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Journal of Bacteriology, September 1999, p. 5865-5870, Vol. 181, No. 18
Departments of
Pediatrics1 and
Microbiology/Immunology,2 University of
Oklahoma Health Sciences Center, Oklahoma City, Oklahoma 73104
Received 19 April 1999/Accepted 12 July 1999
Haemophilus influenzae utilizes hemoglobin and
hemoglobin-haptoglobin as heme sources. The H. influenzae
hemoglobin- and hemoglobin-haptoglobin binding protein genes,
hgpA, hgpB, and hgpC, contain
lengths of tetrameric CCAA repeats. Using an hgpA-lacZ
translational gene fusion, we demonstrate phase-variable expression of
lacZ associated with alteration in the length of the CCAA
repeat region.
Many pathogenic bacteria reversibly
vary their array of cell surface components with high frequency from
one generation to another, a phenomenon termed phase variation
(12, 17). One genetic mechanism mediating phase variation
involves changes in the number of repeated nucleotides in
mononucleotide (homopolymeric) tracts or tandemly iterated
oligonucleotides (12, 17).
Haemophilus influenzae is able to bind hemoglobin, and we
have cloned three genes, hgpA, hgpB, and
hgpC, encoding heme-repressible hemoglobin- and
hemoglobin-haptoglobin binding proteins from H. influenzae
type b strain HI689 (7, 8, 11, 13). Variable expression of
these three proteins has been observed. Some hemoglobin binding protein
affinity experiments yielded a single band at 120 kDa (HgpA)
(7), while others yielded two bands at 120 and 115 kDa
(8, 13). An hgpA mutant exhibited loss of a
120-kDa protein and increased expression of the 115-kDa protein (HgpB) (13). Furthermore, the hgpA hgpB double mutant
exhibited a faint band at approximately 120 kDa, which was not observed
in either the hgpA or hgpB single mutant and was
identified as HgpC (13). Passage of the hgpA hgpB
double mutant through a medium in which hemoglobin-haptoglobin was the
sole heme source resulted in increased isolation of HgpC on a
weight-per-weight basis (13).
The nucleotide sequences of hgpA, hgpB, and
hgpC reveal multiple repeats of tetrameric CCAA units
immediately following the sequence encoding the signal peptide (7,
8, 11, 13). The H. influenzae Rd KW20 genome contains
four open reading frames (ORFs) with CCAA repeats, encoding proteins of
high homology to HgpA (3, 8). This study investigates the
potential role of the CCAA repeats in variable expression of the
hemoglobin- and hemoglobin-haptoglobin binding proteins of H. influenzae.
Construction of an hgpA-lacZ translational gene
fusion.
An hgpA-lacZ fusion was constructed in H. influenzae Rd KW20 (Table 1). The
gene fusion was initially constructed in Escherichia coli
with subsequent transformation into the H. influenzae
chromosome (Fig. 1). In the fusion
construction, the codons for mature LacZ are in the same translational
frame as those for mature HgpA, resulting in an in-frame HgpA-LacZ
fusion protein (Fig. 2A). Strain Rd KW20
was selected for construction of the fusion strain partly because it is
more readily transformed than strain HI689 from which hgpA
was cloned (unpublished observation). In addition, Rd KW20 does not
contain hgpA (8). A 6.6-kbp DNA fragment, containing the ORFs of HI0588, HI0589, HI0590, HI0591, and HI0592 in Rd
KW20, has apparently been replaced by hgpA in strain HI689 (8). Thus, insertion of the hgpA-lacZ fusion in
strain Rd KW20 at this locus avoids interruption of the heme
acquisition pathway of the pathogenic strain HI689. To construct the
hgpA-lacZ fusion, a 1.3-kbp DNA fragment was amplified by
PCR using the primer pair Phgpfus1 and Phgpnot1 (Table
2) with pHFJ2 (7) as the
template. The reaction was performed in 50 µl containing 2 mM
MgCl2, 0.2 mM (each) deoxynucleoside triphosphate, 10 pM
(each) primer, and 2 U of Pfu DNA polymerase (Stratagene, La
Jolla, Calif.). Thirty cycles of PCR were performed (one cycle consists
of denaturation at 95°C for 1 min, annealing at 60°C for 1 min, and
extension at 72°C for 1 min) before a final extension step of 10 min
at 72°C. This PCR product, encompassing a region upstream of the hgpA promoter, the promoter itself, the signal peptide
coding region, and the CCAA repeat region, was cloned into the
pCR-Blunt cloning vector (Invitrogen, Carlsbad, Calif.) to yield
pFusNot7. The primer Phgpnot1 was designed to incorporate a
NotI restriction site at the end of the PCR product. The
ExSite PCR-based site-directed mutagenesis kit (Stratagene) was used to
construct a NotI site in the hgpA leader
sequence, using pFusNot7 as the template, the primers Psdm1 and Psdm2
(Table 2), and an annealing temperature of 52°C, yielding pFusNotII.
