Characterization of the Gene Cassette Required for Biosynthesis of the (alpha 1right-arrow6)-Linked N-Acetyl-D-Mannosamine-1-Phosphate Capsule of Serogroup A Neisseria meningitidis

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J Bacteriol, March 1998, p. 1533-1539, Vol. 180, No. 6
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Characterization of the Gene Cassette Required for Biosynthesis of the ( $alpha$ 1 $right-arrow$ 6)-Linked N-Acetyl-D-Mannosamine-1-Phosphate Capsule of Serogroup A Neisseria meningitidis

John S. Swartley,¹^,²^,³ Li-Jun Liu,³^,¹^,³ Yoon K. Miller,¹^,³ Larry E. Martin,¹^,³ Srilatha Edupuganti,¹^,³ and David S. Stephens¹^,²^,³^,^*

Departments of Medicine¹ and Microbiology and Immunology,² Emory University School of Medicine, and Department of Veterans Affairs Medical Center,³ Atlanta, Georgia

Received 21 August 1997/Accepted 13 December 1997

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

The ( $alpha$ 1 $right-arrow$ 6)-linked N-acetyl-D-mannosamine-1-phosphate meningococcal capsule of serogroup A Neisseria meningitidis is biochemicallydistinct from the sialic acid-containing capsules produced byother disease-associated meningococcal serogroups (e.g., B, C,Y, and W-135). We defined the genetic cassette responsible forexpression of the serogroup A capsule. The cassette compriseda 4,701-bp nucleotide sequence located between the outer membranecapsule transporter gene, ctrA, and galE, encoding the UDP-glucose-4-epimerase.Four open reading frames (ORFs) not found in the genomes of theother meningococcal serogroups were identified. The first serogroupA ORF was separated from ctrA by a 218-bp intergenic region. Reversetranscriptase (RT) PCR and primer extension studies of serogroupA mRNA showed that all four ORFs were cotranscribed in the oppositeorientation to ctrA and that transcription of the ORFs was initiatedfrom the intergenic region by a $sigma$ -70-type promoter that overlappedthe ctrA promoter. The first ORF exhibited 58% amino acid identitywith the UDP-N-acetyl-D-glucosamine (UDP-GlcNAc) 2-epimerase ofEscherichia coli, which is responsible for the conversion of UDP-GlcNAcinto UDP-N-acetyl-D-mannosamine. Polar or nonpolar mutagenesisof each of the ORFs resulted in an abrogation of serogroup A capsuleproduction as determined by colony immunoblots and enzyme-linkedimmunosorbent assay. Replacement of the serogroup A biosyntheticgene cassette with a serogroup B cassette by transformation resultedin capsule switching from a serogroup A capsule to a serogroupB capsule. These data indicate that assembly of the serogroupA capsule likely begins with monomeric UDP-GlcNAc and requiresproteins encoded by three other genes found in the serogroup AN. meningitidis-specific operon located between ctrA and galE.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Recurrent, devastating epidemics of meningitis and septicemia due to serogroup A Neisseria meningitidis continue to plaguemany parts of the developing world (2, 28, 29, 31, 32,42, 43) and can produce attack rates that approach 1% of thepopulation. The serogroup specificity of N. meningitidis is determinedby the structure of the expressed capsular polysaccharide. Theserogroup A capsule is composed of repeating units of ( $alpha$ 1 $right-arrow$ 6)-linkedN-acetyl-D-mannosamine-1-phosphate (26). This structure is chemicallydistinct from those of the capsules of the other major disease-associatedmeningococcal serogroups, B, C, Y, and W-135, which are composedof or contain sialic acid. The genes required for biosynthesisof the sialic acid-containing capsules of N. meningitidis haverecently been characterized (38), but the genetic basis forserogroup A capsular polysaccharide biosynthesis has not beendefined.

