Organization and Transcriptional Analysis of a Six-Gene Cluster around the rplK-rplA Operon of Corynebacterium glutamicum Encoding the Ribosomal Proteins L11 and L1

doi:10.1128/AEM.67.5.2183-2190.2001

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Applied and Environmental Microbiology, May 2001, p. 2183-2190, Vol. 67, No. 5
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.5.2183-2190.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Organization and Transcriptional Analysis of a Six-Gene Cluster around the rplK-rplA Operon of Corynebacterium glutamicum Encoding the Ribosomal Proteins L11 and L1

Carlos Barreiro,¹ Eva González-Lavado,² and Juan F. Martín¹^,²^,^*

Instituto de Biotecnologia (INBIOTEC), Parque Cientifico de León, 24006 León,¹ and Facultad de Ciencias Biológicas y Ambientales, Area de Microbiologia, Universidad de León, 24071 León,² Spain

Received 5 December 2000/Accepted 22 February 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

A cluster of six genes, tRNA^Trp-secE-nusG-rplK-rplA-pkwR, was cloned and sequenced from a Corynebacterium glutamicum cosmid libraryand shown to be contiguous in the C. glutamicum genome. Thesegenes encode a tryptophanyl tRNA, the protein translocase componentSecE, the antiterminator protein NusG, and the ribosomal proteinsL11 and L1 in addition to PkwR, a putative regulatory proteinof the LacI-GalR family. S1 nuclease mapping analysis revealedthat nusG and rplK are expressed as separate transcriptional unitsand rplK and rplA are cotranscribed as a single mRNA. A 19-nucleotideinverted repeat that appears to correspond to a transcriptionalterminator was located in the 3' region downstream from nusG.Northern analysis with different probes confirmed the S1 mappingresults and showed that the secE-rplA four-gene region gives riseto four transcripts. secE was transcribed as a 0.5-kb monocistronicmRNA, nusG formed two transcripts of 1.4 and 1.0 kb from differentinitiation sites, and the two ribosomal protein genes rplK andrplA were cotranscribed as a single mRNA of 1.6 kb. A consensusL1 protein binding sequence was identified in the leader regionof the rplK-rplA transcript, suggesting that expression of therplK-rplA cluster was regulated by autogenous regulation exertedby the L1 protein at the translation level. The promoters of thenusG and rplK-rplA genes were subcloned in a novel corynebacterialpromoter-probe vector and shown to confer strong expression ofthe reportergene.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Ribosomal proteins of both gram-positive and gram-negative bacteria are involved in the translational control of the expressionof genes for the initiation of physiological and morphologicaldifferentiation (29), although the molecular mechanisms involvedare poorly known. One of these mechanisms, relA control, involvedin adaptation of the cells to amino acid starvation, is mediatedby the hyperphosphorylated guanosine tetraphosphate and pentaphosphate[(p)ppGpp]. These compounds are formed from GTP and the pyrophosphorylgroup of ATP in a reaction mediated by the RelA factor that isassociated with ribosomal proteins. The RelA protein becomes activewhen uncharged tRNA accumulates due to the lack of the correspondingamino acids, and ribosomes are unable to work (11).

In Escherichia coli, a functional ribosomal protein, L11, encoded by the rplK gene, is required for the activation of theRelA factor (10). Similarly, a functional rplK gene productis required for (p)ppGpp biosynthesis in Bacillus subtilis (41)and Streptomyces coelicolor (30, 32).

Corynebacterium glutamicum and Brevibacterium lactofermentum, renamed Corynebacterium lactofermentum (2), are widely usedfor industrial production of amino acids (22, 37). A largenumber of genes involved in primary metabolism have been clonedfrom corynebacteria (9, 24) and have been used to improvethe production of amino acids (25).

Amino acid accumulation in corynebacteria follows a decrease in rRNA synthesis and growth (E. González-Lavado, C. Barreiro,and J. F. Martin, unpublished data). Initial evidence indicatesthat the growth rate of corynebacteria is inversely correlatedwith the cellular (p)ppGpp concentration (36). The roles ofribosomal proteins and the rel mechanism in the switch from thegrowth phase to the amino acid production phase in corynebacteriaare of greatinterest.

A relA (also similar to spoT) gene of C. glutamicum encoding a bifunctional enzyme with (p)ppGpp synthetase and (p)ppGpp-degradingactivity was cloned (45). However, the role of the L11 ribosomalprotein in the synthesis of (p)ppGpp and in the switch from thegrowth phase to the amino acid accumulation stage in corynebacteriaremains unknown. Ribosomal protein engineering is receiving increasingattention as a tool to modify growth-related control mechanisms(31). It was, therefore, of great interest to clone the geneencoding L11 and other ribosomal proteins to elucidate its rolein the mechanism of rel control in C. glutamicum. We report thecloning, organization, and transcriptional analysis of a six-generegion of corynebacteria that contains the genes for the L11 andL1 ribosomalproteins.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains, plasmids, and growth conditions. All bacterial strains and plasmids used in this work are listed in Table 1. E. coli was grown in Luria Bertani broth (38)at 37°C. C. glutamicum ATCC 13032 and B. lactofermentum R31, renamedC. lactofermentum (2), a high-efficiency host strain for plasmidtransformation (25, 40), were grown in trypticase-soy broth(TSB) at 30°C. E. coli transformants were selected in the presenceof ampicillin (100 µg/ml), and C. glutamicum and C. lactofermentumtransformants were selected in media with kanamycin (30 µg/ml).

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TABLE 1. Strains and plasmids used in this work

DNA isolation and manipulation. E. coli plasmid DNA was obtained by alkaline lysis as described by Birnboim and Doly (3). Total C. glutamicum DNA was preparedas described by Martín and Gil (25), and C. lactofermentumand C. glutamicum plasmidic DNA were prepared by the method ofKieser (17, 25).

DNA manipulations were performed as described by Sambrook et al. (38). DNA fragments were isolated from agarose gels usingthe Geneclean II kit (Bio101).

E. coli cells were transformed as described by Hanahan (12), whereas corynebacteria were transformed by electroporation(8, 25).

Southern hybridizations. DNA fragments were vacuum blotted from 0.8% agarose gels to nylon membranes (42). Labeling of the DNA probes was done withdigoxigenin (Boehringer Mannheim, Mannheim, Germany) accordingto the manufacturer'sinstructions.

