INTRODUCTION

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In response to starvation, the gram-negative bacterium Myxococcus xanthus initiates a multicellular developmental program that culminates in cells aggregating and forming a fruiting body (19). Within this structure vegetative cells differentiate into spores. This process depends on gliding motility. Gliding is controlled by two distinct genetic systems called adventurous (A)-motility and social (S)-motility (22). S-motility, but not A-motility, depends on polar type IV pili (58, 61). Most of the M. xanthus pil genes are homologous to type IV pil genes found in Pseudomonas aeruginosa and Neisseria gonorrhoeae, which are also required for a type of motility called twitching and for pathogenesis (33, 53). These pili may retract, as well as polymerize, and they may provide the force for movement by pushing and pulling cells (2, 53). Many type IV pil genes are homologous to type II secretion genes (general secretion pathway) (42). In the type IV system, pilin (PilA) is the only known secretion product (33).

Pili and fibrils have been shown to mediate cohesion among cells and adhesion to substrates (4, 49, 61). Cohesive cells clump or aggregate in suspension, and their clumps stick to the walls of culture flasks. Native cultures of M. xanthus isolated from soil fail to suspend in liquid culture. To obtain dispersed growth in liquid medium, a spontaneous mutant which retained the ability to form fruiting bodies was isolated after continuous selection; it was named strain FB (15). This mutant of M. xanthus was amenable to necessary microbiological manipulations, such as dilutions, and as a result most laboratory strains were derived from strain FB. Later work showed that this mutation was in a social gliding motility gene, named sglA (22). Unlike other sgl mutations, the sglA1 mutant retains some S-motility and expresses pili at reduced levels, suggesting that sglA1 is a hypomorphic allele (23). Strains which carry sglA1 can form fruiting bodies on agar but not in submerged culture (27). This quality is associated with the decreased cohesiveness of sglA1 mutants, which consequently are unable to form a mat of cells (biofilm) within which fruiting bodies can develop. Strain DK1622 was constructed from strain FB; DK1622 is sglA⁺, fully S-motile, and capable of developing in submerged culture. Type IV pili are required by P. aeruginosa to form a biofilm (40), a process that resembles the formation of fruiting bodies (12).

Here we report the mapping and cloning and the sequence of the sglA locus. SglA is found to belong to a large family of proteins called secretins (33), which include PilQ proteins from P. aeruginosa and N. gonorrhoeae. To indicate the molecular nature of sglA, we have changed its name to pilQ, as has been done for other sgl genes in M. xanthus when their functions were recognized. In-frame deletions in pilQ and its downstream gene orfL were constructed. pilQ is shown to be essential for the biogenesis of pili and for S-motility, while orfL is not. The origin of the pilQ⁺ DK1622 strain and the role of PilQ in M. xanthus are discussed.

	MATERIALS AND METHODS

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Bacterial strains, phage, plasmids, and DNA manipulations. Bacterial strains and plasmids are listed in Table 1. M. xanthus was cultured in CTT medium, CTT agar, or 1/2 CTT agar plates (21). DNA manipulations were done in Escherichia coli XL1-Blue cultured in Luria-Bertani medium (46). Antibiotics were added when appropriate (kanamycin at 20 µg/ml for M. xanthus and at 40 µg/ml for E. coli and ampicillin at 100 µg/ml). M. xanthus chromosomal DNA preparations, plasmid preparations, DNA manipulations, and Southern hybridizations were all performed as recommend by the manufacturers or as described previously (46, 58).

DNA sequencing and analysis. Double-stranded plasmid DNA was sequenced with the Thermo Sequenase cycle-sequencing kit (Amersham Life Sciences). Restriction fragments were generated and cloned into pBluescript SK or pBGS18 (51) for sequencing. Additional deletion subclones were generated with exonuclease III (46). Primers were designed to cover gaps in the sequence. Both strands were completely sequenced at least once.

Development. Cells were grown overnight in CTT and placed at a calculated density of 1,000 Klett units on CF or TPM starvation agar plates (26). Fruiting body formation and rippling were monitored with a Leitz inverted microscope. Spore counts and -galactosidase assays were performed as described previously (6, 26).

