SUMMARY
Enterohemorrhagic Escherichia coli (EHEC) employs a type III secretion system (T3SS) to export translocator and effector proteins required for mucosal colonization. The T3SS is encoded in a pathogenicity island called the locus of enterocyte effacement (LEE) that is organized in five major operons, LEE1 to LEE5. LEE4 encodes a regulator of secretion (SepL), translocators (EspA, D and B), two chaperones (CesD2 and L0017), a T3SS component (EscF), and an effector protein (EspF). It was originally proposed that the esp transcript is transcribed from a promoter located at the end of sepL but other authors suggested that this transcript is the result of a post-transcriptional processing event. In this study, we established that the espADB mRNA is generated by post-transcriptional processing at the end of the sepL coding sequence. RNase E is the endonuclease involved in the cleavage, but the interaction of this enzyme with other proteins through its C-terminal half is dispensable. A putative transcription termination event in the cesD2 coding region would generate the 3’ end of the transcript. Similar to what has been described for other processed transcripts, the cleavage of LEE4 seems a mechanism to differentially regulate SepL and Esp protein production.
Keywords: enterohemorrhagic Escherichia coli, LEE4, RNase E, type III secretion system, espA, sepL
INTRODUCTION
Enterohemorrhagic Escherichia coli (EHEC) O157:H7 is a causative agent of bloody diarrhea, non-bloody diarrhea and haemolytic uremic syndrome (HUS) in humans. EHEC causes an ‘attaching and effacing’ (A/E) lesion characterized by localized destruction of brush border microvilli, intimate attachment to the eukaryotic cell membrane, and formation of a pedestal-like structure in the host cell. Most EHEC strains contain a ca. 43-kb pathogenicity island called the locus of enterocyte effacement (LEE), which encodes many of the virulence proteins necessary for the A/E phenotype (McDaniel et al., 1995; Perna et al., 1998). Other pathogens including enteropathogenic E. coli (EPEC), Citrobacter rodentium, and rabbit EPEC also contain LEE and are able to cause the A/E lesion (for reviews see Nataro and Kaper, 1998; Kaper et al., 2004).
LEE is organized into five major operons, LEE1 to LEE5, encoding a type III secretion system (T3SS), secreted proteins, chaperones, and regulators. The secreted proteins consist of effectors that are translocated into the host cell by the T3SS, and translocators required for delivering the effectors. LEE4 encodes the translocators EspA, EspB and EspD, a chaperone for EspD (CesD2) (Neves at al., 2003), the effector protein EspF (Nougayrède and Donnenberg, 2004; Guttman et al., 2006), a chaperone for EspA (L0017 or Orf29) (Su et al., 2008), and a component of the T3SS (EscF) (Figure 1A). EspA is polymerized to form a large filamentous structure extending from the bacterial surface by as much as 600 nm that connects the bacterium to the host cell membrane (Knutton et al., 1998; Sekiya et al., 2001; Shaw et al., 2001). The three dimentional structure of the EspA filament reveals a hollow tube forming an extension of the T3SS needle complex that is presumably composed of EscF (Wilson et al., 2001; Daniell et al., 2003). EspD is essential for the elaboration of mature EspA filaments and is thought to form a pore in the host cell membrane through which the effector proteins are translocated (Daniell et al., 2001; Kresse et al., 1999). EspB interacts with EspD (Ide et al., 2001) helping in pore formation (Luo and Donnenberg, 2006), and is also an effector protein that binds myosins in the eukaryotic cell facilitating microvillus lesions and evasion of phagocytosis (Iizumi et al., 2007).
SepL is a non-secreted protein encoded upstream of the espA gene, and shares more than 90% identity among the different A/E pathogens. A sepL mutant shows highly reduced or undetectable secretion of translocator proteins, increased secretion of effector proteins, and is unable to form EspA filaments and A/E lesions (Kresse et al., 2000; O’Connell et al., 2004; Deng et al., 2005). SepL interacts with SepD, another component of the T3SS, probably forming a molecular switch to control the secretion of translocators and effectors by the T3SS (Deng et al., 2005). Recently, SepL was found to bind the effector protein Tir, preventing its secretion until the translocator components are exported (Wang et al., 2008). How the binding of SepL to SepD, Tir, and possibly to other proteins, regulates the kinetics of secretion of translocators and effectors is not currently understood.
In EHEC, espADB is proposed to be transcribed from a promoter (‘esp’) located at the end of the sepL coding region whereas sepL is transcribed independently (Beltrametti et al. 1999; Kresse at al., 2000; Sharma and Zuener, 2004). However, in EPEC sepL is cotranscribed with the other genes of LEE4 (Mellies et al., 1999). Experiments with chromosomal lacZ transcriptional fusions to the proposed ‘esp’ promoter failed to detect promoter activity in several different EHEC strains (Roe et al., 2003). In the same study, a transcript of 3 kb was detected with probes for espA and espD by Northern blot. These authors proposed that a promoter upstream of sepL drives the transcription of LEE4, and a post-transcriptional processing of this primary transcript generates the espADB mRNA.
In this study we define how the espADB mRNA is generated using a variety of techniques including reverse transcription (RT) -PCR, Northern Blot, Ribonuclease Protection Assay (RPA) and 5’ and 3’ Rapid Amplification of cDNA Ends (RACE). We show that sepL is part of the LEE4 operon, and that a post-transcriptional processing of the LEE4 transcript generates the espADB mRNA. The processing of LEE4 occurs in an E. coli K-12 background as well, and the endonuclease RNase E, which has a central role in RNA metabolism in participating in the degradation, processing and maturation of a variety of RNA molecules, is involved in the cleavage. This post-transcriptional processing of the LEE4 transcript has important implications in SepL and EspADB gene expression.