DNA sequencing. The nucleotide sequence of the cloned region was determined in both strands by the dideoxynucleotide chain termination methodusing an automatic DNA sequencer (ALF; Pharmacia). The nucleotideand deduced amino acid sequences were compared with those in theEMBL and GenBank databases by using the Clustal W program (43).

RNA extraction. Total RNA from corynebacteria was extracted by a method based on that of Eikmanns et al. (9) except that the cell pellet,obtained after centrifugation, was frozen with liquid nitrogenand kept at $-$ 70°C before RNA extraction. The RNA concentrationwas determined spectrophotometrically by determining the absorbanceat 260nm.

S1 nuclease protection assays. Low-resolution S1 mapping was performed as described by Sambrook et al. (38) using 200 µg of total C. glutamicum RNA and100 to 150 ng of probe DNA. Treatment with S1 nuclease was madefor 30 min (longer times were found to be less suitable). tRNAfrom Saccharomyces cerevisiae (type X-SA; Sigma) was used as anegative control for the hybridizations and the complete probe,or only the homologous part of the probe, was used as a positivecontrol.

Northern hybridization. Denaturing RNA electrophoresis was performed in 0.9% agarose gels in MOPS (morpholine propane sulfonic acid) buffer (20 mMMOPS, 5 mM sodium acetate, 1 mM EDTA [pH 7.0]) with 17% (vol/vol)formaldehyde. RNA (30 µg) was dissolved in denaturing buffer (50%formamide, 20% formaldehyde, 20% MOPS [5×]) with 10% DYE (38)and 1% ethidium bromide. DNA probes were labeled with ³²P by nick translation(Promega).

Hybridizations were performed at 42°C with 50% formamide; membrane washings were carried out as described by Sambrook et al.(38) except that the second washing was done at 42°C. The labeledbands were detected by autoradiography with exposition times of72 and 96h.

Promoter-probe plasmids. A new promoter-probe plasmid, pULCE0, was constructed from the vector pUL880M (23, 26). pUL880M was linearized with BglII.The protruding BglII ends were partially filled with dGTP anddATP using the Klenow fragment of the DNA polymerase. A polylinkercontaining the restriction sites BstXI and ClaI (sites that wereabsent in the rest of the vector) was synthesized and linked tothe linearized pUL880M vector. The appropriate orientation ofthe polylinker was confirmed by PCR using the following primers:Oligo 1 (5'-TCGCCAGAGCTCTGGATCGATA-3'), identical to that usedto construct the polylinker, and Oligo 2 (5'-GGGAGCGGCGATACCGTAAA-3'),internal to the kanamycin resistance gene of pUL880M. An amplificationband of 804 bp was obtained that corresponded to the insertionof the polylinker in the correct orientation (Fig. 1). Finally,the region of the polylinker was sequenced in both strands (Fig.1), and the functionality of the polylinker was confirmed by hydrolysiswith restriction endonucleases. This vector (unlike pUL880M) alloweddirected cloning of promoter sequences with several differentcohesive ends.

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FIG. 1. Construction of the promoter-probe vector pULCE0. This vector was constructed by inserting a polylinker (shaded nucleotide sequence) with unique restriction sites (absent from other places in the vector) in the BglII site upstream from the promoterless kanamycin resistance marker. One of the BglII sites was removed (X) by appropriate selection of oligonucleotides (arrowhead). Reverse-type letters indicate BglII ends partially filled to avoid vector religation. Km^R, kanamycin-resistance gene; Hyg^R, hygromycin resistance gene; Ap^R, ampicillin resistance gene. ori E. coli is the colE1 plasmid replication origin, and ori B. lactofermentum corresponds to the replication origin of plasmid pBL1 of B. lactofermentum (synonymous with C. lactofermentum). T_trp, transcriptional terminator of the C. lactofermentum tryptophan operon (to avoid readthrough expression).

Subcloning of the promoters. The promoter region upstream of rplK, controlling expression of rplK-rplA, was amplified by PCR as a 225-bp fragment containingits own translation start codon and was subcloned in pULCE0. Thispromoter region was named P_rplKA. The construction withthe promoter P_rplKA was introduced by transformationinto C. lactofermentum R31 (a high-efficiency host strain forinitial transformation), reisolated, and then transformed intoC. glutamicum. Direct transformation of C. glutamicum with theligation mixture was inefficient, but transformation with plasmidisolated from C. lactofermentum R31 was quiteefficient.

Similarly, the promoter region upstream of nusG (named P_nusG) was subcloned as a 567-bp fragment with its own translationstart codon in the promoter-probe vector pULCE0 and was introducedfirst into C. lactofermentum and then into C. glutamicum.

Ten transformants containing the plasmid with the P_rplKA promoter (named pULCE_rplKA) and another 10 containingthe plasmid with the P_nusG promoter (named pULCE_nusG)were selected and used to test the promoter strength by growingthem in plates of TSB medium with increasing concentrations ofkanamycin (from 100 to 1,200 µg/ml).

Nucleotide sequence accession number. The nucleotide sequence of the 4.42-kb fragment containing the tRNA^Trp-secE-nusG-rplK-rplA-pkwR cluster was deposited in the EMBL databaseunder accession number AJ300822.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Cloning the DNA region encoding L11 and L1 ribosomal proteins. Since the rplA and rplK genes (encoding the L1 and L11 proteins, respectively) are linked to the secE and nusG genes in somegram-positive bacteria, a search for this gene cluster in thecosmid library of C. glutamicum was made using two probes, A andB. Probe A corresponded to an 800-bp BglII-SalI fragment containingthe secE gene of Streptomyces lividans (J. Blanco and J. F. Martín,unpublished data), and probe B was a 1,500-bp KpnI fragment containingthe S. lividans nusGgene.

The results of Southern hybridization with total DNA of C. glutamicum digested with SalI showed a single 6.6-kb SalI bandthat hybridized with both probes. Similarly, a 5.5-kb BamHI fragmenthybridized with both probes, suggesting that the secE and nusGgenes are linked and probably maintain the same organization asin other gram-positivebacteria.

The C. glutamicum cosmid library was then hybridized with an 800-bp KpnI fragment containing the secE of S. lividans, and10 positive cosmids were selected and reconfirmed by a secondhybridization with the secE and nusG probes (see above). CosmidpCG1 was selected and used for further studies. pCG1 DNA was digestedwith BamHI, and the hybridizing 5.5-kb band was subcloned in pBluescriptSK(+) to form the new plasmidpB1.