We and others (15, 38) have previously shown that serogroup A N. meningitidis contains a homolog of ctrA, the first offour polycistronic genes, ctrA to -D, found in meningococcal serogroupsB, C, Y, and W-135. The ctrA to -D genes are members of the ABCtransporter family and encode proteins involved in the transportof the assembled capsule across the inner and outer membranes(14). The serogroup A ctrA homolog, however, is distinct inSouthern ClaI fragment size (38) and 5' nucleotide sequence(15) from ctrA in the sialic acid capsule-expressing serogroups.Adjacent to the 5' end of ctrA in serogroups B, C, Y, and W-135is a 134-bp intergenic region separating the ctrA to -D transportcluster from the sialic acid biosynthesis and capsule polymerasegenes, synA to -D (E, F, G) (37, 38). In this report we characterizethe genetic cassette immediately upstream of ctrA in serogroupA N. meningitidis and establish its role in ( $alpha$ 1 $right-arrow$ 6)-linked N-acetyl-D-mannosamine-1-phosphatecapsule biosynthesis.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Strains, plasmids, and growth conditions. Serogroup A meningococcal strains F8229 and F8239 were originally isolated during an outbreak in Nairobi, Kenya in 1989 (32)and were provided by the Centers for Disease Control and Prevention(CDC), Atlanta, Georgia. Strain F8229 (CDC1750) is encapsulatedand was clinically isolated from the cerebrospinal fluid of apatient with meningitis. Strain F8239 (CDC16N3) is an unencapsulatedvariant originally isolated as a serogroup A strain from the pharynxof an asymptomatic carrier. These strains belong to clonal groupIII-1 and are closely related to strains that have caused epidemicsin Saudi Arabia, Chad, Ethiopia, and other parts of the world(2, 28, 31, 32). F8229-ORF1 $Omega$ , F8229-ORF2 $Omega$ , F8229-ORF2aphA-3,F8229-ORF3 $Omega$ , and F8229-ORF4 $Omega$ are serogroup A mutants created byinsertional mutagenesis, as described below. Strains F8229-43and F8229-43^R were created by transformation of strain F8229 with chromosomalDNA obtained from serogroup B meningococcal mutant strain 43 (37).

Escherichia coli $alpha$ InvF' (Invitrogen, San Diego, Calif.) was used as the host strain for all cloned PCR products and recombinantplasmids created during these studies. Plasmid pHP45 (33) wasthe source of the spectinomycin-resistant $Omega$ -fragments used forpolar gene mutagenesis (see below), and plasmid pUC18K (27)was the source of the aphA-3 kanamycin resistance cassette usedfor nonpolar mutagenesis (see below).

Meningococcal strains were grown on gonococcal (GC) base agar (Difco Laboratories, Detroit, Mich.) or in GC broth (30) at37°C with 3.5% CO₂, with the exception of meningococcal mutantsgrown under kanamycin selection, which was performed on brainheart infusion base agar (Becton Dickinson and Co., Cockeysville,Md.) containing 2.5% fetal bovine serum (GIBCO BRL, Gaithersburg,Md.) at 37°C with 3.5% CO₂. E. coli strains were grown in Luria-Bertani(LB) broth or on LB agar plates (GIBCO BRL) at 37°C. Antibiotics(Sigma Chemical Co., St. Louis, Mo.) were used at the followingfinal concentrations: kanamycin, 60 µg/ml; spectinomycin, 100µg/ml; ampicillin, 100 µg/ml; and tetracycline, 5 µg/ml.

Nucleic acid purification. Chromosomal DNA was isolated from N. meningitidis by the procedure described by DiLella and Woo (12). RNA was prepared bya previously described modification of the method published byBaker and Yanofsky (3, 37). DNA was digested with restrictionendonucleases obtained from New England Biolabs, Beverly, Mass.

Standard PCR and SSP-PCR. Standard PCRs were performed as previously described (39). Amplitaq DNA polymerase (Perkin-Elmer, Norwalk, Conn.) was usedfor these reactions, and in some reactions, Taq Extender PCR additive(Stratagene, La Jolla, Calif.) was used to increase efficiencyand reliability. The oligonucleotide primers used are shown inTable 1. Amplified products were visualized by 1.2% agarose gelelectrophoresis and UV detection after ethidium bromide staining.PCR products were purified by passage through QIAquick PCR purificationspin columns (Qiagen, Chatsworth, Calif.) prior to further manipulations.Chromosome walking via single-specific-primer (SSP) PCR was performedby the technique described by Shyamala and Ames (34) and previouslyused by us (37).

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TABLE 1. Oligonucleotide primers used in this study

Primer extension and RT-PCR. We used the AMV Reverse Transcriptase Primer Extension System (Promega, Madison, Wis.) according to the manufacturer's directions.A reverse transcriptase (RT) PCR assay developed in our laboratoryand previously described was used for these studies (37).

Colony PCR. A single colony from a plated culture was collected with a sterile loop and was resuspended in 20 µl of sterile distilledwater. The colony suspension was then subjected to two roundsof freeze-thawing using a dry-ice-ethanol bath and a 37°C waterbath. One microliter of the freeze-thaw mixture was then usedas the template in standard PCR.

Cloning of PCR products. DNA products amplified by standard PCR or SSP-PCR were cloned with the TA Cloning Kit (Invitrogen) or the pGEM-T Vector System(Promega).

Nucleotide sequencing. Purified plasmid DNA and PCR products were sequenced by both manual and automated means. For manual sequencing we used theAmpliCycle Cycle Sequencing Kit (Perkin-Elmer) according to themanufacturer's directions. Automated DNA sequencing was performedwith the Prism Dye-Deoxy Terminator Cycle Sequencing Kit (AppliedBiosystems, Inc. [ABI], Foster City, Calif.), and completed reactionswere run on an ABI model 377 Automated DNA Sequencer.

