Multiple Roles for the sRNA GcvB in the Regulation of Slp Levels in <i>Escherichia coli</i>

Stauffer, Lorraine T.; Stauffer, George V.

doi:https://doi.org/10.1155/2013/918106

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Research Article | Open Access

Volume 2013 | Article ID 918106 | https://doi.org/10.1155/2013/918106

Multiple Roles for the sRNA GcvB in the Regulation of Slp Levels in Escherichia coli

Lorraine T. Stauffer¹and George V. Stauffer¹

Academic Editor: S. Chatzipanagiotou, A. Grisold

Received04 Mar 2013

Accepted31 Mar 2013

Published24 Apr 2013

Abstract

The Escherichia coli gcvB gene encodes a small RNA that regulates many genes involved in the transport of dipeptides, oligopeptides, and amino acids (oppA, dppA, cycA, and sstT). A microarray analysis of RNA isolated from an E. coli wild-type and a ΔgcvB strain grown to midlog phase in Luria-Bertani broth indicated that genes not involved in transport are also regulated by GcvB. One gene identified was slp that encodes an outer membrane lipoprotein of unknown function induced when cells enter stationary phase. The aim of this study was to verify that slp is a new target for GcvB-mediated regulation. In this study we used RT-PCR to show that GcvB regulates slp mRNA levels. GcvB negatively controls slp::lacZ in cells grown in Luria-Bertani broth by preventing an Hfq-mediated activation mechanism for slp::lacZ expression. In contrast, in glucose minimal medium supplemented with glycine, GcvB is required for inhibition of slp::lacZ expression, and Hfq prevents GcvB-mediated repression. Thus, GcvB regulates slp in both LB and in glucose minimal + glycine media and likely by mechanisms different than how it regulates sstT, dppA, cycA, and oppA. Repression of slp by GcvB results in an increase in resistance to chloramphenicol, and overexpression of slp in a ΔgcvB strain results in an increase in sensitivity to chloramphenicol.

1. Introduction

The E. coli chromosome encodes ~100 small non-translated regulatory RNAs (sRNAs) [1]. A number of these sRNAs have been shown to function as regulators of outer membrane proteins and therefore play important roles in stress responses and virulence gene regulation [2–4]. In addition, most of these sRNAs regulate expression of target genes posttranscriptionally by base pairing with the target mRNAs [5]. The Hfq protein is required for regulation by this class of sRNAs [6]. In most cases, base pairing results in negative regulation of translational activity and altered stability of the target mRNA [5]. However, DsrA and RprA bind to rpoS mRNA, likely preventing formation of an inhibitory secondary structure that sequesters the ribosome-binding site, resulting in increased translation [7–9].

The gcvB gene encodes a nontranslated RNA of 206 nucleotides (nts) [10]. Transcription of the gcvB gene is activated by the GcvA protein when the cellular level of glycine is high and repressed by GcvA when the cellular level of glycine is limiting; repression requires an additional protein GcvR [10]. The production of GcvB is highest during the log phase of growth, and GcvB is not detectable in stationary phase cells [12]. In E. coli, GcvB regulates genes involved in the transport of amino acids and small peptides [10, 11, 14, 15]. GcvB also plays a role in acid resistance, although the precise mechanism is unknown [16, 17]. Recently it was shown that GcvB acts as a negative regulator of CsgD, the master regulator of curli and cellulose synthesis [18]. In Salmonella enterica serovar Typhimurium, GcvB has been validated to regulate more than 20 targets and possibly acts as a regulatory node in amino acid metabolism [19, 20]. GcvB represses many of its target mRNAs at the posttranscriptional level by an antisense mechanism, and repression requires the Hfq protein [14, 15, 20–22]. The sRNA RyhB regulates as many as 18 operons encoding 56 genes [23], and many other sRNAs are also predicted to regulate more than one target [24]. Thus, it is likely that GcvB regulates other genes in E. coli. To identify additional regulatory targets for E. coli GcvB, we compared RNA isolated from a wild type (WT) and an otherwise isogenic ΔgcvB strain grown to midlog phase in Luria-Bertani broth (LB) by microarray analysis [15]. One potential target identified was slp, encoding a carbon starvation-inducible outer membrane protein [25]. Although the function of Slp is unknown, a null slp mutant showed a modest increase in CM resistance and a strain that overproduced Slp was more sensitive to CM [26]. The EvgAS two-component system increases expression of slp, and the MarRA system downregulates slp expression [27, 28]. Our results confirm GcvB and Hfq also regulate slp::lacZ expression in both LB and glucose minimal (GM) supplemented with glycine. However, the mechanisms of regulation are different under the two growth conditions tested. GcvB appears to inhibit Hfq activation of slp::lacZ expression in LB, whereas Hfq appears to prevent GcvB from functioning to negatively regulate slp::lacZ in GM + glycine. The results confirm that slp is a new target for GcvB regulation and show that GcvB has multiple mechanisms for controlling gene expression.