The cloned DNA fragment comprises six genes, including the rplA-rplK cluster. Cosmid pCG1 was mapped with restriction endonucleases. A PstI-BamHI region of 4.42 kb was entirely sequenced in both strands,showing a G+C content of 53.48%. Computer analysis of the sequencetaking into account the codon usage of corynebacteria (23) revealedfive open reading frames (ORFs) in the sequenced DNA fragment(Fig. 2A).

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FIG. 2. (a) Restriction map and locations of the six genes found in the sequenced 4.42-kb DNA fragment (see the text). The wavy arrows correspond to the transcripts of the genes. The shaded bars show the S1 protection probes, and the solid bars represent the probes used in Northern analysis (see Fig. 4 and 5). (B) Stem-and-loop structure formed in the intergenic region between nusG and rplK-rplA corresponding to an imperfect inverted repeat of 19 nt. (C) Alignment of the L1-binding sequence in the 5' untranslated region of the rplK-rplA transcript with those of S. coelicolor (35) and S. griseus (20).

Upstream of the first ORF, we found a gene encoding a tRNA^Trp (73 bp). Comparison of the nucleotide sequences and the deducedamino acid sequences of the five ORFs with the sequence of proteinsin the Swiss-Prot data bank indicates that the first, ORF1, encodesa protein of 111 amino acids that shows homology with the membraneprotein SecE of different gram-positive and gram-negative bacteria(36.1% identity with SecE of Mycobacterium tuberculosis). ORF1was separated from the tRNA^Trp gene by an intergenic region of 230 bp. A sequence of 60 bp presentin the upstream region of ORF1 is identical to that of a promoterregion that was randomly cloned as a transcription initiationregion (34). Downstream from ORF1 and in the same orientationwe found ORF2, which encodes a protein of 318 amino acids anda deduced molecular mass of 34.7 kDa that shows very high homologywith the antiterminator protein NusG (48.9% identity with NusGfrom M. tuberculosis). Downstream from nusG, ORF3 and ORF4 encodeproteins of 145 and 236 amino acids that show extensive homologywith the ribosomal proteins L11 and L1, respectively (85.4% identitywith the L11 protein of M. tuberculosis and 71.5% identity withthe L1 protein of M. tuberculosis). These two genes have beennamed rplK and rplA,respectively.

ORF5 is located at the end of the sequenced fragment and in the opposite orientation to ORF4. It corresponds to a truncatedgene (918 bp) encoding a protein fragment (lacking the N-terminalend) with significant homology (63.3% identity at the nucleotidelevel) with the pkwR gene of Thermomonospora curvata (14). PkwRis a putative regulatory protein that is a member of the LacI-GalRfamily of regulatoryproteins.

These results clearly indicate that the region cloned in cosmid pCG1 contains the desired genes, rplK and rplA, for the ribosomalproteins L11 and L1. In some gram-positive bacteria, the genesrplJ and rplL, encoding other ribosomal proteins, map downstreamof rplA. To study the possibility that a DNA rearrangement mighthave occurred during cosmid packaging, the entire region of cosmidpCG1 and the total DNA of C. glutamicum were digested in paralleland hybridized with a 1,820-bp HindIII-BamHI probe (Fig. 3) thatcontains both the complete rplA gene and the sequenced ORF5.

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FIG. 3. Southern hybridization showing that ORF5 (pkwR) is adjacent to rplA both in the cosmid pCG1 (lanes 1, 3, 5, 7, 9, and 11) and in the chromosome (lanes 2, 4, 6, 8, 10, and 12). Cosmid DNA and total DNA were digested with BamHI plus SpeI (lanes 1 and 2), BamHI plus SacI (lanes 3 and 4), BamHI plus EcoRI (lanes 5 and 6), BamHI plus BstXI (lanes 7 and 8), BamHI plus ApaI (lanes 9 and 10), and BamHI (lanes 11 and 12).

The results (Fig. 3) showed unequivocally that ORF5 (pkwR) is adjacent to rplA both in the chromosome and in the cosmid. InM. tuberculosis, the region downstream of rplA does not containrplJ and rplL (5).

Transcriptional analysis of the secE-rplA region. Knowledge of the expression of the ribosomal protein genes is extremely important to understand the downshift in growth rateand protein synthesis that leads to amino acid accumulation. Low-resolutionS1 mapping with the "heterologous tail" probe procedure (33)was used to locate the transcription initiation regions that werestudied in detail. The modified heterologous tail probe methodallows us to distinguish in a simple form RNA-DNA hybrids fromreannealed DNA-DNA formed by base pairing of the two strands oftheprobe.

Protection analysis of the nusG-rplK intergenic region was done with probe PvuII (1,721 bp) and, in the case of the rplK-rplAintergenic region, with the 855-bp PvuII fragment as the probe(Fig. 4).

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FIG. 4. Low-resolution S1 mapping experiments. The probes used in each protection experiment are shown below the cloned DNA fragment. Note that each probe contains a homologous region (solid) and a heterologous region (shaded) belonging to lacZ and lacI. (A) Protected bands in the nusG-rplK region. Lanes: 1, probe A; 2, homologous part of probe A; 3, negative control with probe A and tRNA; 4, S1 protection assay (protected bands are indicated by arrows); 5, molecular size marker. (B) Lanes: 1, probe B; 2, homologous part of probe B; 3, negative control with probe and tRNA; 4, S1 protection assay (60-min digestion with nuclease S1); 5, S1 protection assay (30-min digestion with nuclease S1) (the protected band is indicated by the arrow); 6, size marker. Sizes in nucleotides are indicated at the right. Commercial tRNA from S. cerevisiae was used as a negative control instead of C. glutamicum RNA.

Three positive protection bands for the nusG-rplK region were found (Fig. 4A); the largest one clearly corresponds to thereannealed probe with the tail (1.72 kb); the second, with a sizeof 950 bp, corresponds to the protected band of nusG mRNA; andthe third corresponds to the protected mRNA of rplK (300 nucleotides[nt]). The lack of a protection band corresponding to the completeApaI-SpeI fragment (without a tail) indicated that there was nota bicistronic transcript for both the nusG and rplK genes. Theintergenic region between nusG and rplK-rplA contains a long (19-nt)inverted repeat forming a very stable stem-and-loop structureand a short poly(U) tail (Fig. 2B) that may work as a transcriptionalterminator. The presence of this terminator structure is in agreementwith the formation of separate transcripts from nusG and rplK-rplA.The 300-nt protected band corresponding to rplK indicates thatthe transcription start point of rplK is located about 180 ntupstream of the ATG translation initiation codon. In summary,all of the evidence indicates that there is a promoter regionbetween nusG and rplK and that the two genes are expressed asseparatetranscripts.