Nucleotide and amino acid sequence analysis was performed with either the DNASTAR (Madison, Wis.) sequence analysis packageor the Genetics Computer Group (GCG) sequence analysis softwarepackage, version 7.3.1-UNIX (11). We also used search toolsand nucleotide and amino acid databases available on the Internet;sites visited included the National Center for Biotechnology Information(http://www.ncbi.nlm.nih.gov), the FA1090 gonococcal genomedatabase at the University of Oklahoma's Advanced Center for GenomeTechnology (http://www.genome.ou.edu), and the Institute forGenomic Research (http://www.tigr.org).

DNA transformation procedures. Serogroup A meningococcal strain F8229 was transformed by the semiquantitative transformation assay of Janik et al. (18).Chemical transformation of E. coli was performed by the methoddescribed by Chung et al. (6).

Southern DNA hybridization. We used the Genius nonradioactive DNA labeling and detection system (Boehringer Mannheim, Indianapolis, Ind.). Specific DNAprobes were PCR amplified, labeled with digoxigenin, and usedto probe Southern DNA blots (35) under high-stringency conditionsaccording to the manufacturer's protocols.

Polar and nonpolar insertional mutagenesis. Polar mutagenesis of defined genes was conducted by insertion of an $Omega$ -spectinomycin resistance cassette derived from pHP45.Briefly, the genetic region to be interrupted was amplified byPCR from chromosomal DNA and then cloned into E. coli $alpha$ InvF'.The plasmid containing the cloned PCR product was then linearizedat a unique, blunt-ended restriction site present in the insert.A blunt SmaI fragment derived from pHP45, containing the entire $Omega$ -spectinomycin resistance cassette, was then ligated into thecloned product and transformed into E. coli with selection forspectinomycin resistance. Putative transformants were checkedby colony PCR to confirm assembly of appropriate constructs. PlasmidDNA was prepared from confirmed colonies and was used to transformserogroup A strain F8229 with selection for spectinomycin resistance.Putative meningococcal transformants were checked by colony PCRand Southern DNA hybridization to confirm acquisition of the polar $Omega$ -insertion mutation by homologous recombination. Primers JS102and JS103 (Table 1) were used to amplify a 600-bp PCR fragmentfrom the 5' end of the F8229 open reading frame 1 (ORF1) whichwas subsequently cloned in E. coli. This product contained a uniqueStuI restriction site located 356 bp downstream of the predictedORF1 start codon. A SmaI fragment from pHP45, encoding the $Omega$ -spectinomycinresistance cassette, was inserted into the unique StuI site, andthe resulting recombinant plasmid was used to transform wild-typeserogroup A strain F8229. Spectinomycin-resistant transformantswere selected, and acquisition of the $Omega$ -insertion was confirmedby colony PCR and Southern hybridization.

A similar approach was used to introduce $Omega$ -spectinomycin resistance cassettes into ORF2, ORF3, and ORF4. To inactivate ORF2,a 451-bp DNA fragment derived from ORF2 was PCR amplified fromstrain F8229 with primers JS104 and JS105 (Table 1). An $Omega$ -fragmentwas inserted into a unique HincII site present in the cloned PCRproduct (located 729 bp from the putative ORF2 start codon), andthe resulting plasmid was transformed into strain F8229. PrimersSE57 and SE61 (Table 1) were used to amplify an 858-bp productfrom ORF3, containing a unique SspI site located 507 bp downstreamof the ORF3 start codon. Again, an $Omega$ -fragment was inserted intothis cloning site, and the construct was transformed into F8229.Finally, a 765-bp product was amplified from ORF4 with primersSE63 and SE56 (Table 1). The unique SspI cloning site in thisproduct was located 159 bp from the putative ORF4 start codon.An $Omega$ -fragment was inserted into the cloning site, and the constructwas transformed into F8229.

Nonpolar mutants were created by the allelic exchange technique described above; however, instead of a polar $Omega$ -fragment, anonpolar aphA-3 kanamycin resistance cassette derived from pUC18K(27) was inserted into the genetic region to be mutated. Theorientation of the aphA-3 insertion was checked by colony PCRand direct DNA sequencing of the product to ensure that the ATGstart site at the end of the cassette was in frame to the downstreamsequence.

Serum selection for capsule revertants. Strain F8229-43 was exposed to normal human serum (NHS) in order to screen for serogroup B capsule revertants. A 100-µl aliquotcontaining 25% NHS and 3.75 × 10⁴ meningococci, diluted in HEPES-minimal essential medium, wasincubated at 37°C for 30 min. The entire aliquot was then platedon a GC agar plate containing 5 µg of tetracycline/ml, and survivors(e.g., putative capsule revertants) were collected after overnightgrowth. Revertants were studied for serogroup-specific capsulephenotype by using colony immunoblots and whole-cell enzyme-linkedimmunosorbent assay (ELISA), as described below.

