Báo cáo Y học: Stimulated biosynthesis of flavins in Photobacterium phosphoreum IFO 13896 and the presence of complete rib operons in two species of luminous bacteria Sabu Kasai and Takumi Sumimoto pot

phosphoreum NCMB 844, it has been reported that a rib gene cluster is present just downstream of the lux operon.However, among rib genes, the gene for pyrimidine deaminase/pyrimidine red

Stimulated biosynthesis of flavins in Photobacterium phosphoreum

of luminous bacteria

Sabu Kasai and Takumi Sumimoto

Department of Bioapplied Chemistry, Faculty of Engineering, Osaka City University, Japan

Photobacterium phosphoreumIFO 13896 emits light strongly

when cultured in medium containing 3% NaCl, but only

weakly in medium containing 1% NaCl.It is known that

dim or dark mutants appear frequently and spontaneously

from this parent strain.To confirm that riboflavin

biosyn-thesis is stimulated when the lux operon is active, the amount

of light emitted and flavins synthesized under strongly or

weakly light emitting conditions was determined.In

com-parison with the parent strain cultured in 3% NaCl, the same

strain cultured in 1% NaCl emitted 1/36 the light and

pro-duced 1/4 the flavins, while three dim or dark mutants, M1,

M2 and M3 cultured in 3% NaCl, emitted almost no light,

1/58 the light and 1/10 the light and produced 1/8, 1/5 and

1/3 the amount of flavins, respectively.From these results,

we deduced that the genes for riboflavin synthesis, rib genes,

are organized in an operon in this strain.In P phosphoreum

NCMB 844, it has been reported that a rib gene cluster is

present just downstream of the lux operon.However, among

rib genes, the gene for pyrimidine deaminase/pyrimidine

reductase, ribD, was not found in this cluster.Because a

complete rib operon seems to be necessary for efficient

regulation at the transcriptional level, we expected ribD to be

present downstream of this cluster and sequenced this region, using SUGDAT, Sequencing Using Genomic DNA

As a Template.We could not find this gene but found a gene for hybrid-cluster protein (prismane protein).To find ribD in

a different region, a partial ribD sequence was amplified and sequenced using a PCR-based method, and subsequently the genomic DNA was sequenced in both directions from this partial sequence using SUGDAT.Because ribC was found just downstream of ribD, we sequenced further downstream

of ribC and confirmed that another complete set of rib genes, ribD, ribC, ribBA, and ribE, is present in P phosphoreum The presence of a complete rib operon in P phosphoreum explains why this species can synthesize flavins at enhanced levels to sustain a strong light emission.Furthermore, we sequenced the rib operon in Vibrio fischeri, another repre-sentative luminous bacterium, in a manner similar to that described above, and confirmed that a complete operon is present also in this species.The organization of rib genes in

an operon in the Proteobacteria c-subdivision is discussed Keywords: biosynthesis of riboflavin; hybrid-cluster protein; Photobacterium phosphoreum; rib operon; SUGDAT

In bacteria and archaea, a complete set of genes for

riboflavin biosynthesis, rib genes, was first identified in

Bacillus subtilis [1].Four enzymes participate in the

synthesis of riboflavin from GTP and ribulose

5-phos-phate: pyrimidine deaminase/pyrimidine reductase,

riboflavin synthase, GTP cyclohydrolase

II/3,4-dihydr-oxy-2-butanone 4-phosphate synthase, and lumazine

syn-thase.The genes coding for these enzymes are designated

ribG, ribB, ribA and ribH, respectively, in B subtilis.But

in Escherichia coli, the genes for GTP cyclohydrolase II

and 3,4-dihydroxy-2-butanone 4-phosphate synthase are

not fused and they are designated ribA and ribB,

respectively [2].The genes corresponding to ribG, ribB and ribH of B subtilis are designated ribD, ribC and ribE,

in E coli, respectively, and if a gene corresponding to ribA of B subtilis is present in other species, it is called ribBA.To avoid confusion, we have used the E coli notational system for rib genes in this report

About 20 years ago, we isolated roseoflavin-resistant mutants from Gram-positive bacteria including B subtilis, and found that they acquire their antibiotic resistance through the overproduction of riboflavin [3].Later, it was found that in B subtilis, rib genes are organized in an operon and the overproduction in mutants is caused by the deregulation of this operon [1].Now genome sequences of many species of Gram-positive bacteria have been released and in riboflavin autotrophs of these bacteria rib genes are organized in an operon.In E coli, however, such riboflavin-overproducing mutants have not yet been identified because rib genes are not organized in an operon but scattered around the chromosome [1,4], and their expression is constitutive [2].Because in two genome-sequenced Gram-negative bacteria, Haemophilus influenzae [5] and Helico-bacter pylori [6], the rib genes are not organized in an operon, it is believed that in Gram-negative bacteria the rib genes are not organized in an operon and stimulated synthesis of riboflavin does not occur

Correspondence to S.Kasai, Department of Bioapplied Chemistry,

Faculty of Engineering, Osaka City University, Sugimoto 3-3-138,

Sumiyoshi-ku, Osaka 558–8585, Japan.