Similarly, low-resolution S1 mapping of the rplK-rplA region showed two positive hybridizing bands (Fig. 4B) that correspondedexactly to the reannealed probe (with its tail) and to an RNAprotection band of 725 nt that coincides with the expected sizeof a bicistronic transcript of both the rplK and rplA genes, i.e.,both rplK and rplA are transcribed as a single mRNA (seeDiscussion).

Northern analysis of the secE-rplA region shows that it is transcribed as four separate mRNAs. Northern analysis of the entire region confirmed the results obtained by low-resolution S1 mapping and provided evidence thatthe secE gene is expressed as a separate unit, unlike what occursin E. coli. The results of Northern analysis with a secE probe(Fig. 5A) showed that secE forms a transcript of 0.5 kb that isclearly smaller than any of the other transcripts formed fromthe genes in the region. This mRNA size is in good agreement withthe size of the secE gene (333 nt).

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FIG. 5. Northern analysis of transcripts of the cloned region with probes corresponding to secE, nusG, rplK-rplA, rplA, or rplK. The probes used are solid in Fig. 2A and were labeled by nick translation. Note that rplK and rplA are expressed as a single transcript of 1.6 kb.

Interestingly, hybridizations with the nusG probe revealed two transcripts of 1.4 and 1.0 kb (Fig. 5B), neither of which coincideswith other transcripts in the region. This result indicated thatthere are two overlapping mRNAs for the nusG gene, probably differingin the transcription start point, because low-resolution S1 mappingindicates that there is a single 3'end.

Northern hybridizations of the RNA with an rplK-rplA probe showed a single transcript of 1.6 kb (Fig. 5C). When the hybridizationwas repeated with individual probes internal to either rplA orrplK, the same 1.6-kb band appeared, thus confirming that bothrplK and rplA are transcribed as a single bicistronic mRNA, inagreement with the conclusions of the S1 nuclease protectionstudies.

Upstream of the rplK-rplA cluster in the leader region of rplK mRNA, we have found a putative L1 binding sequence that showsstrong conservation (Fig. 2C) with the reported L1 binding sequencein the rplK-rplA transcript of Streptomyces griseus (20) andS. coelicolor (35).

Promoter studies. The promoter region upstream of secE was isolated previously (34) and was not studied further. The two other promoter regionsupstream of nusG and rplK-rplA were analyzed by subcloning themin a new promoter-probe vector, pULCE0 (Fig. 1), to quantify theirtranscription initiation abilities. The subcloned promoter fragmentscontained the $-$ 35 and $-$ 10 regions and their ribosome bindingsites.

All transformants expressing the kanamycin resistance marker from the P_rplKA promoter were able to grow in the presenceof up to 975 µg of kanamycin/ml, whereas the control untransformedstrain was sensitive to 20 µg/ml. Similarly, the level of resistanceto kanamycin of the transformants with the P_nusG promoterwas 800 µg/ml.

Figure 6 compares the efficiencies of P_rplKA and P_nusG with those of other endogenous promoters of the C.lactofermentum plasmid pBL1 (4). The efficiency of P_rplKAwas clearly higher than those of the other known corynebacterialpromoters with the same marker and vector, indicating that thereis a strong expression of the rplK-rplA operon in C. glutamicum.

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FIG. 6. Levels of resistance to kanamycin (in solid TSB plates) conferred by expressing the kanamycin resistance gene of pULCE0 from the rplK-rplA promoter and from the nusG promoter in comparison with expression from the promoters obtained from pBL1 of C. lactofermentum (4).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The ribosomal protein L11 is involved in control of the expression of genes regulated by the rel mechanism (16, 30, 45).The L11 protein is required for ribosome-dependent accumulationof (p)ppGpp (32). We have cloned this gene (rplK) and foundthat it is associated with rplA (encoding the ribosomal proteinL1) in a cluster with the secE, nusG, and pkwR genes, in additionto a tRNA^Trp gene located in the distal region (with respect to rplK-rplA)of thecluster.

There are notable differences in the conservation of the genes in this region in different bacteria. The rplK gene has beencloned from E. coli (6) and other gram-negative bacteria, andmore recently from gram-positive microorganisms, including B.subtilis (19), M. tuberculosis (5), Streptomyces virginiae(15), and S. coelicolor (35). In all these organisms, as inC. glutamicum, the gene encoding L11 is clustered with the secE,nusG, and rplAgenes.

A gene homologous to the pkwR gene of the actinomycete T. curvata (14) was located downstream from rplA and in oppositeorientation to it in C. glutamicum. In M. tuberculosis (5),the region downstream of rplA contains five small ORFs in oppositeorientation to that of rplA (4), and none of these ORFs correspondto the pkwR gene, whereas in B. subtilis (19), S. virginiae(15), S. coelicolor (http://www.sanger.ac.uk/Projects/S_coelicolor/),and other bacteria, such as E. coli and Thermotoga maritima (28),rplA is followed by the genes rplJ and rplL, encoding the ribosomalproteins L10 and L7/L12.

These results suggest that there are two types of organization of the rplK-rplA genes in actinomycetes: (i) the arrangementof rplK-rplA-pkwR that occurs in C. glutamicum and (ii) that knownin species of Streptomyces (16, 20). The pkwR gene encodesa putative regulatory protein, a member of the LacI-GalR familyof regulatory proteins, but its exact role is unknown (14).It is likely that the larger cluster of ribosomal proteins inStreptomyces species may have been formed by recruiting genesfrom other gram-positive or gram-negativebacteria.

Our results with transcriptional analysis indicate that rplK and rplA are transcribed as a single bicistronic mRNA, whereassecE and nusG form separate transcripts. Similar results havebeen reported in E. coli (6), S. virginiae (15), and S. griseus(20). The rplK-rplA promoter region of C. glutamicum is precededby a putative transcriptional terminator (a long stem-and-loopstructure), further supporting the conclusion that nusG formsa transcript separate from that of rplA-rplK.