Capsule quantitation by colony immunoblot and whole-cell ELISA. Colony immunoblots were performed as previously described (36) by using the anti-serogroup A monoclonal antibody 14-1-A(45) (generously provided by Wendell Zollinger, Walter ReedArmy Institute of Research). Whole-cell ELISA was performed bythe method of Abdillahi and Poolman (1). Briefly, strains tobe assayed were grown overnight on GC agar plates. Plate growthwas then harvested and suspended in 5 ml of phosphate-bufferedsaline containing 0.02% sodium azide (Sigma Chemical Co.). Thecells were heat inactivated at 56°C for 30 min, then adjustedto an A₆₅₀ of 0.1 and stored at 4°C to be used in assays within1 week. To perform the ELISA, 100 µl of the cell suspension wasadded to a flat-bottom microtiter plate (Maxi-sorp or Poly-sorp[Nalge Nunc International, Naperville, Ill.]) and evaporated overnightat 33°C. The plate was then washed three times with a 0.05% solutionof Tween 80 (Sigma Chemical Co.) in sterile water. One hundredmicroliters of monoclonal antibody 14-1-A (diluted 1:30,000 inphosphate-buffered saline containing 0.01% Tween 80 and 0.3% CasaminoAcids [Difco Laboratories]) was added to each well, and the platewas incubated at 33°C for 1 h. After three washes, 100 µl of goatanti-mouse immunoglobulin A (IgA), IgG, and IgM alkaline phosphatase-conjugatedantibody (ICN Pharmaceuticals, Inc., Costa Mesa, Calif.) was added(diluted 1:10,000 in the above buffer), and the plate was incubatedfor 90 min at 33°C. The plate was washed three times, 200 µl ofsubstrate (1 mg of p-nitrophenyl phosphate [Sigma Chemical Co.]dissolved per ml of 0.5 M diethanolamine buffer containing 0.5mM MgCl₂ [pH 9.8]) was added, and the plate was left to standat room temperature for 20 to 45 min. The reaction was stoppedby the addition of 50 µl of 3 N NaOH, and the A₄₀₅ of each wellwas read with a BIO-TEK Instruments (Winooski, Vt.) model EL 312eAutomated Plate Reader. Mean values were averages of 3 to 10 opticaldensity values for individual wells ± standard deviations (SD).

Nucleotide sequence accession number. The nucleotide sequences and predicted amino acid translations described in this article have been submitted to GenBank andare available under accession no. AF019760.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Serogroup A ctrA-to-galE nucleotide sequence. The nucleotide sequence spanning the region between ctrA and galE in the encapsulated serogroup A meningococcal strain F8229was determined by a combination of standard PCR and SSP-PCR. PrimerLJ4, which anneals to a sequence complementary to the 5' end ofctrA, and primer SE26, which anneals to a sequence upstream ofctrA (Table 1; Fig. 1), were used to "chromosome walk" 2.2 kbupstream of ctrA in strain F8229 by SSP-PCR. Sequence obtainedfrom these products was used to construct primer SE33, designedto anneal to the 3' end of the 2.2-kb region. Primer SE33 andprimer GalE1, designed to anneal to a sequence complementary tothe 5' end of galE, were used to PCR amplify the additional 2.5kb of DNA separating ctrA and galE. The double-stranded sequenceof the 4,701-bp stretch separating ctrA from galE in serogroupA N. meningitidis was determined from these products by a combinationof manual and automated DNA sequencing methods. The sequence wasfurther confirmed by analysis of overlapping PCR products (Fig.1).

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FIG. 1. Genetic organization of the ~4.7-kb region separating ctrA and galE in serogroup A meningococcal strain F8229. Open arrows, drawn to scale, represent the locations and orientations of ORF1 to -4. Dotted open arrows indicate the flanking genes ctrA and galE only, portions of which are shown. Open triangles point to the locations of insertion mutations created in ORF1 to ORF4 (see text). Locations of primers (Table 1) are shown by solid arrows.

Computer analysis of the 4.7-kb sequence indicated the presence of four ORFs transcribed in the opposite orientation fromctrA (Fig. 1). The first ORF (ORF1) was separated from ctrA bya 218-bp intergenic region. ORF1 was 1,119 nucleotides and waspredicted to encode a 372-amino acid (aa) protein. ORF1 was separatedby a single base pair from the second ORF, designated ORF2, whichwas 1,638 bp and was predicted to encode a 545-aa protein. ORF2was in turn separated by 72 bp from a 744-bp ORF, designated ORF3,predicted to encode a 247-aa protein. Finally, ORF3 was separatedby a single nucleotide from an 864-bp ORF, designated ORF4, whichwas predicted to encode a 287-aa protein.

