Instituto de Bioquímica Vegetal y
Fotosíntesis, Consejo Superior de Investigaciones
Científicas
Universidad de Sevilla, Seville, Spain
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INTRODUCTION |
Nitrate is probably the most
abundant source of combined nitrogen for cyanobacterial nutrition, its
assimilation being a process closely linked to photosynthesis
(9). Nitrate is transported into the cyanobacterial cell by
a multicomponent transport system of the ABC (ATP-binding cassette)
type (34). Once inside the cell, nitrate is reduced to
ammonium by two sequential reactions catalyzed by nitrate reductase and
nitrite reductase, respectively. Ammonium is incorporated into carbon
skeletons mainly via the glutamine synthetase/glutamate synthase cycle
(9).
In Synechococcus sp. strain PCC 7942, the nir
gene encoding nitrite reductase (22), the nrtABCD
genes encoding the components of the nitrate transport system
(34), and the narB gene encoding nitrate
reductase (1, 45) are clustered together and constitute an
operon (24, 51). Two other loci, narA and
narC, involved in nitrate reduction in
Synechococcus sp. strain PCC 7942 have been identified and
cloned by means of complementation of nitrate reductase-deficient,
Tn901-induced mutants with a gene library from strain PCC
7942 (20, 21). These loci are not clustered together in the
Synechococcus genome. With regard to regulation, ammonium
acts as a nutritional repressor of the nitrate assimilation system
(9). The NtcA protein found in cyanobacteria (9, 10,
52) acts as a transcriptional activator that controls the
expression of cyanobacterial genes subjected to repression by ammonium
such as the nir operon (23).
Nitrate reductases from cyanobacteria are monomeric molybdoenzymes of
about 75 kDa that use reduced ferredoxin as a physiological electron
donor (9). Molybdoenzymes other than nitrogenase catalyze either oxidative hydroxylations or reductive dehydroxylations, and its molybdenum center is constituted by a molybdenum-pterin cofactor in the form of molybdopterin (MPT), molybdopterin guanine dinucleotide (MGD), molybdopterin cytosine dinucleotide, or
others (40). In Escherichia coli, the pathway for
molybdenum cofactor biosynthesis is the subject of intense research.
The genes responsible for the transport of molybdate
(modABC) (29), for MPT biosynthesis (moaABCDE and moeAB) (33, 36, 44), and
for assembly of molybdenum into MPT (mog) (18)
have been identified and sequenced, as is also the case for
mobA, which is involved in the addition of GMP to MPT during
the synthesis of the MGD form of the molybdenum cofactor (16, 17,
35).
In cyanobacteria, information about molybdenum cofactors is scarce.
Some molybdenum cofactor, partially bound to a carrier protein that
would stabilize the cofactor, has been reported to be present in the
soluble fraction of Nostoc muscorum (3). In
Anabaena variabilis, the existence of common and specific
genes for the synthesis of the iron-molybdenum (of nitrogenase) and molybdenum cofactors has been inferred (28); in
Anabaena sp. strain PCC 7120, inactivation of a
moeA gene leads to loss of nitrate reductase activity
(41), while the moeB-like hesA gene found downstream of the nifHDK operon seems to be necessary
for attaining full nitrogenase activity (5). Recently, the
entire genome of Synechocystis sp. strain PCC 6803 has been
sequenced (19), and a cluster of open reading frames (ORFs)
showing similarity to the moeA, moaA,
moaC, and moaE genes of E. coli has
been found close to the nir gene. Although not identified by
the authors, ORF ssr1527, also found in this gene cluster,
would encode a putative MoaD homolog (see below).
In this report, we describe a genetic analysis of the
Synechococcus sp. strain PCC 7942 narA locus and
show that it consists of five genes whose products are essential for
nitrate reduction and would be involved in the biosynthesis of
molybdopterin.
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MATERIALS AND METHODS |
Organisms, growth conditions, and plasmids.