RESULTS
Genes of the LEE4 operon are cotranscribed
We used RT-PCR to determine whether sepL and the genes of the LEE4 operon are part of the same transcriptional unit. EHEC strain Sakai was grown in DMEM and LB media and cells were collected for RNA extraction. cDNA was synthesized, and amplified using a forward primer located at the end of sepL and a reverse primer located at the beginning of espF, the first and final genes in LEE4 (Fig 1A and Table I). The expected size of the PCR product was 4,113 bp, and a PCR product of approximately this size was obtained from all cDNA samples analyzed (Fig 1B, lanes (+)) consistent with the transcription process including the entire LEE4 operon. The expected size of the entire LEE4 transcript is approximately 5.7 kb considering the position of the sepL promoter reported previously (Kresse et al., 2000). However, Northern blot analysis using a probe for espA, revealed a major transcript of approximately 3 kb and two shorter transcripts of approximately 2.8 kb and 1.4 kb (Fig 1C). To gain further insight into the mechanism that generates the major esp transcript, we studied the sepL-espA intergenic region by RPA.
TABLE I.
Name | Directiona | Sequence 5’ to 3’ |
---|---|---|
fLF | F | tccttctcgggtatcgattg |
rLF | R | tcgcattaacattcgacgag |
F-T3LEE4b | F | aattaaccctcactaaagggaagtatgtcacgagtgcgatccttctcgggtatcgattg |
R-T7LEE4c | R | taatacgactcactataggctgaatcgtatgaatcggaaccacctcatccttcgaca |
F-T3LEE4b | F | aattaaccctcactaaagggaagtatgtcacgagtgcgacacttgataactatgcagatat |
R-T7LEE4c | R | taatacgactcactataggctgaatcgtatgaatcgggtatccatctatatacctcttg |
oligo-sepL | F | gggtatcgattgtcgaagataaacata |
oligo-espA | F | gatctatgacttaggtaatatgtcgaag |
roEspA | R | gcttaaatcaccactaagatcacga |
riEspA | R | ttgtgccgtggttgacgctttagat |
f3’RACE | F | gaccagtcttgctgaaggtacga |
fespA | F | gctgatgttcagagtagcactg |
respA | R | gaacgtgcactcgttaagag |
frne-sd | F | caccggtagctatctggttctgatg |
rrne-s | R | gtgaggttaacggtgattatgt |
fdel-rne-s | F | ggtaaaggtgccgcaggtggt |
rdel-rne-s | R | atcagacgcagaatagagag |
f-rrnBe | F | agtagggatccgccaggcat |
r-rrnBf | R | ggcagtgcccgcaaggcaatta |
fΔsepL | F | aggaggaaattatttgatatta |
rΔsepL | R | gagaaggactctccagcaac |
fsep-esp | F | aatggctaatggtattgaattt |
rsep-esp | R | taattaaattcggccactaaca |
fsep-esp2 | F | atggctaatggtattgaatttaa |
BamHI-LEE4-2g | R | taaggatcctaattaaattcggccactaaca |
RACE-S20-r | R | agcttcagcaaattggcaattaagc |
F, forward; R, reverse
The sequence of the T3 promoter is underlined. A non-homologous sequence is in italics.
The sequence of the T7 promoter is underlined. A non-homologous sequence is in italics.
The first 4 nucleotides (underlined) were added for directional cloning into pENTR/SD/D-TOPO.
BamHI restriction site is underlined.
BglI restriction site is underlined.
Heterogeneous population of transcripts for esp genes
To analyze the transcripts in the sepL-espA intergenic region by RPA, a RNA probe was designed that spans the 3’ end of sepL, the intergenic region, and the 5’ end of espA (probe 1, Fig. 2A). A protected fragment of 326 bases would be generated if the probe hybridizes to a complementary transcript including the entire protected region. In addition, shorter protected fragments would be expected if transcripts initiate, terminate or are cleaved within this region. Sakai was grown in DMEM and cells were collected at different OD600 readings for RNA extraction and RPA (Fig. 2B). A protected fragment of about 320 bases and several shorter protected fragments were detected (Fig. 2C, lanes ‘T2’, ‘T3’ and ‘T4’). The highest level of expression was at the end of the exponential or beginning of stationary phase, and diminished in stationary phase to undetectable levels under these experimental conditions (Fig. 2C, lane ‘T7’) which is consistent with the Northern Blot analysis (Fig. 1C). In a previous study, quantification of espA mRNAs by real-time RT-PCR showed increasing levels from early to late exponential phase, but levels in stationary phase were not reported (Walters and Sperandio, 2006). In addition, the proportion of cells expressing EspA filaments in a bacterial population increased during the exponential phase, but then dropped off rapidly as the bacteria entered the stationary phase (Roe et al., 2003).
An RPA using yeast RNA as substrate did not yield protected fragments indicating that the hybridization was specific to the sepL-espA region (Fig. 2C, lane ‘- control’, also see Fig. 5A for other negative controls). As an additional control, the complementary strand of probe 1, which is the sense strand, was transcribed in vitro and used as a substrate in an RPA instead of total RNA. In this case, the fragment corresponding to the entire sepL-espA protected region but none of the smaller protected fragments (Fig. 2C, lane ‘control B’) was detected, indicating the smaller fragments are due to mRNA differences and not to an RPA technical problem. RPAs performed with RNA extracted from EHEC strains EDL933 and 86-24 showed the same pattern of protected fragments (Fig. 2D).
The smaller protected fragments could include the 5’ ends of ‘esp’ transcripts but also the 3’ end of sepL transcripts which could be generated by endonucleolytic cleavage or transcription termination. To discriminate between these possibilities, we designed the following assay. Duplicate RNA samples were subjected to RPA as described before but with unlabeled probe 1. Then, the protected RNA fragments were transferred and fixed to a membrane, and two separate hybridizations were done with two 5’-end labeled DNA oligomers complementary to sepL and espA, respectively (Fig. 2A). The small fragments hybridized to espA and not to sepL oligomer (Fig. 3), indicating a population of espADB transcripts with heterogeneous 5’ ends resulting from transcription initiation or endonucleolytic cleavage.
