INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Myxococcus xanthus moves via a surface-dependent motility mechanism called gliding, which, although still poorly understood, is known to involve many genetic loci (8). Hodgkin and Kaiser (9) first demonstrated that gliding motility involves two distinct systems: A (adventurous gliding), which allows movement of individual cells when isolated from other cells, and S (social gliding), which has recently been shown to be similar to twitching motility in Pseudomonas aeruginosa, since both involve type IV pili (25). Both A- and S-motility systems contribute to the wild-type gliding phenotype, and both systems appear to be under directional control from the Frz signal transduction system. Directed motility is of particular interest in M. xanthus since groups of cells can display complex motility behaviors, swarming under nutrient-rich conditions or, alternatively, aggregating into fruiting bodies when starved.

The Frz signal transduction system shows striking homology to the Che system of the enteric bacteria. However, chemotactic signal transduction in this slow-moving bacterium is still only partially understood (24). Whereas the enteric bacteria respond to defined chemical stimuli by using transmembrane receptor proteins (the methyl-accepting chemotaxis proteins [MCPs]), the MCP homologue in M. xanthus (FrzCD) has no membrane-spanning regions and must therefore either interact with membrane-associated sensors or detect stimuli within the cytoplasm. FrzCD is, however, methylated and demethylated during developmental aggregation (13) and vegetative swarming (17). This methylation and demethylation of FrzCD suggest that chemotaxis, which requires such adaptive modifications, may play a role in both fruiting body formation and colony dispersal, although chemokinesis (which does not require adaptation) has also been suggested to be involved in swarming behavior (23). The FrzE protein, which shows homology to both CheA and CheY, appears to act similarly to the enteric Che proteins; i.e., it is capable of autophosphorylation, and the phosphate group can be transferred from the histidine protein kinase (CheA domain) to the response regulator (CheY) domain (1). The Frz system is also known to involve several additional protein components, including FrzB and FrzZ. While little is known about the function of either protein, frzZ mutants show reduced swarming and developmental aggregation defects while retaining responses to repellent stimuli (21).

To date, no interactions between the motility-regulating Frz signal transduction system and the motility machinery of M. xanthus have been identified. We have used interaction trap methodology (6) to facilitate the identification of such interactions. Both the FrzE and FrzZ proteins have been cloned as bait into the two-hybrid system and used to screen a M. xanthus genomic DNA library for interacting proteins. These proteins were chosen as baits because they both encode CheY-like response regulator domains, which should presumably be involved in regulating output from the Frz system and might therefore be of use in the identification of motor proteins. The FrzZ protein is composed of two domains which both show homology to CheY but are quite distinct with respect to each other. These domains were therefore cloned separately into the two-hybrid system to determine if they interact with different proteins. In this study, we report an unexpected, potential interaction between the first domain of FrzZ and a putative extracytoplasmic-function (ECF) sigma factor involved in regulation of motility-associated behavior.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Strains and culture conditions. The strains used in this study are listed in Table 1. Plasmids are listed in Table 2. M. xanthus strains were grown in CYE medium (3), and developmental assays were performed on CF starvation media (7). Escherichia coli strains were grown in LB media. Yeast strains were grown in YPAD rich media or minimal SD media containing appropriate amino acids and 2% glucose (Stratagene).

HybriZAP two-hybrid system. DNA-binding domain fusion constructs were prepared by PCR amplification of the DNA encoding the bait proteins. PCR was performed with the high-fidelity polymerase Pfu. Primers were designed with 5' EcoRI restriction sites (underlined in the sequences below) to simplify cloning into the EcoRI site of pBD-GAL4. The following primer pairs were used: FrzZ1 (pBD-Z1), forward 5'-ATGAATTCACGATGTCGCGCGTACTGGTCATTGATGACAGCCCG and reverse 5'-ATGAATTCGATGCTCAGGGCGGGGGGGCCAATGAGACCCATGAC; FrzZ2 (pBD-Z2), forward 5'-ATGAATTCAAGCCGCGCATCCTCATCGTGGATGAC and reverse 5'-ATGAATTCCTACTCGTTACCGGTGGGCATCAGCTC; FrzE (pBD-E), forward 5'-ATGAATTCCGTACGCCGGCCATGGACACCGAGGCTCTC and reverse 5'-ATGAATTCTCAGGTCAGCCGGTCGATGGCCTGCGCGAG. The insertions within the resultant constructs (pBD-Z1, pBD-Z2, and pBD-E) were sequenced to ensure error-proof amplifications, and then the plasmids were transformed into Saccharomyces cerevisiae YRG-2. The transformants containing just the binding domain constructs were tested for reporter gene expression prior to retransformation with the activation domain library or test activation domain fusion constructs. No reporter gene activity was observed with any of the bait constructs transformed alone into YRG-2.