Fax: +81 6 6605 2769, Tel.: +81 6 6605 2783,

E-mail: kasai@bioa.eng.osaka-cu.ac.jp

Note: The nucleotide sequences reported in this paper have been

submitted to DDBJ/EMBL/GenBank nucleotide sequence database

and are available under the accession numbers AB065117, AB065118

and AB076605.

(Received 16 July 2002, revised 8 September 2002,

accepted 10 October 2002)

Photobacterium phosphoreum IFO 13896 is a strongly

light emitting strain.The strong emission of light in this

bacterium is primarily attained by the activated expression

of the lux (luminescence) operon, by which luciferase and

tetradecanal, one of the substrates of luciferase, are supplied

in large quantities.Furthermore, the stimulated biosynthesis

of flavins seems to be necessary for the strong emission

because FMN is another substrate of luciferase.The colour

of the cells is a deeper yellow when the strain is strongly

emitting light and so this inference appears correct.Because

luminous bacteria are classified as Gram-negative, this

stimulated synthesis of riboflavin seems to contradict the

concept described above.Lee et al.reported that in

P phosphoreum, all of the rib genes except ribD are clustered

just downstream of the lux operon [7].However, this cluster

is not a complete rib operon, the presence of which seems to

be absolutely necessary for the efficient regulation of

riboflavin biosynthesis at the transcriptional level in this

strain.Recently, the genome sequences of Vibrio cholerae [8]

and Pseudomonas aeruginosa [9] were released.The rib genes

are organized in an operon in both cases although the two

species are classified as Gram-negative

bacteria.Accord-ingly, it is quite possible that there is a complete rib operon

also in P phosphoreum IFO 13896

We attempted to confirm that P phosphoreum

IFO 13896 synthesizes flavins at enhanced levels when

strongly emitting light and then to identify a complete rib

operon in this species.We expected ribD to be present just

downstream of the rib cluster reported by Lee et al.[7]

However, we could not find it although we found another

complete rib operon in a different region.Because rib

operons are duplicated in P phosphoreum, albeit

incom-pletely, there are three rib genes of the same name in one

species.So, in this report, to distinguish among duplicated

genes, we give names with prime such as ribC¢, ribBA¢, ribE¢

and ribA¢, for genes in the rib gene cluster located just

downstream of the lux operon, and names without prime

such as ribD, ribC, ribBA and ribE, for those in the newly

found complete rib operon

M A T E R I A L S A N D M E T H O D S

Bacteria

P phosphoreum IFO 13896 is almost the same strain as

NCMB 844 [10] and emits much light.The strain is

maintained in our laboratory and the Institute for

Fermen-tation, Osaka (IFO).Dark or dim mutants, M1, M2 and

M3, appeared spontaneously on agar plates with cultures of

the parent strain, P phosphoreum IFO 13896, and were

isolated

Growth and bioluminescence curves

A diluted medium was used to obtain growth curves

ensuring that the maximum turbidity of the liquid culture

did not exceed 10.One litre of the medium contained: 2 g

polypeptone (Nihon Pharmaceutical); 1 g yeast extract

(Oriental yeast); 6 g glycerol; 1 g KH2PO4; 660 mg NaOH;

and 30 g or 10 g NaCl for 3% or 1% NaCl medium,

respectively; pH of the medium was 7.0 The parent strain

and three mutants were precultured in the respective media

until a turbidity of 2–6 was attained.The seed cultures

(150–500 lL) were transferred to 10 mL respective medium

in L-shaped culture tubes 15 mm in diameter and 165 mm long, and incubated at 20C with shaking.Growth was monitored by measuring turbidity at 650 nm with a 1-mm light path cuvette, inserting a red glass filter (Toshiba, R-63) between the cuvette and detector to cut off the light emitted

by bacteria.Bioluminescence was measured in arbitrary units at a distance of 5 mm from the culture tube in a dark box using a photodiode (Hamamatsu Photonics, S2281) connected to an amplifier (Hamamatsu Photonics, C2719)

A curve of the bioluminescence plotted as a function of time was designated the bioluminescence curve

Measurement of the total amount of flavins

To obtain faster growth, the concentrations of polypeptone and yeast extract in the media used for this experiment were increased to 5 and 2 5 gÆL)1, respectively.To determine the total amount of flavins in the respective exponential cells, the parent strain and three mutants were grown until a turbidity of
7 in the case of the parent strain cultured in 3% NaCl medium and 10–13 in the other cases.For the parent strain grown in 3% NaCl, cells in 3 mL culture, while in other cases cells in 4.5 mL, were collected by centrifugation at 16 000 g for 5 min.The supernatant was discarded and any remaining was removed by using filter paper.Each cell pellet was suspended in 1.5 mL distilled water using a vortex mixer.After heating at 95C for