5’ ends of esp transcripts are mono-phosphorylated
Primary transcripts can be discriminated from processed transcripts on the basis of the phosphorylation state of their 5’ ends, triphosphorylated or monophosphorylated, respectively. Briefly, total RNA was treated with specific phosphatases to modify the 5’ ends, then the monophosphorylated 5’ ends were ligated to an RNA adapter and subjected to 5’ RNA Ligase Mediated Rapid Amplification of cDNA Ends (RLM-RACE) (Bensing et al., 1996; Sawers, 2005; and see Experimental Procedures). When RLM-RACE is done with an RNA sample untreated with phophatases, only processed transcripts can yield a PCR product whereas transcripts with tri-phosphorylated 5’ ends cannot be ligated to the RNA adapter and detected. The same pattern of PCR products was obtained from an RNA sample treated to detect primary and processed transcripts, and from an RNA sample that was untreated with phosphatases (Fig. 4A, compare lanes 1 and 2 with lanes 7 and 8). This result suggests that the ‘esp’ transcripts are generated by endonucleolytic cleavage and not transcription initiation. We observed faint products from the sample treated to detect only primary transcripts (Fig. 4A, lanes 3 and 4) that might be due to inefficient monophosphate removal (see Experimental Procedures). Even though pyrophosphate can be removed from the 5’ ends of primary transcripts (Deana et al, 2008), these transcripts should have been detected by RLM-RACE because only a fraction of the population is converted to a monophosphorylated form (Celesnik et al., 2007). To determine the exact 5’ end of the ‘esp’ transcripts the PCR products were cloned and sequenced. Several 5’ ends were located in a region including ca. 90 nucleotides upstream of the sepL stop codon (Fig. 4B).
RNAse E is involved in the endonucleolytic processing of LEE4
The processed region, including the intergenic sepL-espA region, is 72% A + T rich, which suggested that RNase E could be a good candidate for LEE4 processing because it cleaves preferentially in A+T rich sequences with no defined consensus sequence (McDowall et al., 1994). RNase E is a large enzyme of 1,061 amino acids that is essential for cell viability (Goldblum and Apririon, 1981; Taraseviciene et al., 1995; Kido et al., 1996). The conditionally lethal rne-3071 mutation is a C→T transition at position 742 that causes phenylalanine to be substituted for leucine and makes RNase E thermosensitive (ts) (Apirion, 1978; McDowall et al., 1993). We examined the role of RNase E in LEE4 processing using an E. coli K-12 rne-3071 strain N3431 and an isogenic rne+ strain N3433. For this purpose, sepL-espADB genes were cloned in the plasmid pACYC184 under the control of the tet promoter, replacing the tetracycline resistance gene (see Experimental Procedures). This plasmid, pPL1, was introduced into E. coli MG1655, N3431 and N3433 and analyzed for LEE4 processing with probe 1. Figure 5A shows that the pattern of bands seen in EHEC is also obtained with E. coli K-12 (pPL1) (compare lanes 1, with lanes 2, 3, 5 and 6). In contrast, when these strains were transformed with the vector only, no protected fragments were obtained (Fig. 5A, lanes 4 and 7). Next, the endonucleolytic processing was evaluated in E. coli N3431 and N3433 at the restrictive temperature. LB cultures from both strains transformed with pPL1 were grown up to the end of the exponential phase at 35°C, and then switched to 43°C. Samples were taken at different times after the temperature shift; RNA was extracted and analyzed by RPA with probe 1. At the restrictive temperature the processing was observed in the rne+ strain whereas processing was greatly reduced in the rne-3071 strain (Fig 5B) indicating that RNase E is required for the cleavage of the LEE4 transcript to generate the espADB mRNA products. An increased concentration of the transcripts was observed after the temperature shift in both rne+ and rne-3071 strains that was unrelated to the endonucleolytic processing being studied. This effect might be due to increased transcription from the vector promoter or an increased plasmid copy number at 43°C, among other possibilities.
The C-terminal domain of RNase E is not required for LEE4 cleavage
While the N terminus of RNAse E is essential for viability, the C terminal domain, which organizes a multiprotein complex called RNA degradosome, is not essential for cell viability (Taraseviciene et al., 1995; Kido et al., 1996). In addition to RNase E, the degradosome is composed of the exonuclease PNPase, the helicase RhlB, and the glycolytic enzyme enolase (for reviews see Marcaida et al., 2006; Carpousis, 2007).
An alignment of RNase E from EHEC and E. coli MG1655 shows 14 amino acid changes that are mostly conservative and located in the C-terminal half (Fig. 6A). To determine whether the interaction of RNase E with other proteins was required for LEE4 transcript cleavage, we constructed a derivative of the Sakai strain in which the 3’ end of rne gene was deleted. This mutant RNase E consists of 426 N-terminal amino acids including the domain sufficient for ribonuclease activity (Caruthers et al., 2006), plus 28 additional amino acids due to a frameshift mutation introduced with the deletion (Fig. 6B). The deletion of the scaffolding region was confirmed by PCR (Fig. 6C). RPA using probe 1 showed that there was no difference in the pattern of RNA protected fragments between the parental strain and the mutant (Fig. 6D), indicating that the degradosome assembly or the interaction of RNase E with other proteins is not required for LEE4 cleavage.
The 5’ product after transcript cleavage is degraded
The 5’ product after endonucleolytic cleavage, which includes the sepL gene, is not detected by RPA with probe 1 (Fig. 3). One possibility is that the 5’ product is rapidly degraded while the 3’ products – espADB mRNAs- are stable. Alternatively, the 5’ product could be undetectable because of inefficient ethanol precipitation in RPA due to its small size. To distinguish between these two possibilities we designed a second probe (probe 2) for RPA. In probe 2, a longer sequence spanned sepL whereas a shorter sequence spanned espA, in comparison with former probe 1 (Fig. 2A). Thus, if the 5’ product after cleavage was as stable as the 3’ product, RPA with probe 2 would give a protected RNA fragment of approximately 235 bases. Figure 7 (lane 4) shows that a fragment of this size was undetectable whereas a protected smaller fragment that corresponds to the 3’ portion of probe 2 was detected. When RNA was hybridized with probe 1, the usual protected fragments were obtained (Fig. 7, lane 3). Therefore, LEE4 is cleaved at the end of the sepL coding region and the 5’ product containing the sepL sequence is efficiently degraded.