Synechococcus sp. strain PCC 7942 was routinely grown
photoautotrophically under white light with shaking (90 rpm) at 30°C in the BG11 medium (17.6 mM NaNO3 as the nitrogen source)
described previously (43). When ammonium was used as the
nitrogen source, nitrate was omitted and 4 mM NH4Cl and 8 mM N-tris(hydroxymethyl)methyl-2-aminoethane sulfonic acid (TES)-NaOH
buffer (pH 7.5) were supplied, rendering medium
BG110NH4+. For growth on plates,
the medium was solidified with separately autoclaved 1% agar (Difco
Laboratories). The plates were incubated at 30°C in the light.
Synechococcus strains as well as plasmids used in this work
are listed in Table 1. Mutant strain FM6
was grown in BG110NH4+ medium, and
mutant strains CSLM26, CSLM27, CSLM35, and CSLM40 were grown in
BG110NH4+ medium supplemented with
10 µg of kanamycin/ml. Mutant strains CSLM32 and CSLM34 were grown in
BG110NH4+ medium supplemented with
2 µg of streptomycin and 2 µg of spectinomycin/ml. Mutant strain
CSLM37 was grown in BG110NH4+
medium supplemented with 2 µg of streptomycin/ml, 2 µg of
spectinomycin/ml and 10 µg of kanamycin/ml.
For 
-galactosidase assays, Synechococcus strains were
grown in 70-ml glass tubes containing 35 ml of the medium indicated in
each experiment, bubbled with air-CO2 (98:2) at 30°C in
the light. At the mid-exponential growth phase (cultures with about 3 to 5 µg of chlorophyll/ml), samples containing an amount of cells
corresponding to about 2 µg of chlorophyll were withdrawn for
determination of protein content and -galactosidase activity.
For nitrate reductase assays and for growth rate determinations,
Synechococcus strains were grown in 70-ml glass tubes
containing 35 ml of BG110NH4+
medium without antibiotics; after extensive washing, the cells were
transferred to and incubated in the medium in each experiment bubbled
with air-CO2 (98:2) at 30°C in the light.
For isolation of DNA and RNA, Synechococcus strains were
grown in 240-ml glass flasks containing 150 ml of BG11 medium bubbled with air at 30°C in the light. Cultures with a cell density
corresponding to 3 to 5 µg chlorophyll/ml were used.
E. coli DH5
, GM48, BL21, and HB101 were grown in
Luria-Bertani medium at 37°C with shaking (200 rpm). For growth of
E. coli on plates, medium solidified with 1.5% agar was
used. Antibiotics were used at standard concentrations (2).
Growth rates were estimated from the increase of protein concentration
in the cultures. The growth rate constant corresponds to
ln2/td, where td
represents the doubling time.
Generation of mutant strains.
Insertions of either
HincII-ended gene cassette C.S3 from plasmid pRL463
(8) or SmaI-ended gene cassette
lacZ-C.K3 from plasmid pPE20 (48) at the
StuI restriction site, which is internal to the
Synechococcus moeA gene, of plasmid pCSLM6 were made to render plasmids pCSLM32 (moeA::C.S3) and pCSLM27
(moeA::lacZ-C.K3), respectively. Similar
insertions were made into the moaC gene, disrupting it at
the HpaI restriction site of pCSLM6 to render plasmids
pCSLM34 (moaC::C.S3) and pCSLM35
(moaC::lacZ-C.K3). The moaA gene
was also mutated by substitution of a 335-bp, NheI DNA fragment at the 3' terminus of the gene, after digestion of pCSLM6 with NheI and treatment with the Klenow enzyme
(2), by SmaI-ended gene cassette
lacZ-C.K3, rendering plasmid pCSLM26. The nir
gene was mutated by substitution of a 99-bp, NaeI DNA
fragment by SmaI-ended gene cassette lacZ-C.K3,
rendering plasmid pCSLM40 (Table 1). Restriction analysis of
plasmids pCSLM26, pCSLM27, pCSLM35, and pCSLM40
confirmed that the antibiotic resistance genes present in the inserted
gene cassettes were, in every case, in the same orientation as the
Synechococcus genes disrupted by the gene cassette.