The simultaneous transcription of rplK-rplA suggests that the formation of the ribosomal proteins L11 and L1 is coordinatedas expected. In E. coli there is, in addition to transcriptionalregulation, an elegant mechanism of autoregulation by the L1 proteinat the translational level (7). The protein L1 binds to a boxin the mRNA upstream of the rplK translation initiation site andprevents translation of the mRNA by the ribosomes. In this way,an excess of the ribosomal protein L1 prevents the wasteful synthesisof additional L1 and L11 proteins. Similarly, in the leader regionof rplK-rplA we have found a putative L1 binding sequence thatis similar to the L1 binding sequence of S. griseus (20) andS. coelicolor (35), suggesting that the rplK-rplA expressionis also autoregulated in C. glutamicum.

Promoter analysis confirmed that nusG and rplK-rplA are preceded by separate promoters. In addition, a promoter cloned byrandom search of transcription-initiating activity by Pátek etal. (34) fully coincided with a fragment of the nucleotide sequenceupstream of secE. The promoter region upstream of rplK-rplA isvery efficient for transcription initiation, since it confersresistance to up to 975 µg of kanamycin/ml when coupled to theTn5 kanamycin resistance gene, higher than previously reportedpromoters from corynebacteria available to us (24, 25). ThenusG promoter is slightly less efficient in transcription initiation.The regulation of these promoters in response to nutrient starvation,osmotic stress, and the rel control is the subject of furtherresearch. These strong promoters may be used for efficient geneexpression incorynebacteria.

	ACKNOWLEDGMENTS

This research was supported by a grant from the European Union (BIO4-CT96-0145). Carlos Barreiro received a fellowship fromthe Ministry of Science and Technology (Spain), and Eva González-Lavado was granted a fellowship by the Basque Government (Vitoria,Spain). We thank H. Sahm for providing the initial cosmid library,A. Rodríguez-García for his scientific support, and M. Mediavilla,B. Martín, J. Merino, R. Barrientos, and M. Corrales for excellenttechnicalassistance.

	ADDENDUM IN PROOF

A related article on a defined deletion within the rplK gene will appear in Microbiology (L. Wehmeier, O. Brockmann-Gretza,A. Pisabarro, A. Tauch, A. Pühler, J. F. Martín, and J. Kalinowski,Microbiology, inpress).

	FOOTNOTES

^* Corresponding author. Mailing address: Instituto de Biotecnología (INBIOTEC), Parque Científico de León, Avda. del Real,no. 1, 24006 León, Spain. Phone: (34 987) 210308. Fax: (34 987)210388. E-mail: degjmm{at}unileon.es.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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3. Birnboim, H. C., and J. Doly. 1979. A rapid alkaline extraction procedure for screening recombinant plasmid DNA. Nucleic Acids Res. 7:1513-1523[Abstract/Free Full Text].

4. Cadenas, R. F., J. F. Martín, and J. A. Gil. 1991. Construction and characterization of promoter-probe vectors for corynebacteria using the kanamycin-resistance reporter gene. Gene 98:117-121[CrossRef][Medline].

5. Cole, S. T., R. Brosch, J. Parkhill, T. Garnier, C. Churcher, D. Harris, S. V. Gordon, K. Eiglmeier, S. Gas, C. E. Barry III, F. Tekaia, K. Badcock, D. Basham, D. Brown, T. Chillingworth, R. Connor, R. Davies, K. Devlin, T. Feltwell, S. Gentles, N. Hamlin, S. Holroyd, T. Hornsby, K. Jagels, B. G. Barrel, et al. 1998. Deciphering the biology of Mycobacterium tuberculosis from the complete genome sequence. Nature 393:537-544[CrossRef][Medline].

6. Downing, W. L., S. L. Sullivan, M. E. Gottesman, and P. P. Dennis. 1990. Sequence and transcriptional pattern of the essential Escherichia coli secE-nusG operon. J. Bacteriol. 172:1621-1627[Abstract/Free Full Text].

7. Draper, D. E. 1989. How do proteins recognize specific RNA sites? New clues from autogenously regulated ribosomal proteins. Trends Biochem Sci. 14:335-338[CrossRef][Medline].

8. Dunican, L. K., and E. Shivnan. 1989. High frequency transformation of whole cells of amino acid producing coryneform bacteria using high voltage electroporation. Biotechnology 7:1067-1070.

9. Eikmanns, B. J., N. Thum-Schmitz, L. Eggelin, K. Lüdtke, and H. Sahm. 1994. Nucleotide sequence, expression and transcriptional analysis of the Corynebacterium glutamicum gltA gene encoding citrate synthase. Microbiology 140:1817-1828[Abstract].

10. Friesen, J. F., N. P. Fiil, J. M. Parker, and W. A. Haseltine. 1974. A new relaxed mutant of Escherichia coli with an altered 50S ribosomal subunit. Proc. Natl. Acad. Sci. USA 71:3465-3469[Abstract/Free Full Text].

11. Goldman, E., and H. Jakubowski. 1990. Uncharged tRNA, protein synthesis, and the bacterial stringent response. Mol. Microbiol. 4:2035-2040[CrossRef][Medline].

12. Hanahan, D. 1983. Studies on transformation of Escherichia coli. J. Mol. Biol. 166:557-580[Medline].

13. Hanahan, D. 1985. Techniques for transformation of Escherichia coli,, p. 109-135. In D. M. Glover (ed.), DNA cloning. A practical approach. Irl. Press, Oxford, United Kingdom.

14. Janda, L., P. Tichy, J. Spizek, and M. Petricek. 1996. A deduced Thermomonospora curvata protein containing serine/threonine protein kinase and WD-repeat domains. J. Bacteriol. 178:1487-1489[Abstract/Free Full Text].

15. Katayama, M., Y. Sakai, S. Okamoto, F. Ihara, T. Nihira, and Y. Yamada. 1996. Gene organization in the ada-rplL region of Streptomyces virginiae. Gene 171:135-136[CrossRef][Medline].

16. Kawamoto, S., D. Zhang, and K. Ochi. 1998. Sequence analysis of the ribosomal L11 protein gene (rplK=relC) in Streptomyces lavendulae using a deletion allele. J. Antibiot. 51:954-957[Medline].

17. Kieser, T. 1984. Factors affecting the isolation of cccDNA from Streptomyces lividans and Escherichia coli. Plasmid 12:19-36[CrossRef][Medline].