Immunoblotting and autoradiography. Proteins were separated by sodium dodecyl sulfate (SDS)-12% polyacrylamide gel electrophoresis (PAGE) and transferred to Immobilon P membranes (Millipore) (46). For Western blotting the membrane was probed with rabbit anti-PilA serum diluted 1:4,000 (59), followed by peroxidase-conjugated goat anti-rabbit immunoglobulin G (Boehringer Mannheim) diluted 1:2,000. The blots were developed with Renaissance chemiluminescence reagent (NEN Life Science Products).

Constructing in-frame deletions of pilQ and orfL. A plasmid, pDW131, which deleted in frame 2,175 bp or 725 codons from the coding region of pilQ, was generated via PCR. To construct this pilQ in-frame deletion, two primers were designed, one for each end of the gene, oriented in opposite directions. These primers, pQ1 (5'-GCGAAGCTTGCCGGAGCCTGGGCGGCGAC-3') and pQ2 (5'-GCGAAGCTTCATTGCGCAGACTCTGTAAGG-3'), had unique HindIII restriction sites (underlined) engineered in their 5' tails. In separate PCRs, two fragments of pilQ DNA were amplified with pQ1 and pQ2, along with corresponding primers that were upstream and downstream of pQ1 and pQ2, respectively. These PCR products were cloned and subsequently ligated together via the HindIII restriction sites, generating an in-frame deletion with a HindIII restriction site inserted. The region across this deletion and insertion was verified by sequencing. To avoid PCR complications, a 0.45-kb BstEII-MluI cassette containing the deletion was swapped with the corresponding cassette of pDW105, generating pDW130. A Km^r-Gal^s cassette (52) was then cloned into the EcoRI-BamHI sites of pDW130, generating pDW131. pDW131 was electroporated into DK1622 and DK1217, and homologous recombination into the chromosomal locus was selected for by Km^r. Candidate transformants were screened for the expected tandem duplication of the pilQ⁺ and pilQ alleles by Southern analysis. Recombinants with the expected duplication were then grown in CTT for 1 day to enrich for cells with a second recombination event that lost pDW131 and one of the pilQ alleles, thus leaving either a pilQ⁺ or pilQ allele at the chromosomal locus. Such recombinants were selected for by galactose resistance. These Gal^r colonies were screened for Km^s. Southern analysis was used to identify recombinants that had only the pilQ allele left at the chromosomal locus.

Nucleotide sequence accession number. The nucleotide sequence of pilQ and orfL has been deposited in GenBank under accession no. AF100157.

	RESULTS

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Mapping and cloning sglA. A Tn5 transposon, 3188, linked to the sglA locus had been isolated by David Morandi in this laboratory (unpublished). When 3188 was transduced into DK101 (sglA1), we observed some S⁺ transductants. However, 3188 is also linked to 10 other pil genes (58, 60, 61). To estimate the physical distance separating 3188 and the sglA locus, transductional crosses were made between DK1217 (A S⁺) as the recipient and DK8611 (3188 sglA1) as the donor. Of 231 Km^r transductants scored, 163 were S, a cotransduction frequency of 70% (Fig. 1). Given that bacteriophage Mx4 packages 65 kb of DNA, Wu's formula (62) suggests that the sglA1 mutation is 7 kb from 3188. Three point crosses between 2231, 3188, and sglA implied that the sglA locus lies to the right of 3188 relative to 2231, as depicted in Fig. 1.

View larger version (18K): [in this window] [in a new window]   FIG. 1.   Genetic map of the pil cluster. Triangles above the line represent Tn5 insertions that do not cause a S-motility defect, while those below the line inactivate S motility. The cotransduction frequency between 3188 and sglA (pilQ1) is given (arrow). The second line shows four pil genes that map to the left of 3188, and the relevant restriction sites are indicated. The abilities of plasmids to rescue the S-motility defect of sglA1 are indicated as follows: +, able to rescue; , unable to rescue.

View larger version (10K): [in this window] [in a new window]   FIG. 2.   Genetic organization of pilQ and orfL. ORFs are read from left to right. The relevant restriction sites are indicated. The two pilQ1 mutations are shown, along with the new restriction site (SacI) generated by the mutation at codon 741. The black lines below these ORFs represent the regions removed by the in-frame deletions.