In addition to the sequence derived from the encapsulated wild-type strain F8229, we also sequenced the first 2,330 bp ofthe region between ctrA and galE in the unencapsulated serogroupA variant strain F8239. Comparison of the nucleotide sequencesderived from F8239 and F8229 indicated that they were nearly identical(11 nucleotide differences [7 deletions or additions, 2 transversions,and 2 transitions]) over the entire 2.2-kb stretch. However, instrain F8239, ORF1 was predicted to be only 744 nucleotides (encodinga 247-aa predicted protein). Computerized alignment of the putativeamino acid translation of the F8239 and F8229 ORF sequences indicatedthat in F8239, ORF1 was prematurely truncated by a frameshiftmutation.

Analysis of serogroup A ctrA-to-galE ORFs. Nucleotide and predicted amino acid sequences of the putative ORFs were compared to the GenBank/EMBL and other genome projectdatabases, including the FA1090 gonococcal genome database (seeMaterials and Methods for Internet addresses). The ORF1 productshowed homology (57.8% amino acid identity and 73.9% similarity)with a cytoplasmic E. coli protein designated NfrC. The 1,131-bpnfrC gene encodes a 377-aa protein predicted to be a UDP-N-acetyl-D-glucosamine2-epimerase (21). ORF2 demonstrated nucleotide and predictedamino acid homology with three separate ORFs of unknown function,the 1,632-bp cpsY of Mycobacterium leprae (30.6% identity and51.7% similarity) (GenBank/EMBL accession no. U15182), a similarORF in the Mycobacterium tuberculosis genome, and a 1,125-bp ORF(ORF5) found downstream of galE/rfbBCD in serogroup B N. meningitidis(GenBank/EMBL accession no. L09188) (16). ORF3 did not exhibitnucleotide or predicted protein homology with any genes or proteinscurrently in the databases. ORF4 exhibited distant homology withthe XcpS protein of Pseudomonas putida (19.4% identity over a129-aa overlap [GenBank/EMBL accession no. X81085] [10])and appeared to share an amino acid motif (aa 123 to 168) withthe presenilin (8) class of eukaryotic proteins. Except forthe homology of ORF2 with the unknown ORF5 in serogroup B N. meningitidis,ORF1 to -4 were not found in the genomes of other meningococcalserogroups or Neisseria gonorrhoeae by database search or Southernhybridizations (data not shown).

ORF1 to -4 are transcribed as an operon. To determine whether ORF1 to ORF4 were organized as an operon, we performed RT-PCR experiments on whole-cell RNA obtainedfrom strain F8229. The results, shown in Fig. 2, indicate thatORF1 to ORF4 are cotranscribed on the same mRNA message. The startsite of transcription of the ORF1 to ORF4 operon, as defined byprimer extension (Fig. 3), was located within the 218-bp intergenicregion separating ctrA and ORF1 (Fig. 4). This transcriptionalstart site was preceded by a putative $sigma$ -70 promoter sequence (17).The $-$ 35 region of the ORF1 promoter, TTTATT, had a three-of-sixmatch to the consensus $sigma$ -70 $-$ 35 promoter binding sequence andwas 18 bp from the $-$ 10 region (Pribnow box) sequence, TATATT.The serogroup A ctrA transcriptional start site was also presentin the 218-bp intergenic region, as shown by primer extension(Fig. 4). The serogroup A ctrA promoter overlapped the ORF1 promoteron the complementary DNA strand. However, the $-$ 35 region of thectrA promoter, TTGTGT, had less resemblance to the $sigma$ -70 consensus $-$ 35 promoter binding sequence.

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FIG. 2. RT-PCR of mRNA prepared from wild-type serogroup A strain F8229 to detect an ORF1 to ORF4 polycistronic transcript. Primer SE56 (Table 1; Fig. 1), which is complementary to the 3' end of ORF4, was used as the RT extension primer to generate cDNA in the RT reaction [RT (+)]. A control without RT added [RT ( $-$ )] was included under otherwise identical conditions. Primers SE46 and SE61 were used for PCR amplification of an approximately 2.8-kb ORF1-to-ORF4 product. Lane 1, 1-kb ladder (Gibco-BRL); lane 2, positive control using F8229 chromosomal DNA as the template; lane 3, PCR result using the RT (+) template; lane 4, negative control using the RT ( $-$ ) template. DNA size standards (in base pairs) are indicated.

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FIG. 3. Autoradiographs showing primer extension products for the serogroup A meningococcal genes ctrA and ORF1. Primer extension reactions were loaded alongside standard double-stranded DNA-sequencing reactions (load orientation of G, A, T, C) obtained by sequencing ctrA and ORF1 control DNA templates with the extension primers SE40 (ctrA) and SE41 (ORF1). The DNA sequence surrounding the primer extension bands has been expanded. The nucleotides corresponding to the putative start points of transcription are circled.

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FIG. 4. Nucleotide sequence of the 218-bp intergenic region separating the start codons for the serogroup A ctrA and ORF1 loci. The start points and directions of transcription of the ORF1 and ctrA mRNAs are indicated by t_i and arrows, respectively. Predicted $-$ 10 and $-$ 35 promoter binding sequences are indicated, as well as the putative Shine-Dalgarno ribosome binding sites (RBS). The predicted initiation codons for ctrA and ORF1 are shown in boxes.