18. Kramer, W., V. Drutsa, H.-W. Jansen, B. Kramer, M. Pflugfelder, and H. K. Fritz. 1984. The gapped duplex method DNA approach to oligonucleotide-directed mutation construction. Nucleic Acids. Res. 12:9441-9456[Abstract/Free Full Text].

19. Kunst, F., N. Ogasawara, I. Moszer, A. M. Albertini, G. Alloni, V. Azevedo, et al. 1997. The complete genome sequence of the Gram-positive bacterium Bacillus subtilis. Nature 390:249-256[CrossRef][Medline].

20. Küster, C., W. Piepersberg, and J. Distler. 1998. Cloning and transcriptional analysis of the rplKA-orf31-rplJL gene cluster of Streptomyces griseus. Mol. Gen. Genet. 257:219-229[CrossRef][Medline].

21. Malumbres, M. 1993. Clonación y caracterización molecular de los genes biosintéticos de treonina (thrC) y lisina de Brevibacterium lactofermentum. Ph.D. thesis. University of León, León, Spain.

22. Malumbres, M., and J. F. Martín. 1996. Molecular control mechanisms of lysine and threonine biosynthesis in amino acid-producing corynebacteria: redirecting carbon flow. FEMS Microbiol. Lett. 143:103-114[CrossRef][Medline].

23. Malumbres, M., J. A. Gil, and J. F. Martín. 1993. Codon preference in corynebacteria. Gene 134:15-24[CrossRef][Medline].

24. Martín, J. F. 1989. Molecular genetics of amino acid-producing corynebacteria, p. 25-29. In S. Baumberg, I. Hunter, and M. Rhodes (ed.), Microbial products: new approaches. Cambridge University Press, Cambridge, United Kingdom.

25. Martín, J. F., and J. A. Gil. 1999. Corynebacteria, p. 379-391. In A. L. Demain, J. E. Davies, R. M. Atlas, G. Cohen, C. L. Hershberger, W.-S. Hu, D. H. Sherman, R. C. Willson, and J. H. D. Wu (ed.), Manual of industrial microbiology and biotechnology, 2nd ed. ASM Press, Washington, D.C.

26. Martín, J. F., R. F. Cadenas, M. Malumbres, L. M. Mateos, C. Guerrero, and J. A. Gil. 1990. Construction and utilization of promoter-probe and expression vectors in corynebacteria. Characterization of corynebacterial promoters, p. 283-292. In H. Heslot, J. Davies, J. Florent, L. Bobichon, G. Durand, and L. Penasse (ed.), Genetics of Industrial Microorganisms. Société Française de Microbiologie, Strasbourg, France.

27. Mead, D. A., and B. Kemper. 1988. Chimeric single-stranded DNA phage-plasmid cloning vectors. Bio/Technology 10:85-102[Medline].

28. Nelson, K. E., R. A. Clayton, S. R. Gill, M. L. Gwinn, R. J. Dodson, D. H. Haft, E. K. Hickey, J. D. Peterson, W. C. Nelson, K. A. Ketchum, L. McDonald, T. R. Utterback, J. A. Malek, K. D. Linher, M. M. Garrett, A. M. Stewart, M. D. Cotton, M. S. Pratt, C. A. Phillips, D. Richardson, J. Heidelberg, G. G. Sutton, R. D. Fleischmann, J. A. Eisen, C. M. Fraser, et al. 1999. Evidence for lateral gene transfer between Archaea and bacteria from genome sequence of Thermotoga maritima. Nature 399:323-329[CrossRef][Medline].

29. Ochi, K. 1986. Occurrence of the stringent response in Streptomyces sp. and its significance for the initiation of morphological and physiological differentiation. J. Gen. Microbiol. 132:2621-2631[Medline].

30. Ochi, K. 1990. Streptomyces relC mutants with an altered ribosomal protein ST-L11 and genetic analysis of a Streptomyces griseus relC mutant. J. Bacteriol. 172:4008-4016[Abstract/Free Full Text].

31. Ochi, K. 1999. Searching for novel ribosomal functions. Tanpakushitsu Kakusan Koso 44:1967-1974[Medline].

32. Ochi, K., D. Zhang, S. Kawamoto, and A. Hesketh. 1997. Molecular and functional analysis of the ribosomal L11 and S12 protein genes (rplK and rpsL) of Streptomyces coelicolor A3(2). Mol. Gen. Genet. 256:488-498[Medline].

33. Paradkar, A. S., A. A. Kwamena, and S. E. Jensen. 1998. A pathway-specific transcriptional activator regulates late steps of clavulanic acid biosynthesis in Streptomyces clavuligerus. Mol. Microbiol. 27:831-843[CrossRef][Medline].

34. Pátek, M., B. J. Eikmanns, J. Pátek, and H. Sahm. 1996. Promoters from Corynebacterium glutamicum: cloning, molecular analysis and search for consensus motif. Microbiology 142:1297-1309[Abstract].

35. Puttikhunt, C., T. Nihira, and Y. Yamada. 1995. Cloning, nucleotide sequence and transcriptional analysis of the nusG gene of Streptomyces coelicolor A3(2), which encodes a putative transcriptional antiterminator. Mol. Gen. Genet. 247:118-122[CrossRef][Medline].

36. Ruklisha, M., U. Viesturs, and L. Labane. 1995. Growth control and ppGpp synthesis in Brevibacterium flavum cells at various medium mixing rates and aeration intensities. Acta Biotechnol. 15:41-48[CrossRef].

37. Sahm, H., L. Eggeling, B. J. Eikmanns, and R. Krämer. 1995. Metabolic design in amino acid producing bacterium Corynebacterium glutamicum. FEMS Microbiol. Lett. 16:243-252.

38. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

39. Santamaría, R. I., J. A. Gil, and J. F. Martín. 1985. High-frequency transformation of Brevibacterium lactofermentum protoplasts by plasmid DNA. J. Bacteriol. 162:463-467[Abstract/Free Full Text].

40. Santamaría, R. I., J. F. Martín, and J. A. Gil. 1987. Identification of a promoter sequence in the plasmid pUL340 of Brevibacterium lactofermentum and construction of new cloning vectors for corynebacteria containing two selectable markers. Gene 56:199-208[CrossRef][Medline].

41. Smith, I., P. Paress, K. Cabane, and E. Dubnau. 1980. Genetics and physiology of the rel system of Bacillus subtilis. Mol. Gen. Genet. 178:271-279[CrossRef][Medline].

