- Email: [email protected]
Cloning and characterization of the mutated threonine operon (thrA15A25BC) of Serratia marcescens
Gene.
151
151-158
57 (1987)
Elsevter GEN 02108
Cloning and characterization of the mutated threonine operon (thrA,SA,5BC) of Sewatia lttarcescens (Recombinant
Takahisa
DNA;
TnlOOO mutagenesis;
Sugita, Sahuro Komatsubara
gene dosage;
and Masahiko
maxicell;
threonine
production)
Kisumi
Research Laboratory of Applied Biochemistry, Tanabe Seiyaku Co., Ltd., Osaka 532 (Japan) Received Revised
25 March
1987
27 May 1987
Accepted
30 May 1987
SUMMARY
The entire threonine operon (thrA,5_4,5BC) of Serratia marcescens TLr156, which lacks threonine-mediated feedback inhibition of both aspartokinase I (AK I) and homoserine dehydrogenase I (HD I), was cloned on a multicopy plasmid pLG339. Hybrid plasmid pSK301 carried a 6.5kb chromosomal DNA. Several derivatives of pSK301 with TnlOOO insertions were obtained. By examining the phenotypes and the physical maps of these plasmids, we could define the loci of the thrA,SA,S, thrB, and thrC genes. The thrA,SA,S and thrC gene products were identified by the maxicell method as proteins with M,s of 85000 and 43000, respectively. The thrA,SA,S genes encode a single polypeptide similar to the thrA,A, genes of Escherichia coli. Plasmid pSK301 was introduced into S. marcescens T-l 112, in which both AK I and HD I are produced constitutively. The resulting transformant carried five to six copies of pSK301 per chromosome and produced the AK I and HD I enzymes at three to four times higher level than control strain T-11 12[pLG339]. Strain T-l 112[pSK301] produced four times higher levels of threonine than strain T-1112[pLG339], yielding about 35 mg of threonine per ml of a medium containing sucrose and urea.
INTRODUCTION
S. marcescens resembles E. coli K-12 in the regulatory mechanism and genetic background for Correspondence Applied Kashima,
to: Dr. S. Komatsubara,
Biochemistry,
Tanabe
Yodogawa-ku,
Abbreviations:
Osaka
AK, aspartokinase;
serine dehydrogenase;
streptomycin; transposon; state;
Laboratory
Co.,
532 (Japan)
Ltd.,
a, sensitivity;
bp, base pair(s);
UV, ultraviolet
electrophoresis;
SDS, sodium
Tc, tetracycline; light;
of
3-16-89,
Tel. (06)300-2571.
kb, 1000 bp; Km, kanamycin;
cation; PAGE, polyacrylamide-gel r, restriction;
Research
Seiyaku
m, modifiR, resistance;
dodecyl
thr, threonine
[ 1,designates
HD, homo-
sulfate; (operon);
Sm, Tn,
plasmid-carrier
::, novel joint.
0378-l 119/87/$03.50
0 1987 Elsevier
Science Publishers
B.V. (Biomedical
threonine biosynthesis. The thr operon is composed of four genes: thrA 1, thrA,, thrB, and thrC, which code for AK I (EC 2.7.2.4), HD I (EC 1.1.1.3), homoserine kinase (EC 2.7.1.39), and threonine synthase (EC 4.2.99.2), respectively (Komatsubara et al., 1979). AK I and HD I are feedback-inhibited by threonine and repressed by threonine plus isoleucine. We have obtained the thrA,S and thrA,S mutants which lacked the feedback inhibition of AK I and HD I by isolating threonine-resistant mutants from a strain sensitive to this amino acid (S.K. and M.K., manuscript in preparation). The hnrA 1 mutant which led to derepressed expression of AK I, HD I, and ilv enzymes was selected among Division)
152
/I-hydroxynorvaline-resistant
mutants
(Komatsu-
bara et al., 1978a; 1979). These regulatory were transductionally tions
releasing
combined
feedback
threonine-producing
to
(a) Strains, plasmids and media
construct
(Komatsubara
Derivatives of E. coli K-12 and S. marcescens Sr41 (Matsumoto et al., 1975) are listed in Table I.
et al.,
1983). To construct
threonine-hyperproducing
strains by
amplifying mechanism
the thr operon and to understand the for feedback controls more clearly, we
intended
to
clone
the
entire
thr
Plasmid
operon
tration at
of
both
AK I and HD I. This paper describes cloning of the entire thr operon of S. marcescens TLr1.56, identitication of the thr operon gene products by the maxicell method, and a gene dosage effect on threonine pro-
obtained
from
Dr.