5 min, the suspension was sonicated for 5 min.After a second heating at 95C for 3 min, cell debris were collected

by centrifugation at 16 000 g for 5 min.Aliquots (1 mL) of each supernatant were measured.Total flavins were deter-mined using a lumiflavin fluorescence method [11] with slight modification: 1 mL each sample was added to 1 mL

1MNaOH in a 10-mL test tube and photolysed under a fluorescent lamp for 10 min The photoproduct, lumiflavin, was extracted with 3 mL chloroform and quantified fluor-ometrically.Total flavins in the cell pellet collected from

1 mL of the culture giving a turbidity of 1, in the respective sample, were calculated

Because P-flavin, 6-(3¢-myristic acid)-FMN and 6-(4¢-myristic acid)-FMN, are present in extracts of P phos-phoreum cells [12] we examined whether the lumiflavin fluorescence method can be used to quantify P-flavin in a solution of FP390, Lux F, which binds this flavin [10,13–15]

A solution of FP390 was heated at 95C for 5 min to denaturate protein and the precipitate was removed by centrifugation at 16 000 g for 5 min.The concentration of P-flavin in the supernatant was 18.4 pmolÆmL)1assuming that the extinction coefficient at 448 nm of this flavin is equal to that of riboflavin (12.3 mM )1Æcm)1[16]).Although this concentration was about four times the maximum measurable by fluorometry, the chloroform extract of the photolysed sample showed only negligible fluorescence.So,

we concluded that P-flavin cannot be quantified using the lumiflavin fluorescence method and P-flavin is not included

in the flavins quantified by this method

DNA sequencing The genomic DNA of P phosphoreum IFO 13896 or

V fischeri ATCC 7744 was prepared using Genomic-tip 500/G (QIAGEN) as previously reported [17].PCR was

conducted using the ASTEC program temperature control

system PC-701 with 0.2 mL PCR tubes The genomic DNA

was used as a template.The oligonucleotides used for

primers were purchased from Genset.On preparation of the

respective template for sequencing, two primers, either

nondegenerate or degenerate, were designed and then a

DNA sequence was amplified using Ready-To-Go PCR

beads (Amersham Biosciences) with a temperature control

program of 20 s at 94C, 20 s at 50 C, and 2 min at 72 C

for 40 cycles.The amplified DNA sequences were purified

by means of agarose gel electrophoresis and then gel

extraction kits (QIAGEN)

Nucleotide sequences were determined using a BigDye

Terminator Cycle Sequencing Ready Reaction Kit and an

ABI PRISM 310 genetic analyser (Applied Biosystems) at

the Graduate School of Science, Osaka City University,

according to the manufacturer’s protocol.In this study, we

first amplified the DNA to be sequenced as above and then

directly sequenced it using the primers for amplification

without cloning [17].The protocol for SUGDAT,

Sequen-cing Using Genomic DNA As a Template, was reported

previously [17] and it worked well also in the sequencing of

the P phosphoreum genomic DNA.When SUGDAT was

repeated, the average length of determined sequences was

300 bp because nonerroneous and non-AT-rich sequences

were necessary to design primers for the subsequent

SUGDAT.In this study, three DNA sequences, the total

lengths of which were 1995, 5616 and 5232 bp, were

sequenced by SUGDAT and a PCR-based method using

degenerate primers as described below.To exclude reading

errors, DNA sequences of appropriate lengths (400–500 bp)

where neighbouring sequences overlapped were amplified

by PCR as described above and sequenced once again on

both strands

A 1995-bp sequence downstream of the rib gene cluster

reported by Lee et al.[7] was determined by performing

SUGDAT seven times as outlined in Fig.1A The first

primer, 5¢-CGAAAGCTTCTCATGGCCGC-3¢, was

designed by referring to the reported sequence (DDBJ/

EMBL/GenBank database accession number, L11391)

Sequencing of the complete rib operon with both flanking

regions in P phosphoreum IFO 13896 (5616 bp) is outlined

in Fig.1B.Two conserved amino acid sequences in RibD,

GATAYVT and (L/I)WVEAGS, were found by comparing

RibD sequences from V cholerae (AE004298), E coli

(X64395) and H influenzae (U32775), and according

to these sequences, two degenerate primers, 5¢-GGN

GCIACNGCITAYGTNAC-3¢ (where I ¼ inosine) and

5¢-NGVICCNGCYTCIACCCANA-3¢, were designed

Using these primers, a 720-bp DNA sequence was amplified

and the nucleotide sequence was determined.To determine

a 1379-bp sequence upstream of the partial ribD, the

genomic DNA was sequenced by five rounds of SUGDAT

A 641-bp sequence downstream of the partial ribD was

determined by two rounds of SUGDAT and it was found

that ribC overlaps with the tail of ribD.To confirm the

presence of ribBA downstream of ribC, a conserved amino

acid sequence in RibBA, NDDGTMA, was found by

comparing RibBA sequences from V cholerae (AE004298),

P phosphoreum (RibBA¢) (L11391), and P leiognathi

(M90094), and a degenerate reverse primer, 5¢-GCCATNG

TICCRTCNTCRTT-3¢ was designed according to this

amino acid sequence.Using this primer and a forward one,

we amplified an 853-bp sequence and sequenced this PCR product.Further, a conserved amino acid sequence