View larger version (42K): [in this window] [in a new window]   FIG. 3.   (A) Modular representation of PilQ. The 29-amino-acid signal sequence (SS), the low-homology region, and the three conserved subdomains are shown. (B) Protein sequence of PilQ. The signal sequence is underlined. The two residues that are changed in PilQ1 are in boldface (residues 741 and 762), as is the signature sequence (V,I)PXL(S,G)XIPXXGXLF. (C) Protein sequence of OrfL. A putative type II signal sequence is underlined, and the signature sequence for a phosphopantetheine attachment site is in boldface.

pilQ mutants. The rescue data shown in Fig. 1 narrowed the location of the pilQ1 (sglA1) mutation to an approximately 250-bp region. Accordingly, we cloned and sequenced this segment of the DNA from a pilQ1 mutant. Two closely linked missense mutations were found, one at codon 741 and a second at 762, which would generate GlySer and AsnGly amino acid substitutions, respectively (Fig. 2 and 3). The missense mutation (GA) in codon 741 creates a new SacI restriction site (Fig. 2). Both mutations lie in the most highly conserved one-third of the carboxyl end of the protein (Fig. 3). Residues that correspond to 741 and 762 show only limited conservation within the secretin family (9, 16, 35, 44). Some family members contain a Gly-741 and an Asn-762, like the pilQ⁺ allele, in these residues. Other members contain different residues, including the PilQ1 mutant alleles, Ser-741, and/or Gly-762. The natural occurrence of the mutant residues is consistent with the fact that the pilQ1 allele retains some biological activity. Whether both missense mutations are required to obtain the PilQ1 phenotype is not known.

Function of pilQ, as deduced from a null mutant. A deletion mutant of pilQ was constructed; the deletion was made in frame to avoid potential polar effects. Effects of the pilQ mutation on S motility were monitored by constructing the double mutant aglB1 pilQ (DK8616). DK8616 was plated on 1/2 CTT 0.5% agar plates, and as shown in Fig. 4, it failed to swarm. No flares were evident at any time over a 6-day period of observation. DK320 (aglB1 pilQ1) also failed to swarm in the absence of CaCl₂. The active swarming and flare formation of DK1217 (aglB1 pilQ⁺) are shown at 6 h for comparison (Fig. 4; note the time difference). Even after prolonged incubation (>20 days) flares were never observed, implying a total loss of S motility in DK8616 (pilQ). DK320 (pilQ1), by contrast, would produce some flares by 20 days (data not shown). Earlier studies have shown that Ca²⁺ is required for gliding motility (57). Although Ca salts are not added to the standard formulations of CTT or 1/2 CTT media, Ca²⁺ is nevertheless present in trace amounts in the agar, casitone, and water that are used for these media. We tested whether Ca²⁺ might be limiting by adding 2 mM CaCl₂, and as shown in the bottom row of Fig. 4, the addition of CaCl₂ did not dramatically change the swarming of DK1217. However, CaCl₂ did enhance the swarming of DK320 (Fig. 4, top row). No swarming of the pilQ strain DK8616 was evident with or without CaCl₂ addition (Fig. 4, middle row). These results suggest that Ca²⁺ may be limiting in 1/2 CTT agar for a pilQ1 mutant.

View larger version (152K): [in this window] [in a new window]   FIG. 4.   Swarming in the presence (2 mM CaCl2) and absence (CaCl2) of CaCl2 on 1/2 CTT 0.5% agar plates. The pictures were taken at 6 days for DK320 (aglB1 pilQ1) and DK8616 (aglB1 pilQ) and at 6 h for DK1217 (aglB1 pilQ+).

View larger version (57K): [in this window] [in a new window]   FIG. 5.   (A) Western blot for PilA expression from 5 × 106 whole cells. (B) Detection of extracellular pili (PilA) from 2 × 108 cells. The pili were sheared off the cells by passage through a 25-gauge 3.5-inch needle as previously described (59). The strains are DK1622 (WT), DK8613 (L), and DK8615 (Q).

Origin of DK1622. Despite its wide use, a detailed description of the origin of DK1622 has never been published. Although DK1622 is a descendent of DK101 (pilQ1), it has a pilQ⁺ allele, resulting in full S-motility, as shown in Fig. 6. DK1622 cells are able to form biofilms and to develop in submerged culture (27). Unlike DK101, DK1622 forms symmetric fruiting bodies, it ripples during development; and it forms fruiting bodies faster than DK101. For these reasons DK1622 is commonly used as a "wild-type" strain. It should be noted, however, that during the construction of DK1622 a 222-kbp deletion occurred that removed several tandem copies of a prophage-like element called Mx alpha without other structural rearrangements, since the physical maps are otherwise identical (5). This deletion may have occurred during the UV irradiation of DK101 used to generate DK320 (22).