Mutations of ORF1 to ORF4. To confirm the role of ORF1 to ORF4 in serogroup A capsule expression, we created insertion mutations in each of the ORFsin the wild-type encapsulated strain F8229 (Fig. 1). Strains F8229-ORF1 $Omega$ ,F8229-ORF2 $Omega$ , F8229-ORF3 $Omega$ , and F8229-ORF4 $Omega$ were created by $Omega$ -spectinomycininsertional mutagenesis of each of the ORFs. PCR and Southernhybridizations (data not shown) confirmed the correct insertionof the $Omega$ -spectinomycin fragments in each of the mutants (Fig.1). Immunoblots, shown in Fig. 5, demonstrated that polar mutagenesisof all of the four ORFs in wild-type strain F8229 resulted ina reduction or loss of encapsulation. These data were confirmedby a quantitative capsule whole-cell ELISA in which the wild-typeencapsulated strain F8229 was used as the 100% standard (A₄₀₅= 0.939 ± 0.16 [mean ± SD]). Strains F8239, F8229-ORF1 $Omega$ , and F8229-ORF2 $Omega$ demonstrated a 100% reduction versus the wild-type strain (A₄₅₀= 0), while F8229-ORF4 $Omega$ demonstrated an 89% reduction (A₄₅₀ =0.101 ± 0.007).

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FIG. 5. Colony immunoblots of wild-type serogroup A meningococcal strain FA8229, its ORF1 to -4 mutants, and unencapsulated variant F8239. Strains were grown overnight on GC base agar, transferred to nitrocellulose, and probed with anti-serogroup A monoclonal antibody 14-1-A (45). (A) Wild-type encapsulated strain F8229; (B) unencapsulated variant F8239; (C) F8229-ORF1 $Omega$ ; (D) F8229-ORF2 $Omega$ ; (E) F8229-ORF2aphA-3; (F) F8229-ORF3 $Omega$ ; (G) F8229-ORF4 $Omega$ .

We also attempted to create nonpolar interruptions of ORF1 and ORF2 by integrating an aphA-3 cassette into the same uniquesites used for the $Omega$ -cassette mutagenesis, but, despite repeatedattempts, we were able to integrate this fragment only into ORF2,producing F8229-ORF2aphA-3. Like the polar $Omega$ -spectinomycin mutants,the nonpolar interruption of ORF2 also resulted in the completeloss of group A capsule expression, as shown by whole-cell ELISA.To further confirm the function of this cassette in serogroupA capsule production, we repaired the F8229-ORF1 $Omega$ mutation withthe 4.7-kb PCR product generated by primers SE40 and GalE1. Capsule-expressingtransformants were selected by survival in 25% NHS, and serogroupcapsule A expression was confirmed by colony immunoblot. Repairof the ORF1- $Omega$ mutation in these transformants was further confirmedby PCR with primers JS102 and JS103.

Capsule switching. We attempted to determine whether replacement of the ctrA-galE capsule cassette in serogroup A strain F8229 with a serogroupB cassette was sufficient to switch capsule expression. ChromosomalDNA from the serogroup B Tn916 meningococcal mutant strain 43(37) was prepared and used to transform encapsulated serogroupA strain F8229. Strain 43 contains a class I "intact" Tn916 insertionin the synD capsule polymerase gene of the group B capsule biosyntheticgene cassette. Tetracycline-resistant transformants of strainF8229 were obtained at a frequency of ~1 × 10⁷. The transformants were checked by colony immunoblot for lossof serogroup A capsule production, and one unencapsulated mutant,designated F8229-43, was saved for further analysis. Strain F8229-43was screened by passage through 25% NHS to identify capsule revertantsresulting from the precise excision of the Tn916 insertion fromsynD (predicted to occur at a frequency of ~10⁴), resulting in restoration of capsule production and serum resistance.A serum survivor, designed F8229-43^R, was tested by colony immunoblot using monoclonal anti-serogroupA and anti-serogroup B antibodies. The F8229-43^R strain no longer expressed the serogroup A capsule, but insteadexpressed serogroup B capsular polysaccharide. PCR confirmed thatthe F8229-43^R strain did not contain a serogroup A biosynthetic gene cassettebut instead harbored an intact serogroup B cassette (data notshown).

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

The biosynthesis of the serogroup A capsule of N. meningitidis requires genes that are not found in other meningococcal serogroups.However, the overall genomic organizations of the capsule transportand biosynthesis regions of serogroup A meningococci and of thesialic acid-containing capsular serogroups (B, C, Y, and W-135)are similar. In all serogroups, the genes of the ctr capsule transportoperon are preceded by an intergenic region which separates thisoperon from divergently transcribed operons required for capsulebiosynthesis. The capsule biosynthetic operons are distinct geneticcassettes located between ctrA and galE encoding the UDP-glucose-4-epimeraseinvolved in lipooligosaccharide biosynthesis (24).