in RibE, NKGAEAA, was found by comparing RibE sequences from V cholerae (AE004298), P phosphoreum (RibE¢) (L11391), P leiognathi (M90094), Ps aeruginosa (AE004821) and E coli (X64395), and a degenerate reverse primer, 5¢-GCNGCYTCIGCNCCYTTRTT-3¢ was designed.Using this primer and a forward one, a 1267-bp sequence was amplified and sequenced.The undetermined part of ribE and an 807-bp sequence further downstream were sequenced by three rounds of SUGDAT

The sequencing of the rib operon with both flanking regions in V fischeri ATCC 7744 (5232 bp) is outlined in Fig.1C Partial of ribD was amplified using the same primers as above, and sequenced.A 1221-bp upstream sequence was determined by six rounds of SUGDAT.A 1554-bp and a 1232-bp sequence were amplified using the two degenerate primers above, and two nondegenerate primers.Further, a 520-bp sequence was amplified using a degenerate primer, 5¢-ACNCCRTTNACRAAYTTRTG-3¢ and a nondegenerate primer.The former was designed according to a conserved amino acid sequence in NusB, HKFVNGV, which was found by comparing NusB sequences from P phosphoreum as determined above,

V cholerae (AE004298), E coli (X64395) and Ps aerugi-nosa(AE004821).The last 262-bp sequence was determined

by one round of SUGDAT

The three nucleotide sequences of hcp (1995 bp), the complete rib operon with some genes (5616 bp) of

Fig 1 Clusters of riboflavin biosynthetic genes in P phosphoreum and

V fischeri Open arrows indicate genes in these orientations.Solid arrows indicate sequences determined in these orientations by SUG-DAT.Solid bars indicate PCR products.(A) The rib gene cluster was found downstream of the lux operon in P phosphoreum by Lee et al [7].Note that ribD is not present in this cluster.A region downstream

of the lux–rib cluster in P phosphoreum was sequenced by SUGDAT seven times and a 1995-bp sequence was determined in which a gene for the hybrid-cluster protein (prismane protein), hcp, was found.The scale is only effective for the rib gene cluster and hcp.(B) A partial ribD sequence was amplified by PCR using two degenerate primers.A

1379-bp upstream sequence was determined by five rounds of SUGDAT and a 641-bp downstream sequence was determined by two rounds Because at this sequencing stage, a new rib operon seemed to be present

in this region, two DNA sequences were amplified using two pairs of primers, degenerate and nondegenerate.An 807-bp further down-stream sequence was determined by three rounds of SUGDAT.(C) A 5232-bp sequence of a rib operon with both flanking regions in

V fischeri was determined using basically the same strategy as des-cribed above.

P phosphoreum, and the corresponding region (5232 bp) of

V fischeri, determined as above, will appear in the DDBJ/

EMBL/GenBank nucleotide sequence database with the

accession numbers, AB065117, AB065118 and AB076605,

respectively

R E S U L T S

Stimulated biosynthesis of flavins inP phosphoreum

IFO 13896 strongly emitting light

P phosphoreum emits light strongly when cultured in a

medium containing 3% NaCl but only weakly in 1% NaCl

[18–20].Meanwhile, dim or dark mutants appear

sponta-neously and frequently from Photobacterium species [21]

These poor light-emitting cells seemed to be useful as a

control to confirm that the biosynthesis of flavins is

stimulated in the cells strongly emitting light.Therefore,

we measured the amount of light and total amount of

flavins produced in the cells.Five growth curves of the

parent strain cultured in 3% and 1% NaCl, and M1, M2

and M3 in 3% NaCl are shown in Fig 2A Growth rates

and maximum cell densities under the respective conditions

were not identical.In mutants cultured in 3% NaCl, growth

rates were almost the same; however, maximum cell density

was highest for M1 (designated 100%), 93% for M3, and

88% for M2.The growth rate of the parent strain cultured

in 1% and 3% NaCl, was 67% and 33% of that of the three

mutants, respectively.The maximum cell density of the parent cells cultured in 1% and 3% NaCl was 82% and 73% of that of M1, respectively.Growth and biolumines-cence curves of the parent strain cultured in 3% or 1% NaCl and M1, M2 or M3 in 3% NaCl are shown in Fig.2 (B1–B5).To estimate the amount of bioluminescence emitted under each set of conditions, the respective biolu-minescence curve was integrated.However, because maxi-mum cell density varied with the conditions or strain, it was necessary to normalize each value.Accordingly, we divided the integrated value of bioluminescence by the maximum cell density of the respective growth curve to estimate the average bioluminescence emitted during growth causing an increase in turbidity of 1 unit, which we designated as specific bioluminescence.These values are shown in Table 1 The parent strain emitted
37 times more light in medium containing 3% NaCl than it did in medium containing 1% NaCl.This drastic diminution of bioluminescence caused by