The two engineered NotI restriction sites, flanking the CCAA
repeat region, facilitated excision of the CCAA repeat region from
chromosomal DNA for direct sizing of the repeat region.
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Role of CCAA Nucleotide Repeats in Regulation of
Hemoglobin and Hemoglobin-Haptoglobin Binding Protein Genes of
Haemophilus influenzae
ABSTRACT
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TABLE 1.
Strains and plasmids used in this study
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FIG. 1.
Construction of the hgpA-lacZ translational
gene fusion in H. influenzae Rd KW20. The insert of the
original hgpA clone pHFJ2 (7), the genomic maps
of strains HI689 and Rd KW20 at the hgpA locus, and the gene
fusion construct pFusion-LacI6 are shown. Each open box indicates an
ORF, the direction of transcription is indicated by an arrow, and gene
names where they have been assigned are given. Numbers are the
numerical designations given to ORFs by Fleischmann et al.
(3) in the Rd KW20 genome sequencing project;
hgpA does not have an assigned number, since it does not
exist in the Rd KW20 genome (8). The shaded area represents
the hgpA-lacZ gene fusion construct. The solid bar is the
CCAA repeat region of hgpA. The dashed lines indicate the
homologous regions, used as the flanking regions for recombination.
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FIG. 2.
hgpA-lacZ translational gene fusion in
H. influenzae HI1718. (A) Genomic location of the
hgpA-lacZ gene fusion. Each open box and an arrow indicate
an ORF and its direction of transcription as designated by Fleischmann
et al. (3), and numbers are the numerical designations given
to ORFs by Fleischmann et al. (3). The shaded area
represents the hgpA-lacZ gene fusion construct. The DNA
sequence at the fusion junction is shown, starting with the ATG
initiation codon for the first amino acid of the HgpA signal peptide.
The codons encoding LacZ, beginning at the proline (10), are
in the same frame as the codons encoding mature HgpA. The solid bar is
the CCAA repeat region of hgpA. The relevant restriction
sites are underlined. Southern analyses were performed with the 1.0-kbp
DNA fragment containing the downstream flanking region (B) and the
6.3-kbp SmaI fragment from pLKC480 containing the
lacZ-Kanr cassette (C) as probes. Lanes 1, labeled 
digested with HindIII; lanes 2, H. influenzae Rd KW20 chromosomal DNA digested with BamHI
and EcoRI lanes 3, the hgpA-lacZ recombinant
H. influenzae HI1718 chromosomal DNA digested with
BamHI and EcoRI.
TABLE 2.
Primers used in this study
-galactosidase. To promote recombination of the gene fusion into the
H. influenzae chromosome, a length of H. influenzae DNA was cloned downstream of the aminoglycoside resistance marker in pRepLac1. One kilobase pair of H. influenzae DNA, including the HI0592 putative coding region, was
amplified by using the primer pair Plac1 and Plac2 (Table 2) and 100 ng of H. influenzae Rd KW20 chromosomal DNA as the template
(annealing at 62°C). The PCR product was ligated into the unique
NruI site of pRepLac1 to yield pFusion-LacI6 (Fig. 1) and
was also ligated into pCR-Blunt (Invitrogen) to yield pDown1.
NotI digestion, followed by religation of pFusion-LacI6,
resulted in the non-CCAA-containing fusion construct pFusion-LacII for
use as a control.
Plasmids pFusion-LacI6 and pFusion-LacII were transformed into
competent H. influenzae Rd KW20 (14), and
transformants were selected for by growth on brain heart infusion (BHI)
agar supplemented with 10 µg of heme and 10 µg of -NAD per ml
(supplemented BHI [sBHI]) and containing ribostamycin (15 µg/ml).
One ribostamycin-resistant Rd KW20 colony from each transformation was
selected for further investigation. Appropriate chromosomal
rearrangement was confirmed by Southern analysis (Fig. 2B and C), using
DNA probes labeled by using the enhanced chemiluminescence (ECL) random
prime labeling kit (Amersham Pharmacia Biotech, Piscataway, N.J.).
Hybridization was detected by using the ECL nucleic acid detection
reagents. The labeled 1.0-kbp downstream flanking region, excised from
pDown1, hybridized to an approximately 1.9-kbp
BamHI/EcoRI fragment in wild-type Rd KW20 (Fig.
2B, lane 2) and to an approximately 8.9-kbp BamHI/EcoRI fragment in the Rd KW20
hgpA-lacZ recombinant strain containing the CCAA repeats
(Fig. 2B, lane 3). The labeled 6.3-kbp SmaI fragment
containing the lacZ-aminoglycoside resistance cassette from
pLKC480 hybridized to the 8.9-kbp BamHI/EcoRI
fragment in the Rd KW20 hgpA-lacZ strain (Fig. 2C, lane 3)
and did not hybridize to wild-type Rd KW20 (Fig. 2C, lane 2). Similar
data were obtained for the non-CCAA-containing recombinant Rd KW20
strain (data not shown). The recombinant strain containing the CCAA
repeats was designated HI1718, and the recombinant strain containing
the fusion without CCAA repeats was designated HI1719.