The endonucleolytic cleavage diminishes SepL cellular concentration without affecting EspA level
The endonucleolytic cleavage of the LEE4 transcript at the end of the sepL coding sequence could diminish the cellular concentration of SepL without affecting EspA levels. To test this hypothesis, we compared SepL protein levels when expressed from pPL1 and a derivative plasmid, pΔSepL3, which lacks the RNase E processed sequence. Plasmid pΔSepL3 carries an in-frame deletion of 141 nucleotides and would generate a SepL polypeptide with a predicted molecular weight of 36.3 kDa whereas pPL1 would produce a SepL polypeptide of 41.9 kDa. A derivative of EHEC strain EDL933 in which the entire LEE region is deleted (EDL933ΔLEE) (Pósfai et al., 1997) was transformed with pPL1, pΔSepL3, or the vector alone. Cell extracts were prepared from DMEM cultures to analyze SepL and EspA protein levels by SDS-PAGE and immunoblot. EPEC strain UMD878 (EPECsepL) (O’Connell et al., 2004) with a kanamycin cassette insertion in sepL, and its complemented strain (EPECsepL(pSepL)) were analyzed as negative and positive controls for SepL synthesis, respectively. SepL was detected in a cell extract from EPECsepL(pSepL) as a product of about 40 kDa (Fig. 8A). As expected, SepL was not detected in the strain EPECsepL or in EDL933 ΔLEE transformed with the vector alone. The concentration of the SepL polypeptide was 2–2.5 fold higher in EDL933 ΔLEE (pΔSepL3) than in EDL933 ΔLEE (pPL1) indicating that the processing at the end of the sepL coding sequence diminishes SepL production. In contrast, EspA production in the same cell extracts was not affected by the deletion at the end of sepL (Fig. 8B). Similar experiments with the Sakai strain also show that under these growth conditions SepL was undetectable while EspA was clearly detected. Thus, our results suggest that this imbalance between SepL and EspA may be due in part to RNase E processing.
3’ end mapping of espADB mRNAs
To determine the 3’ end of the espADB mRNAs, total RNA was extracted from the Sakai strain, polyA tails were added to the 3’ ends using poly(A)polymerase (PAP), and 3’-RACE was employed to amplify fragments containing the modified 3’ ends (see Experimental Procedures). A major PCR product was obtained (Fig. 9A lane 1) that was cloned and sequenced. The major terminus of the espADB transcripts was at position 215 considering the ‘A’ of cesD2 start codon as position 1 with other 3’ end sites found in a minority of clones (Fig. 9B). The size of the espADB transcript determined by Northern Blot is ~3 kb which is in good agreement with the size determined by 5’ and 3’ mapping. The sequence at the 3’ end of the espADB transcript can be folded into a putative secondary structure with features of an intrinsic transcriptional terminator (d’Aubenton Carafa et al., 1990) (Fig. 9B). The cesD2 nucleotide sequence is highly conserved (90% identity or higher) among EHEC, EPEC (strains E2348/69, 0181-6/86 and 3431-4/86), Citrobacter rodentium, and rabbit EPEC. In the loop of the hairpin, only a single nucleotide change was seen in the Citrobacter rodentium sequence.
The same RNA sample was the substrate for a 3’ RACE reaction but without prior treatment with PAP. In this case, a different pattern of amplification products was obtained (Fig. 9A, lane 2). The products shown in Fig 9A lane 2 corresponded to mRNA 3’ ends located in cesD2 or espB and they might be the result of polyadenylated transcripts that are intermediates of degradation. Polyadenylation in E. coli serves to facilitate the exonucleolytic degradation of structured RNA molecules (Dreyfus and Régnier, 2002), and can occur on fragments resulting from endo or exonucleases cleavages (Haugel-Nielsen et al., 1996).
Discussion
In this study we established that transcription of the LEE4 operon in EHEC proceeds from sepL to espF, the first and the last genes of this operon, respectively. This result is consistent with previous results from our laboratory for the transcription of LEE4 in EPEC (Mellies et al., 1999). Our current work demonstrates that the LEE4 transcript is processed to generate an espADB transcript. First, E. coli K-12 (pPL1) harboring a ts mutation in rne does not produce the ‘esp’ transcripts at the restrictive temperature, indicating they are generated by RNase E-dependent processing. Second, the 5’ ends of the espADB transcripts in EHEC are monophosphorylated, which indicates formation by processing rather than transcription initiation. Third, EspA levels were unaffected by deletion of the processing region, ruling out a role for the deleted regions in transcription initiation. Even though the observed espADB transcripts are the products of processing, we cannot definitively rule out the existence of a weak promoter at the end of sepL. For example, in Salmonella typhimurium processed mRNAs were detected in the his operon and also an internal weak promoter (P2) close to a processing site (Alifano et al, 1992). Using 3’ RACE we mapped a major end of espADB transcripts inside the coding region of cesD2. A predicted stem-loop structure at the 3’ end of these transcripts resembles a Rho-independent transcription terminator in that it has a G + C -rich stem, a poly U tail at the 3’ end, a tetraloop, and the presence of As at the 5’ end of the stem-loop (d’Aubenton Carafa et al., 1990). Interestingly, a bioinformatic analysis of the E. coli K-12 genome predicted more than 40 intrinsic transcriptional terminators residing in ORFs (Lesnik et al., 2001), and a functional intragenic Rho-independent transcriptional terminator was found in the coding region of the bmpB gene in Borrelia burgdorferi (Ramamoorthy et al., 2005).
