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Journal of Bacteriology, March 2001, p. 1891-1898, Vol. 183, No. 6
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.6.1891-1898.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Involvement of a CbbR Homolog in Low
CO2-Induced Activation of the Bicarbonate Transporter
Operon in Cyanobacteria
Tatsuo
Omata,*
Satoshi
Gohta,
Yukari
Takahashi,
Yoshimi
Harano, and
Shin-ichi
Maeda
Laboratory of Molecular Plant Physiology,
Graduate School of Bioagricultural Sciences, Nagoya University,
Nagoya 464-8601, Japan
Received 28 August 2000/Accepted 12 December 2000
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ABSTRACT |
The cmpABCD operon of Synechococcus sp.
strain PCC 7942, encoding a high-affinity bicarbonate transporter, is
transcribed only under CO2-limited conditions. In
Synechocystis sp. strain PCC 6803, the slr0040,
slr0041, slr0043, and slr0044 genes, forming an
operon with a putative porin gene (slr0042), were
identified as the cmpA, cmpB, cmpC, and cmpD
genes, respectively, on the basis of their strong similarities to the
corresponding Synechococcus cmp genes and their induction
under low CO2 conditions. Immediately upstream of and
transcribed divergently from the Synechocystis cmp operon
is a gene (sll0030) encoding a homolog of CbbR, a LysR family transcriptional regulator of the CO2 fixation
operons of chemoautotrophic and purple photosynthetic bacteria.
Inactivation of sll0030, but not of another closely related
cbbR homolog (sll1594), abolished low
CO2 induction of cmp operon expression. Gel
retardation assays showed specific binding of the Sll0030 protein to
the sll0030-cmpA intergenic region, suggesting that the
protein activates transcription of the cmp operon by
interacting with its regulatory region. A cbbR homolog
similar to sll0030 and sll1594 was cloned from
Synechococcus sp. strain PCC 7942 and shown to be involved
in the low CO2-induced activation of the cmp
operon. We hence designated the Synechocystis sll0030 gene
and the Synechococcus cbbR homolog cmpR. In the
mutants of the cbbR homologs, upregulation of
ribulose-1,5-bisphosphate carboxylase/oxygenase operon expression by
CO2 limitation was either unaffected (strain PCC 6803) or
enhanced (strain PCC 7942), suggesting existence of other low
CO2-responsive transcriptional regulator(s) in cyanobacteria.
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INTRODUCTION |
Cyanobacteria fix CO2
efficiently despite the low affinity and selectivity of their
ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) for
CO2, because they possess a CO2-concentrating
mechanism (CCM) to elevate the CO2 concentration around the
active site of Rubisco (11, 21). The CCM involves the
abilities to actively transport HCO3
into the
cell, to convert CO2 to HCO3
intracellularly, and to effectively convert
HCO3 into CO2 in carboxysomes,
the polyhedral inclusion bodies to which Rubisco is localized. It is
supposed that the conversion of CO2 to
HCO3 in the cytoplasm not only helps to
maintain high intracellular HCO3
concentrations but also allows diffusion of CO2 from
external medium into the cytoplasm (10). Biosynthesis of
the components of CCM, including Rubisco, is supposed to be controlled
by CO2 availability (11, 21); however,
detailed studies on the transcriptional regulation of the CCM-related
genes are yet to be performed, and the underlying molecular mechanism
is unknown.
Among the CCM-related genes, the cmp operon of
Synechococcus sp. strain PCC 7942, encoding a high-affinity
bicarbonate transporter (12, 18), is known to be a typical
low CO2-inducible transcription unit; the cmp
operon mRNA and the CmpA protein, which is by far the most abundant
protein among the proteins encoded by the operon, are undetectable in
cells grown under high CO2 conditions (1 to 5%, vol/vol)
and accumulate to a high level when the cells are transferred to
CO2-limited growth conditions (17, 18). To initiate studies on the regulation of the CCM-related genes, we identified a gene involved in the induction of cmp operon
expression. Since genome sequence information is available for
Synechocystis sp. strain PCC 6803 (9), we first
identified the cmp operon and its regulator in this strain
and then cloned and characterized the corresponding regulatory gene in
Synechococcus sp. strain PCC 7942. It is shown that a
homolog of cbbR (designated cmpR) plays an
essential role in the low CO2 induction of the
cmp operon in the two strains of cyanobacteria. From the
persistence of the low CO2-responsive activation of Rubisco
operon expression in the cmpR mutants, the existence of
another mechanism for low CO2-responsive gene activation in
cyanobacteria is deduced.
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MATERIALS AND METHODS |
Strains and growth conditions.