42. Southern, E. M. 1975. Detection of specific sequences among DNA fragments separated by gel electrophoresis. J. Mol. Biol. 98:503-517[CrossRef][Medline].

43. Thompson, J. D., D. G. Higgins, T. J. Gibson, and W. Clustal. 1994. Improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Res. 22:4673-4680[Abstract/Free Full Text].

44. Vieira, J., and J. Messing. 1982. The pUC plasmids, an M13mp7-derived system for insertion mutagenesis and sequencing with synthetic universal primers. Gene 19:259-268[CrossRef][Medline].

45. Wehmeier, L., A. Schäfer, A. Burkovski, R. Krämer, U. Mechold, H. Malke, A. Pühler, and J. Kalinowski. 1998. The role of the Corynebacterium glutamicum rel gene in (p)ppGpp metabolism. Microbiology 144:1853-1862[Abstract/Free Full Text].

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J. Bacteriol.	Microbiol. Mol. Biol. Rev.	Eukaryot. Cell	All ASM Journals

1.	Alting-Mees, M. A., and J. M. Short. 1989. pBluescript II: gene mapping vectors. Nucleic. Acids Res. 17:9494[Free Full Text].
2.	Amador, E., J. M. Castro, A. Correia, and J. F. Martín. 1999. Structure and organization of the rrnD operon of Brevibacterium lactofermentum: analysis of the 16s rRNA gene. Microbiology 145:915-924[Abstract].
3.	Birnboim, H. C., and J. Doly. 1979. A rapid alkaline extraction procedure for screening recombinant plasmid DNA. Nucleic Acids Res. 7:1513-1523[Abstract/Free Full Text].
4.	Cadenas, R. F., J. F. Martín, and J. A. Gil. 1991. Construction and characterization of promoter-probe vectors for corynebacteria using the kanamycin-resistance reporter gene. Gene 98:117-121[CrossRef][Medline].
5.	Cole, S. T., R. Brosch, J. Parkhill, T. Garnier, C. Churcher, D. Harris, S. V. Gordon, K. Eiglmeier, S. Gas, C. E. Barry III, F. Tekaia, K. Badcock, D. Basham, D. Brown, T. Chillingworth, R. Connor, R. Davies, K. Devlin, T. Feltwell, S. Gentles, N. Hamlin, S. Holroyd, T. Hornsby, K. Jagels, B. G. Barrel, et al. 1998. Deciphering the biology of Mycobacterium tuberculosis from the complete genome sequence. Nature 393:537-544[CrossRef][Medline].
6.	Downing, W. L., S. L. Sullivan, M. E. Gottesman, and P. P. Dennis. 1990. Sequence and transcriptional pattern of the essential Escherichia coli secE-nusG operon. J. Bacteriol. 172:1621-1627[Abstract/Free Full Text].
7.	Draper, D. E. 1989. How do proteins recognize specific RNA sites? New clues from autogenously regulated ribosomal proteins. Trends Biochem Sci. 14:335-338[CrossRef][Medline].
8.	Dunican, L. K., and E. Shivnan. 1989. High frequency transformation of whole cells of amino acid producing coryneform bacteria using high voltage electroporation. Biotechnology 7:1067-1070.
9.	Eikmanns, B. J., N. Thum-Schmitz, L. Eggelin, K. Lüdtke, and H. Sahm. 1994. Nucleotide sequence, expression and transcriptional analysis of the Corynebacterium glutamicum gltA gene encoding citrate synthase. Microbiology 140:1817-1828[Abstract].
10.	Friesen, J. F., N. P. Fiil, J. M. Parker, and W. A. Haseltine. 1974. A new relaxed mutant of Escherichia coli with an altered 50S ribosomal subunit. Proc. Natl. Acad. Sci. USA 71:3465-3469[Abstract/Free Full Text].
11.	Goldman, E., and H. Jakubowski. 1990. Uncharged tRNA, protein synthesis, and the bacterial stringent response. Mol. Microbiol. 4:2035-2040[CrossRef][Medline].
12.	Hanahan, D. 1983. Studies on transformation of Escherichia coli. J. Mol. Biol. 166:557-580[Medline].
13.	Hanahan, D. 1985. Techniques for transformation of Escherichia coli,, p. 109-135. In D. M. Glover (ed.), DNA cloning. A practical approach. Irl. Press, Oxford, United Kingdom.
14.	Janda, L., P. Tichy, J. Spizek, and M. Petricek. 1996. A deduced Thermomonospora curvata protein containing serine/threonine protein kinase and WD-repeat domains. J. Bacteriol. 178:1487-1489[Abstract/Free Full Text].
15.	Katayama, M., Y. Sakai, S. Okamoto, F. Ihara, T. Nihira, and Y. Yamada. 1996. Gene organization in the ada-rplL region of Streptomyces virginiae. Gene 171:135-136[CrossRef][Medline].
16.	Kawamoto, S., D. Zhang, and K. Ochi. 1998. Sequence analysis of the ribosomal L11 protein gene (rplK=relC) in Streptomyces lavendulae using a deletion allele. J. Antibiot. 51:954-957[Medline].
17.	Kieser, T. 1984. Factors affecting the isolation of cccDNA from Streptomyces lividans and Escherichia coli. Plasmid 12:19-36[CrossRef][Medline].
18.	Kramer, W., V. Drutsa, H.-W. Jansen, B. Kramer, M. Pflugfelder, and H. K. Fritz. 1984. The gapped duplex method DNA approach to oligonucleotide-directed mutation construction. Nucleic Acids. Res. 12:9441-9456[Abstract/Free Full Text].
19.	Kunst, F., N. Ogasawara, I. Moszer, A. M. Albertini, G. Alloni, V. Azevedo, et al. 1997. The complete genome sequence of the Gram-positive bacterium Bacillus subtilis. Nature 390:249-256[CrossRef][Medline].
20.	Küster, C., W. Piepersberg, and J. Distler. 1998. Cloning and transcriptional analysis of the rplKA-orf31-rplJL gene cluster of Streptomyces griseus. Mol. Gen. Genet. 257:219-229[CrossRef][Medline].
21.	Malumbres, M. 1993. Clonación y caracterización molecular de los genes biosintéticos de treonina (thrC) y lisina de Brevibacterium lactofermentum. Ph.D. thesis. University of León, León, Spain.