Determination of variable expression of the hgpA-lacZ
fusion.
To examine expression of the hgpA-lacZ fusion,
a single H. influenzae colony was selected and incubated in
sBHI at 37°C for 16 h. One hundred microliters of the culture
was serially diluted and spread on sBHI agar to obtain 200 to 500 colonies per plate. After overnight incubation at 37°C, the plates
were flooded with 1 ml of a 5-mg/ml
5-bromo-4-chloro-3-indolyl--D-galactopyranoside (X-Gal)
solution. Color differences among the colonies were evident within 15 min.
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Frequency of variable expression of the hgpA-lacZ
translational gene fusion in H. influenzae.
The frequency of
alteration in expression of the hgpA-lacZ fusion was
determined in H. influenzae HI1718. Because hemoglobin and
hemoglobin-haptoglobin binding is heme repressible (4), the
frequency of variation in expression of the hgpA-lacZ gene fusion in HI1718 under heme-replete and -depleted growth were determined (Table 3). Heme-depleted
growth was performed in BHI supplemented with 10 µg of -NAD per ml
(heme-depleted BHI). Additional experiments were initiated with
bacteria which had been passaged through hemoglobin-haptoglobin as
previously described (11, 13). No significant difference
(P > 0.05 by the Student t test) was found
in the frequency of variation under different heme conditions for
either blue-to-white or white-to-blue transitions. The overall frequency of variants, calculated based on results from all growth conditions, in H. influenzae HI1718 was 1.07% ± 0.09% for
blue-to-white transitions and 0.60% ± 0.05% for white-to-blue
transitions. A significant difference in rates between blue-to-white
and white-to-blue transitions was detected (P < 0.03
by the Student t test): the frequency of blue-to-white
transitions was approximately twice that of white-to-blue transitions.
These findings are consistent with the slipped-strand hypothesis, since
an in-frame gene may switch to either of two out-of-frame sequences,
while an out-of-frame gene may switch to only one in-frame sequence.
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Regulation of gene expression by slipped-strand mispairing: direct
analysis of chromosomal DNA.
The NotI restriction sites
engineered into the hgpA-lacZ fusion were used to directly
determine the length of DNA in the CCAA region. Chromosomal DNA was
digested with NotI and separated on a QuickPoint sequencing
gel (6% [wt/vol] polyacrylamide-7 M urea) (NOVEX, San Diego,
Calif.), and following transfer to a membrane, the blot was probed with
a (CCAA)6 oligonucleotide labeled by using the ECL
3'-oligonucleotide labeling kit (Amersham Pharmacia Biotech). Following
development of the blot, hybridizing bands were sized by comparison to
a radioactive sequencing reaction run on the same sequencing gel. The
length of the CCAA repeat region was followed over several generations
of phenotypic switching. A single band from each variant hybridized to
the probe, and variable numbers of CCAA repeats were noted in
successive generations (Fig. 4). All of
the changes in the lengths of the fragments resulted from elongation or
contraction by 4 or 8 bp, corresponding to an increase or reduction in
the length of the CCAA repeats of one or two tetranucleotide repeats
(Fig. 4). In each case, the length of the DNA fragment in a variant
expressing -galactosidase activity was consistent with an in-frame
gene, and the CCAA length in a variant lacking -galactosidase
activity was consistent with an out-of-frame gene. These data
demonstrate that changes in the length of the CCAA region are
associated with phase variation of the hgpA-lacZ fusion.
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ACKNOWLEDGMENTS |
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This work was supported in part by Public Health service grant AI29611 from the National Institute of Allergy and Infectious Disease to T.L.S. and by Health Research contract HN5-055 from the Oklahoma Center for the Advancement of Science and Technology to D.J.M. We gratefully acknowledge the support of the Children's Medical Research Institute.
We thank David Dyer, Robert McLaughlin, and Karen Carter for helpful suggestions and Kenneth Hatter for critical review of the manuscript.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Pediatrics, CHO 2308, University of Oklahoma Health Sciences Center, 940 N.E. 13th St., Oklahoma City, OK 73104. Phone: (405) 271-4401. Fax: (405) 271-8710. E-mail: Terrence-Stull{at}ouhsc.edu.
Present address: Department of Genetics, University of
Wisconsin
Madison, Madison, WI 53706.
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Journal of Bacteriology, September 1999, p. 5865-5870, Vol. 181, No. 18
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Copyright © 1999, American Society for Microbiology. All rights reserved.
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