2. Materials and Methods

2.1. Bacterial Strains, Plasmids, and Phage

The E. coli strains and plasmids used in this study are listed in Table 1 or are described in the text. The λslp::lacZ translational fusion was constructed by PCR as follows. A DNA fragment was synthesized using primer Slp-EcoRI 5′-GGGGTGGAAATAGAAATACCATC that hybridized to E. coli DNA upstream of an EcoRI site that begins 288 base pairs (bps) upstream of the slp translation start site and primer Slp-SmaI 5′-CCTAAACCCGGGGAGGATGAGTGCACCTTTTGTC with a SmaI site (underlined) and that hybridized to DNA beginning at codon 10 within the slp structural gene (Figure 1(a)). The amplified fragment was digested with EcoIRI + SmaI and the 320 bp EcoRI-SmaI fragment purified from a 1% agarose gel and ligated into the EcoRI-SmaI sites of plasmid pMC1403 [29], fusing the first 10 codons of the slp structural gene in frame with the 8th codon of the lacZ gene in pMC1403. The fusion was verified by DNA sequence analysis at the DNA Core Facility of the University of Iowa. The intermediate plasmid was designated pslp::lacZ. A 5,771 bp EcoRI-MfeI fragment from pslp::lacZ carrying the slp::lacZ fusion and lacYA genes was then ligated into the EcoRI site of phage λgt2 [30]. The phage was used to lysogenize appropriate E. coli host strains as described previously [31]. Each lysogen was tested to ensure that it carried a single copy of the λ chromosome by infection with λcI90c17 [32]. All lysogens were grown at 30°C, since all fusion phage carry the λcI857 mutation, resulting in a temperature sensitive λcI repressor [30].

(a)

(b)

Figure 1

The slp control region sequence. (a) slp. The promoter −35 and −10 sequences, the +1 transcription initiation site, Shine-Dalgarno (SD) sequence, and translation start codon are underlined [25]. The translation fusion point at codon 10 of slp with codon 8 of lacZ is indicated with an arrow. The upstream fusion site occurs 288 bps upstream of the transcription start site (not shown). (b) Comparison of GcvB between nts +125 and +177 with slp mRNA. The AUG translation initiation site and SD sequence for slp are indicated above the sequence. Complementarity between GcvB and slp mRNA is indicated with lines between the sequences and GU bps with dots. Separate changes made to gcvB [15] are indicated below the sequence and are color coded.

2.2. Media

The rich medium used was Luria-Bertani broth (LB) [33]. The defined medium used was Vogel and Bonner minimal salts [34] supplemented with 0.4% glucose (GM). GM medium was always supplemented with phenylalanine, glycine, and thiamine, since all strains carry the pheA905 and thi mutations and glycine induces gcvB expression [10]. Agar was added at 1.5% for solid media. Supplements were added at the following concentrations (μg mL⁻¹): phenylalanine, 50; glycine, 300; thiamine, 1; chloramphenicol (CM), 3; ampicillin (AP), 50 for single-copy plasmids and 150 for multicopy plasmids.

2.3. Enzyme Assays

β-galactosidase assays were performed on cultures harvested at midlog phase of growth (OD₆₀₀ ~ 0.5) using the chloroform/SDS lysis procedure [33]. Results are the averages of two or more assays with each sample done in triplicate.

2.4. CM Sensitivity Assay

CM sensitivity was tested by the agar disk diffusion method. Cells were grown overnight, and ~5 cells spread on Mueller-Hinton plates. CM disks (disk potency, 30 μg CM) were added to each plate and zones of inhibition measured after 18 hours incubation at 30°C. A total of eight measurements were made for each strain tested. Results were analyzed using the Student’s -test.