N.G.
to 0.5%. Required
1 mM.
acids were used
~-amino
DL-/&Hydroxynorvaline
was
used
at
0.1 mM. Antibiotics were added at the specified concentrations: Km, 100 pg/ml; Sm, 50 pg/ml; Tc, 10 pg/ml. The medium for threonine production contained 15% sucrose, 1.5% urea, 0.05 y0 (NH&SO,, 0.1% K,HPO,, 0.1% MgSO, .7H,O, 0.02% corn steep liquor, and 1% CaCO,.
duction.
TABLE
was
Davis and Mingioli (1950) was modified by omitting the Na * citrate and increasing the glucose concen-
threonine-mediated
inhibition
pLG339
Stoker (Stoker et al., 1982). The minimal medium of
(thrA ,5A,5BC) of S. marcescens TLr 156 which lacks feedback
AND METHODS
mutations
with other muta-
controls
strains
MATERIALS
I
Bacterial
strains
used
Strain
Genotype
Source
a
or reference
E. coli Bachmann
thr-1 IeuBl thi-1 supE44 lacy1 tonA
GT12
thrB metLM
IysC pro ser
GT13
thrC metLM
1ysC pro ser
GT15
thrA, metLM
IysC pro ser
Theze et al. (1974)
GT16
thrA , metLM
IysC pro ser
Thbze et al. (1974)
GT121
As GT12 except for SmR
SmR derivative
of GT12
GT131
As GT13 except for SmR
SmR derivative
of GT13
GT151
As GT15 except for SmR
SmR derivative
of GT15
GT161
As GT16 except for SmR
SmR derivative
of GT16
GT1211
As GT121 except for srlC300::Tn10
recA56
Hfr cross: JClO240
x GT121
GT1311
As GT131 except for srlC300::TnZO
recA56
Hfr cross: JC10240
x GT131
GT1515
As GT151
except for srlC300::TnZO
recA56
Hfr cross: JC10240
x GT151
GT1614
As GT161
except for srlC300::TnZO
recA56
Hfr cross: JC10240
x GT161
JC10240
HfrC(P045),
srlC300::TnZO
hsdR hsdM
(1972)
C600r - m
Theze et al. (1974) Thtze
et al. (1974)
Laszlo
recA56 thr-300 ilv-318 rpsE300
and Alvin (1980)
Mark (1978)
MG1063
F’,
MM294
thi hsdR
red1
Backman
N1790
recA99 uwA54
Horii et al. (1981)
et al. (1976)
s. mareeseens D-60
ilvA
Komatsubara
T-1112
thrA,S thrA,5 hnrA 1 ilvA
S.K. and M.K.
TLr156
thrA,S thrA,S ilvA
TT392
NW-
(manuscript
thrA,S, lack of feedback
Takagi
r - ApS Kms
a In E. coli K-12, the thrA gene specifies a single polypeptide (Thtze
inhibition
and Saint-Girons,
in preparation)
SK. and M.K. (manuscript
to AK I and HD I, respectively
et al. (1978b)
chain but is composed 1974). Genotype
of HD I; hnrA 1, derepression
of two cistrons,
designations:
(1985)
thrA, and thrA,, which correspond
thrA,S, lack of feedback
of AK I, HD I, and ilv enzymes.
in preparation)
and Kisumi
inhibition
of AK I;
153
(b) General methods
RESULTS
Standard procedures for DNA manipulations were as described by Maniatis et al. (1982). The maxicell method (Sancar et al., 1979) was employed for labelling proteins encoded by plasmids. SDS-PAGE of proteins was carried out according to Laemmli (1970). Plasmid copy number was determined by fluorescence densitometry as described by Projan et al. (1983). Transformation of E. coli or S. marcescens was carried out following the method of Takagi and Kisumi (1985). Plasmids were introduced into S. marcescens by transformation first into strain TT392, which is deficient in DNA restriction enzymes, but proficient in modification. They were re-isolated and transformed into strains D-60 and T-1112.
(a) Cloning
(c) Assay of enzyme activity and threonine productivity The activities of AK and HD were measured as described by Kisumi et al. (1977). Threonine productivity was determined according to Komatsubara et al. (1979).