a decrease of ionic strength in the medium has been reported previously [18–20].M1 is a dark mutant and does not emit light detectable with the naked eye.M2 and M3 showed about 1/60 and 1/10 the specific bioluminescence of the parent strain cultured in 3% NaCl, respectively

To confirm that strongly light emitting cells produce large amounts of flavins, we determined the total amount of flavins in cells from the parent strain cultured in 3% or 1% NaCl, and from three mutants cultured in 3% NaCl Respective values are shown in Table 1.We determined the

Fig 2 Growth and bioluminescence curves of the parent and three mutant strains of P phosphoreum IFO13896 Five growth curves are collectively shown in panel (A) for comparison j, Parent strain cultured in 3% NaCl medium; d, parent strain in 1% NaCl; m, mutant strain M1 cultured in 3% NaCl; , M2 in 3% NaCl; r, M3 in 3% NaCl Growth (h) and bioluminescence (s) curves of the parent strain in 3% and 1% NaCl are shown in panel B1 and B2, respectively, and those of M1, M2 and M3 in 3% NaCl are shown in B3, B4 and B5, respectively.

total amount of flavins using the lumiflavin fluorescence

method.The term flavins refers to riboflavin, FMN and

FAD.P-flavin, which is contained in the extract of luminous

bacterial cells [12], is not included because it is not

photolysed to a fluorescent lumiflavin-type product, as

described above.Because M1 emits light sparingly, this

mutant seems to produce flavins at a basal level.The parent

strain cultured in 3% NaCl, meanwhile, produced about

eight times more flavin than M1 cells.Considering that the

parent cells produce P-flavin, it is appropriate that they

produce more flavin.The parent cells in 1% NaCl, and the

M2 and M3 cells in 3% NaCl, produced about 2, 1.5- and

2.5-times more flavin than M1 cells, respectively From

these results, we concluded that the biosynthesis of flavins is

regulated strictly in P phosphoreum and the strain can emit

much light because it can produce flavins on demand when

the expression of the lux operon is activated

Identification of a gene for hybrid-cluster protein,

Hcp, inP phosphoreum

Biosynthesis is regulated by many mechanisms.Among

them the regulation of gene expression is important and for

efficiency genes are often organized in an operon in

prokaryotes.Because the biosynthesis of flavins is

stimula-ted vigorously on demand in P phosphoreum as described

above, we speculated that rib genes are organized in an

operon in this species.Because a gene coding for pyrimidine

deaminase/pyrimidine reductase, ribD, is not present in the

ribcluster reported by Lee et al.[7], which is located just

downstream of the lux operon (Fig.1A), we sequenced the

genomic DNA of P phosphoreum IFO 13896 downstream

of the terminal region of ribA¢ as shown in Fig 1A,

assuming that ribD may be present here.A 270-bp

nucleotide sequence was obtained in the first SUGDAT

A partial sequence of ribD was not found in this sequence,

but a partial gene in the opposite orientation was found.We

compared the 48-amino acid sequence deduced from this

partial gene sequence with the sequences of proteins

collected in the DAD database using theFASTAprogram

at DDBJ and found it to be
60% identical to the

C-terminal region of the E coli hybrid-cluster protein, Hcp

(prismane protein).To confirm unequivocally the presence

of the gene for this protein, we performed SUGDAT a

further six times.In the determined sequence (AB065117),

an open reading frame of 1662 bp was located 80 bp

downstream of the termination codon of ribA¢ in the

opposite direction

Hcp was originally found in Desulfovibrio vulgaris and

named prismane protein because it was postulated that the

protein contains the [6Fe)6S] cluster

[22].Three-dimen-sional structural analysis revealed that the protein does not

contain this cluster but has two Fe/S clusters, one of which is

a hybrid [4Fe)2S)2O], and was consequently renamed

hybrid-cluster protein [23].Recently, E coli hcp was

over-expressed in a recombinant E coli and it was shown that the protein has properties similar to those of D vulgaris Hcp [24].A homology search using FASTA revealed that it is present in 22 species as of today.In addition, K€uuhn et al reported that a putative protein displaying 55% homology

to the D desulfuricans Hcp is present in Morganella morganii[25].The number of amino acid residues compo-sing each of the E coli [24], Salmonella typhimurium (AE008739), Salmonella enterica (AL627268), Yersinia pestis (AJ414147), Acidithiobacillus ferrooxidans (TFU73041),