Synechocystis sp.
strain PCC 6803 and Synechococcus sp. strain PCC 7942, and
mutants derived therefrom, were grown photoautotrophically under
continuous illumination provided by fluorescent lamps (70 µmol of
photons m2 s1) at 30°C. The medium used
was prepared by supplementing a nitrogen-free medium, obtained by
modification of BG11 medium (27) as previously described
(28), with 15 mM KNO3. The medium was buffered
with 20 mM HEPES-KOH (pH 8.0). When appropriate, kanamycin and
spectinomycin were added to the medium at 15 µg ml1.
The cultures were routinely maintained under high CO2
conditions, i.e., aeration with 2% (vol/vol) CO2 in air.
For induction of cmp operon transcription, cells grown to
the mid-logarithmic phase of growth were collected by centrifugation at
5,000 × g for 5 min at 25°C, washed twice with
growth medium by resuspension and recentrifugation, inoculated into
fresh medium, and aerated with air containing ca. 0.005% (vol/vol)
CO2 under the same general conditions as before.
Insertional mutagenesis of Synechocystis cbbR
homologs.
A DNA fragment carrying the entire sll0030
coding region (nucleotides +1 to +937 with respect to the translation
start site) was amplified by PCR using the Synechocystis
chromosomal DNA as the template and cloned into pT7Blue T-Vector. The
forward primer used carried two additional nucleotides at the 5' end,
which created a BspHI recognition sequence at the
translational start site so that the cloned sll0030 gene can
be excised and used for construction of a translational fusion with
maltose-binding protein (see below). After verification of the
nucleotide sequence, a spectinomycin resistance cassette, which had
been excised from plasmid pRL463 (3) by digestion with
XbaI, was inserted at the NheI site in the cloned
sll0030 gene. Wild-type Synechocystis sp. strain
PCC 6803 was transformed with the resulting plasmid to spectinomycin resistance through homologous recombination between the wild-type copy
of sll0030 on the genome and the interrupted copy of the gene, which resulted in replacement of the former with the latter to
give rise to an sll0030 insertional mutant (designated MR1) (Fig. 1B).
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FIG. 1.
Gene organization in the cmp genomic region
of Synechocystis sp. strain PCC 6803 and construction of
insertional mutants of the cbbR homologs. (A) Map of the
cmp region of the genome of Synechococcus sp.
strain PCC 7942 and Synechocystis sp. strain PCC 6803, showing the extent of identity of the deduced amino acid sequences of
the corresponding cmp genes. (B) Structure of the
sll0030 genomic region of the MR1 and MR12 mutants and that
of the sll1594 genomic region of the MR2 and MR12 mutants of
Synechocystis sp. strain PCC 6803. The gene organization in
Synechocystis was obtained from Cyanobase
(http://www.kazusa.or.jp/cyano/cyano.html). The cmp genes
are indicated by stippled bars, and the cbbR homologs
(sll0030 and sll1594) are indicated by filled
bars. Open bars represent the antibiotic resistance gene cassettes,
with hatched bars showing the locations and orientations of the
kanamycin resistance gene (npt) and the spectinomycin
resistance gene (aad). Abbreviations for restriction
endonuclease sites: B, BglII; E, EcoRV; N,
NheI; D, DraI.
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For construction of insertional mutants of
sll1594, a DNA
fragment carrying the entire
sll1594 coding region
(nucleotides
1 to +962 with respect to the translation start site)
with a
base substitution from T to A at position +462 was generated by
overlap extension PCR using oligonucleotide primers carrying mismatches
with the wild-type sequence (
8). The base substitution
created
a
BglII recognition sequence in the
sll1594 coding region. After
cloning of the DNA fragment
into pT7Blue T-Vector and confirmation
of the nucleotide sequence, a
kanamycin resistance cassette excised
from plasmid pUC4K
(
30) with
BamHI was inserted into the
engineered
BglII site to interrupt the cloned
sll1594 gene. The resulting
plasmid was used to transform
the wild-type
Synechocystis strain
and the MR1 mutant to
kanamycin resistance through homologous
recombination to obtain an
sll1594 insertional mutant (MR2) and
an
sll0030
sll1594 double mutant (MR12), respectively (Fig.
1B).
Identification, nucleotide sequence analysis, and insertional
mutagenesis of a Synechococcus cbbR homolog.