TABLE
AND DISCUSSION
of
the
mutated
threonine
operon
(thrA,SA,SBC) The chromosomal DNA of S. marcescens TLr 156, which lacks feedback inhibition of both AK I and HD I, was prepared and hybrid plasmids carrying the chromosomal fragments on the Sal1 site of the cloning vector pLG339 were constructed. E. coli C600r - m - (thrB) was transformed with the mixture of these hybrid plasmids, and then spread on minimal agar plates supplemented with leucine, thiamine, and threonine analog p-hydroxynorvaline. Since thrA,SA,S mutations render strain TLr156 resistant to fi-hydroxynorvaline, /I-hydroxynorvaline-resistant and ThrB + clones were selected as the candidates carrying cloned thrA,SA,SBC genes. Subsequently, these clones were examined for threonine excretion by spotting cells on a minimal agar plate seeded with a threonine auxotroph. Thus, we obtained one transformant showing threonine excretion. This strain was designated C600rm[pSK301] and tested for AK and HD (Table II). These enzymes of C600r-m- [pSK301] were insensitive to feedback inhibition by threonine as were those of strain TLr156. On the contrary, the two enzymes were feedback-inhibited by threonine in strains D-60 (wild type) and C600r-m-[pLG339]. These results convinced us that this transformant carried the chromosomal fragment carrying thrA,5A25 genes.
II
Lack of threonine-mediated
inhibition
of aspartokinase
and homoserine
dehydrogenase
activities
in an Escherichiu coli strain carrying
pSK301 Inhibition
Strain
(%)
Aspartokinase
a
Homoserine
dehydrogenase’
E. coli C600r _ m _ [pLG339]
91
68
C600r -m
11
18
85
19
[pSK301]
S. marcescens D-60
-23
TLr156 a Assayed
as described
lysine-sensitive b L-Threonine
in MATERIALS
AK activity. was added
L-Threonine at 10 mM.
9 AND METHODS, was added
section c. L-Lysine was added at 50 mM to the reaction
at 50 mM.
mixture to inhibit
154
The plasmid from this strain, designated pSK301, was introduced into E. coli MM294(r- m +). It was re-isolated and transferred into E. coli GT16(t/zrA,), GTlS(thrA,), GT12(thrB), and GT13(thrC). The transformants were purified and tested for the presence of the thrA,S, thrA,S, thrB, and thrC genes by complementation tests. Since pSK301 complemented all four mutations, we concluded that the cloned segment carries the entire thr operon (thrA,SA,SBC) of S. marcescens TLr156.
5A25BC
fhrB, and ~/WCgenes
(b) Location of the thrA,5A,5, on pSK301
The restriction map of pSK301, which consists of a 6.5-kb chromosomal DNA fragment and 6.2-kb pLG339 DNA, was constructed (Fig. 1). To locate the thrA,SA,SBC genes on pSK301, its derivatives with TnlOOO insertions were obtained and the sites of insertions were mapped by restriction enzyme cleavage patterns (Fig. 2). The phenotypes of these plasmids were also determined by examining their ability to complement the thrA , , thrA,, thrB, and thrC
h
s2
thrB
\ I
of the thrA,5A,SBC
on plates and pSK301
by Sal1 and Hind111 digestion
are oriented Insertions ThrA,5
Insertions
on pSK301
42 and 43 are pLG339
20-27,
28-37,
and
+ A,5 + B + C + phenotypes,
under the map of TnZOOO insertions. bottom.
orientations
are indicated
SalI,-SalI,
fragment
The positions
insert
from
represents
the
of the genes and their
on the outer circle. pSK304 carries the
on pLG339.
Abbreviations
S, SalI; EI, EcoRI;
tion enzymes:
EV, EcoRV;
for the restricH, HindHI;
M,
MluI; X, XhoI.
pLG339 h
with TnlOOO insertions
38-41
respectively.
were isolated.
of the thr genes on pSK301
Phenotypes
with the yend of the transposon l-19,
pLG339.
sector
gene loci on pSK301. Transposon TnZOOO(y6) was inserted into pSK301 as described by was mated with GT1211, GT1311, GT1515, and GTl614. KmR and SmR exconjugants
derivatives
patterns.
tests. The sites of TnZOOO insertions the plasmid.
vector
and the solid-line
>
thrC
Linder et al. (1983). Strain MGl063[pSK301] were selected
plasmid
TLr156
The double-line
DNA
s4
s3 . I
thrAISA25 Fig. 2. Determination
S. marcescens
and pSK304.