Plasmids pCSLM26, pCSLM27, pCSLM32, pCSLM34,
pCSLM35, and pCSLM40 were transferred to
Synechococcus sp. strain PCC 7942 by means of
transformation (12) for generation of mutant strains CSLM26, CSLM27, CSLM32, CSLM34, CSLM35, and CSLM40, respectively. For generation of mutant strain CSLM37, pCSLM34 was transferred to
strain CSLM26 (Table 1). After transformation, cells were spread onto
nitrocellulose filters (Nuclepore; REC85) set successively atop
BG110NH4+ solid medium (incubated
for 48 h) and BG110NH4+ with
the appropriate antibiotics (incubated for 3 weeks). Individual colonies were selected and, after recloning, maintained in
BG110NH4+ solid medium with
antibiotics.
DNA manipulations.
PCR using EcoTaq DNA polymerase (EcoGen
S.R.L.), plasmid constructions, DNA electrophoresis, isolation of DNA
fragments from agarose gels, ligation, and transformation of E. coli were carried out by standard methods (2).
Restriction endonucleases were used according to the manufacturer's
recommendations or by standard methods (2). Sequencing was
performed in double-stranded DNA by the chain termination method with a
T7 Sequencing kit (Pharmacia LKB) and [35S]deoxyadenosine
5'-(-thio)triphosphate (1,000 to 1,500 Ci/mmol). Both strands of the
DNA were sequenced. Computer searching for homologies was made by using
the FASTA and TFASTA algorithms included in the Genetics Computer Group
package (7). Isolation of DNA from Synechococcus
strains was performed essentially as described by Cai and Wolk
(6). For Southern blots, restriction endonuclease-digested DNA or PCR products were subjected to electrophoresis in agarose gels
and transferred to Genescreen Plus membranes (Dupont) as instructed by
the manufacturer. Probes were labeled with [-32P]dCTP
(3,000 Ci/mmol). Prehybridization and hybridization were performed
essentially as described by Frías et al. (10) in a
solution containing 5× SSPE (0.8 M NaCl, 10 mM sodium phosphate, 1 mM
EDTA [pH 7.4]), 5× Denhardt's solution (47), 0.5%
(wt/vol) sodium dodecyl sulfate (SDS), and 100 µg of nonhomologous
DNA/ml, under high-stringency conditions at 65°C and under
low-stringency conditions at 55°C.
RNA isolation and RT-PCR analysis.
Isolation of RNA from
Synechococcus sp. strain PCC 7942 was performed as described
by Mohamed and Jansson (32), with the modifications
described in Luque et al. (23). Samples were treated with
RNase-free DNase I (from bovine pancreas; Boehringer) for elimination
of any remaining DNA. For retrotranscription-PCR (RT-PCR) experiments,
4 µg of strain PCC 7942 total RNA was mixed with 20 pmol of the
oligonucleotide 5'-ATTGACCTTGAGGATCGGTAAGCG-3' (complementary to nucleotides 479 to 456 with respect to the
translation start of the moaA gene) in the presence of 50 mM
Tris-HCl, 8 mM MgCl2, 30 mM KCl, and 1 mM dithiothreitol,
pH 8.5 (AMV [avian myeloblastosis virus] buffer), heated for 2 min at
90°C, and immediately cooled down to 55°C. Then 1 mM each
deoxynucleoside triphosphate, 20 U of RNA Guard (Pharmacia), and 50 U
of AMV reverse transcriptase (Boehringer) were added, and the extension
reaction was developed for 1 h at 54°C in a volume of 20 µl.