Based on the data presented here, previous studies of the biosynthetic cassettes of serogroups B, C, Y, and W-135 (38),and epidemiologic observations, the meningococcal biosyntheticgene cassettes can undergo recombinational exchange resultingin capsule switching. The genetic mechanism by which cassetteexchange occurs is not defined but may be the result of homologousrecombination between identical regions in the ctr operon andgalE. Replacement of the capsule cassette and, possibly, of adjacentgenes (e.g., ctrA) appears to be sufficient for capsule switchingin N. meningitidis. E. coli, Streptococcus pneumoniae, and Haemophilusinfluenzae also contain type-specific capsule gene cassettes whichmay be transferred by transformation and recombination events,resulting in a switching of the type of capsule expressed (5,7, 20, 22).

In meningococcal serogroups B, C, Y, and W-135, the intergenic region separating ctrA from the biosynthesis operon (synA to-D [E, F, G]) is 134 bp and contains the ctrA to -D promoter,the divergent synX to -D (E, F, G) biosynthesis operon promoter,and other transcriptional regulatory elements (37, 38). The218-bp intergenic region of serogroup A N. meningitidis does nothave any homology with the 134-bp region found in the sialic acidcapsular serogroups. However, both intergenic regions containoverlapping promoters that initiate transcription of the capsuletransport operon and the divergent biosynthetic operons, suggestingthat encapsulation of all the serogroups may be coordinately regulatedthrough transcriptional control of promoters located in the intergenicregions. Both the serogroup A and the sialic acid biosyntheticoperon promoters (37) resemble $sigma$ -70 promoters and thus may beconstitutively transcribed. However, the ctrA promoters are different,do not resemble $sigma$ -70 promoters, and may require activators.

For N. meningitidis producing sialic acid-containing capsules, the first three genes of the biosynthetic cassette, synA, -B,and -C, convert N-acetyl-D-glucosamine-6-phosphate (GlcNAc-6-P)into CMP-N-acetylneuraminic acid. The fourth gene, synD (E, F,G), is the distinct capsule polymerase which links the capsulesugar monomers together, thereby defining the serogroup (38).In the serogroup A N. meningitidis biosynthetic cassette, ORF1has significant homology with the E. coli gene nfrC, which encodesa cytoplasmic protein required for bacteriophage N4 adsorption(21), and with rffE (o389) (23), which encodes a UDP-N-acetyl-D-glucosamine2-epimerase responsible for converting UDP-N-acetyl-D-glucosamine(UDP-GlcNAc) into UDP-N-acetyl-D-mannosamine (UDP-ManNAc). Immediatelydownstream of rffE in E. coli is rffD (o379), which encodes aUDP-N-acetyl-D-mannosamine dehydrogenase (9, 25). Both rffEand rffD are required for the biosynthesis of the enterobacterialcommon antigen, a tricyclic, polysaccharide structure presenton the cell surfaces of most enterobacterial species (23). ORF1also has amino acid homology with other UDP-GlcNAc 2-epimerasesfrom H. influenzae (13) and humans (GenBank/EMBL accession no.AA210747). Thus, ORF1 likely encodes the epimerase which convertsUDP-GlcNAc to UDP-ManNAc.

UDP-ManNAc, in addition to its role in enterobacterial common antigen biosynthesis in gram-negative species (23), is a commonbiosynthetic precursor in the formation of several cell wall structuresin gram-positive organisms such as Micrococcus luteus (19) andnumerous Bacillus species (44), including Bacillus pumilus (41).Thus, in contrast to the sialic acid capsule pathway, which utilizesGlcNAc-6-P (40), the serogroup A capsule biosynthetic pathwayutilizes UDP-GlcNAc as the starting substrate. Interestingly,the first genes of all meningococcal capsule biosynthetic genecassettes encode 2-epimerases converting either UDP-GlcNAc orGlcNAc-6-P to UDP-ManNAc or N-acetyl-D-mannosamine-6-phosphate,respectively.

ORF2 has the greatest amount of homology with a pair of uncharacterized mycobacterial genes, in terms of both amino acid identityand protein length, and with another gene of unknown function,designated ORF5, that has been identified downstream of galE andrfbBCD in serogroup B meningococci (16). The homology of ORF2with the mycobacterial gene products and ORF5 is concentratedtowards the C termini of the predicted proteins. We hypothesizethat ORF2 may be the polymerase linking individual UDP-ManNAcmonomers together. This is likely to occur through the releaseof UMP from UDP-ManNAc, which provides the requisite energy forthe creation of a phosphodiester bond between the 1 and 6 positionsof individual monomers (26). The large size of the ORF2 genemay support this proposed function. In the sialic acid-producingserogroups, the ORFs encoding the capsule polymerases are significantlylarger than the other biosynthetic genes (38).