chromosomal
1
I I
1 I
Sl
map of pSK301 the 6.5kb
represents
TLr156 chromosome I\
Strain
I
Fig. 1. Restriction sector
or pLG339
The sites of TnZOOO insertions
derivatives
are shown by the vertical
were also determined
lines. Each number
: :T&000 and others are pSK301:: TnZOOO. Insertions to the left. Insertions showed
Appropriate
The direction
shown below the horizontal
ThrA,S-A,S-B+C+, locations
of transcription
and translation
clone number
above the horizontal
line are in the opposite
ThrA,S+A,S+B-C+,
of thrA,SA,5BC
indicates
shown
were determined
by complementation
orientations.
ThrA,S+A,5+B+C-,
genes and Sal1 sites (S,-S,)
of the thr genes is indicated
of line and
are represented
by the arrows
at the
155
mutations. Derivatives with insertion numbers 1 to 19, 20 to 27, 28 to 37, and 38 to 41 showed ThrA,-A,-B’C’, ThrA,+Az+B-C’, ThrA,’ A,+B+C-, and ThrAi+A,‘B+C+ phenotypes, respectively. Based on these results, the correlated physical and genetic map of the cloned thrA ,SA,SBC region was constructed as shown in Fig. 2. The approximate sizes of the zhrA,5A,5, thrB, and thrC genes seemed to be 2.4 kb, 1.0 kb, and 1.3 kb, respectively. Among the 27 independent derivatives, there were none that showed any polar effect although TnlOQO was inserted into the thrA,SA,S or thrB gene. The deletion plasmid pSK304, which carries SatI,-S&I, fragment and lacks most of the thrA 15A,5 genes, also complemented the thrB and thrC mutations. These results indicate that the thrA ,5A,5, thrB, and thrC genes of S. marcescens are transcribed, at least partially, from separate promoters. However, a possibility cannot be ruled out that the promoters on TnlOOO or pLG339 are related to the expression of the downstream thr gene(s).
thrC gene product. Only a small amount of the thrA,SA,5 gene product was produced in the cells bearing the ThrA,+AZ+B+CCplasmids. This might result from the difference of the effects of UV radiation, because, in another expe~ment, the from the thrA,5A,5 gene products ThrA, + A, + B + C - plasmids were expressed at the same level as those produced from other ThrA, + AZ+ plasmids (not shown). Cells bearing the ThrA, + A, + B - C + plasmids produced all of the three kinds of unique proteins as cells bearing pSK301 did (Fig. 3, lanes j and k); an additional 29-kDa protein was produced from the pSK301 derivative with insertion number 24. The maximal size of the coding region of the thrB’ gene on the pSK301 derivative with insertion number 24 is about 800 bp, which is very similar to the deduced size of the coding region of 29-kDa protein. Therefore the 29-kDa protein is likely to be the truncated poly peptide of the thrB gene product. When plasmid pSK30 1 was introduced into S. marcescens T-l 112, in which both AK I and HD I are produced constitutively, the unique proteins with Mrs of 85 000,43 000,
(c) Ide~ti~cation of the br operon gene products To identify the thr operon gene products, proteins encoded by pSK301 and its derivatives were labelled with [ 35S]methionine in maxicells, and the cell extracts were analyzed by SDS-PAGE, followed by &orography. In cells bearing pSK301, unique proteins of 85,43 and 3 1 kDa were synthesized whereas similar proteins were not observed in cells bearing pLG339 or pLG339: : TnfOUO (Fig. 3, lanes a-c). The above proteins are similar in size to the thr operon gene products of E. co&(Parsot et al., 1983). Cells bearing the ThrA, - A, - B + C + plasmids produced unique smaller proteins, which are probably the truncated polypeptides of the 85-kDa protein (Fig. 3, lanes g-i). By correlating the sizes of truncated pol~eptides with the sites of Tn~~U~ insertions, the tr~sc~ption~ direction of the thrA,SA,S genes was determined to be from left to right in Fig. 2. The thrA,SA,S genes could not be further divided into cistrons by TnlOOO insertions. These results suggest that the thrA,SA,S genes encode a single 85-kDa protein. When plasmids in which the TnlOOOinsertion inactivated the thrCgene were used as templates, the 43-kDa protein was not observed (Fig. 3, lanes l-n), suggesting that this protein is the
abcdetg‘hi
jklmno
Mrxlo-”
WrMv ‘=‘414yr;u*
-g4thrA,5Ar5 -67
-3
thrC
Fig. 3. [35S]Methionine-labelled proteins produced in maxicells by plasmids derived from pSK30 1or pLG339. Proteins produced in maxi&Is were analyzed by SDS-PAGE, followed by fluorography. E. cob N1790 was used as a host for each plasmid to be tested. Lanes: (a) pLG339; (b) 42; (c) pSK301; (d) 38; (e) 39; (f) 1; (g)5; (h) 11; (i)4; (j)20; (k)24; (1)29; (m)30; (n)31; (a) pSK304. These clone numbers of pSK301::TnlOOO or pLG339 : :TnlOOOare shown in Fig. 2. The arrowheads indicate the truncated polypeptides of the thr gene products (lanes g, h, i, and k). Symbols thrA,SA,5 and thrC represent chrA,SA,S and thrC gene products with M,s of 85 000 and 43 000, respectively. The markers are phosphorylase b (94 kDa), albumin (67 kDa), ovalbumin (43 kDa), and carbonic anhydrase (30 kDa).