DNA manipulations and PCR. All plasmids used in this study were prepared by using a QIAprep spin miniprep kit (Qiagen). Chromosomal DNA was prepared by a miniprep protocol using cetyltrimethylammonium bromide-NaCl and phenol-chloroform extraction (22). Restriction enzyme digests and modifying enzyme protocols were performed as specified by the manufacturers. PCR optimizations and cycling parameters were identified by the protocol of Kramer and Coen (11). In general, glycerol concentrations of 20% were required for high yields of pure products. Taq polymerase (Promega) and Pfu polymerase (Stratagene) were used in amplifications requiring low and high fidelity, respectively.

RNA preparation and analyses. Total RNA of M. xanthus was isolated by using a modification of the hot phenol procedure of Oelmüller et al. (15). RNA from developing cells was prepared as follows. An exponentially growing culture of DZ2 was diluted to 10⁷ CFU/ml in CYE. Thirteen sterile glass petri dishes were filled with 50 ml of this diluted culture and then incubated at 32°C for 24 h. After this time, the growing cells had adhered to the bottom of the dishes and the growth medium was carefully removed. The cells were washed once with water; then the water replaced with an aliquot (20 ml) of 1 mM CaCl₂ in 10 mM morpholinepropanesulfonic acid (MOPS) buffer (pH 6.8). The dishes were further incubated at 32°C. Starvation-induced development was considered to start from the time point of growth medium removal. At 0.5, 1, 2, 4, 6, 8, 10, 12, 18, 28, 42, 63, and 80 h, the wash solution was removed and the cells were resuspended in a 5-ml aliquot of ice-cold AE buffer (20 mM sodium acetate [pH 5.5], 1 mM EDTA). A phenol solution (acid-phenol-chloroform, 5:1, pH 4.5; Ambion Inc.) containing 0.25% sodium dodecyl sulfate was prewarmed in a 60°C water bath and added to the cells. The liquid-cell mixture was placed in a tube and incubated for 10 min in a fast-shaking water bath (60°C). RNA from vegetative growing cells was isolated by taking 10 to 20 ml of the initial exponentially growing culture and quickly harvesting the sample in precooled vessels. Samples were then resuspended in 5 ml of ice-cold AE buffer and incubated in the hot phenol solution as described above. After phase separation by low-speed centrifugation (4,000 × g, 15 min, 4°C) the aqueous phase of all RNA preparations was adjusted to 0.25 M sodium acetate (pH 5.2) and extracted twice with phenol solution. After ethanol precipitation and washing and drying of the RNA pellet, the RNA was resuspended in DNase buffer (40 mM Tris-HCl [pH 7.5], 6 mM MgCl₂) and treated with 100 U of DNase I (RNase free; Ambion). After another phenol extraction and ethanol precipitation, the RNA was resuspended in Tris-EDTA buffer at a concentration of 1 mg/ml. Per sample, 20 to 300 µg of total RNA was obtained.

1

Production of mutants. Mutants were constructed by cloning internal fragments of the specified genes into pZErO-2 (Invitrogen). These constructs were then electroporated into M. xanthus strains, and selection on CYE containing kanamycin (25 µg/ml) was used to identify mutants which had inserted the entire vector into the chromosome by homologous recombination. Internal fragments of the following genes were prepared by PCR using Taq polymerase (Promega). The following primer combinations were designed with 5' EcoRI ends (underlined) to facilitate simple cloning into the EcoRI site of pZErO: rpoE1 (pZRpoE1), forward 5'-ATGAATTCGCTCTATTCGGCGGCGCTGC and reverse 5'-ATGAATTCAAGACGCCCTGGCCCTCGGC; orf5 (pZOrf5), forward 5'-ATGAATTCCCAGTTCGGCGTCTGGCTGC and reverse 5'-ATGAATTCGAGCATCCGGCGGATGTCGC.