2.5. RNA Isolation and RT-PCR

Strains GS162 (WT), GS1144 (ΔgcvB), GS1144 [pGS594] , and GS1149 (ΔgcvBΔhfq) were grown in 5 mL LB to an OD₆₀₀ ~ 0.5. RNA was isolated from cell pellets by phenol extraction [35]. RNA samples were DNase I treated for 1 hour at 37°C, isolated by phenol/chloroform extraction, ethanol precipitated, and the RNA pellets resuspended in 30 μL of DEPC treated water. RNA was quantified using a NanoDrop ND-1000 Spectrophotometer. The Access RT-PCR kit (Promega, Madison, WI) was used with 0.5 μg of total cell RNA isolated from each sample in a 25 μL reaction. The slp primers were (sense primer) slp-RT 5′-CTCAGCCTTTCATTTTTGCTTGCC and (antisense primer) slp-RT 5′-CTGACTCACCGCATTGGTGTAG. The ompT control primers were (sense primer) ompT-RT 5′-GCTTCTACCGAGACTTTATCG and (antisense primer) ompT-RT 5′-GCTGTAGTCTGAAGTGTTATTATTG. The PCR fragment for slp was 515 bp and for ompT was 830 bp. Cycling conditions were 45°C for 45 minutes, 94°C for 2 minutes, 20 cycles of 94°C for 30 seconds, 49°C for 30 seconds, and 68°C for 2 minutes followed by 1 cycle of 68°C for 7 minutes. PCR products were run on 2% agarose gels and stained with ethidium bromide.

2.6. DNA Manipulation

Plasmid DNA was isolated using a QIAprep Spin Miniprep Kit (Qiagen, Santa Clara, CA). Vent DNA polymerase, restriction enzymes, and DNA ligase were from New England Biolabs, Inc. (Beverly, MA), and reactions were as described by the manufacturer.

3. Results

3.1. The slp Gene Is a Target for GcvB and Hfq Regulations

Microarray analysis of RNA isolated from an E. coli WT strain and an otherwise isogenic ΔgcvB strain grown in LB suggested that Slp, an outer membrane lipoprotein of unknown function [25], is negatively regulated by GcvB [15]. To confirm the microarray analysis that slp is regulated by GcvB, we carried out RT-PCR. WT strain GS162, the ΔgcvB strain GS1144, and GS1144 transformed with the single-copy plasmid pGS594 carrying WT gcvB () were grown in LB at 30°C to midlog phase of growth (OD₆₀₀ ~ 0.5) and total cellular RNA isolated. Samples of 0.5 μg of RNA from each culture were used in an RT-PCR assay. We observed an increased level of DNA corresponding to the slp mRNA amplified from the ΔgcvB sample compared to the level of DNA amplified from either the WT or ΔgcvB complemented strain (Figure 2, compare lane 3 with lanes 2 and 4). The results agree with the microarray analysis indicating that GcvB negatively regulates slp mRNA levels in cells grown in LB. As a control, we added primers to the RT-PCR reactions to amplify ompT mRNA; ompT was not identified by microarray analysis to be regulated by GcvB. We observed roughly the same levels of amplified DNA corresponding to the ompT mRNA from each strain (Figure 2). These data confirm that GcvB does not regulate ompT mRNA levels in LB and that the increased slp mRNA levels observed in the ΔgcvB strain are due to the absence of GcvB.

Figure 2

slp and ompT mRNA levels from WT (GS162), ΔgcvB (GS1144), complemented (GS1144 [pGS594]), and GS1149 (ΔgcvBΔhfq) strains. The levels of slp and ompT mRNAs were determined by semiquantitative RT-PCR. Each reaction had 0.5 μg of total cellular RNA added for the RT reaction with 20 PCR cycles. The amplification product for slp was predicted to be 515 bps, and the amplification product for ompT was predicted to be 830 bps. When reverse transcriptase was omitted from the reactions, there was no product, indicating that no DNA was present in the RNA samples (data not shown).