Polar and nonpolar insertional mutagenesis of ORF1-4 demonstrated that each of these genes is involved in the production ofthe serogroup A capsule. However, the functions of ORF3 and ORF4are unclear. ORF3 does not have homology with other genes or predictedproteins in the computerized nucleotide and amino acid databasesbut is transcribed as part of the serogroup A biosynthetic cassetteoperon. In studies of the composition and chemical propertiesof the group A capsule, Liu et al. (26) noted that the polysaccharidewas not completely N-acetylated and that the 1 $right-arrow$ 6 phosphodiesterbond was not the only linkage present. Cross-linking of the polysaccharidechains was predicted from their analyses. ORF3 may be involvedin these modifications to the serogroup A polysaccharide.

ORF4 demonstrated distant homology with the XcpS protein of Pseudomonas aeruginosa (4) and P. putida (10). ORF4 alsoexhibited homology with a 46-aa motif shared by members of thepresenilin class of eukaryotic proteins (8). Presenilins containmultiple transmembrane domains and are thought to be involvedin sensory transduction or in the formation of ion channels. The46-aa presenilin motif found in ORF4 is thought to contain twotransmembrane domains separated by a hydrophilic loop (8).Interestingly, the insertion mutation affecting ORF4 resultedin only an 89% reduction in serogroup capsule production comparedwith the complete abrogation seen with interruptions of the otherORFs. This suggests that ORF4 is not directly required for thebiosynthesis of the ( $alpha$ 1 $right-arrow$ 6)-linked N-acetyl-D-mannosamine-1-phosphatepolymers. Considering the homology to membrane-associated proteins,the ORF4 gene product may be involved in membrane transport, assembly,or cross-linking of the serogroup A capsule to the meningococcalcell surface.

In summary, an operon of four genes, ORF1 to -4, located between ctrA and galE in the serogroup A N. meningitidis genome,is required for the production of serogroup A ( $alpha$ 1 $right-arrow$ 6)-linked N-acetyl-D-mannosamine-1-phosphatecapsule. We propose that ORF1 to ORF4 be designated mynA, mynB,mynC, and mynD (for mannosamine capsule biosynthesis genes), respectively.The first biosynthetic step in the pathway is likely the productionof UDP-ManNAc from UDP-GlcNAc, a function that is likely performedby the gene product of mynA. The mynB gene may encode the ( $alpha$ 1 $right-arrow$ 6)UDP-ManNAc polymerase, and mynC and mynD may be involved in furthermodification and assembly of the serogroup A capsule.

The data also support the model that meningococcal capsular serogroups are determined by specific biosynthesis genetic cassettesthat insert between the ctrA operon and galE. We have previouslyshown (38) that the cassettes determining the sialic acid serogroupscan recombine to switch the type of capsule expressed. In thisreport we have shown that the serogroup A capsule can be switchedby a similar recombinational exchange of biosynthetic cassettes.Our data should prove useful in the design of improved meningococcalvaccines, in development of rapid diagnostic approaches for thedetection of serogroup A disease, and for understanding of themolecular basis of serogroup A meningococcal pathogenesis.

	ACKNOWLEDGMENTS

We thank Lane Pucko for manuscript preparation.

This work was supported by National Institutes of Health R01 grant (AI40247-01).

	FOOTNOTES

^* Corresponding author. Mailing address: Division of Infectious Diseases, Emory University School of Medicine, 69 Butler Street,SE, Atlanta, GA 30303. Phone: (404) 728-7688. Fax: (404) 329-2210.E-mail: DSTEP01{at}Emory.edu.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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1.	Abdillahi, H., and J. T. Poolman. 1987. Whole-cell ELISA for typing Neisseria meningitidis with monoclonal antibodies. FEMS Microbiol. Lett. 48:367-371.
2.	Achtman, M. 1990. Molecular epidemiology of epidemic bacterial meningitis. Rev. Med. Microbiol. 1:29-38.
3.	Baker, R. F., and C. Yanofsky. 1968. Periodicity of RNA polymerase initiations: a new regulatory feature of transcription. Proc. Natl. Acad. Sci. USA 60:313-320[Free Full Text].
4.	Bally, M., A. Filloux, M. Akrim, G. Ball, A. Lazdunski, and J. Tommassen. 1992. Protein secretion in Pseudomonas aeruginosa: characterization of seven xcp genes and processing of secretory apparatus components by prepilin peptidase. Mol. Microbiol. 6:1121-1131[Medline].
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Characterization of the Gene Cassette Required for Biosynthesis of the (16)-Linked N-Acetyl-D-Mannosamine-1-Phosphate Capsule of Serogroup A Neisseria meningitidis

Characterization of the Gene Cassette Required for Biosynthesis of the ( $alpha$ 1 $right-arrow$ 6)-Linked N-Acetyl-D-Mannosamine-1-Phosphate Capsule of Serogroup A Neisseria meningitidis