To control for the presence of contaminating DNA, samples containing 4 µg of the RNA preparation, 20 pmol of the same oligonucleotide, and 1 µg of RNase A (DNase free; Boehringer) were incubated, in a 20-µl
reaction volume, at 37°C for 1 h. PCR was carried out with 35 µl of retrotranscription mixture (diluted 10-fold with 10 mM
Tris-HCl, 1 mM EDTA [pH 8.0]) or RNase-treated sample (see above) as
the template, and oligonucleotides 5'-ATTGACCTTGAGGATCGGTAAGCG-3'
(complementary to nucleotides 479 to 456 with respect to the
moaA translation start; same as above) and
5'-GGTCTATCAGCGCGTTACTCAAGG-3' (complementary to nucleotides 74 to 97 with respect to the moaC translation start) as
primers. Control samples containing the same oligonucleotides and
strain PCC 7942 genomic DNA as the template were run in parallel. PCR consisted of 35 cycles of template denaturation at 95°C for 1 min,
annealing with the oligonucleotides for 1 min at 69°C, and DNA
extension at 72°C for 2 min. One half of each sample was resolved by
electrophoresis in 1% agarose gels and transferred to membranes for
Southern blot analysis. A 0.53-kb, PvuII DNA fragment from plasmid pNR1211 (Table 1), internal to the moa operon (see
Fig. 2), was used as the probe.
Expression of the Synechococcus moaC gene in E. coli.
A 1,030-bp DNA fragment, containing the
moaC gene and part of the moaD gene, from an
unmethylated pCSLM6 plasmid restricted with ClaI and
SacI and treated with Klenow enzyme was isolated and cloned
into the BamHI site of plasmid pGEX-4T-2 (Pharmacia), made blunt ended with Klenow enzyme, to render plasmid pCSLM43. E. coli BL21 carrying plasmid pCSLM43 was used for
overproduction of the glutathione S-transferase (GST)-MoaC
fusion protein after induction with 1 mM
isopropyl--D-thiogalactoside (IPTG). Preparation of cell
extracts from BL21(pCSLM43), purification of GST-MoaC protein
by using bulk glutathione-Sepharose 4B in batch, and thrombin cleavage
of fusion proteins were carried out as recommended by the manufacturer.
Proteins were resolved by SDS-polyacrylamide gel electrophoresis (PAGE)
as described by Schleif and Wensink (49), using a 12%
acrylamide running gel with an upper 4% acrylamide stacking gel.
Enzyme assays and analytical procedures.
Nitrate reductase
activity was determined by using dithionite-reduced methyl viologen as
the reductant in alkyltrimethylammonium bromide-permeabilized
Synechococcus cells (14). -Galactosidase activity was determined as described by Schaefer and Golden
(48) by colorimetric assay with
o-nitrophenyl--D-galactopyranoside (ONPG)
(31). One unit of enzymatic activity corresponds to the formation of 1 µmol of product (nitrite or o-nitrophenol)
per min. Protein quantifications were made by a modified Lowry method (27), using bovine serum albumin as the standard.
Chlorophyll a determinations were made in methanolic
extracts as described by MacKinney (25).
Nucleotide sequence accession number.
The nucleotide
sequence of the moeA and moa genes reported in
this paper will appear in the EMBL/GeneBank/DDBJ nucleotide sequence
data libraries under accession no. X99625.
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RESULTS |
Identification of the narA locus.
FM6 is a
Tn901-induced mutant derived from Synechococcus
sp. strain PCC 7942 that is impaired in nitrate reductase activity. This mutant is readily transformable to the wild-type phenotype by the
4.7-kb, XhoI DNA fragment from strain PCC 7942 that is cloned in plasmid pNR1211. This genetic locus has been named
narA (20). For localization and identification of
the nitrate reduction-related gene(s) corresponding to the
narA locus, genomic DNA from mutant strain FM6 was
restricted with the endonucleases XhoI, BglII, and PvuII and subjected to Southern blot analysis using as a
probe the 4.7-kb, strain PCC 7942 DNA fragment of pNR1211. Compared to
strain PCC 7942 DNA, mutant FM6 DNA showed a clear change in the
hybridization pattern indicative of a Tn901 insertion into an 0.53-kb, PvuII DNA fragment (Fig.