Phenotypic analyses. Carotenoid production was screened preliminarily by colony color after cells were left incubating in the light for 2 days. These cells were then extracted with methanol, and the extract was analyzed spectrophotometrically for absorption between wavelengths of 300 and 600 nm. Cells that had been incubated in the dark were used as control standards. Carotenoid production was considered positive if a peak at 480 nm was identified only in the light-grown cells.

Computer analysis. Computer analyses of the sequenced genes, including GC coding predictions, identification of open reading frames (ORFs), translations, and sequence alignments, were performed with the program Gene Inspector (Textco Inc.).

Nucleotide sequence accession number. The DNA sequence presented here have been submitted to the EMBL, GenBank, and DDBJ nucleotide sequence data libraries under accession no. AF049107.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Identification of a potential ECF sigma factor by using interaction trap technology. A yeast two-hybrid screen, with the first domain of FrzZ (on pBD-Z1) used as bait, identified a construct, pAD-RpoE1, from a random M. xanthus genomic DNA library (pAD-LIB), which when present in combination with pBD-Z1 resulted in positive reporter gene assays in the system. Both plasmids were purified, and pAD-RpoE1 was retransformed into S. cerevisiae YRG-2 in combination with pBD-Z1 and other bait-encoding constructs (Table 3). While the same positive reporter gene expression was observed with the pAD-RpoE1-pBD-Z1 combination, the pAD-RpoE1 construct (one of the reporter systems in the Stratagene HybriZAP two-hybrid system) also produced a low level of -galactosidase expression when transformed in combination with pBD-AsgA (kindly provided by L. Plamann, University of Missouri). Since asgA encodes a protein with two separate domains, a histidine protein kinase and a response regulator domain (16), we speculate that the protein encoded by pAD-RpoE1 may interact with a response regulator, but perhaps not specifically with FrzZ. However, the negative results produced by transforming YRG-2 cells with pAD-RpoE1 and other response regulator expression constructs (pBD-Z2 and pBD-E) suggest that the fusion protein expressed from pAD-RpoE1 does not interact nonspecifically with all response regulators. To extend our analysis of the gene cloned in pAD-RpoE1, the insert DNA was used as a probe to identify a large genomic fragment from within a cosmid library (kindly provided by T. Hartzell, University of Idaho). The identified clone (pBS9) contained the gene of interest and both upstream and downstream regions.

The rpoE1 gene is positioned downstream of frzZ. The 6,464-bp insert present on the construct pBS9 was sequenced and shown to encode six potential ORFs (Fig. 1), all with appropriate M. xanthus codon usage, a good indicator of translational potential (18). The first ORF spanned from the start of the sequenced region to a stop codon at bp 829 and was considered to be the 3' end of a gene. A gapped BLAST analysis (2) of the translated protein identified it to be the C-terminal end of FrzZ (21), placing the gene encoding the potentially FrzZ-interacting protein downstream of the frzZ gene itself. The second ORF, present on the opposite DNA strand, spans from a potential ATG start codon at bp 2320 to a stop codon at bp 972. The orf2-encoded protein showed no homology to known proteins in a GenEMBL database search. The third ORF is transcribed divergently from orf2, with a potential GTG start codon at bp 2458 and a stop codon at bp 3580. A potential ribosome-binding (Shine-Dalgarno [SD]) site (GGAGG) was apparent 6 bp upstream of the proposed start codon. A gapped BLAST search showed orf3 to have significant similarity (57% identity) to the alanine dehydrogenase gene (ald) of Bacillus subtilis (19); orf3 has, therefore, been speculatively renamed ald. A potential terminator structure was identified downstream of the ald gene, suggesting it to be a discrete transcriptional unit. This structure could, however, play an alternative role, perhaps as a binding site for a DNA-binding regulatory protein.