A 0.6-kbp
fragment of a cbbR homolog was amplified from chromosomal
DNA of Synechococcus sp. strain PCC 7942 by PCR, using degenerate oligonucleotides synthesized according to the amino acid
sequences conserved in the two Synechocystis CbbR homologs encoded by sll0030 and sll1594:
5'-TT(CT)AC(CGT)A(AG)(AG)GC(AGCT)GC(AGCT) GA(AG)GA-3'
and 5'-TT(CT)AC(CGT)CG(AGCT)GC(AGCT)GC(AGCT)GA(AG)GA-3' for FT(RK)AAEE (forward primer), and
5'-GC(CT)TG(CT)TT(AG)AT(ACGT)GC(CT)TC(AG)TT-3' for NEAIKQA
(reverse primer). For amplification of the DNA regions contiguous to
the 0.6-kbp internal segment of the cbbR homolog, 1-µg
aliquots of Synechococcus chromosomal DNA were digested with BamHI and NheI, respectively, the resulting
fragments were circularized by self-ligation, and the circularized DNA
fragments were used as the templates for inverse PCR. DNA fragments of
6 and 2.5 kbp were obtained from the BamHI and
NheI digests, respectively, and used for determination of
the nucleotide sequences of the 5' and 3' portions of the
cbbR homolog and its 5' and 3' flanking regions.
For insertional interruption of the
cbbR homolog in
Synechococcus sp. strain PCC 7942, a DNA fragment carrying
nucleotides
260 to +739 with respect to the translation start site
was amplified
by PCR and cloned into pT7Blue T-Vector. After
confirmation of
the nucleotide sequence, the spectinomycin resistance
cartridge
from pRL463 was inserted into the
MscI site to
interrupt the coding
region. The resulting plasmid was used to
transform the wild-type
Synechococcus strain to
spectinomycin resistance through homologous
recombination to yield an
insertional mutant (MR4) of the
cbbR homolog.
Preparation of the Synechocystis CmpR protein and gel
shift assay.
The PCR-amplified sll0030 gene cloned into
pT7Blue T-Vector (see above) was excised from the plasmid with
BspHI and BamHI and, after blunting of the
termini, cloned into the SalI site in the polylinker of the
expression vector pMAL-c2 (22). The resulting plasmid,
designated pMR1, carried a chimeric gene encoding a translational
fusion of the maltose-binding protein with CmpR. Cells of
Escherichia coli NM522 transformants carrying pMR1 were grown in Luria-Bertani medium. Expression of the chimeric gene was
induced by 1 mM isopropyl-B-D-thiogalactopyranoside (IPTG), and the recombinant protein was purified on amylose resin
(22). The purified fusion protein was cleaved with factor
Xa and used for gel retardation assays.
The DNA fragment used as the probe, carrying the entire intergenic
region between
cmpA and
cmpR (nucleotides
252
to
1 with
respect to the
cmpA start codon), was labeled at
both termini
with
32P, using the Klenow fragment of DNA
polymerase I and [
-
32P]dCTP. Gel retardation assays
were performed essentially as described
by Buratowski and Chodosh
(
2). Gels containing 4% polyacrylamide
were used for
separation of the free probe and the protein-DNA
complexes. Gels were
dried, and the signals were detected by
autoradiography.
Isolation and analysis of DNA and RNA.
Chromosomal DNA was
extracted and purified from Synechocystis sp. strain PCC
6803 and Synechococcus sp. strain PCC 7942 cells as
described by Williams (31). Manipulations and analyses of DNA were performed according to standard protocols (24).
For Southern hybridization analysis of the genomic DNA digests, the following 32P-labeled double-stranded DNA probes were used:
a 0.92-kbp entire coding region of sll0030; a 0.95-kbp
entire coding region of sll1594; a 0.59-kbp
HincII fragment of Synechococcus cmpR; a 2-kbp
spectinomycin resistance cassette; and a 1.3-kbp kanamycin resistance
cassette. Total RNA was extracted and purified from the cyanobacterial
cells by the method of Aiba et al. (1). For Northern
hybridization analysis, RNA samples (10 µg per lane) were denatured
by treatment with formaldehyde, fractionated by electrophoresis in
1.2% agarose gels that contained formaldehyde, transferred to
positively charged nylon membranes (Hybond N+; Amersham), and
hybridized with the following gene-specific probes: a 737-bp
PCR-amplified rbcL fragment of strain PCC 6803, carrying
bases +50 to +786 of the coding region; a 3.8-kbp PCR-amplified
fragment of strain PCC 6803 DNA, carrying 1,147 bases of
cmpA, the entire cmpB gene, and 1,704 bp of
slr0042 (bases +213 to +4079 with respect to the translation
start site of cmpA); a 0.71-kbp
SalI-SphI fragment of cmpC of strain
PCC 7942; a 17-mer oligonucleotide complementary to bases +1566 through +1582 of the rbcL coding region of strain PCC 7942; and a
288-bp PCR-amplified ccmK fragment of strain PCC 7942, carrying bases +11 to +298 of the coding region. The double-stranded
DNA probes were labeled with 32P as described by Feinberg
and Vogelstein (4). The oligonucleotide probe was labeled
with 32P, using [
-32P]ATP and T4
polynucleotide kinase. The radioactivity of the probes that hybridized
to mRNA was quantified with a Bio-Image analyzer (Fuji Photo Film).