D vulgaris [22], and D desulfuricans [26] Hcp is 545–556 and comparable with that of the P phosphoreum Hcp (553 amino acids).The P phosphoreum Hcp shows 62–40% amino acid identity with the Hcp of these species.We therefore concluded that hcp is present just downstream of ribA¢ in P phosphoreum

Identification of another completerib operon in

P phosphoreum IFO 13896 and analysis of its 5616-bp sequence

The ribD gene was not found downstream of ribA¢ in

P phosphoreum but the gene is surely present because riboflavin cannot be synthesized without RibD.To find it,

we tried to amplify part of the gene by PCR using two degenerate primers and obtained a DNA sequence of the expected length (Fig.1B).Because the amino acid sequence deduced from this nucleotide sequence showed 56% identity with that of RibD of V cholerae (AE004298), we concluded that we had amplified an expected partial ribD sequence After two rounds of SUGDAT downstream of the partial ribD, we recognized that another ribC is present in succession.Because this arrangement is generally found in the rib operons of other species we expected ribBA to also be present downstream of ribC.We therefore designed a degenerate primer according to the conserved amino acid sequence in RibBA, and amplified an 853-bp sequence.A partial amino acid sequence deduced from the nucleotide sequence showed 78% identity with that of RibBA of

V cholerae, and we concluded that ribBA is present downstream of ribC in P phosphoreum.At this stage, we assumed that the remaining gene, ribE, would be present downstream of ribBA and confirmed this in the same way as above (Fig.1B).Further, we determined 1379-bp upstream and 855-bp downstream sequences by SUGDAT as described above

In the sequence shown in Fig.3, six complete and two partial open reading frames were found.The amino acid sequences deduced from the nucleotide sequences of these open reading frames are also shown in Fig.3.At the 5¢-end,

a partial glyA sequence, which encodes serine hydroxy-methyl transferase, was found in the same orientation as the riboperon.A gene of 450 bp was found 217 bp downstream

of the termination codon of glyA.This gene is conserved and generally found just upstream of ribD in Gram-negative

Table 1 Specific bioluminescence emitted and total amount of flavins produced.

P phosphoreum strain Parent Parent M1 M2 M3 Concentration of NaCl in the medium 3% 1% 3% 3% 3% Specific bioluminescence (arbitrary units/turbidity) 18 401 515 2 315 1840 Total amount of flavins (pmol/mL turbidity) 348 86 45 72 120

bacteria, whether or not the rib genes are organized in an

operon.Because it seems to be closely related to the rib

operon, we designated it ribX and will discuss its function

later.Downstream of ribX, four rib genes) ribD, ribC,

ribBAand ribE) were organized in a complete operon in

the same arrangement as the complete rib operons in other

species.The tail of ribD overlapped with the head of ribC

(Fig.3) and the number of amino acid residues of RibD in

this species is larger by about 20 residues than the numbers

in other species (Table 2).Although in E coli, ribA and ribB

are separated, in P phosphoreum they were fused as one

gene, ribBA, as in other species in which rib genes are

organized in an operon.The ribBA gene is separated from

ribEby 202 bp (Fig.3), but a similar long spacing, 215 bp,

is also found in V cholerae (AE004298).The homologies of

these five rib gene products with those of five different

species, along with RibC¢, RibBA¢ and RibE¢ of P

phos-phoreumor P leiognathi, and the number of amino acid

residues composing the respective protein are shown in

Table 2.From these data, we concluded that a complete rib

operon is present in P phosphoreum, which explains why

this species can synthesize flavins at enhanced levels to

sustain a strong light emission.On the other hand, the

question of why a rib cluster, the lux–rib cluster, is present

downstream of the lux operon, arises.The respective rib

gene product, RibC, RibBA or RibE, in the newly found rib

operon showed the highest identity with the corresponding

gene product in the lux–rib operon of the same species,

RibC¢, RibBA¢ or RibE¢, among gene products from any

other species, as shown in Table 2.This evidence indicates

that the genes in the lux–rib cluster were not incorporated

into the genome of this species by horizontal transfer

Because the lux–rib cluster does not contain ribD, this

incomplete operon would be unlikely to contribute mainly

to riboflavin biosynthesis and the cluster seems to be an

auxiliary operon.It was recently reported that a

homolog-ous rib cluster is present in a closely related species,

P leiognathi [27].In the lux–rib cluster, ribA¢ is present along with ribBA¢ as shown in Fig.1A.Fassbinder et al reported that both genes are present together in He pylori, but ribBA did not complement the ribA mutation in E coli [28].Downstream of the rib operon, a complete nusB, which encodes an antitermination factor, and a partial thiL, which encodes thiamine phosphate kinase, were found.The array

of three genes, ribE, nusB and thiL, is conserved widely in bacteria classified in the Proteobacteria c-subdivision (Fig.4)

Identification of a completerib operon in V fischeri ATCC 7744 and analysis of the determined 5232 bp sequence

Callahan and Dunlap reported that in V fischeri, a gene encoding 3,4-dihydroxy-2-butanone 4-phosphate

Fig 4 Comparison of the arrangement of the rib genes in bacteria classified in the Proteobacteria c-subdivision and Gram-positive bacteria.