Even though the function of the potential intrinsic terminator has to be tested experimentally, its location inside a coding region raise the question of how the genes located downstream of the terminator could be transcribed. One possibility is that transcription could be imperfectly terminated at this particular terminator and thus, the genes located downstream might be transcribed as a result of readthrough by the RNA polymerase. In this respect, previous studies have stated that termination efficiency of different terminators varies greatly both in vitro and in vivo (Reynolds et al, 1992; Nojima et al., 2005) based not only on the terminator structure but also upon the context of the transcription unit in which it is placed. The context affecting termination efficiency includes both early transcribed sequences (Goliger et al., 1989; King et al., 1996) and terminator-distal sequences (Telesnitsky and Chamberlin, 1989). Transcription anti-termination could also be the result of protein factors that interact with RNA polymerase changing its properties (for reviews see Bailey et al.,1997; Nudler and Gottesman, 2002; Borukhov et al., 2005) or protein factors with RNA chaperone activity that melt RNA secondary structures (Phadtare et al., 2007). We did not map the 3’ end of the primary transcript, but by visual inspection or the use of RNA folding programs we could not find a structure that might resemble a prototypical intrinsic terminator at the end of espF. Thus, transcription of the whole operon-from sepL to espF- could terminate by a Rho-dependent transcription termination mechanism.
We found that RNase E is the endonuclease involved in LEE4 processing. Mutations of other genes encoding RNases -P, III, and G- had no effect (data not shown). RNase E cleaves its substrates in A + U rich-regions with no defined consensus sequence recognition (McDowall et al., 1994; Callaghan et al., 2005) which is consistent with our results. However, the endonucleolytic cleavage by RNase E should be tested by in vitro experiments. Our results with a deletion mutant of the C-terminal half of RNase E in EHEC establish that the degradosome assembly or the interaction of RNase E with other proteins like Hfq (Morita et al., 2005) is not necessary for LEE4 processing. In this regard, the C-terminal part of RNase E is dispensable for the maturation of 5S rRNA as well (Lopez et al., 1999; Ow et al., 2000). As far as we know, other studies have not evaluated the participation of the RNase E C-terminal half in RNA processing or maturation.
RNase E has a central role in RNA metabolism that ultimately controls gene expression. It is involved in bulk chemical decay of RNAs (Mudd et al., 1990) and in the degradation of specific RNAs (Tomcsányi and Apirion, 1985; Spickler et al., 2001; Régnier and Hajnsdorf, 1991; Aiba, 2007). RNase E not only cleaves RNAs that are then degraded but also cleaves precursor RNAs to yield functional mature products. Examples include: 5S rRNA (Apirion and Lassar, 1978), 16 S rRNA (Li et al., 1999), tRNAs (Li and Deutscher, 2002; Ow and Kushner, 2002), the RNA subunit of RNAse P (Lundberg and Altman, 1995), and ssrA RNA which adds a tag to truncated peptides for its degradation (Lin-Chao et al., 1999). Processing of precursor mRNAs by RNase E can also yield transcripts of different stability contributing to a different molar ratio of the encoded proteins as appear to be the case here. Examples of this kind of processing include: precursor mRNAs of phage f1 (Kokoska and Steege, 1998), the polycistronic ftsQAZ transcript encoding essential cell division proteins (Cam et al., 1996; Tamura et al., 2006), and mRNAs from operons such as pap responsible for the synthesis of pili for adhesion to mammalian cells (Nilsson and Uhlin, 1991; Nilsson et al., 1996).
Our results are reminiscent of what has been reported for the regulation of gene expression of pap and other operons encoding fimbriae in pathogenic E. coli (Jordi et al., 1993; Loomis and Moseley, 1998; Balsalobre, et al., 2003; Koo et al., 2004). The major structural subunit of fimbriae is needed in large excess relative to minor structural subunits or regulatory proteins encoded in the same operon. In the pap operon, the most-promoter proximal gene, papB, encodes a transcriptional activator that is cotranscribed with the gene for the major pilus subunit, papA. Processing by RNase E in the papB-papA intercistronic region of the mRNA B-A produces the stable transcript mRNA-A leading to high-level expression of PapA (Båga et al., 1988; Nilsson and Uhlin, 1991; Nilsson et al., 1996).
In A/E pathogens, EspA, D and B are secreted proteins forming the translocation apparatus whereas SepL is an intracellular protein that regulates secretion of translocators and effectors. The processing at the end of sepL would be a coordinate way to synthesize higher levels of EspA, D, and B relative to SepL, which might be needed in a lower concentration. In our experimental conditions SepL was undetectable in immunoblots whereas EspA was easily detected. This result, combined with the efficient cleavage in the sepL coding region, suggests that poor translation of sepL mRNA might expose it to RNase E binding and degradation. We noticed the absence of a prototypic Shine-Dalgarno sequence for sepL, which suggests inefficient translation initiation. In this respect, it was shown that inefficient translation of epd mRNA, which encodes the enzyme erythrose-4-phosphate dehydrogenase in E. coli, exposes an RNase E entry site that results in mRNA cleavage and contributes to epd low level expression (Bardey et al., 2005). In contrast, translation of espADB mRNA would increase its stability by hiding entry sites for RNase E as it was reported for other transcripts (Iost and Dreyfus, 1995; Baker and Mackie, 2003).
The function of SepL as a regulator has not yet been fully elucidated, and thus, why the expression of different levels of SepL and Esp proteins would be necessary for infection is unknown. In EPEC, mutant strains of sepL showed a defect in A/E lesion and EspA filament formation in vitro, and this effect was reversed with the expression of very little SepL whereas its overexpression did not interfere with its function (O’Connell, 2004). EspA forms the extracellular filament of the T3SS essential for the injection of virulence proteins to the host cell. The intracellular availability of EspA subunits limits the length of the filaments (Crepin et al., 2005), and thus, a constant supply of EspA subunits might be necessary to maintain the integrity of the filaments to allow a successful colonization of the epithelium. In a similar way, EspD is required for efficient EspA filament formation because mutations in espD affect filament formation in EHEC (Kresse et al., 1999) and EPEC (Knutton et al., 1998). EspB is targeted to the cytosol and membrane of the host cell (Knutton et al., 1998; Ide et al., 2001). It is a translocator protein necessary for the injection of proteins by the T3SS, and also is an effector that interferes with myosin and actin interaction in EPEC (Iizumi et al., 2007). The myosin binding domain of EPEC EspB shows 75% and 38 % identity with the same region of Citrobacter rodentium EspB and EHEC EspB, respectively (Iizumi et al., 2007). EspB was proposed to be delivered in highly concentrated doses to its site of action to prevent myosin binding to the highly abundant protein actin (Mattoo et al., 2008).