3.2. Regulation of slp::lacZ in LB

To confirm that GcvB negatively regulates slp, we constructed a slp::lacZ translational fusion (Figure 1(a)). The fusion was cloned onto phage λgt2, and the fusion phage used to lysogenize the WT strain GS162 and the ΔgcvB mutant strain GS1144. The lysogens were grown in LB to midlog phase of growth (OD₆₀₀ ~ 0.5), and the cultures assayed for β-galactosidase activity. Expression of the slp::lacZ fusion in the WT lysogen was about 2-fold lower than in the ΔgcvB lysogen (Figure 3(a), lanes 1 and 2). Transformation of the WT lysogen with plasmid pGS594, a single-copy plasmid carrying WT gcvB, reproducibly reduced slp::lacZ expression compared to the nontransformed WT strain (Figure 3(a), compare lanes 1 and 5). Transformation of the ΔgcvB lysogen with pGS594, however, only partially restored the level of expression to that of the WT lysogen (Figure 3(a), compare lanes 1, 2 and 6). It is unknown why the single-copy plasmid failed to fully complement the ΔgcvB mutation. These results, however, support the microarray assay and RT-PCR data that GcvB has a negative role in slp expression.

(a)

(b)

Figure 3

β-Galactosidase levels of λ slp::lacZ lysogens. (a) WT (GS162), ΔgcvB (GS1144), Δhfq (GS1148), and ΔgcvBΔhfq (GS1149) λ slp::lacZ lysogens and the same lysogens transformed with the indicated plasmids were grown in LB (+ AP for complemented strains) to midlog phase of growth (OD₆₀₀ ~ 0.5) and assayed for β-galactosidase activity. (b) WT (GS162), ΔgcvB (GS1144), Δhfq (GS1148), and ΔgcvΔhfq (GS1149) λ slp::lacZ lysogens or the same lysogens transformed with the indicated plasmids were grown in GM + glycine (+ AP for complemented strains) to midlog phase of growth (OD₆₀₀~ 0.5) and assayed for β-galactosidase activity. Results are averages of two independent assays with each assay performed in triplicate.

The Hfq protein is required for regulation by sRNAs that base pair with target mRNAs [6]. Thus, the λslp::lacZ fusion was also used to lysogenize the Δhfq mutant strain GS1148. The lysogen was grown in LB to midlog phase of growth and assayed for β-galactosidase activity. Expression of the slp::lacZ fusion in the Δhfq lysogen was reduced compared to the level in the WT lysogen (Figure 3(a), compare lanes 1 and 3). Transformation of the WT lysogen and the Δhfq lysogen with multicopy plasmid (pGS609) resulted in about a 2-fold increase in slp::lacZ expression compared to the WT lysogen (Figure 3(a), compare lane 1 with lanes 7 and 8). These results suggest that Hfq has a positive role in slp expression.

Two models could explain the pervious results for a positive role of Hfq in slp::lacZ expression. GcvB RNA could directly reduce slp::lacZ expression, and the role of Hfq could be to antagonize this repression. Alternatively, Hfq could act to directly activate slp::lacZ expression, and GcvB could function in some manner to block Hfq activation. To test which model, if either, is correct, we lysogenized the ΔgcvBΔhfq double mutant GS1149 with λslp::lacZ, grew the lysogen in LB to midlog phase of growth, and assayed for β-galactosidase activity. We hypothesized that if the role of Hfq is merely to prevent GcvB repression, then slp::lacZ expression should be high in the double mutant without GcvB, whereas if GcvB functions to block Hfq activation, then slp::lacZ expression should be low in the double mutant without Hfq. Expression of slp::lacZ was reduced in the double mutant compared to WT (Figure 3(a), compare lanes 1 and 4). The results suggest that Hfq is required to elevate slp::lacZ expression.

Two additional experiments support a positive role for Hfq in slp::lacZ expression. If GcvB directly represses slp::lacZ rather than antagonize Hfq activation, we hypothesized that high levels of GcvB would superrepress slp::lacZ in the absence of Hfq. We transformed the Δhfq lysogen with plasmids (pGS594), (pGS554), and (pGS571). is a single-copy plasmid that expresses gcvB from the native gcvB promoter, is a single-copy plasmid that constitutively expresses gcvB [10], and is a multicopy plasmid that overexpresses gcvB [13]. Expression of slp::lacZ in the three transformants was only slightly lower than in the WT lysogen (Figure 3(a), compare lane 1 with lanes 9, 10, and 11). The results suggest that GcvB’s role is not to directly repress slp::lacZ.