In Enterobacteriaceae ribX, ribD and ribE are organized in a cluster but ribC and ribBA are not.The latter is not fused but remains as two separate genes, ribA and ribB.In Vibrionaceae, Pseudomonadaceae and the Xanthomonas group, the rib genes are organized in a complete operon and two genes, ribA and ribB, are fused as one, ribBA.In Gram-positive bacteria, four rib genes are organized in an operon but ribX is separate.Neighbouring genes are bound with solid lines and separated genes with dashed lines.Arrows under the genes indicate the orientation in which the respective genes are arranged.The orientation

of separated genes is not indicated because it changes depending on the species.

Table 2 Homologies of five rib proteins, RibX, RibD, RibC, RibBA and RibE of P phosphoreum or V fischeri with those of seven species Amino acid identity (%) in the sequences of five Rib proteins of P phosphoreum (P.p.) or V fischeri (V.f.) with respect to one of the seven species and number of amino acid residues composing the respective protein of each species (No.aa).

P.p V.f No aa P.p V.f No aa P.p V.f No aa P.p V.f No aa P.p V.f No aa Number of amino acid residues 149 149 388 372 218 218 367 369 156 156

Species compared

P phosphoreum (RibC¢, RibBA¢, RibE¢) – – – – 73 65 218 77 65 363 87 78 155

P leiognathi (RibC¢, RibBA¢, RibE¢) – – – – 60 58 218 73 64 364 78 75 144

V cholerae 84 84 156 57 62 367 62 69 217 70 81 369 82 91 173

E coli 82 80 149 59 51 367 35 34 213 – – 68 67 156

Ps aeruginosa 71 67 154 49 48 373 61 56 219 58 58 365 69 65 158

B subtilis 48 47 152 41 44 361 38 40 215 42 44 398 52 53 154

Fig 3 Nucleotide sequence of a newly found rib operon in P

phos-phoreum with the deduced amino acid sequences of GlyA, RibX, RibD,

RibC, RibBA, RibE, NusB and ThiL The nucleotides are numbered on

the left, and the amino acid residues are numbered on the right.The

location of each gene is indicated at the head of the gene.The asterisks

indicate the translational termination codons.

synthase (ribB) is one of the LuxR- and acylhomoserine

lactone-controlled nonlux genes, and also that the gene is

monocistronic and not a member of the rib operon [29].This

poses the question of whether rib genes are organized in

an operon and the genes for 3,4-dihydroxy-2-butanone

4-phosphate synthase and GTP cyclohydrolase II are fused

to ribBA in V fischeri.To answer these questions, we

examined whether in this species the rib operon is present,

and if so, whether ribBA is present in the fused form

We tried to amplify a partial ribD sequence by PCR using

the two degenerate primers used to amplify the gene of

P phosphoreum.The DNA sequence was amplified

success-fully and a 5232-bp sequence of a complete rib operon with

both flanking regions was determined as shown in Fig.1C

In the sequence determined, six complete and two partial

open reading frames were found.At the 5¢-end of the

sequence, a partial 430 bp gene of unknown function

(ORF1) was found in the opposite orientation to the rib

operon.Although we performed a homology search on this

partial protein using FASTA, no homologues were found

Downstream of this open reading frame, seven genes, ribX,

ribD, ribC, ribBA, ribE, nusB and thiL, were arranged in the

same sequence as that in P phosphoreum.Homologies of

the five rib gene products of V fischeri with those of five

different species, along with RibC¢, RibBA¢ and RibE¢ of

P phosphoreum and P leiognathi are shown in Table 2

Based on these results, we concluded that a complete rib

operon, in which ribBA is fused as one gene, is present also

in V fischeri

Callahan and Dunlap constructed a mutant of V fischeri

MJR1 defective in ribB, and examined it for altered growth

and bioluminescence in comparison with the parent strain

[29].However, the mutant showed no difference, regardless

of the presence or absence of exogenously supplied

ribofla-vin.They concluded that RibB apparently is not required

for, and does not play a significant role in normal light

production.Their conclusion is appropriate because also in

V fischeri, a complete rib operon is present as shown above

and even if ribB does not work, ribBA seems to complement

this defect

D I S C U S S I O N

In this study, we reconfirmed that the light emitted from

P phosphoreum IFO 13896 is largely diminished in 1%

NaCl medium as compared with that in medium containing

3% NaCl (Fig.2, B1 and B2).Although the mutant M1

emitted light sparingly even in the logarithmic growth phase,

the strain grew quite well (Fig.2, B3).In the past, it was

difficult to maintain strongly light emitting strains on a slant

because they gradually changed in storage.We speculate

that this change is caused by reverse mutations as follows

The strains, which are available from depositories, are

usually strongly light emitting because they were screened

based on this criterion.However, such strains seem to be

unusual, while dim or dark mutants seem to be common

Once a mutation occurs in a light emitting strain, dim or

dark mutants prevail rapidly as if they grow faster and more

densely than the parent.The evidence above supports that

the function of the lux operon is not to produce light, and

light is a by-product of the bacterial luciferase [17,30]