View larger version (120K): [in this window] [in a new window]   FIG. 6.   Role of pilQ in swarming. Strains were inoculated on 1/2 CTT 0.5% agar plates and incubated for three days at 33°C. Genotypes: DK101, pilQ1; DK8612, pilQ+ (isogenic derivative of DK101); DK1622, pilQ+; and DK8615, pilQ (isogenic derivative of DK1622).

Role of pilQ in development. S-motility is necessary for rippling, and it plays an important role in fruiting body development (22, 50, 60). The specific effects of the pilQ mutation on development were examined. Figure 7 shows that the aggregation stage of development was greatly delayed in the pilQ mutant DK8615: At 72 h, aggregates appeared, with structures similar to those seen 60 h earlier (at 6 to 10 h) in wild-type cells. These aggregates never developed into dark fruiting bodies (Fig. 7). On hard (1.5%) agar, A-motility dominates (Fig. 7, top). On soft (0.5%) agar, S-motility dominates (48). Figure 7 (bottom) shows that aggregation and fruiting body formation were completely blocked in the pilQ strain on soft agar, nor did ripples ever form. These results suggest that under certain conditions, i.e., hard agar, A-motility can partially substitute for the lack of S-motility.

View larger version (105K): [in this window] [in a new window]   FIG. 7.   Development on CF. DK1622 (pilQ+) and DK8615 (pilQ) were placed on 1.5 or 0.5% CF agar plates, and development was monitored over three days as indicated.

View larger version (18K): [in this window] [in a new window]   FIG. 8.   Developmental expression of 4414 (A) and 4401 (B) on TPM (1.5%) agar. Reporter -galactosidase transcriptional fusions are in DK1622 () or DK8615 (). ONP, o-nitrophenol.

View larger version (69K): [in this window] [in a new window]   FIG. 9.   Rippling on CF agar. DK101 (pilQ1) and DK8612 (pilQ+) were placed on CF (1.5%) agar at a cell density of 1,000 Klett units and allowed to develop for 5 days at 27°C.

orfL. Thirty-nine base pairs downstream of pilQ is the 220-amino-acid ORF orfL. A Shine-Dalgarno site (GGAG) was found 12 bp upstream from its putative translational start ATG. OrfL shows no significant sequence homology to any other protein in the GENEMBL database. However, orfL does contain a type II signal sequence (discrimination score, 4.3), suggesting that it may encode a lipoprotein. A lipid moiety would be predicted to be attached to Cys-17 (Fig. 3C). Near the C terminus of OrfL there is a signature sequence for a phosphopantetheine attachment site (Fig. 3C). Phosphopantothenate is the prosthetic group of acyl carrier proteins in some multienzyme complexes, where it functions as a "swing arm" for the attachment of activated fatty acids and amino acid groups. These enzymes produce diverse products, such as polyketide antibiotics and nodulation factor for Rhizobium species. In OrfL the putative pantetheine attachment site is Ser-170 (Fig. 3C).