View larger version (8K): [in this window] [in a new window]   FIG. 1.   Map of the rpoE1 region. The rpoE1 gene, which was shown to lie downstream of frzZ, was cloned and sequenced on pBS9 and various subclones (not shown). The EcoRI-XhoI fragment from pAD-RpoE1 which when expressed in yeast showed a potential interaction with the expressed insert in pBD-Z1, and was used as a probe to identify pBS9, is shown. The start of the large frz operon, which is transcribed divergently from frzZ, is also shown. Restriction enzyme cut sites: E, EcoRI; S, SacI; X, XhoI.

View larger version (29K): [in this window] [in a new window]   FIG. 2.   Alignment of the newly identified M. xanthus (M.x.) ECF sigma factor, RpoE1, with the previously identified M. xanthus CarQ sigma factor (14) and RpoE from E. coli (E.c.) (5).

Transcriptional regulation of rpoE1 expression. We found a potential terminator downstream of the 3' end of the ald gene and a potential ECF sigma factor binding site upstream of the rpoE1 gene (by alignment with the carQRS promoter site [Fig. 3]). Although both structures were determined by sequence analysis alone, they were suggestive that the ald and rpoE1 genes could be transcriptionally separate. To determine if the rpoE1 gene could be transcribed from this putative ^E promoter, primer extension analysis, using a primer within the rpoE1 gene close to the ATG start codon, was performed on both vegetative and developmental RNA samples. A transcriptional start site was identified upstream of rpoE1 in both samples (Fig. 3), although it was shown to be positioned downstream of a potential ⁷⁰-type promoter rather than the potential ^E promoter. However, since primer extension studies identify only 5' ends of RNA transcripts, further investigation will be required to confirm the promoter status of either site.

View larger version (30K): [in this window] [in a new window]   FIG. 3.   Primer extension analysis (left) used to identify the transcriptional start site for expression of the rpoE1 gene, within the ald-rpoE1 intergenic region (right). A sequencing reaction (TCGA), performed with the same primer, is shown next to the primer extension analysis on vegetative (v) and developmental (d) RNA templates. Potential E and 70 promoters are underlined (bold), with alignments to the carQRS promoter region and the 70 consensus, respectively. A second potential 70 promoter (TGCATA-16 bp-GACAAC), closer to the proposed transcriptional start site, was also identified. The potential SD site upstream of rpoE1 is also underlined. The 3' end of the ald gene is shown upstream of rpoE1, with the proposed transcriptional terminator identified by inverted arrows.

Mutational analyses. A 500-bp, PCR-derived internal fragment of the rpoE1 gene was cloned into pZErO-2 to create pZRpoE1. This construct was electroporated into M. xanthus, and cells which had acquired the plasmid were selected for by antibiotic resistance. Since the vector is unable to replicate in M. xanthus, kanamycin-resistant electroporants should arise through the integration of the vector into the host genome at the rpoE1 gene by homologous recombination. A single crossover event using such an internal fragment of the rpoE1 gene would therefore result in two truncated copies of rpoE1 in the genome, separated by the kanamycin-resistant vector. Mutants produced by this technique were screened for, and shown to contain, correct insertion mutations by Southern analysis (data not shown).

View larger version (60K): [in this window] [in a new window]   FIG. 4.   Swarming of DZF1 and DZF1 rpoE1 cells on CYE medium containing 1.5% agar. Cells were photographed after 3 days of incubation.

View larger version (63K): [in this window] [in a new window]   FIG. 5.   Developmental aggregation of DZF1 and DZF1 rpoE1 cells stabbed directly onto CF agar plates. The DZF1 rpoE1 aggregation phenotype was photographed after 24 h of incubation, since substantial darkening occurs after longer periods, obscuring the worm trail effect. The DZF1 aggregation pattern is shown after 48 h of incubation.

View larger version (92K): [in this window] [in a new window]   FIG. 6.   Density-dependent aggregation effect of the rpoE1 mutant shown in both DZF1 and DZ2 backgrounds. Cells were spotted directly onto CF plates and photographed after 96 h of incubation.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

In this study, we have identified a second homologue belonging to the ECF subfamily of sigma factors, RpoE1, in M. xanthus. The original identification, using interaction trap technology, with the first domain of the directed-motility-associated protein FrzZ as bait, suggested that RpoE1 could potentially interact with FrzZ. However, control interaction screens suggest that RpoE1 might also interact with a second response regulator protein, AsgA. While this second interaction was weaker than the RpoE1-FrzZ interaction, the possibility remains that both interactions are nonspecific. Therefore, the specificity of the RpoE1-FrzZ interaction remains speculative, and further studies, using alternative protein-protein analysis techniques, are required to convincingly characterize what would be an unusual and interesting interaction.