We then transformed the ΔgcvB and ΔgcvBΔhfq lysogens with multi-copy plasmid (pGS609) carrying WT hfq. If Hfq is a positive regulator of slp::lacZ, and GcvB functions to block Hfq activation, then slp::lacZ should be overexpressed in the presence of high levels of Hfq and in the absence of GcvB. Expression of slp::lacZ was more than 4-fold higher in the transformants than in the WT lysogen (Figure 3(a), compare lane 1 with lanes 12 and 13). The results are in agreement with Hfq positively regulating slp::lacZ, and the role of GcvB is to prevent activation by Hfq. Whether Hfq directly interacts with slp mRNA to increase stability or to increase translation is unknown, Hfq has been shown to be able to act alone as a translational repressor of mRNA [36, 37]. Thus, it is possible that Hfq alone could bind slp mRNA to increase expression. We have purified Hfq and are in the process of making slp mRNA and GcvB RNA to run in vitro gel mobility shift experiments to test whether Hfq binds slp mRNA and determine if GcvB competes with this binding. Also, Hfq could interact with an additional sRNA to regulate slp mRNA levels. We used the TargetRNA program [38] to search the E. coli chromosome for a possible sRNA that could base pair with the slp mRNA, but found no significant matches. However, if small or noncontiguous sequences are involved in the sRNA/slp mRNA interaction, the identification of this putative sRNA could have been missed in the search.

Many E. coli sRNAs that use base pairing to regulate gene expression require Hfq [6]. It was shown previously that GcvB repression of oppA, dppA, cycA, and sstT mRNAs is Hfq-dependent [11, 14, 15], and it is known that GcvB interacts with Hfq [39]. The same results were reported for S. typhimurium [19]. If the role of GcvB in slp regulation is to bind Hfq and prevent Hfq activation of slp, we predicted that in a ΔgcvBΔhfq mutant, there would not be a significant increase in slp mRNA levels. We carried out RT-PCR on total RNA isolated from the ΔgcvBΔhfq strain GS1149 grown in LB at 30°C to midlog phase of growth (OD₆₀₀ ~ 0.5). As expected, we did not observe an increased level of DNA corresponding to slp mRNA amplified from the ΔgcvBΔhfq sample and possibly a decreased level, compared to the level of DNA amplified from the WT strain (Figure 2, compare lanes 2 and 5). We will use qRT-PCR to test if there is less slp mRNA in the ΔgcvBΔhfq strain compared to the WT. The results, however, are in agreement with the β-galactosidase assays (Figure 3(a)) suggesting that Hfq is required for increased slp expression in LB.

3.3. Regulation of slp::lacZ in GM + Glycine Medium

Significant repression of dppA::lacZ, oppA::phoA, and cycA::lacZ fusions by GcvB was only observed in WT lysogens grown in LB, with little or no repression seen when the lysogens were grown in GM + glycine [10, 15]. Repression of an sstT::lacZ fusion by GcvB in a WT lysogen grown in LB was ~12-fold, and repression of the WT lysogen in GM + glycine was ~2-fold [14]. Because the gcvB gene is regulated over a 25-fold range in GM media [10], we tested if GcvB and Hfq are able to regulate slp::lacZ in GM medium. The lysogens used previously were grown in GM + glycine to midlog phase of growth (OD₆₀₀ ~ 0.5) and assayed for β-galactosidase activity. Expression of slp::lacZ in WT was ~7-fold higher in GM + glycine compared to LB grown cells (Figures 3(a) and 3(b)). In addition, β-galactosidase levels in the WT lysogen were about 2-fold lower compared to the ΔgcvB lysogen (Figure 3(b), lanes 1 and 2). Transformation of the WT lysogen with the single-copy plasmid consistently reduced slp::lacZ expression compared to the nontransformed WT lysogen (Figure 3(b), compare lanes 1 and 5). Transformation of the ΔgcvB lysogen with reduced slp::lacZ expression, although full complementation was not observed (Figure 3(b), compare lanes 2 and 6). The results suggest that GcvB has a negative role in slp::lacZ expression in cells grown in GM + glycine as well as in LB.

Expression of slp::lacZ in the Δhfq lysogen was consistently lower than in the WT lysogen (Figure 3(b), lanes 1 and 3). Transformation of the Δhfq lysogen with multicopy restored slp::lacZ expression to slightly higher levels than in the WT lysogen (Figure 3(b), compare lanes 1 and 7). The results suggest Hfq is required for normal slp::lacZ expression in GM + glycine. However, expression of slp::lacZ in the ΔgcvBΔhfq double mutant was 2-fold higher than in the WT lysogen (Figure 3(b), compare lanes 1 and 4). This is opposite of the result observed in LB (Figure 3(a), lanes 1 and 4) and suggests that GcvB and Hfq have different roles in GM + glycine compared to LB.