Protein secretion. M. xanthus secretes many proteins and is one of the most active secreters among gram-negative bacteria (17). Protein secretion appears to be required for (i) transporting catabolic enzymes into the medium for vegetative growth, (ii) intercellular signaling, and (iii) production and assembly of type IV pili. In gram-negative bacteria, type II and III secretion systems are major pathways for protein transport. Both of these pathways employ secretins. In P. aeruginosa, there is some overlap between type II secretion and type IV pilus production. The same protein, PilD/XcpA, is used by both systems as a signal peptidase, for example (38). In addition, secretion of type II-dependent proteins is decreased by a pilA mutation (31). To test whether a pilQ mutation had an effect on protein secretion in M. xanthus, the spectrum of proteins secreted into the medium was examined. Figure 10 shows the protein composition of concentrated [³⁵S]methionine-cysteine-labeled culture supernatants separated by PAGE. The pilQ mutant had an amount and profile of proteins similar to those of the pilQ⁺ culture when grown in CTT-rich medium (casitone has low levels of methionine and cysteine). The pilQ supernatant did contain a >100-kDa protein that was absent in the pilQ⁺ supernatant. When these identical cultures were shifted from CTT to A1 minimal medium (3) for 6 h, there were significant changes in the patterns of proteins found in the culture supernatants. Some proteins were more abundant in A1, e.g., those at 17, 31, 51, 62, and ~120 kDa, while others decreased, e.g., those at 24, 36, 38, and 45 kDa. Compared to growth in CTT, greater differences between pilQ⁺ and pilQ strains were seen in A1. Six proteins at 31, 32, 50, 55, 58, and 84 kDa were more abundant, while the protein(s) at ~120 kDa was less abundant in pilQ supernatants. In N. gonorrhoeae, pilQ mutations result in increased levels of PilC (~105 kDa) and S-pilin (soluble truncated pilin, ~16 kDa) in culture supernatants (13, 14). Perhaps some of these more abundant proteins from M. xanthus pilQ supernatants are Pil proteins.

View larger version (48K): [in this window] [in a new window]   FIG. 10.   Profile of proteins found in culture supernatants. DK1622 (WT) and DK8615 (Q) cells were grown in either CTT or A1 minimal medium with Tran35S-label. Culture supernatants were precipitated with trichloroacetic acid, and protein samples were separated by SDS-12% PAGE. The positions of molecular mass standards (in kilodaltons) are given.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

We have shown that pilQ (sglA) encodes a secretin homolog. Secretins are an evolutionarily conserved superfamily of proteins involved in macromolecular transport across the outer membrane in three different secretion systems. Secretins are the only proteins common to type II (including type IV pili), type III, and filamentous phage secretion systems, suggesting that they play a fundamental role (33). In all three systems secretins are found in the outer membrane, where they form ring structures of 10 to 18 secretin subunits. These cylindrical structures, as visualized by electron microscopy, have central cavities ranging in size from 50 to 95 Å (1, 25, 30). Such cavities are large enough to accommodate the transport of folded proteins and assembled macromolecular complexes, such as filamentous phage (diameter, 65 Å) or type IV pili (diameter, ~52 Å). Our evidence that pilQ mutants lack pili and that pilQ1 mutants are hypersensitive to vancomycin also suggests that PilQ functions as a channel for type IV pilus export. In M. xanthus these polar pili have been observed to extend from "polar holes" (32). It is tempting to speculate that these polar holes are multimeric PilQ channels.

Multimerization of secretin subunits in the outer membrane requires assembly factors or chaperones. For example, the secretins PulD and OutD require their cognate assembly factors, PulS and OutS, for localization and assembly in the outer membrane (8, 18, 47). The PulS and OutS lipoproteins bind to the C-terminal 65 and 62 amino acids of PulD and OutD. M. xanthus PilQ protein does not have a C-terminal binding sequence, nor has a PulS or OutS homolog been identified in M. xanthus. Instead, multimerization of PilQ may be mediated by a PilP-like lipoprotein, as has been shown for N. gonorrhoeae (14). Upstream of the M. xanthus pilQ gene is an ORF that shows homologies to N. gonorrhoeae and P. aeruginosa pilP (unpublished data). Another candidate for a protein that interacts with PilQ is the Tgl lipoprotein (54), which contains six tandem tetratricopeptide repeats (43), motifs which are known to mediate protein-protein interactions (11). In M. xanthus we are interested in how these three proteins might interact.

Secretins can serve as signals for the induction of stress genes. During the course of filamentous bacteriophage (e.g., f1 or M13) infection in E. coli or overproduction of the phage secretin GpIV, it was discovered that an operon called pspABCE (for phage shock protein) is induced (reviewed in reference 37). This ⁵⁴-dependent operon is also specifically induced by the expression of other heterologous secretins, starvation, osmotic shock, heat stress, or ethanol stress (18, 37). Mutations in psp result in a loss of viability during stationary phase, and the mutants have defects in protein transport and maintaining membrane potential (37). Model and coworkers explain a diverse set of results by proposing that the secretin signal for psp induction is the process of insertion and assembly of a secretin in the outer membrane (37). Conditions which render this insertion process slow or inefficient or which mislocalize it lead to amplification of the signal for psp induction. In M. xanthus these findings are of interest because many differences have been found between pilQ⁺ and pilQ1 strains during development. For example, frz (che homolog) mutants are defective in sporulation in a pilQ⁺ background but sporulate at wild-type levels in a pilQ1 background (24). To explain this suppression, perhaps the PilQ1 mutant protein results in a psp-like induction of stress genes, which could compensate for the frz sporulation defect.

