All Seven comG Open Reading Frames Are Required for DNA Binding during Transformation of Competent Bacillus subtilis

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J Bacteriol, January 1998, p. 41-45, Vol. 180, No. 1
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

All Seven comG Open Reading Frames Are Required for DNA Binding during Transformation of Competent Bacillus subtilis

Y. S. Chung and D. Dubnau^*

Public Health Research Institute, New York, New York 10016

Received 15 September 1997/Accepted 19 October 1997

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

The seven proteins encoded by the comG operon of Bacillus subtilis exhibit similarity to gene products required for the assemblyof type 4 pili and for the secretion of certain proteins in gram-negativebacteria. Although polar transposon insertions in comG resultin the loss of transformability and in the failure of cells grownthrough the competence regimen to bind DNA, it was not known whetherthe ComG proteins are all required for competence. We have constructedstrains missing each of these proteins individually and foundthat they are all nontransformable and fail to bind transformingDNA to the cell surface. The implications of these findings arediscussed.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Naturally competent organisms, such as Bacillus subtilis, efficiently bind and internalize transforming DNA. This processrequires a set of proteins that was first identified in B. subtilis(reviewed in reference 9) but which has more recently beenshown to mediate transformation in a variety of bacterial species,both gram positive and gram negative (8, 11-13, 17, 21,27). Among these proteins are several possessing hydrophobicN termini with cleavage sites for processing typical of type 4prepilins. The comG operon of B. subtilis encodes four such proteins(1), which are processed by a mechanism that requires ComC(6, 7), also an essential transformation protein (18).The predicted amino acid sequence of ComC resembles those of agroup of proteins known to process the prepilins of gram-negativebacteria (20, 26). In addition to the four prepilin-like ComGproteins (ComGC, ComGD, ComGE, and ComGG), the comG operon encodesthree other proteins: ComGF is a small integral membrane proteinwith no known ortholog, and ComGA and ComGB are predicted to bea nucleotide binding protein and an integral membrane protein,respectively (1). Both ComGA and ComGB resemble morphogeneticproteins, such as PilB and PilC from Pseudomonas aeruginosa (19),which are required for the assembly of type 4 pili.

With the exception of ComGF, the comG and comC gene products all resemble proteins needed for the secretion of certain proteinsacross the outer membrane of gram-negative organisms (23). Thus,members of the same families of proteins are required for pilusassembly, protein secretion, and competence for genetic transformation.Aside from the facts that the ComC orthologs in the secretoryand pilus assembly systems are needed for the processing of theircognate prepilin-like proteins and that one of the prepilin proteinsis the structural component of pili, little is known concerningthe precise functions of these gene products. Particularly curiousis the fact that all three systems (competence, secretion, andpilus assembly) involve multiple members of the prepilin proteinfamily.

Null comC and comG mutants are nontransformable and appear to exhibit no additional phenotype (1, 18). In null comC mutants,competence is reduced at least 10⁷-fold, suggesting that the processing of at least one prepilin-likeprotein is required for transformation. An in-frame deletion mutationin comGC and a transposon insertion mutation in comGG also completelyeliminate transformation. However, since the available transposoninsertion mutations in the remaining comG proteins are polar ondownstream open reading frames, including comGG, it is not knownif the ComGA, -GB, -GD, -GE, and -GF gene products are individuallyrequired for competence.

In this study, we have constructed strains in which the comG open reading frames are individually inactivated. These strainsare completely noncompetent and are deficient in DNA binding whengrown under conditions in which the remaining competence proteinsare expressed. We conclude that each of the ComG proteins is neededfor DNA binding, and we discuss certain implications of this result.

	MATERIALS AND METHODS

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Strains and growth conditions. All of the B. subtilis strains used were derivatives of strain 168 (Table 1). Competent cultures were grown as describedpreviously (3), and extracts for Western blotting were preparedfrom cultures grown in competence medium (3) to a point 2 hafter the transition to stationary phase (T₂), at which time thecultures were maximally competent.

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TABLE 1. B. subtilis strains used in this study

Transformation. Competent cultures were incubated with transforming DNA (1 µg/ml) for 30 min at 37°C.

DNA manipulations and strain construction. Molecular cloning and related procedures were carried out by standard methods (24).