Transformation of cyanobacteria.
Transformation of
Synechocystis and Synechococcus was performed as
described by Williams (31). The transformants were allowed to grow on solid medium supplemented with kanamycin and/or
spectinomycin at 15 µg ml1 (see above). After three
serial streak purifications to segregate homozygous mutants
(31), genomic DNA was isolated from the selected clones
and analyzed by Southern hybridization to confirm the presence and
position of the antibiotic resistance gene.
Nucleotide sequence accession number.
The nucleotide
sequence data reported in this paper will appear in the DDBJ, EMBL, and
GenBank nucleotide sequence databases with accession number AB047379.
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RESULTS |
Construction of Synechocystis mutants lacking the
cbbR homologs.
The cmpA, cmpB, cmpC, and
cmpD genes of Synechococcus sp. strain PCC 7942, encoding the high-affinity bicarbonate transporter BCT1, form a low
CO2-inducible operon (18). These genes are similar, respectively, to the nrtA, nrtB, nrtC, and
nrtD genes of the same cyanobacterium, which encode the
nitrate/nitrite transporter (15, 16). Among the genes of
Synechocystis sp. strain PCC 6803 (9),
slr0040, slr0041, slr0043, and slr0044 are the
most similar to cmpA, cmpB, cmpC, and cmpD,
respectively (Fig. 1A). They are more similar to the cmp
genes than to the nrt genes of Synechococcus,
although they were initially designated "nrt" genes in
Cyanobase (http: //www.kazusa.or.jp/cyano/cyano.html). On the other hand, another set of Synechocystis
"nrt" genes in Cyanobase, sll1450, sll1451,
sll1452, and sll1453, having the second-best similarities to the cmp genes among the
Synechocystis genes, are more similar to the nrt
genes than to the cmp genes of Synechococcus and
are in fact involved in nitrate/nitrite uptake (M. Kobayashi and T. Omata, unpublished results). Northern hybridization analysis showed
that slr0040, slr0041, slr0043, and slr0044
constitute a low CO2-inducible operon (see below) with a
putative porin gene, slr0042 (6). On the basis
of these observations, we have identified slr0040, slr0041,
slr0043, and slr0044 as the cmpA, cmpB,
cmpC, and cmpD genes, respectively, of the
Synechocystis strain. While there is no potential
protein-coding region within 700 bases upstream from the cmp
operon of Synechococcus (11), a gene
(sll0030) coding for a protein 31 to 51% identical to
bacterial CbbR (RbcR) proteins is located 253 bases upstream of the
Synechocystis cmp operon, being oriented divergently from
the cmp operon (Fig. 1A). CbbR is a LysR family protein
involved in transcriptional activation of the Rubisco operon in
chemoautotrophic and phototrophic bacteria (5, 26). Since
many of the LysR family proteins activate the divergently transcribed
operon located upstream (7, 25), sll0030 was
likely to be involved in activation of the cmp operon in
Synechocystis.
To determine the role of
sll0030, we constructed an
insertional mutant of this gene. Since the
Synechocystis
genome contains
two other
cbbR homologs,
sll1594
and
sll0998, encoding proteins
53 and 33% identical to the
Sll0030 protein, respectively, insertional
mutagenesis was attempted
also for these two genes. In the case
of
sll0030 and
sll1594, the insertionally inactivated genes segregated
to
give rise to homozygous mutants MR1 and MR2 (Fig.
1B), respectively,
as
determined by Southern hybridization analysis (data not shown).
By
inactivating
sll1594 in MR1, an
sll0030 sll1594
double mutant
MR12 was also constructed (Fig.
1B). Since segregation of
the
mutant genome, carrying the interrupted copy of the gene, was
not
attained for
sll0998 (data not shown), the mutants of
sll0030 and
sll1594 (MR1, MR2, and MR12) were
further
characterized.
Under photoautotrophic conditions, the three
cbbR mutants
grew slightly more slowly than the wild-type strain in the presence
of
both high (2%) and low (0.035%) CO
2 (data not shown). The
final
cell density in the mutant cultures was close to that in the
cultures
of the wild-type strain, indicating that
sll0030
and
sll1594 are
not essential for growth of
Synechocystis under the given
conditions.
Activation of the cmp operon in the
Synechocystis mutants.