Fruiting body development depends on cell-cell signaling (6, 19, 28, 29) and on cell movement. Mutational defects in pilQ retard aggregation (Fig. 7) by eliminating S-motility. A decrease in the efficiency of C signaling is evident in the decreased expression of the 4414 reporter (Fig. 8A). The developmental defects of asg and dsg mutants worsen in a pilQ1 background (28). In that background (DK101) asgB and asgC mutants fruit poorly and produce only 10% as many viable spores as the parental strain (28). In a pilQ⁺ (DK1622) background, asgB and asgC mutants sporulate at 43 and 100% efficiencies relative to their parental strain and their morphological defects are less severe. A-factor, which requires asg genes, is a set of eight amino acids which are released by the action of extracellular proteases on extracellular proteins (28, 29, 41). Enhancement of the asg defect suggests that the PilQ secretin may be involved in releasing peptides, proteins, and proteases from the cell, and hence in A-factor production. If there were such a defect, then when the pilQ1 allele is combined with asgB or asgC mutations it could exaggerate their developmental defects.

In addition, dsg mutants fail to form fruiting bodies in a pilQ1 background and their ability to sporulate is reduced >10,000-fold (6). However, in a pilQ⁺ background dsg mutants can sporulate at wild-type levels, though aggregation is delayed. Recently, it has been suggested that the developmental block in dsg mutants is not related to a new signaling molecule but instead is a result of lower A-factor levels (6a). Thus, similarly to asg mutants, dsg would fail to develop due to the secretion defect of pilQ1.

Several caveats relating to genetic interactions with pilQ should be mentioned. First, pilQ1 mutants have pleotropic defects, including defects in piliation, S-motility, cell cohesiveness, and permeability properties. Any one or a combination of these defects could have indirect effects on other mutations. Second, the strains used, e.g., DK1622 and DK101 (or DZF1 and DZ2), are less isogenic (see "Origin of DK1622" in Results) than DK101 and DK8612 or DK1622 and DK8615. Third, the molecular natures of the pilQ alleles were not previously defined. Here we have constructed an in-frame deletion mutant, sequenced the pilQ1 mutations, and identified 19 additional pilQ alleles. Hopefully, these new alleles and the construction of DK8612 and DK8615 will facilitate understanding the genetic relationships between pilQ and other properties of the cell.

Our characterization of PilQ extends the striking similarities between proteins involved in S-motility and those required for twitching motility in P. aeruginosa and N. gonorrhoeae (53, 58). Additionally, we have found S-motility genes upstream of pilQ (downstream of pilD) which are homologous to the pilM, -N, -O, and -P genes from Pseudomonas sp. and N. gonorrhoeae (references 14 and 34 and unpublished data). No S-motility mutants or pil ORFs have been found downstream of pilQ, suggesting that pilQ is at the end of the pil cluster. Extensive screens for genes required for S-motility have yielded 160 mutants (22, 37a). About 100 of these mutations map to the pil cluster described here, and another 7 map to the tgl locus (reference 43 and unpublished data), which is also required for pilus assembly. This screen may be approaching saturation, since many of the new mutations are falling into known S-motility genes, e.g., 20 independent mutations map to pilQ, 4 map to pilA (58), 5 map to pilT (61), and the aforementioned 7 map to tgl. The genomes of P. aeruginosa and N. gonorrhoeae are sequenced, and at least in the case of P. aeruginosa, a near-saturation screen for twitching motility genes has been completed. Almost all of the twitching genes are either pil genes, transcriptional regulators, or, in the case of P. aeruginosa, signal transduction genes, i.e., frz and che homologs (10, 36) (N. gonorrhoeae has no obvious che homologs). Thus, type IV pilus genes are the major genetic determinant for S-motility and twitching motility. Future work with M. xanthus will be aimed at understanding how pil gene products interact and how they contribute to S-motility.