the trp operon (45) during amino acid starvation was demonstrated.However, we have not found a similar cleavage in the his leaderregion transcript. Moreover, the his leader luciferase fusionin the chromosome (pInt-1, Table 2) is subject to the two controlswhereas in LC plasmid it is not (pProm-1, Table 2). mRNA stabilityis not likely to be dependent on the location of the gene, suggestingthat the second control of the his operon is exerted at the levelof initiation of transcription. Several mechanisms could regulatethis step by altering the formation of the complex between theRNA polymerase and the promoter. In some cases repressors actby binding to operators which are adjacent to or overlap the promoter,resulting in a steric hindering of the binding of the RNA polymeraseto the promoter. In E. coli, such sites are most frequently foundbetween positions $-$ 50 and +30 of the respective promoters (4).In L. lactis, few combinations of regulatory proteins and theiroperator are known (24); however, the E. coli paradigm mayapply.

Unexpectedly, deletions or substitutions in the terminator structure were found to abolish both the attenuation mechanismand most of the repression, which dropped from six- to eightfoldto less than twofold (pInt-1m3 and pInt-1m4, Table 2). We haveno evidence for a significant role of the TATTAT box in the regulation.The simplest way to explain this result is to assume that an operatorsite overlaps the terminator, the sequence of which is an imperfectpalindrome. This feature is commonly found for the binding sitesof homodimeric DNA-binding proteins. The difference in the controlof transcription for the same fragment, 10-fold or 120-fold whenpresent on a plasmid or integrated in the chromosome, shows thatthe activity of the repressor is dependent on the operator context(chromosome or plasmid) (wild type, Table 2). The absence ofrepression of the promoter carried on a plasmid does not dependon the copy number (4, 30, and 80 copies per chromosome tested)and the mechanism of plasmid replication (theta or sigma type).It is possible that the putative repressor is titrated, even byan LC plasmid. However, another possibility is that the initiationof the transcription or the repression mechanism is sensitiveto DNA supercoiling. Alteration of the regulation of a promoter,due to a change in DNA supercoiling, has been widely described(9, 10, 43). In addition, expression from a promoter sensitiveto supercoiling is also dependent on the location and thereforeon the sequence context (11, 42). In particular, the degreeof chromosomal superhelicity controls expression of the his-tRNAgene promoter, the product of which is an effector of the hisoperon regulation in E. coli (37).

Whatever the detailed mechanism involved, the total rate of regulation of the L. lactis his operon is only 120-fold, a factorwhich is more than one order of magnitude less than that in E.coli. This relatively low stringency of control could be a reasonfor the observed inactivation of the his operons of dairy strains(7). Indeed, in milk, where histidine is mostly provided bycasein breakdown and the uptake of released oligopeptides, itcould be advantageous to abolish completely the synthesis of thisamino acid by introducing inactivatingmutations.

	ACKNOWLEDGMENTS

This work was supported by contract B104-CT96-0498 of the Commission of the EuropeanCommunities.

We thank M. van de Guchte for critical reading of the manuscript. We acknowledge T. Henkin and H. Putzer for helpfuldiscussions.

	FOOTNOTES

^* Corresponding author. Mailing address: Laboratoire de Génétique Microbienne, Institut National de Recherche Agronomique,78352 Jouy-en-Josas Cedex, France. Phone: 33 1 34 65 25 26. Fax:33 1 34 65 25 21. E-mail: delorme{at}biotec.jouy.inra.fr.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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