Figure
2 shows the effects of CO2
conditions on transcription of the cmp operon and
rbc operon in the wild-type and mutant Synechocystis strains. In the case of the wild-type strain,
transfer of the cells to low CO2 conditions induced
accumulation of the cmp operon transcript (Fig. 2A, lanes 1 and 2). The hybridization profile showed a smeary signal ranging from 2 to 7 kb in size, indicating that the primary transcript is rapidly
turned over. The low CO2-induced accumulation of the
cmp transcript was abolished in the MR1 and MR12 mutants
lacking sll0030 (lanes 3, 4, 7, and 8), but the MR2 mutant,
which is defective solely in sll1594, showed normal low
CO2-induced accumulation of the cmp operon
transcript (lanes 5 and 6). These results indicated that
sll0030 but not sll1594 is essential for the low
CO2-responsive activation of the cmp operon in
Synechocystis. On the basis of these results, we named
sll0030 as cmpR.
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FIG. 2.
Northern blot analysis of total RNA from the wild-type
strain (WT; lanes 1 and 2), the sll0030 insertional mutant
(MR1; lanes 3 and 4), the sll1594 insertional mutant (MR2;
lanes 5 and 6), and the sll0030 sll1594 double mutant (R12;
lanes 7 and 8) of Synechocystis sp. strain PCC 6803, showing
the effects of CO2 conditions on expression of the
cmp and rbc operons. Cells were grown under high
CO2 conditions (2% CO2 in air) and transferred
to low CO2 conditions (0.005% CO2 in air);
total RNA samples (10 µg per lane) were extracted from the cells
before (lanes 1, 3, 5, and 7) and 90 min after (lanes 2, 4, 6, and 8)
the transfer and analyzed, using probes specific to
cmpA-cmpB-slr0042 (A) and rbcL (B). Arrowheads
indicate calculated sizes (in kilobases) of the full-length mRNA of the
cmp operon (A) and the rbc operon (B).
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Transfer of the wild-type
Synechocystis cells to low
CO
2 conditions also caused an increase in the abundance of
the mRNA for
the
rbcLXS (
slr0009-slr0011-slr0012)
operon (Fig.
2B, lanes 1
and 2). The extent of the increase in the mRNA
abundance was 60
to 70% in three separate experiments (data not
shown). The low
CO
2-induced increase in the
rbcLXS mRNA abundance was observed
also in the
sll0030 and
sll1594 mutants (lanes 3 to 8; 60 to
70%
increase in MR1 and MR2 and 55 to 80% increase in MR12 in three
separate experiments). Thus, neither gene was likely to be involved
in
regulation of
rbcLXS expression.
Gel shift assay.
To examine whether CmpR binds to the
cmpA operon regulatory region, gel shift assays were
performed with CmpR, using a DNA fragment carrying the
cmpR-cmpA intergenic region as the probe. Since
His6-tagged CmpR was insoluble and could not be easily
solubilized, CmpR was expressed in a soluble form as a MalE-CmpR fusion
in E. coli (Fig. 3A, lanes 1 and 2), purified to near homogeneity (lanes 3 and 4), cleaved from MalE
with factor Xa (lane 5), and used for the experiments (Fig. 3B). While
addition of the MalE-CmpR fusion up to a concentration of 1 µM did
not affect the electrophoretic mobility of the DNA probe (Fig. 3B, lane
1), addition of the CmpR-MalE mixture to give CmpR and MalE
concentrations higher than 10 nM yielded two retarded bands
representing DNA-protein complexes (lanes 3, 4, 5, and 7). Addition of
an excess amount of cold DNA probe prevented binding of the labeled
probe to the protein (lane 8), but addition of a nonhomologous DNA
fragment had no effect thereon (lane 9). No change in mobility of the
DNA probe was observed when a MalE-LacZ mixture, obtained by
cleavage of the MalE-LacZ fusion expressed from the vector
(pMAL-c2), was used in place of the MalE-CmpR mixture for the
experiments (data not shown). These results showed that the CmpR
protein specifically binds to the cmpR-cmpA intergenic
region. Thus, CmpR is likely to activate transcription of the target
operon by interacting with its promoter region, as other LysR-type
transcription activators do (25).
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FIG. 3.