156
a
b
c
sis of the nucleotide sequences will provide information for understanding this problem.
d
MKKY3
(d) Expression of the t/w operon genes from plasmid pSK301 in Serratia marcescens
5‘A25
Fig. 4. Overproduction of the thr operon gene products in S. mnrce~cen~ T-l 112. Cell extracts used in Table III were analyzed by SDS-PAGE, followed by Coomassie brilliant blue staining. Lanes: (a) T-l 112; (b) T-l 112[pLG339]; (c)T-l 112[pSK301]; (d)M, markers (see Fig. 3). Symbols thrA,SA,S and thrC represent thrA,SA,S and thrC gene products with M,s of 85 000 and 43 000, respectively.
and 3 1000 were produced in large amounts as seen on an SDS-polyacrylamide gel stained with Coomassie brilliant blue (Fig. 4, lane c). These proteins were not amplified when pSK301 was introduced into D-60, which is of wild type for the thr operon gene expression (not shown). These results suggest that these unique proteins are from the thr operon genes and the 31-kDa protein is likely to be from the thrB gene. But cells bearing the ThrA, + A, + B - C + plasmid produced the 3 l-kDa protein. There is a possibility that another gene which encodes the 31-kDa protein exists on pSK301 and this protein and the thrB gene product comigrate on an SDS-polyacrylamide gel. The analy-
Plasmid pSK301 was introduced into S. marcescens D-60 and T- 1112, which are of wild type and constitutive for the thr operon gene expression, respectively. The AK and HD activities were assessed to see whether the thr operon genes on pSK301 were expressed in these transformants (Table III). When the cells were grown with excess isoleucine, where the wild type thr operon genes are repressible, the HD level of D-60[pSK301] was about five times as much as that of D&O[pLG339]. The HD level of T-1112~pSK301] was about four times as much as that of T-l 112[pLG339] and about 20 times as much as that of D&O[pLG339]. In strain D-60[pSK301], the HD activity was not inhibited by threonine. Similar results were obtained for the AK. Cell extracts of these transformants were analyzed by SDS-PAGE, followed by Coomassie brilliant blue staining (Fig. 4). Strain T-1112[pSK301] produced large amounts of proteins with M,s of 85000, 43 000, and 31000 as mentioned above. The copy number of pSK30 1 was assessed to find the gene dosage of the cloned thr operon. Plasmid pSK301 existed at five to six copies per 5’. marcescens chromosome (Table III). Since strain T-l 112 lacks feedback repression of AK I and HD I, the thr operon genes on pSK301 were expressed at higher levels in this strain, reflecting the gene dosage. (e) Threonine pSK301
production
by
strains
carrying
Threonine production by strains carrying pSK301 was examined (Table IV). Strain T-1112[pSK301] produced 35 mg of threonine per ml, whereas strain T-l 112[pLG339] produced 8 mg of threonine per ml. The threonine productivity was markedly improved by introducing pSK301 into a threonineproducing strain. The fmal cell amount of strain T-l 112 was slightly decreased by introducing pSK301 (Table IV). But even when Km was not added to the medium, pSK301 was almost stably maintained in the cells during the entire period of
157
TABLE
III
Aspartokinase
and homoserine
Strain
dehydrogenase
activities
Specific
a
activity
Aspartokinase
in Serru~iu marcescens strains
carrying
the plasmids
Copy number e
b
Homoserine dehydrogenase
D-60[pLG339]
17 (
7S)C
10 (
D-60[pSK301]
37 (
12)
48 (- 15)
T-l 112[pLG339]
38 (-22)
T-11 12[pSK301]
120 (- 16)
a Assayed
as described
b Assayed
in the presence
in MATERIALS
49 ( 202 ( AND METHODS,
NT NT
4) 1)
5.4 f 0.4
section c and expressed
(%) by 50 mM L-threonine
(minus values might depend
d Inhibition
(%) by 10 mM L-threonine
(minus value might depend
expressed
NT
in nmol product/mg
proteimmin.