In Yersinia pseudotuberculosis, a strain with attenuated RNase E function showed a reduction in infectivity of culture macrophages and reduced secretion of one effector protein-YopE- by the T3SS. However, as YopE expression levels were not affected in this strain, the authors proposed that RNase E should control the levels of other transcripts required for optimal T3SS functioning (Yang et al., 2008). As far as we know, our study shows for the first time the RNase E-dependent processing of an operon necessary for the biogenesis of the T3SS in a pathogen. Finally, an additional post-transcriptional mechanism whose factors are encoded outside LEE, seems to control the heterogeneous production of EspA filaments in populations of EHEC cells (Roe et al., 2003). We did not analyze the expression of the remaining genes of LEE4, but previously published information suggests that post-transcriptional regulation would control the production of proteins encoded by those genes as well. For example EspF is detected in whole bacterial pellets and supernatants of cultures from both EHEC and EPEC (Viswanathan et al., 2004) while two other proteins – EscF and Orf29- were reported undetectable in immunoblots suggesting very low concentrations (Wilson et al., 2001; Su et al, 2008). In summary, previous studies and our results establish that there is a differential expression among the genes encoded in LEE4, and a tight regulation of protein production kinetics and secretion. However, we have just begun to unravel the post-transcriptional mechanisms controlling gene expression of this operon whose controlled expression presumably helps assure the efficient colonization of the intestine.
Experimental Procedures
Bacterial strains, culture conditions and recombinant DNA techniques
The EHEC O157:H7 strains used in this study were RIMD 0509952 (a Δstx Kanr derivative of the Sakai outbreak strain referred to in this study as simply ‘Sakai’) (Hayashi et al., 2001; Dahan et al., 2004), EDL933 (Perna et al., 2001), EDL933ΔLEE (Pósfai et al., 1997), and 86-24 (Griffin et al., 1988). The E. coli strain N3431 harbors a thermosensitive mutation in the rne gene that encodes RNase E, and N3433 is an isogenic rne+ strain (Apirion, 1978). Both strains were supplied by The Coli Genetic Stock Center at University of Yale. Other E. coli strains employed were MG1655 (Blattner et al., 1997), DH5α λ pir (Ménard et al., 1993) and E. coli SM10 λ pir (Simon et al, 1983). Bacteria were grown routinely in Luria broth (LB) (Sambrook and Russell, 2001). Antibiotics were added to the media when required in the following final concentrations: ampicillin (Ap), 100 µg ml−1; chloramphenicol (Cm), 20 µg ml−1.
Plasmid purification, DNA gel electrophoresis, genomic DNA extraction, transformation, ligation, and PCR were performed using standard methods (Sambrook and Russell, 2001). Easy-A™ Hi-Fi PCR cloning enzyme (Stratagene) or Pfu Ultra™ II Fusion HS DNA Polymerase (Stratagene) were used for PCR and cloning, and all constructs were confirmed by sequencing.
RNA extraction and reverse transcription-polymerase chain reaction (RT-PCR)
Cultures of EHEC strains were grown aerobically in Luria-Bertani broth (LB broth) overnight at 37°C and diluted (1:1,000 or 1:500) in pre-warmed Dulbecco’s modified Eagle’s medium (DMEM) (Invitrogen, catalog number 11885) supplemented with 1 or 0.2% glucose, grown aerobically at 37°C and shaken at 250 rpm. Samples were collected, and mixed with 2 volumes of RNAprotect Bacteria Reagent (Qiagen). Then, the cells were sedimented by centrifugation, and stored at −80 °C until RNA extraction. RNA was extracted with RNeasy Midi extraction kit (Qiagen), and treated twice with DNase (Qiagen and Ambion). RNA was quantified by UV absorbance, and its integrity was verified by visualization in denaturing agarose gel. cDNA was synthesized from 2 µg of total RNA using SuperScript III First-Strand (Invitrogen) following manufacturer’s instructions. PCR to detect LEE4 expression was performed with specific primers for sepL and espF genes (fLF and rLF, respectively) (Table I) and Easy-A Hi-Fi PCR cloning enzyme (Stratagene).
Northern blot
Electrophoresis of 20 µg of total RNA was performed on 1.2 % agarose formaldehyde-morpholinepropanesulfonic acid as previously described (Sambrook and Russell, 2001). After electrophoresis, the RNA was blotted onto a Hybond-N nylon membrane (Amersham Biosciences) by downward transfer (Chomcynski, 1992) and fixed by UV crosslinking (UV Stratalinker 1800, Stratagene). Prehybridization and hybridization were done at 42°C using NorthernMax Prehybridization/Hybridization Buffer (Ambion) following manufacturer’s instructions. The espA probe, a PCR fragment of 260 bp amplified with primers fEspA and rEspA (Table I), was labeled with [32P]dCTP and Ready-To-Go DNA labeling beads (GE Healthcare). After hybridization, the membrane was washed twice for 5 min at room temperature with 2X SSC, 0.1% SDS and twice for 15 min at 42°C in 0.1X SSC, 0.1% SDS.