Preparation of recombinant CmpR and the mobility shift
assays. (A) Expression in E. coli and purification of the
MalE-CmpR fusion (lanes 1 to 4) and cleavage of the MalE-CmpR fusion
with factor Xa (lane 5). Proteins were separated on a sodium dodecyl
sulfate-10% polyacrylamide gel and stained with Coomassie brilliant
blue. Lane 1, total protein from the E. coli expression
strain before IPTG treatment; lane 2, total protein from the expression
strain after 2-h treatment with IPTG; lane 3, soluble fraction from the
IPTG-induced expression strain; lane 4, the protein purified on amylose
resin; and lane 5, the MalE-CmpR fusion cleaved with factor Xa. (B)
Mobility shift assays showing retardation in a 4% polyacrylamide gel
of the 32P-labeled cmpR-cmpA intergenic segment
by CmpR. Samples of the MalE-CmpR fusion (lane 1) and the MalE-CmpR
fusion cleaved with factor Xa (lane 2 to 9) were added to the reaction
mixtures to give the indicated final concentrations; 100-fold-excess
amounts of nonlabeled cmpR-cmpA intergenic segment and a
0.7-kb segment of rbcL coding region were added to lanes 8 and 9, respectively, as competitors. C1 and C2, DNA-protein complexes;
F, free probe.
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Identification and nucleotide sequence determination of a
cbbR homolog of Synechococcus sp. strain PCC
7942.
Although functionally related genes are usually clustered on
the genome of Synechococcus sp. strain PCC 7942, no
cmpR-like gene was found in the region upstream of its
cmp operon (Fig. 1A). This raised a question as to whether a
cbbR homolog is involved in regulation of the cmp
operon in this strain of cyanobacterium. Using degenerate
oligonucleotides synthesized according to the amino acid sequences
conserved in the proteins encoded by sll0030 and
sll1594 (see Materials and Methods), a 0.6-kbp fragment was amplified from chromosomal DNA of Synechococcus sp. strain
PCC 7942 by PCR and shown to encode a CbbR homolog, as confirmed by cloning and nucleotide sequence determination, verifying the existence of a cbbR-like gene in Synechococcus sp. strain
PCC 7942. Using the set of primers, only one species of cbbR
homolog was amplified. A 2.5-kbp NheI fragment and a 6-kbp
BamHI fragment of Synechococcus DNA, carrying the
regions contiguous to the PCR-amplified 0.6-kb segment of the
cbbR homolog, were subsequently amplified by inverse PCR and
used for nucleotide sequence determination of the entire cbbR homolog and its flanking regions. Figure
4A shows the map of the DNA region around
the Synechococcus cbbR homolog thus obtained. A homolog of
slr2141, a Synechocystis gene of unknown
function, was found to be located 71 bases upstream from the
cbbR homolog. The open reading frame located farther
upstream, which overlaps the slr2141 homolog by four bases,
was partially sequenced from its 3' end and tentatively identified as a
tryptophanyl-tRNA synthetase gene (trpS) of
Synechococcus sp. strain PCC 7942, because the encoded amino
acid sequence was 73% identical to the C-terminal portion of
tryptophanyl-tRNA synthetase from Synechocystis sp. strain
PCC 6803. There was no potential protein-coding region within 600 bases
downstream from the cbbR homolog. These results suggested
that the cbbR homolog is the last gene of an operon. The
organization of genes around the Synechococcus cbbR homolog is thus totally different from those in Synechocystis (Fig.
1B). The open reading frame of the cbbR homolog starts with
a GTG codon and encodes a protein of 323 amino acids (see entry
AB047379 in DDBJ, EMBL, and GenBank nucleotide sequence databases)
which is 54.2 and 59.4% identical to the proteins encoded by
sll0030 and sll1594, respectively (Fig.
5).
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FIG. 4.
(A) Map of the genomic region of the cbbR
homolog in Synechococcus sp. strain PCC 7942. The filled bar
represents the Synechococcus cbbR homolog. The triangle
above the map indicates the MscI site where a 2.0-kbp gene
cassette carrying the spectinomycin resistance gene (aad)
was inserted to construct the MR4 mutant. Abbreviations for restriction
endonuclease sites: H, HincII; M, MscI. (B)
Southern blot analysis of DNA from the wild-type strain (WT; lanes 1 and 3) and the MR4 mutant (lanes 2 and 4) of Synechococcus
sp. strain PCC 7942. DNA samples (5 µg per lane) were digested with
HincII, fractionated on a 0.7% agarose gel, transferred to
a positively charged nylon membrane (Hybond N+; Amersham), and
hybridized with the 32P-labeled gene-specific probes as
indicated.
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FIG. 5.
Alignment of the deduced amino acid sequence of the
cbbR homolog of Synechococcus sp. strain PCC 7942 with those of the proteins encoded by sll0030
(cmpR) and sll1594 of Synechocystis
sp. strain PCC 6803. The alignments were optimized by the FASTA program
(19). Vertical lines indicate aligned and identical amino
acid residues between adjacent sequences; dots indicate conservative
replacements of amino acid residues.
|
|
Functional analysis of the cbbR homolog of
Synechococcus.