One model to explain the previous results is that GcvB negatively regulates slp::lacZ in GM + glycine, and the role of Hfq is to block GcvB repression rather than to activate slp::lacZ expression as in LB. To test this hypothesis, the Δhfq lysogen was transformed with plasmids (pGS594), (pGS554), and (pGS571), the transformants grown in GM + glycine to midlog phase of growth (OD₆₀₀ ~ 0.5) and assayed for β-galactosidase activity. We hypothesized that high levels of GcvB would superrepress slp::lacZ in the absence of Hfq. Expression of slp::lacZ in the transformants was reduced significantly compared to the WT lysogen (Figure 3(b), compare lane 1 with lanes 8–10). The results suggest that GcvB does negatively regulate slp::lacZ levels in GM + glycine, and the role of Hfq is likely to prevent GcvB repression.

3.4. The slp Leader Sequence

Most sRNAs affect translation of target mRNA molecules, although the precise mechanism(s) remain(s) unknown. Thus, it makes sense that sRNAs with either known or predicted targets base pair to the 5′-untranslated region near or overlapping the translation initiation site (e.g., RyhB/sodB mRNA, DsrA/rpoS mRNA) [8, 24]. In addition, these target mRNAs usually have long 5′ untranslated regions that normally can fold into distinct secondary structures. The slp mRNA has a short untranslated region of 25 nts [25]. This sequence, including the first 20 nts of the coding region, does not fold into any distinct secondary structure by the mfold program [40, 41]. A comparison of the slp mRNA to GcvB RNA did not identify any region of significant complementarity between the two RNAs. However, small noncontiguous regions of complementarity between the two RNAs around the slp translation start codon and nts +125 to +177 of GcvB were identified (Figure 1(b)). Thus it is possible that GcvB/mRNA pairing is part of the mechanism employed by GcvB for negative regulation of slp mRNA in GM + glycine. Previously, we mutated nucleotides in GcvB predicted to disrupt base pairing with cycA mRNA [15]. Since these mutations also disrupt putative base pairing of GcvB with slp mRNA, we determined if there was an effect of the mutations on slp::lacZ expression. We transformed the ΔgcvBλslp::lacZ lysogen with single-copy plasmids carrying WT gcvB or various mutations in gcvB between nts +125 and +177 that disrupt complementarity between GcvB and slp mRNA (Figure 1(b)). The strains were grown in GM + glycine (+ AP for the complemented strains) to midlog phase of growth (OD₆₀₀ ~ 0.5) and assayed for β-galactosidase activity. However, none of the gcvB mutations predicted to alter base pairing between GcvB and slp::lacZ mRNA altered expression of slp::lacZ compared to WT GcvB (data not shown). Recently it was shown that a high degree of redundancy exists in the E. coli and S. enterica GcvBs [20, 22]. Thus, it is possible that more extensive changes are required to prevent GcvB repression or a few critical base pairing interactions necessary for repression were not changed in the mutational analysis. It is also possible that GcvB does not regulate slp::lacZ directly in GM + glycine media but regulates an additional factor necessary for repression.

3.5. GcvB Does Not Regulate slp Indirectly by Altering marR Expression

The E. coli marRAB multiple antibiotic resistance operon encodes two regulatory proteins. The marR gene encodes a repressor for the marRAB operon, and the marA gene encodes a transcriptional activator of genes in the Mar regulon [42, 43]. The operon is normally repressed by MarR and is induced by compounds such as tetracycline, CM, menadione, and salicylates, leading to increased antibiotic resistance [44, 45]. Expression of the slp gene is downregulated by the Mar system [27, 28]. If GcvB alters expression of the marRAB operon, it could regulate slp expression indirectly by altering MarRAB levels. The marRAB mRNA levels were not altered by the presence or absence of GcvB in a microarray analysis [15] or by the presence or absence of Hfq by microarray analysis [46]. Nevertheless, we constructed a marR::lacZ translational fusion to verify that the levels of the MarR gene product are not altered by GcvB. The λmarR::lacZ fusion was used to lysogenize WT strain GS162, ΔgcvB strain GS1144, and Δhfq strain GS1148. The ΔgcvB and Δhfq lysogens were then transformed with (pGS594) and (pGS609), respectively. The strains were grown in LB (+ AP for the transformants) and in GM + glycine (+ AP for the transformants) to midlog phase of growth (OD₆₀₀ ~ 0.5) and assayed for β-galactosidase activity. GcvB and Hfq had no significant effect on marR::lacZ expression in LB or in GM + glycine medium (data not shown). The results suggest that GcvB regulates the slp::lacZ fusion by a mechanism that is independent of the Mar regulatory system.