22.	Malumbres, M., and J. F. Martín. 1996. Molecular control mechanisms of lysine and threonine biosynthesis in amino acid-producing corynebacteria: redirecting carbon flow. FEMS Microbiol. Lett. 143:103-114[CrossRef][Medline].
23.	Malumbres, M., J. A. Gil, and J. F. Martín. 1993. Codon preference in corynebacteria. Gene 134:15-24[CrossRef][Medline].
24.	Martín, J. F. 1989. Molecular genetics of amino acid-producing corynebacteria, p. 25-29. In S. Baumberg, I. Hunter, and M. Rhodes (ed.), Microbial products: new approaches. Cambridge University Press, Cambridge, United Kingdom.
25.	Martín, J. F., and J. A. Gil. 1999. Corynebacteria, p. 379-391. In A. L. Demain, J. E. Davies, R. M. Atlas, G. Cohen, C. L. Hershberger, W.-S. Hu, D. H. Sherman, R. C. Willson, and J. H. D. Wu (ed.), Manual of industrial microbiology and biotechnology, 2nd ed. ASM Press, Washington, D.C.
26.	Martín, J. F., R. F. Cadenas, M. Malumbres, L. M. Mateos, C. Guerrero, and J. A. Gil. 1990. Construction and utilization of promoter-probe and expression vectors in corynebacteria. Characterization of corynebacterial promoters, p. 283-292. In H. Heslot, J. Davies, J. Florent, L. Bobichon, G. Durand, and L. Penasse (ed.), Genetics of Industrial Microorganisms. Société Française de Microbiologie, Strasbourg, France.
27.	Mead, D. A., and B. Kemper. 1988. Chimeric single-stranded DNA phage-plasmid cloning vectors. Bio/Technology 10:85-102[Medline].
28.	Nelson, K. E., R. A. Clayton, S. R. Gill, M. L. Gwinn, R. J. Dodson, D. H. Haft, E. K. Hickey, J. D. Peterson, W. C. Nelson, K. A. Ketchum, L. McDonald, T. R. Utterback, J. A. Malek, K. D. Linher, M. M. Garrett, A. M. Stewart, M. D. Cotton, M. S. Pratt, C. A. Phillips, D. Richardson, J. Heidelberg, G. G. Sutton, R. D. Fleischmann, J. A. Eisen, C. M. Fraser, et al. 1999. Evidence for lateral gene transfer between Archaea and bacteria from genome sequence of Thermotoga maritima. Nature 399:323-329[CrossRef][Medline].
29.	Ochi, K. 1986. Occurrence of the stringent response in Streptomyces sp. and its significance for the initiation of morphological and physiological differentiation. J. Gen. Microbiol. 132:2621-2631[Medline].
30.	Ochi, K. 1990. Streptomyces relC mutants with an altered ribosomal protein ST-L11 and genetic analysis of a Streptomyces griseus relC mutant. J. Bacteriol. 172:4008-4016[Abstract/Free Full Text].
31.	Ochi, K. 1999. Searching for novel ribosomal functions. Tanpakushitsu Kakusan Koso 44:1967-1974[Medline].
32.	Ochi, K., D. Zhang, S. Kawamoto, and A. Hesketh. 1997. Molecular and functional analysis of the ribosomal L11 and S12 protein genes (rplK and rpsL) of Streptomyces coelicolor A3(2). Mol. Gen. Genet. 256:488-498[Medline].
33.	Paradkar, A. S., A. A. Kwamena, and S. E. Jensen. 1998. A pathway-specific transcriptional activator regulates late steps of clavulanic acid biosynthesis in Streptomyces clavuligerus. Mol. Microbiol. 27:831-843[CrossRef][Medline].
34.	Pátek, M., B. J. Eikmanns, J. Pátek, and H. Sahm. 1996. Promoters from Corynebacterium glutamicum: cloning, molecular analysis and search for consensus motif. Microbiology 142:1297-1309[Abstract].
35.	Puttikhunt, C., T. Nihira, and Y. Yamada. 1995. Cloning, nucleotide sequence and transcriptional analysis of the nusG gene of Streptomyces coelicolor A3(2), which encodes a putative transcriptional antiterminator. Mol. Gen. Genet. 247:118-122[CrossRef][Medline].
36.	Ruklisha, M., U. Viesturs, and L. Labane. 1995. Growth control and ppGpp synthesis in Brevibacterium flavum cells at various medium mixing rates and aeration intensities. Acta Biotechnol. 15:41-48[CrossRef].
37.	Sahm, H., L. Eggeling, B. J. Eikmanns, and R. Krämer. 1995. Metabolic design in amino acid producing bacterium Corynebacterium glutamicum. FEMS Microbiol. Lett. 16:243-252.
38.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
39.	Santamaría, R. I., J. A. Gil, and J. F. Martín. 1985. High-frequency transformation of Brevibacterium lactofermentum protoplasts by plasmid DNA. J. Bacteriol. 162:463-467[Abstract/Free Full Text].
40.	Santamaría, R. I., J. F. Martín, and J. A. Gil. 1987. Identification of a promoter sequence in the plasmid pUL340 of Brevibacterium lactofermentum and construction of new cloning vectors for corynebacteria containing two selectable markers. Gene 56:199-208[CrossRef][Medline].
41.	Smith, I., P. Paress, K. Cabane, and E. Dubnau. 1980. Genetics and physiology of the rel system of Bacillus subtilis. Mol. Gen. Genet. 178:271-279[CrossRef][Medline].
42.	Southern, E. M. 1975. Detection of specific sequences among DNA fragments separated by gel electrophoresis. J. Mol. Biol. 98:503-517[CrossRef][Medline].
43.	Thompson, J. D., D. G. Higgins, T. J. Gibson, and W. Clustal. 1994. Improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Res. 22:4673-4680[Abstract/Free Full Text].
44.	Vieira, J., and J. Messing. 1982. The pUC plasmids, an M13mp7-derived system for insertion mutagenesis and sequencing with synthetic universal primers. Gene 19:259-268[CrossRef][Medline].
45.	Wehmeier, L., A. Schäfer, A. Burkovski, R. Krämer, U. Mechold, H. Malke, A. Pühler, and J. Kalinowski. 1998. The role of the Corynebacterium glutamicum rel gene in (p)ppGpp metabolism. Microbiology 144:1853-1862[Abstract/Free Full Text].