In vitro transcription and Ribonuclease Protection Assay (RPA)
Probes for RPAs were synthesized by in vitro transcription using Maxiscript T7/ T3 kit (Ambion). Templates for in vitro transcription were PCR products generated with primers that incorporated a T7 promoter and a T3 promoter sequence at the 5’ ends. In addition, each primer included a non-homologous sequence to allow discrimination between the probe and the full-length protected fragment in RPAs. Primer pairs F-T3LEE4/ R-T7LEE4 and F-T3LEE4b /R-T7LEE4b were used to amplify the template for in vitro transcription of probe 1 and probe 2, respectively (Table I). Probes were labeled using Biotin-16-UTP (Roche) to UTP ratio of 40:60, and were gel purified after in vitro transcription. The RPA III Ribonuclease Protection Assay kit (Ambion) was employed for RPAs following the manufacturer’s recommendations. 5 µg of total RNA and 700 pg of labeled probe were used in overnight hybridization reactions at 42°C, except in the experiment shown in Figure 2C where 40 µg of total RNA and 800 pg of labeled probe were employed. As negative controls, hybridizations were performed with yeast total RNA provided with the kit, or E. coli K-12 RNA. Digestion of unhybridized RNA was performed with 1:30 dilution of RNase T1 supplied with the kit. The reactions were resolved in a 5% polyacrylamide/8 M urea denaturing gel, and transferred to a positively charged nylon membrane (Hybond-N+, Amersham Biosciences) using a semi-dry transfer system (Trans-Blot SD Semi-Dry electrophoretic Transfer Cell, Bio Rad) in 0.5X TBE. After transfer, the RNA was immediately fixed by UV crosslinking. The detection of the protected fragments was performed with CDP-Star substrate (Tropix, Applied Biosystems) following manufacturer’s recommendations with some modifications. The blot was washed twice for 5 min in 0.5 ml cm−2 Blocking Buffer (1X PBS, 0.2% I-Block reagent, 0.5% SDS), and blocked in the same buffer for 1 h (1 ml cm−2), with the exception of the experiment shown in Fig. 2C where skim milk was employed as a blocking agent. Then, the blot was incubated for 20 min with agitation in Streptavidin-AP conjugate (Roche) diluted 1:5,000 in Blocking Buffer (0.1 ml cm−2). The following washes were performed: 5 min in Blocking Buffer (0.5 ml cm−2), three 10 min washes in 1 ml cm−2 Washing Buffer (1X PBS, 0.5 % SDS), and two 2 min washes in Assay Buffer (20 mM Tris-HCl (pH 9.8), 1 mM MgCl2). After washing, the blot was incubated for 3–4 min in the substrate (3 ml 100 cm−2), and exposed to film X-Omat Blue XB-1 (Kodak).
Identification of protected fragments
For the experiment shown in Figure 3, RPA was performed with 40 µg of total RNA and 800 pg of unlabeled probe 1. The products were run in a denaturing polyacrylamide gel and transferred to a membrane as described above. To determine whether the protected fragments corresponded to sepL or espA coding regions, hybridizations were performed with specific DNA oligomers, oligo-sepL and oligo-espA (Table I) labeled with [γ-32P]ATP (GE Healthcare) using T4 Polynucleotide Kinase (Invitrogen). For hybridizations Rapid-hyb buffer (GE Healthcare) was employed. After hybridization, the membranes were washed following manufacturer’s recommendations.
RNA ligase mediated rapid amplification of cDNA ends (RLM-RACE)
The strategy described by Bensing et al. (1996) and Sawers (2005) was used to discriminate between mono or triphosphorylated 5’ ends. Total RNA was treated with phosphatases, and then 5’-RLM-RACE was performed using FirstChoice RLM-RACE kit (Ambion) following the manufacturer’s protocol. Briefly, a RNA sample was subjected to 4 separate treatments with tobacco acid pyrophosphatase (TAP) digestion, which removes pyrophosphate from the 5’ end of primary transcripts, and calf intestine phosphatase (CIP), which removes monophosphate groups from processed transcripts. In the first treatment, RNA was treated only with TAP and thus, processed and primary transcripts yield a product. In the second treatment, RNA was first treated with CIP and then with TAP, and thus only primary transcripts yield a product. In the third reaction, the RNA sample was untreated and thus only processed transcripts can be detected. Finally, the negative control is an RNA sample treated only with CIP. 900 ng of total RNA that were previously treated with CIP and TAP, CIP only, TAP only, or not treated, were ligated to the 5’ RACE adapter. After ligation and reverse transcription, the first PCR was done with the primers 5’-RACE outer primer, which hybridizes the adapter sequence, and roEspA (Table I). Then, an aliquot of the first PCR was employed as substrate for the second, nested PCR, with the primers 5’RACE inner primer and riEspA (Table I). The PCR products shown in lanes 2 and 8 of Figure 4A were cloned using the TOPO TA Cloning system (Invitrogen) and sequenced. As a positive control for the 5’ RLM-RACE technique, we analyzed the 5’ ends generated by transcription initiation of rpsT mRNAs which encode the ribosomal protein S20 (Fig. 1S). Primers 5’-RACE outer primer and RACE-S20-r (Table I) were employed in this assay.
The 3’ end of the espADB transcripts was mapped by 3’-RLM-RACE using the FirstChoice RLM-RACE kit (Ambion). Prior to 3’-RLM-RACE, 2 µg of total RNA were treated with poly (A) polymerase (PAP) (Ambion) to add a poly A tail to the 3’ ends. 3’-RLM-RACE was also done with 2 µg of total RNA without poly A to show that the amplification product obtained with PAP treatment was a specific product resulting from poly A addition to the 3’ end of espADB mRNAs. Reverse transcription was performed with the 3’ RACE Adapter, which is provided with the kit, and has a poly T sequence for annealing to poly A tails at the 3’ ends. Then, PCR was performed with the primers 3’ RACE Outer primer, which hybridizes the adapter, and f3’RACE (Table I). The PCR product was gel purified and cloned using the TOPO TA Cloning system.