3.6. Effects of GcvB Levels on CM Resistance

In addition to expression of slp being downregulated by the Mar system [27, 28], a null slp mutant showed a modest increase in CM resistance and a strain that overproduced Slp was more sensitive to CM [26]. We hypothesized that a ΔgcvB strain that overproduces Slp would be more sensitive to CM than a WT strain, and a strain carrying multicopy plasmid that overproduces GcvB RNA would produce less Slp and be more resistant to CM. We tested the effect of CM on growth of WT (GS162), ΔgcvAΔgcvB (GS1132), and WT transformed with plasmid (pGS571). We used the ΔgcvAΔgcvB strain since it carries a spectinomycin resistance cassette, whereas the ΔgcvB strain (GS1144) carries a CM resistance cassette. We showed previously that dppA::lacZ and oppA::phoA fusions are regulated similarly in a ΔgcvB strain and a ΔgcvAΔgcvB strain [12]. In an agar diffusion disk assay, the ΔgcvAΔgcvB strain showed a modest but statistically significant increase in CM sensitivity, and the WT () strain showed a modest but statistically significant decrease in CM sensitivity relative to the WT strain (Table 2). Because the changes were small, we also tested the previous strains in a growth experiment. The generation times (GTs) of the 3 strains in LB were essentially the same (Table 2). Thus, neither the ΔgcvAΔgcvB allele nor plasmid had any significant effect on growth rate. The presence of 3 μg mL⁻¹ CM added to LB significantly increased the GTs of all 3 strains. In addition, we saw a consistent increase in the GT of the ΔgcvAΔgcvB strain relative to WT and a consistent decrease in the GT of WT () compared to the WT strain (Table 2). Although the differences in generation times are modest, in conjunction with the results from the diffusion disk assay, suggest that negative regulation of Slp levels by GcvB alters the sensitivity to CM.

4. Discussion

In both E. coli and S. enterica, genes shown to be regulated directly by GcvB are controlled by an antisense mechanism, and many are involved in the transport of amino acids and small peptides [10, 11, 14, 19, 20]. Since GcvB is only expressed in log-phase cells when nutrients are plentiful [12, 19], it likely controls the uptake of amino acids, peptides, and small toxic molecules under this condition to optimize cell growth. The slp gene encodes an outer membrane protein of unknown function [25]. Thus, Slp possibly does not fit the typical class of target genes controlled by GcvB. The localization of Slp in the outer membrane suggests a potential role in protecting stationary phase cells from environmental stress or facilitating nutrient availability in the periplasm. Since GcvB is not detected in stationary phase cells [12, 19], our results suggest that the role of GcvB is to keep Slp levels low in exponentially growing cells. The disappearance of GcvB in stationary phase would allow a more rapid induction of slp expression.

In LB grown cells, the mechanism of regulation of slp::lacZ by GcvB appears to be by sequestration of Hfq, which is required for full expression of slp::lacZ, rather than by an antisense mechanism (Figure 3(a)). In GM + glycine, however, GcvB negatively regulates slp::lacZ, and the role of Hfq appears to be to block repression by GcvB (Figure 3(b)). The ability of GcvB to repress slp::lacZ expression in the absence of Hfq suggests that GcvB might function alone or with a different chaperone to regulate this system. In Staphylococcus aureus, RNAIII functions to repress the synthesis of virulence factors without a requirement for Hfq, suggesting another protein chaperone [47, 48]. If GcvB regulates slp expression in GM + glycine without Hfq, it possibly does so in a way that is mechanistically different from the way it regulates other known target mRNAs [11, 12, 14, 15, 18, 20]. Verification of this model for regulation of slp would demonstrate that GcvB is a more versatile regulatory RNA than previously thought.

Acknowledgments

This work was supported by the Vice President for Research of the Carver College of Medicine and the Department of Microbiology of the University of Iowa.

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Copyright © 2013 Lorraine T. Stauffer and George V. Stauffer. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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