1). Sequencing of this PvuII fragment revealed the existence of two ORFs. The putative product of
one of them showed homology to the large subunit of the MPT-converting factor, the MoaE polypeptide of E. coli.
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FIG. 1.
Localization of Tn901 in the narA
locus of mutant strain FM6. Genomic DNA from the indicated
strain was simultaneously digested with XhoI,
BglII, and PvuII and subjected to Southern blot
analysis using the 4.7-kb XhoI insert of plasmid pNR1211 as
a probe. The positions and sizes (in kilobases) of some standards are
indicated to the left.
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Sequencing of the entire Synechococcus sp. strain PCC 7942 DNA fragment cloned in pNR1211 was carried out by using several synthetic oligonucleotides as primers and plasmid pNR1211 as the template. Sequence analysis revealed the existence of five ORFs in that
fragment (Fig. 2). Putative ribosome
binding sites could be found only in front of ORF1, ORF4, and ORF5. No
other ORF was found after sequencing 300 bp of the
Synechococcus DNA adjacent to the XhoI site
closest to ORF5, using as template cosmid pNR12 (20), whose
insert includes that of plasmid pNR1211.
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FIG. 2.
Structure of a genomic region of
Synechococcus sp. strain PCC 7942 that contains
moeA and several moa genes. The identities and
orientations of gene cassettes inserted at some restriction sites for
the generation of cyanobacterial mutants are indicated together with
the CSLM denomination of the resulting mutant strain. The location of
Tn901 in mutant strain FM6 is also indicated. B,
BglII; E, EcoRV; H, HpaI; N,
NheI; P, PvuII; S, StuI; X,
XhoI.
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As summarized in Table 2, ORF1 would
encode a polypeptide of 403 amino acids that shows homology to MoeA
polypeptides from E. coli (33) and
Anabaena sp. strain PCC 7120 (41). ORF2
would encode a 319-amino-acid polypeptide whose
N-terminal half shows homology to the MoaC polypeptide of
E. coli (44) and whose C-terminal half shows
homology to MoaB and Mog polypeptides of E. coli (it should be noted that MoaB and Mog are themselves homologous to each
other) (44, 53). ORF3 would encode a polypeptide of
90 amino acids that in its C-terminal part (amino acids 60 through 90)
shows homology to the MoaD polypeptide of E. coli
(44). The putative product of ORF4 (165 amino acids) shows
homology to the E. coli MoaE polypeptide
(44). ORF5 would encode a polypeptide of 327 amino
acids homologous to E. coli MoaA (44), to
Bacillus subtilis NarA (11), and to Cnx2 from
Arabidopsis thaliana (15). All Moa, Moe, and Mog
polypeptides of E. coli have been shown to be
involved in the biosynthesis of Mo-MPT (39). Because of the
homologies described above, we propose to name ORF1 as
moeA, ORF2 as moaC (whose product would
bear a domain homologous to MoaC and another one homologous to
MoaB and Mog from E. coli), ORF3 as moaD,
ORF4 as moaE, and ORF5 as moaA.
No evidence for the existence in strain PCC 7942 of other genes
homologous to those present in the moeA-moa cluster here
described could be obtained by means of Southern blot analysis under
low-stringency conditions using a 3,458-bp, EcoRV DNA
fragment containing most of the moa-moe gene cluster (Fig.
2) as a probe (not shown).
Overexpression of the Synechococcus moaC gene in
E. coli.
The MoaC polypeptide from strain PCC
7942 was produced in E. coli BL21(pCSLM43)
cells as a GST-MoaC fusion protein of about 60 kDa. After purification
of the GST-MoaC protein and cleavage with thrombin, a 36-kDa MoaC
protein was released (Fig. 3). This protein would differ from the native MoaC only in the first two amino
acids, which were changed from Met-Ile in the native protein to Gly-Ser
in the recombinant protein. The size of MoaC polypeptide derived from the nucleotide sequence of the Synechococcus
moaC gene would be 33 kDa.
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FIG. 3.