The strains carrying in-frame deletions in comGA (BD2685) and comGB (BD2686) were constructed as follows. Plasmid pMA13, carryingcomGABC (2), was cut with AvaI (blunt ended with T4 polymerase)and with BglII. The resulting fragment carrying comGABC was clonedinto pUCCM18 (15), a pUC18 derivative which carries a chloramphenicolresistance (Cm^r) marker. SphI (blunt ended) and BamHI sites were used for thiscloning. The resulting plasmid was cut with SphI and NheI, bluntended, and self-ligated. This removed 486 in-frame base pairsencoding 162 of the 356 amino acid residues of comGA (residues139 through 300). The plasmid carrying this deletion was usedto transform BD630 with selection for Cm^r transformants which had received the deleted allele by singlereciprocal recombination and also carried an intact copy of comGA.This transformant was then grown in the absence of chloramphenicolselection to allow the loss of one of the copies of comGA. Thedesired strains were detected by replica plating, and severalsuch colonies were tested by PCR to detect those carrying onlythe deletion allele of comGA.

To construct the comGB deletion strain, the same AvaI (blunt ended)-BglII fragment from pMA13 was cloned between the BanIIand BamHI sites of pUC19. The resulting plasmid was cut with BanIIand StuI and self-ligated. This removed 501 in-frame base pairsencoding 167 of the 323 residues of comGB (residues 36 through202). A fragment carrying the deletion allele in comGB was removedfrom this plasmid by cutting with EcoRI and XbaI and then clonedinto pUCCM18 which had been cut with the same enzymes. The resultingplasmid was then used to construct a strain of B. subtilis carryingthe comGB deletion in place of the wild-type comG allele, as describedabove for the comGA deletion.

To clone a fragment containing comGCDEFG, the plasmid pED19 (1), which carries the entire comG operon, was cut with StuIand KpnI. The latter enzyme cuts at a unique site downstream fromcomGG, and StuI cuts in comGB. The resulting fragment was clonedinto pG67, which had been cut with SmaI and KpnI. The vector pG67was a derivative of pDR67 (16) into which a fragment containingthe comG promoter, isolated by PCR, had been inserted betweenthe EcoRI and BamHI sites (14a). Cutting with EcoRI and BamHIremoved the pSPAC promoter from pDR67. pG67 carried genes forchloramphenicol and ampicillin resistance as well as amyE frontand back sequences present in pDR67. As a result, fragments underthe control of the comG promoter could be readily inserted atthe B. subtilis amyE locus. comGCDEFG-carrying derivatives ofthis plasmid with individual in-frame deletions in comGD, comGE,and comGF were then prepared. These deletions were introducedby using the QuickChange site-directed mutagenesis kit (Stratagene).This involved a limited number of amplification cycles with thehigh-fidelity Pfu DNA polymerase (Stratagene) and complementaryprimers, each carrying a desired deletion and about 10 bases flankingeach deletion. The mutagenized fragments were then sequenced todocument the presence of the expected deletions and to ensurethat no unplanned mutations had been introduced. The wild-typeand deletant fragments were each integrated at amyE. For comGD,codons 65 through 78 were deleted. For comGE, codons 46 through60 were deleted. For comGF, codons 83 through 97 were deleted.

Finally, comG107, a polar Tn917 insertion in comGC, was introduced into the strains carrying comGCDEFG and its deletion derivativesby transduction with phage PBS1, generating strains BD2684 throughBD2689 (1) (see Fig. 1).

DNA binding. [³H]thymidine-labeled DNA was prepared by metabolic labeling of BD204 (his thyA thyB) as described previously (10). To measurebinding, competent cultures were incubated as described above,0.5-ml samples were withdrawn and washed three times in minimalsalts solution (4), and radioactivity was determined by scintillationcounting.

Western blotting. Antibody to ComGG was raised in rabbits against a peptide (CDQKQKKLLRWTE) corresponding to the C-terminal 12 residues of thatprotein, with the addition of the single C residue used for couplingto maleimide-activated bovine serum albumin (Pierce). Antibodyagainst ComGA was raised in rabbits by injecting the peptide CDHALLKKRDMKKEE-NH₂,which had been coupled to maleimide-activated keyhole limpet hemocyanin.This peptide corresponds to ComGA amino acid residues 39 to 52,with the addition of the single C residue. Membranes were purifiedas described previously (6) and fractionated by sodium dodecylsulfate-polyacrylamide gel electrophoresis in a Tricine buffersystem (25). The gels were blotted to nitrocellulose membraneswith a Bio-Rad semidry transfer apparatus and the standard buffer(28). Signals were detected by enhanced chemiluminescence (ECL;Amersham).