Van den Berg et al.divided species bearing hcp into three

classes [24].According to their classification, P phosphoreum

is in class II.They reported that the spacing of the N-terminal cysteines in this class is CX2CX11CX6C and this spacing was found in the amino acid sequence of P phosphoreum Hcp Although the bacteria classified in class II are also classified in the Proteobacteria c-subdivision, hcp is present nonubiqui-tously in bacteria classified in this subdivision and was not detected even in the genome of V cholerae.Evidence that hcp

is present in P phosphoreum in addition to E coli,

S typhimurium, S enterica, Y pestis and M morganii, among bacteria in this subdivision, strongly supports that the luminous bacteria should be placed with enteric bacteria

of sea animals.It was suggested that Hcp has a role in nitrate/

or nitrite respiration [24], and overproduction of the protein

is toxic to the cells of Clostridium perfringens in the presence

of oxygen [31]

Comparing the arrangement of rib genes in bacteria classified in the Proteobacteria c-subdivision, we can deduce the process of organization of these genes.Among these species, in Buchnera, rib genes are scattered and not organized at all (NC 002528).In two species of Pasteurell-aceae, H influenzae and Pasteurella multocida, rib genes are not yet organized but there are indications of organization The ribX gene is present upstream of ribD in these species (U32775 and AE006112).In four species in Enterobacteri-aceae, E coli (X64395), S typhimurium (AE008714), S ent-erica(AL627266) and Y pestis (AJ414155), ribX, ribD and ribEare organized in a cluster but ribC and ribBA are not as shown in Fig.4.The latter is not fused but remains as two divided genes, ribA and ribB.Finally, in Vibrionaceae (AE004298), Pseudomonadaceae (AE004821 and AE004822) and the Xanthomonas group (AE003934, AE011704 and AE012168), two genes, ribA and ribB, are fused as ribBA and the rib genes are organized in a complete operon, although a gene may be inserted between ribD and ribCin Xanthomonas group (Fig.4)

The function of ribX is not yet clear.Although the gene is not present in Buchnera, it appears just upstream of ribD in Pasteurellaceaeand is present at this location in all other species in the Proteobacteria c-subdivision, although a gene may be inserted between ribX and ribD in the Xanthomonas group.However, the genes found just upstream of ribX in these species are quite variable and not arranged in one direction, as shown in Fig.4.This may indicate that ribX is related to the rib operon.The gene is not very long and its product is rich in basic amino acids P phosphoreum RibX was calculated to have a pI of 7.6 suggesting that the protein could be a DNA binding protein.In B subtilis, regulation

of the biosynthesis of riboflavin has been studied intensively FMN has been identified as the effecter molecule for regulation of the rib operon [1,32,33] and the cis-acting region has been identified as ribO [1] However, just upstream of ribD in B subtilis, no regulatory gene is present and the trans-acting protein(s) has not been identified in any other location [1].To date, genome sequences of 19 species

of Gram-positive bacteria have been deposited in the database; 12 of these species are riboflavin autotrophic and seven are auxotrophic.In autotrophs, rib genes are organized in an operon, although in three species

of Mycobacterium (MTCY21B4, AE007016 and MLEPRTN2), some genes are inserted in the rib operon

In all of these species, ribX is present not just upstream of the rib operon but far from the operon.For example, in

B subtilis, ribX is designated as ytcG (Z99118).In four

auxotrophs, ribX is not present but it is in three, Listeria

innocua (AL596169), Listeria monocytogenes (AL591979)

and Streptococcus pyogenes (AE006498).On the basis

described above, we suggest that RibX may be a regulator

for the rib operon.In Gram-positive bacteria, ribX may

move to another position because it may acquire additional

function(s).For the same reason, the gene may be present

even in auxotrophs.We have no experimental evidence of

this but we consider that it is worth examining whether the

gene works as expected, because in none of the species have

regulatory gene(s) for the rib operon been identified in spite

of a great deal of effort

A C K N O W L E D G E M E N T S

This work was supported in part by a Grant-in-Aid for Scientific

Research (C) from the Ministry of Education, Culture, Sports, Science

and Technology of Japan.We are indebted to T.Nakamura of the

Graduate School of Science, Osaka City University, for assistance in

operating the DNA sequencer.

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