To determine whether the Synechococcus
cbbR homolog is involved in regulation of the cmp
operon, a mutant (MR4) was constructed by inserting a spectinomycin
resistance cassette in the gene (Fig. 4). Similar to the case of
Synechocystis, a homozygous mutant lacking the wild-type
gene was obtained (Fig. 4B). The mutant grew as fast as the wild-type
strain under both high (2%) and low (0.035%) CO2
conditions (data not shown), indicating that the cbbR
homolog of Synechococcus is not essential for growth of the
cyanobacterium under the given conditions.
Figure
6 compares the effects of
CO
2 conditions on expression of the three transcription
units of
Synechococcus, i.e., the
cmp operon, the
rbc operon, and the carboxysome-related gene cluster
ccmKLMNO, in the wild-type strain and the MR4 mutant. In the
case
of the wild-type strain, transfer of the cells to low
CO
2 conditions
induced accumulation of the
cmp
operon transcript as previously
shown (
18) (lanes 1 and
2). The mRNA from the
rbcLS operon was
detected in high
CO
2-grown cells, and its abundance was increased
by
transfer of the cells to low CO
2 conditions (lanes 5 and
6).
While only low-molecular-size signals of <1.4 kb were detected
with the
ccmK-specific probe in the mRNA samples from high
CO
2-grown
cells (lane 9), CO
2 limitation caused
accumulation of abundance
of larger signals (lane 10). The maximum size
of the hybridization
signal, 3.8 kb (lane 10), corresponded to the
entire size of the
ccmKLMNO gene cluster, verifying that the
five genes are transcribed
as an operon at least under the
CO
2-limited conditions. Unlike
the
cmpR mutants
(MR1 and MR12) of
Synechocystis, the
Synechococcus MR4 mutant accumulated the
cmp
operon transcript in response to
CO
2 limitation (compare
lanes 3 and 4), but the level of the transcript
was much lower than
that in the wild-type strain (lane 2). On
the other hand, the abundance
of the transcripts from the
rbc operon and the
ccm operon was greater in the mutant than in the
wild-type
strain after induction (compare lanes 6 and 10 with
lanes 8 and 12, respectively). The extent of low CO
2-responsive
increase in
levels of the
cmp,
rbc, and
ccm
transcripts was variable
in different experiments, but that of the
rbc and
ccm transcripts
was always larger in the
MR4 mutant than in the wild-type strain
(Fig.
7B and
C), and the maximum level of
cmp operon transcript
in the mutant was insignificant
compared to that in the wild-type
strain (Fig.
7A), being 10 to 25% of
the wild-type level. It should
also be noted that the mutant often
accumulated higher levels
of
rbc and
ccm operon
transcripts than the wild-type strain even
under the high
CO
2 conditions (Fig.
7B and C). The specific reduction
in
the level of
cmp operon expression in the MR4 mutant
indicated
that the
cbbR homolog of
Synechococcus
is involved in activation
of the
cmp operon. We therefore
identified this gene as the
cmpR gene of
Synechococcus sp. strain PCC 7942.
View larger version (71K):
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|
FIG. 6.
Northern blot analysis of total RNA from the wild-type
strain (WT; lanes 1, 2, 5, 6, 9, and 10) and the insertional mutant of
the cbbR homolog (MR4, lanes 3, 4, 7, 8, 11, and 12) of
Synechococcus sp. strain PCC 7942, showing the effects of
CO2 conditions on expression of the cmp, rbc,
and ccm operons. Synechococcus cells were grown
under high CO2 conditions (2% CO2 in air) and
transferred to low CO2 conditions (0.005% CO2
in air), and total RNA was extracted from the cells before (lanes 1, 3, 5, 7, 9, and 11) and 30 min after (lanes 2, 4, 6, 8, 10, and 12) the
transfer. RNA samples (10 µg per lane) were denatured, fractionated
by electrophoresis, transferred to positively charged nylon membranes,
and hybridized with probes specific to cmpC (lanes 1 to 4),
rbcL (lanes 5 to 8), and ccmK (lanes 9 to 12).
Arrowheads indicate calculated sizes (in kilobases) of the full-length
mRNA of the cmp (A), rbc (B), and ccm
(C) operons.
|
|
View larger version (14K):
[in this window]
[in a new window]
|
FIG. 7.