PAGE and immunoblot analysis of proteins
Bacterial cells were collected from DMEM cultures and frozen for later analysis. Cell extracts were prepared by boiling cell pellets and protein concentration was measured by DC Protein Assay (Bio-Rad) to load equal amounts in gels. Cell extracts were mixed with NuPAGE LDS sample buffer 4X, and heated for 10 min at 75 °C before loading gels. Proteins were resolved on PAGE gels (Laemmli, 1970) using Next Gel (Amresco) and Next Gel Running Buffer (Amresco). After electrophoresis, proteins were transferred to Immobilon-FL membranes (Millipore). For immunoblotting and detection, the Odyssey Infrarred Imaging System (Li-Cor) was used following manufacturer’s protocols. EspA was detected with anti-EPEC EspA polyclonal antibodies raised in rabbits (Elliott et al., 2000) and diluted 1:10,000 in Odyssey Blocking Buffer, 0.1 % Tween 20. SepL was detected with polyclonal antibodies against EPEC SepL raised in rabbit (O’Connell et al., 2004) and diluted 1:5,000 in Odyssey Blocking Buffer, 0.05 % Tween 20. Anti-rabbit Alexa Fluor 680 was used as a secondary antibody diluted 1:10,000 in Odyssey Blocking Buffer, 0.1 % Tween 20.
Construction of RNase E mutant
Genomic DNA from Sakai Δstx strain was used as template to amplify the last 2,817 bp of the rne gene plus 709 bp downstream of the TAA stop codon using the primers frne-s and rrne-s (Table I). This product was cloned into pENTR/SD/D-TOPO (Invitrogen), and was the template for inverse PCR to create a deletion in the rne gene using the primers fdel-rne-s and rdel-rne-s. This mutant sequence, named rne426, would encode a polypeptide of 426 amino acids of the N-22 terminal region plus 28 additional amino acids (rne426). The mutant rne sequence was cloned in pJMM112 (a gift from Jane Michalski) that is a derivative of pCVD442 (Donnenberg and Kaper, 1991), and the resulting plasmid was named pJrne426. pJMM112 has an Ap resistance marker, the gene sacB and a module with the following determinants: attR1- cat-ccdB- attR2.
The attR sites are bacteriophage λ -derived DNA recombination sequences, cat specifies a Cm resistance marker, and ccdB allows negative selection of the plasmid. The rne426 sequence was moved to pJMM112 using the Gateway LR clonase II Enzyme Mix (Invitrogen) following the manufacturer’s directions. E. coli DH5α λ pir was transformed with the clonase reaction. Transformants were selected for Ap resistance and tested for Cm sensitivity. The presence of the rne426 deletion in transformants was confirmed by PCR. Plasmid pJrne426 was introduced into the donor E. coli SM10 λ pir and transfer to Sakai Δstx by mating overnight in LB agar. The cells were resuspended in PBS, and Sakai exconjugants were selected in MacConkey agar containing Ap (100 µg ml−1), sorbitol (10 g l−1) and potassium tellurite (2.5 µg ml−1). Several white colonies (non-fermenting sorbitol) were inoculated in LB cultures, and after overnight growth, dilutions were prepared and plated on LB agar containing no NaCl and 5% (w/v) sucrose. Sucrose-resistant colonies were tested for Ap sensitivity indicative of the loss of vector sequences. Colony PCR was done to detect the mutated rne allele. Approximately half of the sucrose resistant and Ap sensitive colonies carried the rne426 deletion, which was confirmed by sequencing.
Plasmid constructions
To construct the plasmid pPL1, the coding sequences of the first three genes of the LEE4 operon- sepL, espA and espD- were cloned into plasmid pACYC184 replacing the tetracycline resistance gene but leaving the coding sequence for the first 19 amino acids of Tet. Thus, transcription of the cloned genes is controlled by the tet promoter and SepL is synthesized as a fusion protein with 19 N-terminal amino acids of the Tet protein. In addition, the rrnB T1 and T2 transcription termination sequences were cloned downstream of espD. To accomplish this, the primers f-rrnB and r-rrnB, carrying BamHI and BglI restriction sites, respectively, were used to amplify rrnB T1 and T2 sequences from plasmid pENTR/SD/D-TOPO. This product was cloned into the BamHI and BglI sites of plasmid pACYC184 to generate pACYC184rrnB. Then the sepLespADB sequence was amplified with primers fsep-esp and rsep-esp using genomic DNA of Sakai Δstx as template, and cloned into the vector pCR 2.1-TOPO (Invitrogen). This construction was used as a template to re-amplify sepLespAD with primers f-sepesp2, and BamHI-LEE4-2 to introduce a BamHI site downstream of the espD stop codon. The PCR product sepLespAD was digested with BamHI, and ligated to BamHI and ScfI-digested plasmid pACYC184 rrnB. The ligation product was gel purified, the ScfI 5’ overhang was filled with DNA polymerase I, Large (Klenow) fragment (New England Biolabs) to create a blunt end, and then the plasmid blunt ends were ligated by T4 DNA ligase (New England Biolabs).
To construct plasmid pΔSepL3 carrying a deletion of the processing region, plasmid pPL1 was used as template in a PCR with primers fΔsepL and rΔsepL. The product was gel purified, phosphorylated by T4 kinase (New England Biolabs), cleaned using QIAquick PCR purification kit (Qiagen) and ligated with T4 DNA ligase (New England Biolabs). Restriction enzyme digestions, PCR and other enzyme treatments were done following the manufacturer’s protocols.
Acknowledgments
We thank Dr Mary Jane Lombardo and Dr Paul S. Lovett for the critical reading of the manuscript. We thank Jane Michalski for the construction of the pJMM112 plasmid, and Dr M. S. Donnenberg for providing SepL antiserum and the EPEC strains UMD878 and UMD878(pCO24). This study was supported by NIH grants DK58957 and AI21657 to J.B.K.
Footnotes
Accession Numbers for LEE sequence
Previously deposited sequences cited in this work are from atypical EPEC (AJ633129 and AJ633130), typical EPEC (AF022236), Citrobacter rodentium (AF311901), rabbit EPEC (AF461393 and AF200363), EHEC O157:H7 strain Sakai (BA000007), EHEC O157:H7 strain EDL933 (AE005174)
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