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

A transposon insertion in comGG, the last open reading frame in the comG operon, as well as an in-frame deletion in comGCresulted in transformation-deficient strains that were incapableof binding DNA (5, 14). These studies did not determine whetherthe remaining five comG open reading frames were required fortransformation and for DNA binding.

Phenotypes of comGA and comGB mutants. In-frame deletions which removed 162 of 336 and 167 of 323 amino acid residues, respectively, were constructed in cloned copiesof comGA and comGB. The mutations were introduced into the B.subtilis chromosome, replacing the wild-type copies of comGA andcomGB. This was accomplished by transforming a wild-type strain(BD630) with DNA from plasmids carrying the deletion alleles andselecting for the Cm^r marker located within the vector. Single reciprocal recombinationevents resulted in the insertion of the entire plasmid withincomG, with duplication of comGA or comGB, so that the transformantseach possessed one wild-type and one deleted copy of the comGopen reading frame. Growth of the resulting strains in the absenceof antibiotic selection permitted the loss of the plasmid andof either the wild-type or deleted comG allele. Cm^s colonies were detected by replica plating and screened by PCRto identify colonies that carried only the deleted alleles. Thenonpolar nature of the comG $Delta$ A and comG $Delta$ B mutations was verifiedby Western blotting of membrane preparations. For this, antiserumagainst the downstream-most comG gene product, ComGG, was used.In both mutant backgrounds, ComGG was produced at levels similarto that of the wild-type strain (data not shown). Western blottingwith anti-ComGA antiserum revealed that the ComGA signal was missingfrom a comG $Delta$ A membrane preparation but was present in preparationsfrom the wild-type and comG $Delta$ B strains (data not shown).

Transformation of a chromosomal marker was undetectable in either the comG $Delta$ A or the comG $Delta$ B strain (Table 2), demonstratingthat both gene products were essential for transformability.

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TABLE 2. Transformation phenotypes of comG mutants

Construction of comGD-, comGE-, and comGF-deficient strains. A different strategy was adopted for the construction of strains individually lacking comGD, comGE, and comGF, to avoid thetime-consuming procedure described above for introducing the comGAand comGB deletions into the chromosome. In-frame deletion derivativesof each gene were constructed in a cloned fragment that carriedthe comGCDEFG open reading frames, as described in Materials andMethods. The vector used for this cloning carried the comG promoter,so that expression of the cloned genes remained under competencecontrol. The three deletion constructs, as well as the fragmentwith the wild-type comGCDEFG fragment, were individually integratedat the amyE locus by replacement recombination. The resultingstrains were then transformed with a Tn917 insertion mutationin comGC, which is known to be polar. In these transformant strains(Fig. 1), the ComGA and ComGB products should be provided by theintact open reading frames at the comG locus while the other products,with the exception of the deleted one, would be provided by thefragment integrated at amyE. Each strain would therefore be uniquelymissing one of the three proteins. To confirm that the in-framedeletions were in fact nonpolar, the presence of ComGG was confirmedby Western blotting (data not shown). ComGG was present in membranepreparations derived from strains carrying the comGC transposoninsertion only if the wild-type or mutant fragments with deletionsin comGD, -GE, or -GF were present at amyE.

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FIG. 1. Genotypes of strains used for the complementation experiments. (A) The mutations used in this study are indicated on a map of the comG operon. The numbers in parentheses correspond to the number of deleted amino acid residues followed by the total number of residues in the open reading frame. The horizontal bar extending from the comG107 arrow indicates that this Tn917 insertion is polar on expression of the downstream open reading frames in the operon. ComGG217 is also a Tn917 insertion mutation. (B) Each of the four strains diagrammed carries the comG107 transposon mutation at the comG locus. In addition, each of them carries a copy of comGCDEFG inserted at the amyE locus, either the wild type or one with an in-frame deletion of comGD, comGE, or comGF as indicated. Strain BD2684 therefore exhibits complementation of comGC107, whereas strains BD2687, BD2688, and BD2689 fail to express ComGD, -GE, and -GF, respectively.

Table 2 contains transformation data obtained with these strains. As expected, no detectable transformation was exhibitedby the strain carrying only the Tn917 insertion in comGC. Whenthe intact fragment carrying comGCDEFG was integrated at amyEin this strain, the level of transformation was essentially equalto that of the wild-type control. This demonstrated that the completefragment, integrated at the ectopic amyE site, was able to completelycomplement the polar transposon mutation. In contrast, the isogenicstrains individually lacking ComGD, ComGE, and ComGF exhibitedno detectable transformation (Table 2), demonstrating that eachof these gene products was essential for competence.