Expression in E. coli and purification
of a GST-MoaC fusion protein. (A) SDS-PAGE of a cell extract from
strain BL21(pGEX-4T-2) containing GST (lane 1), cell extract from
BL21(pCSLM43) containing GST-MoaC (lane 2), purified GST (lane
3), and purified GST-MoaC protein (lane 4). (B) SDS-PAGE of purified
GST-MoaC protein (lane 1) and thrombin-treated GST-MoaC protein (lane
2). The arrowhead points to the ca. 36-kDa Synechococcus
MoaC protein. Positions and sizes (in kilodaltons) of some molecular
weight markers are indicated to the left of each panel.
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Mutational analysis of the moeA and moa
genes.
Three of the genes found in the insert of pNR1211 were
mutated by in vitro gene cassette insertion (Fig. 2 and Table 1) to test their involvement in expression of nitrate reductase activity. Synechococcus strains bearing those mutations in the
moeA or moa genes were obtained by genetic
transformation of strain PCC 7942 with plasmids bearing the inactivated
genes (see Fig. 2 and Materials and Methods for details). Strain CSLM26
bears gene cassette lacZ-C.K3, which does not carry
transcriptional terminators (30), substituting for the
335-bp NheI fragment internal to the moaA gene;
strain CSLM27 bears gene cassette lacZ-C.K3 inserted into
the StuI site of the moeA gene; strain CSLM32
bears gene cassette C.S3, which carries transcriptional terminators
(38), inserted into the StuI site within the
moeA gene; strain CSLM34 bears gene cassette C.S3 inserted
into the HpaI site within the moaC gene; strain CSLM35 bears gene cassette lacZ-C.K3 inserted at the same
HpaI site within the moaC gene. We also
constructed a double mutant, strain CSLM37, that bears the mutations
present in strains CSLM34 and CSLM26. The genetic structure of
each of the mutant strains in the moeA-moa region, as well
as the absence of wild-type chromosomes in them, was confirmed by
PCR analysis using primers flanking each mutation (not shown). In
addition, strain FM6, which bears Tn901 inserted into the
0.53-kb PvuII fragment, was analyzed by PCR using several
primers internal to the moaE and moaA genes. Results obtained (not shown) indicated that Tn901 in strain
FM6 is inserted into the moaE gene (Fig. 2).
Strains CSLM26, CSLM27, CSLM32, CSLM34, CSLM35, and CSLM37 were
unable to grow with nitrate as the sole nitrogen source (Table 3). Moreover, in contrast to strain PCC
7942, none of the mutants exhibited nitrate reductase activity upon
incubation in medium containing nitrate as the sole nitrogen source
(Table 3).
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TABLE 3.
Growth rates and nitrate reductase activities of mutant
strains derived from Synechococcus sp. strain PCC 7942
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Expression of the moeA and moa genes.
Because we were unable to detect any moa transcript in
Synechococcus sp. strain PCC 7942 by means of Northern
analysis, we studied the expression of moa genes by
subjecting mRNA to RT-PCR (see Materials and Methods for details). For
retrotranscription, an oligonucleotide complementary to sequences
internal to the moaA gene was used as the primer. The
resulting cDNA was then amplified by PCR using the same primer used for
retrotranscription and another one that should anneal at the beginning
of the moaC gene. After electrophoresis of the RT-PCR
products on an agarose gel, a band of the expected size, 2.1 kb, was
observed. This band was verified by Southern blot analysis to hybridize
to a probe of the moaE gene (Fig.
4, lane 3). Since this RT-PCR product was strictly dependent on the presence of RNA (Fig. 4, lane 2), it cannot
be due to amplification of contaminating genomic DNA. These results suggest that the moaC, moaD,
moaE, and moaA genes of strain PCC 7942 (Fig. 2)
are cotranscribed into a single mRNA species. It is worth noting that
overlapping of termination and start codons is found between the
moaC and moaD genes, as well as between the moaE and moaA genes, of strain PCC 7942.
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FIG. 4.