Changes in relative abundance of the cmpC,
rbcL, and ccmK transcripts after transfer of the
wild-type strain and the cmpR insertional mutant (MR4) of
Synechococcus sp. strain PCC 7942 from high (2%) to low
(0.005%) CO2 conditions. Results of the dot hybridization
analysis with 2.5 µg of RNA per dot were quantified and plotted. A
representative of three sets of essentially the same results, obtained
with three independent sets of cultures, is shown.
|
|
| |
DISCUSSION |
The CbbR protein of chemoautotrophic and photosynthetic bacteria
is required for activation of the operons encoding the enzymes of the
Calvin-Benson-Bassham (CBB) cycle (5, 26). As is usually the case with the LysR family transcription regulator proteins (7, 25), the genes encoding CbbR are located immediately upstream of their target operons (5). While a single
cbbR gene is present in most of these bacteria
(5), the genome sequencing project of the cyanobacterium
Synechocystis sp. strain PCC 6803 revealed the presence of
three genes coding for CbbR-like proteins, two of which
(sll0030 and sll1594) are more similar to the
cbbR genes of chemoautotrophic and phototrophic bacteria (31 to 54% identity at the amino acid sequence level) than the third one (sll0998) is (25 to 33% identity) (9). None of
the cyanobacterial cbbR homologs is, however, clustered with
other cbb genes, and their functions remain to be
determined. The present results indicate that the sll0030
gene product activates the divergently transcribed operon located
upstream, encoding the bicarbonate transporter, presumably by binding
to its regulatory region (Fig. 3). Identification of a
Synechococcus cbbR homolog involved in activation of the cmp operon (Fig. 4 to 7) suggests that cyanobacteria
commonly utilize a CbbR homolog for the low CO2 induction
of the bicarbonate transporter operon. Since the transporter is not a
component of the CBB cycle, we have named the sll0030 gene
and the cbbR homolog of Synechococcus sp. strain
PCC 7942 as cmpR.
Rubisco activity (20) and the cellular carboxysome content
(14, 29) have been shown to increase during adaptation of Synechococcus strains to low CO2 conditions, and
elevated expression of the rbcLS and ccmNO genes
following transition from high to low CO2 conditions has
been reported in strain PCC 7942 (23). The present results
confirm the latter observation and further show that the
ccmKLMNO genes form an operon (Fig. 6). The
upregulation of the rbcLS and ccmKLMNO
operons was not abolished by inactivation of cmpR but rather
enhanced by the mutation (Fig. 6 and 7). Low CO2-induced
increase in the abundance of rbcLXS mRNA was observed also
in Synechocystis sp. strain PCC 6803 and was found to be unaffected by the mutation of cmpR and sll1594
(Fig. 2). These findings suggest the presence of a
cmpR-independent (and, in Synechocystis, sll1594-independent as well) mechanism for low
CO2-induced activation of the rbc and
ccm operons. The transcriptional regulator(s) involved in
this process is not known, but the third cbbR homolog of
Synechocystis sp. strain PCC 6803 (sll0998),
which could not be completely deleted from the cell, is a good
candidate for the regulator, because its close homolog has been found
not only in the cyanobacteria Synechococcus sp. strain PCC
7942 (78% identity at the amino acid sequence level [T. Omata and S. Gohta, unpublished results, GenBank accession no. AB053349]),
Anabaena sp. strain PCC 7120 (82% identity
[Cyanobase]), Nostoc punctiforme (83% identity
[http://www.jgi.doe.gov/JGI_microbial/html/nostoc_homepage.html]), and Synechococcus sp. strain WH8102 (64% identity
[http://www.jgi.doe.gov/JGI_microbial/html/synechococcus.html]) but also in cyanelle and chloroplast DNA from all known eukaryotes having rbcS in an operon with rbcL (51 to 72%
identity) (summarized in reference 13; see GenBank entry
NC001675 for the cyanelle sequence). Much more work is required to
obtain a comprehensive view of the mechanism of low
CO2-induced gene regulation in cyanobacteria.
| |
ACKNOWLEDGMENTS |
This work was supported by a Grant-in-Aid for Scientific Research
(09640768) and Grants-in-Aid for Scientific Research in Priority Areas
(09274101 and 09274103) to T.O. from the Ministry of Education,
Science, Sports and Culture, Japan.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratory of
Molecular Plant Physiology, Graduate School of Bioagricultural
Sciences, Nagoya University, Nagoya 464-8601, Japan. Phone:
81-52-789-4106. Fax: 81-52-789-4107 E-mail:
omata{at}agr.nagoya-u.ac.jp.
Present address: Molecular Plant Physiology Group, Research School
of Biological Sciences, Australian National University, Canberra ACT
2601, Australia.
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Journal of Bacteriology, March 2001, p. 1891-1898, Vol. 183, No. 6
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.6.1891-1898.2001
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Abstract
Introduction