All of the ComG proteins are required for DNA binding. Competence mutants can be deficient in DNA binding to the cell surface or in a subsequent step, such as the transport of transformingDNA across the cell membrane. Binding is measured as the associationof radioactively labeled DNA with competent cells after centrifugalwashing. Transport is determined as the association of the labeledDNA in DNase-resistant form and cannot be measured in bindingmutants.

DNA binding was measured in the mutant strains constructed in this study and in the wild-type strains grown through the competenceregimen (Table 3). The strain carrying a polar insertion in comGCwas, as expected, deficient in binding, and the comGCDEFG fragmentinserted in the amyE locus complemented binding activity in thisstrain nearly to the wild-type level. The in-frame comGA and comGBmutations eliminated binding completely, as did the absence, individually,of ComGD, ComGE, and ComGF. Finally, as reported previously, aTn917 insertion in comGG likewise resulted in the loss of DNAbinding. The transformation deficiency of each of the comG mutantscan therefore be explained by the failure of these strains tobind DNA to the cell surface.

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TABLE 3. DNA binding by comG mutants

	DISCUSSION

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This study, together with previous experiments (5, 14), revealed that each of the seven ComG proteins is essential forthe binding of DNA to the competent-cell surface. ComC, a peptidaserequired for the processing of ComGC, ComGD, ComGE, and ComGG,is also required for DNA binding (14). This is most simply interpretedas indicating a requirement of processing for the function ofone or more of these proteins. Since these null mutations resultin the complete absence of binding, we cannot exclude the possibilitythat one or more of the ComG proteins are also required for transport.For instance, ComEA is required for both binding and transport,since a mutation in this protein that eliminates binding has beenisolated while another mutation eliminates uptake but not binding(15). We have recently found that ComEA acts as a DNA bindingprotein in vitro (22).

The ComG proteins must somehow function together with ComEA to bind transforming DNA to the cell surface. The bound DNA mustthen engage the transport machinery, which consists minimallyof ComEA, ComEC, and ComFA. Since ComEA is required for both bindingand transport, it may function at the interface of the bindingand transport machinery, for instance, by presenting the boundDNA to the exterior of a transport pore. Alternatively or additionally,it may be required to process the bound DNA to a form competentfor transport, for instance, by generating a newly cleaved terminus.We have observed that the processed forms of the pilin-like ComGproteins are located on the outer face of the membrane as wellas outside the cell membrane (6, 7), possibly in associationwith cell wall material. ComEA contains a single membrane-spanningsegment near its N terminus and extends outward from the membranesurface (15). Thus, these proteins are appropriately locatedto constitute a DNA binding receptor complex. There is no evidencethat the pilin-like proteins themselves bind directly to DNA.They may instead be required for the correct presentation of ComEAat the surface of the cell, for instance, by remodeling cell wallmaterial. Alternatively, by analogy with the part played by thepilin-like proteins in certain protein secretion systems of gram-negativeorganisms, these proteins may be needed for secretion of an unknowncompetence protein. However, in the gram-negative systems, transportacross the inner membrane is mediated by the sec machinery andthe pilin-like proteins are needed for secretion across the outermembrane (23). Since no outer membrane is present in B. subtilis,we favor the first hypothesis.

Like the processing peptidase ComC, ComGA and ComGB are orthologs of proteins required for the assembly of type 4 pili, whichare not themselves part of the completed organelle. They are thereforelikely to play morphogenetic roles in the assembly or disassemblyof a DNA binding structure located at the cell surface. This iscertainly true for ComC, whose role has been assigned. An understandingof the parts played by ComGA and ComGB, as well as the roles ofthe prepilin-like proteins, awaits the characterization of theproposed cell surface complex.

	ACKNOWLEDGMENTS

This work was supported by Public Health Service grant GM43756.

We thank Gordon Inamine for useful discussions and members of our lab for their support and for comments on the manuscript.

	FOOTNOTES

^* Corresponding author. Mailing address: Public Health Research Institute, 455 First Ave., New York, NY 10016. Phone: (212)578-0842. Fax: (212) 578-0804. E-mail: dubnau{at}phri.nyu.edu.

REFERENCES

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

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Appl. Environ. Microbiol.	Infect. Immun.	Eukaryot. Cell
Mol. Cell. Biol.	J. Virol.	Microbiol. Mol. Biol. Rev.
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