Southern analysis of RT-PCR products of the
moa gene cluster of Synechococcus sp. strain PCC
7942, using a moaE gene probe. The primers used for the
RT-PCR corresponded to DNA sequences of the moaA and
moaC genes (see Materials and Methods for primers used).
Lane 1, PCR-amplified strain PCC 7942 genomic DNA; lane 2, PCR-amplified, RNase-treated strain PCC 7942 total RNA; lane 3, RT-PCR-amplified RNA. Samples of lanes 2 and 3 were incubated with
DNase before the RNase treatment or the retrotranscription reaction.
The size of the amplified DNA fragment is indicated to the left.
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The effect of the presence of ammonium or nitrate in the extracellular
medium on the expression of the moeA and moa
genes of strain PCC 7942 was studied by measuring -galactosidase
activity in mutant strains bearing gene fusions to the
lacZ-C.K3 gene cassette. Ammonium-grown cells of
mutant strains CSLM26 (moaA::lacZ-C.K3), CSLM27 (moeA::lacZ-C.K3), CSLM35
(moaC::lacZ-C.K3) (Fig. 2), and, as a
control, CSLM40 (nir::lacZ-C.K3) (Table 1)
were incubated for 14 h in media containing either ammonium or
nitrate as the sole nitrogen source, and protein and -galactosidase
activities were determined (Table 4).
While the activity level of -galactosidase in CSLM40 (carrying the
nir::lacZ-C.K3 fusion) was about 4.2-fold higher in nitrate- than in ammonium-incubated cells, only 1.7- to
1.9-fold-higher levels were found in nitrate- than in
ammonium-incubated cells of the strains carrying lacZ fused
to the moeA or moa genes. Data in Table 4 should
be interpreted with caution, however, since -galactosidase basal
levels can be relatively high in Synechococcus cells
carrying lacZ. As an example, -galactosidase activity in ammonium-grown cells of strain CSLM37, in which lacZ is
inserted within the moa operon about 1.8 kb downstream from
the transcriptional terminator present in the C.S3 gene cassette, was
about 60 mU/mg of protein. No -galactosidase activity was detected
in wild-type strain PCC 7942.
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TABLE 4.
-Galactosidase activities of Synechococcus
sp. mutant strains CSLM40, CSLM26, CSLM27, and CSLM35 incubated
with ammonium or nitratea
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DISCUSSION |
Some years ago, three genetic loci, narA,
narB, and narC, whose mutation leads to
impairment of nitrate reductase activity in the unicellular
cyanobacterium Synechococcus sp. strain PCC 7942 were
identified and cloned (20, 21). The narB locus
was later identified as the structural gene for nitrate reductase (1, 45) that is part of an operon of nitrate assimilation genes which includes, in addition to narB, the
nir and nrtABCD genes (22, 24, 34). Up
to now, nothing was known about the actual function of the genes in the
narA or narC locus.
We have mapped the site of insertion of Tn901 in a
previously reported narA mutant of Synechococcus
sp. strain PCC 7942, strain FM6 (26), and have determined
that the inactivated genomic region carries a cluster of genes
whose putative polypeptide products show similarity to genes
involved in the biosynthesis of the molybdenum cofactor of nitrate
reductase and other molybdoenzymes. The genes identified include
homologs of the moaA, moaB and mog,
moaC, moaD, moaE, and moeA
genes from E. coli and some other biological sources.