While a direct protein-protein interaction between RpoE1 and FrzZ remains unconfirmed, sequence analysis of the region surrounding the rpoE1 gene showed it to be genetically linked to the frzZ gene. Two transcriptionally divergent genes are positioned between the frzZ and rpoE1 genes. Neither gene has a known function in M. xanthus, although we presume that the ald gene may encode a functional alanine dehydrogenase due to the high degree of amino acid homology found in this protein. Mutational analyses performed on both genes (not reported in this study) suggest that neither is involved with vegetative swarming, developmental aggregation, or sporulation. The presence of a potential terminator structure between the ald and rpoE1 genes suggested that these genes could be transcriptionally separate.

The identification of a potential ECF sigma factor binding site upstream of the rpoE1 gene indicated that RpoE1, or another ECF sigma factor, might regulate transcription of rpoE1. However, primer extension studies performed on RNA samples extracted from both vegetatively growing and developmental cells suggested that the gene is transcribed under both conditions from a ⁷⁰-like promoter positioned downstream of the potential ^E-like promoter. A dot blot analysis confirmed the low-level, constitutive expression of the rpoE1 gene. While the possibility still exists that the proposed ^E promoter is functional under a specific set of conditions and might cause enhanced transcription of the gene, currently we have no indication of whether this region is actually a promoter or under what conditions it might be active.

The genetic organization of the ORFs downstream of rpoE1 suggested that rpoE1 and orf5 could be transcriptionally linked. The identification of a potential terminator structure at the end of the orf5 gene suggested that the orf6 gene might then be transcriptionally separate. RT-PCR was therefore used to analyze these possibilities and demonstrated that, in fact, both orf5 and orf6 are read on a single transcript with the rpoE1 gene. Since the currently available sequence covers only a portion of the orf6 gene, we are unable to speculate on the presence of further genes within this operon. However, it appears that rpoE1, orf5, and orf6 can be transcribed from a ⁷⁰-type promoter positioned upstream of the rpoE1 gene, although it remains possible that the downstream genes also have separate promoters.

ECF sigma factors have been proposed to respond to extracytoplasmic stimuli and regulate extracytoplasmic functions (12). Mutational analysis of cells with an insertion at the rpoE1 site suggest that rpoE1 may play a role in regulating motility behavior during both vegetative swarming and developmental aggregation. These phenotypes are unlikely to be associated with loss of function of the genes downstream of rpoE1, since cells with mutations in orf5 showed normal swarming and aggregation. However, rpoE1 mutants do still swarm and can form normal aggregates, particularly at lower cell densities, indicating that the role of RpoE1 may be cell density specific. The potential role of RpoE1 in regulating motility behavior during both vegetative swarming and developmental aggregation again draws analogy with the Frz signal transduction system. However, the aggregation phenotypes produced by frz mutants are highly distinctive, swirling patterns, disparate from the rpoE1 aggregation phenotype, and are not known to be cell density dependent.

In conclusion, we have identified a putative ECF sigma factor, RpoE1, in M. xanthus. The rpoE1 gene has been shown to be genetically linked to the frzZ gene. The RpoE1 protein also shows a potential (although currently speculative) interaction with the first domain of FrzZ in a two-hybrid analysis. In addition, RpoE1 appears to be involved in the regulation of motility behavior during both vegetative swarming and developmental aggregation. While the Frz system is known to regulate motility behavior under both of these situations, the RpoE1 developmental defect appears to be cell density specific and the resultant aggregation patterns are unique. Currently we are involved in expressing the RpoE1 protein to facilitate further protein-protein interaction studies (in order to confirm or refute an interaction between RpoE1 and the Frz signal transduction system) and to confirm functional sigma factor status for RpoE1. We are also interested in identifying an active ^E promoter and any genes which may be transcriptionally regulated by RpoE1.