The synthesis of all molybdenum cofactors of molybdoenzymes, except the
iron-molybdenum cofactor of nitrogenase, comprises the synthesis of
Mo-MPT, which presumably is common to all molybdoenzyme-containing organisms, and, in some cases, the posterior formation of different dinucleotide variants. Synthesis of MPT takes place through the formation of a sulfur-free pterin precursor, termed precursor Z, that
is then sulfurylated, leading to MPT and, after incorporation of
molybdenum, to the Mo-MPT complex (39). The
moaABC genes of E. coli, which are part of
the moaABCDE operon, are involved in the biosynthesis of
precursor Z. The moa operon of Synechococcus sp.
strain PCC 7942 described in this work contains genes homologous to
moaABC. While Synechococcus MoaA would be similar
to other MoaA (or Cnx2) proteins, Synechococcus MoaC is
unique in that it resembles a fusion protein of MoaC (N-terminal half)
and MoaB or Mog (C-terminal half). Sequence similarities do not allow
us to conclude whether the C-terminal half of Synechococcus
MoaC represents a MoaB or a Mog domain. In Synechocystis sp.
strain PCC 6803, ORFs showing similarity to moaA
(slr0901) and moaC (slr0902) are also
clustered together (19). In this case, moaC would
be fused to mobA (a gene required in a late step of MGD
biosynthesis), but the actual assignments of these genes to the
corresponding ORFs awaits experimental confirmation. The
moaDE genes of E. coli encode the two
subunits of the so-called converting factor or MPT synthase that adds
dithiolene sulfurs to precursor Z, thus generating MPT (37).
The Synechococcus moa operon also contains moaDE
homologs (Table 2 and Fig. 2), as is also the case for the
Synechocystis genome (19). The putative
cyanobacterial MoaD polypeptides are peculiar in that they show
appreciable identity to E. coli MoaD only in the 30 C-terminal amino acids; notably, however, these include the C-terminal
Gly-Gly sequence that is thought to be essential for MoaD function
(39). On the other hand, the moeB gene, which in
E. coli encodes MPT synthase sulfurylase that catalyzes
the transfer of sulfur to the MoaD subunit of MPT synthase, is not
present in the Synechococcus moeA-moa gene cluster. Finally,
the MoeA protein from strain PCC 7942 would be similar to MoeA from
E. coli that has recently been suggested to be involved in activation of molybdate (13). The fact that
Synechococcus strains bearing mutations in the
moeA-moa gene cluster are devoid of nitrate reductase
activity indicates that this gene cluster is involved in the synthesis
of the Mo cofactor of nitrate reductase. In particular, four of the
genes in the cluster (moeA, moaC,
moaE, and moaA) have been inactivated, the
phenotype of the corresponding mutants showing the involvement of these
genes in production of an active nitrate reductase. It should be noted
that both the lacZ-C.K3 gene cassette and transposon
Tn901 allow transcription of genes located downstream from
them in a transcriptional unit (30, 46, 50).
Results of RT-PCR presented in this work show that
Synechococcus sp. strain PCC 7942 synthesizes mRNA molecules
containing a message for both the moaC and moaA
genes. This finding indicates that the moa genes in the
identified gene cluster can be expressed as a single mRNA molecule from
a promoter located upstream from moaC, thus constituting an
operon. On the other hand, moeA, which is located in the
complementary DNA strand, would be expressed independently.
In Synechococcus sp. strain PCC 7942, structural genes for
nitrate assimilation proteins including nitrite reductase, the components of the nitrate/nitrite transport system, and nitrate reductase, which constitute the nir operon, are subjected to
repression by ammonium. Results presented here on the expression of the
moeA gene and the moa operon, compared to that of
the nir operon, using -galactosidase as a transcriptional
reporter indicate that the expression of these Mo cofactor biosynthesis
genes is not regulated by the nitrogen source to the same extent as the
nir operon is. This resembles the situation with the
moa genes in E. coli, whose expression is
not affected by the regulatory element NarL, a nitrate-responsive activator of the synthesis of nitrate reductase, or by high levels of
nitrate in the growth medium (4). Lack of regulation by the
nitrogen source of the moeA and moa genes in
Synechococcus sp. strain PCC 7942 would be consistent with a
role of these genes in this cyanobacterium, as is also the case for
E. coli, in the synthesis of the Mo cofactor not only
of nitrate reductase but also of some other molybdoenzymes involved in
processes other than nitrogen assimilation.
This work was supported by grant PB95-1267 from the
Dirección General de Enseñanza Superior (Spain).
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Abstract
Introduction