of 50 mM L-lysine.
’ Inhibition
e The copy number
77)d
per chromosome
was calculated
on stabilization
of the enzyme
on stabilization
of the enzyme
by t_-threonine). by L-threonine).
by taking the M, of the S. marcescens chromosome
to be 2.5 x 109. The value is
as mean + SD (n = 4). NT, not tested.
incubation (not shown). Strain T-1112[pSK301] is useful for the industrial production of threonine. We have succeeded in constructing S. marcescens strains producing this amino acid in much larger amounts by using the hybrid plasmid described here.
REFERENCES
Bachmann,
B.J.: Pedigrees
coli K-12. Bacterial. Backman,
K., Ptashne,
plasmids Acad. Davis, ACKNOWLEDGEMENTS
carrying
of same mutant
strains ofEscherichiu
Rev. 36 (1972) 525-557. M. and Gilbert,
W.: Construction
the cI gene of bacteriophage
of
1. Proc. Natl.
Sci. USA 73 (1976) 4174-4178.
B.D. and
requiring
Mingioli,
methionine
E.S.:
of Escherichiu co/i
Mutants
or vitamin
B,,. J. Bacterial.
60 (1950)
17-28. Horii, T., Ogawa,
We are grateful to Dr. G.N. Cohen for providing GT12, GT13, GT15, and GT16, to Dr. N.G. Stoker for pLG339 and to Dr. A. Nakata for JC10240 and MG1063. We also thank Dr. I. Chibata and Dr. T. Tosa for encouragement.
TABLE Threonine
T. and Ogawa,
H.: Nucleotide
sequence
of the
IexA gene of E. coli. Cell 23 (1981) 689-697. Kisumi,
M., Komatsubara,
isoleucine
S. and Chibata,
hydroxamate-mediated
provement
of isoleucine-producing
cescens. Appl. Environ.
Microbial.
I.: Enhancement
growth strains
inhibition
of
and im-
of Serratiu mur-
34 (1977) 647-653.
IV production
Strain
D-60[pLG339] D-60[pSK301] T-l 112[pLG339] T-1112[pSK301]
by strains
carrying
Growth
the plasmids
a (mg/ml)
L-Threonine produced b (mg/ml)
120h
144 h
120h
144 h
38 37 36 30
NT” NT 35 31
0 15 8 29
NT” NT 8 35
a A loopful of cells grown overnight on a nutrient agar slant supplemented with Km was inoculated into a 15 ml liquid medium in a 500-ml Sakaguchi shaking flask and was incubated at 30°C with reciprocal shaking (140 rev./min, 7-cm stroke). The growth is expressed as dry cell weight. b L-Threonine was determined by bioassay with Leuconostoc mesenteroides P-60, as described by Komatsubara et al. (1979). ’ NT, not tested.
158
Komatsubara,
S., Kisumi,
Threonine
production
M., Murata,
K. and
by regulatory
mutants
marcescens. Appl. Environ. Komatsubara,
S., Murata,
Threonine
Microbial.
Chibata,
35 (1978a)
K., Kisumi,
I.:
of Serruriu
M. and
834-840.
Chibata,
M. and Chibata,
I.: Transductional
of a threonine-producing
murcescens. Appl. Environ. Komatsubara,
S., Kisumi,
construction
Microbial.
38 (1979) 1045-1051.
M. and Chibata,
murcescens: lack of feedback
controls
dehydrogenases.
U.K.:
assembly
Cleavage
of three aspartokinases
of the head of bacteriophage
proteins
Micro-
during
T4. Nature
Laszlo, N.C. and Alvin, J.C.: Construction recA
J. Bacterial.
Linder, P., Churchward, cation mutants
the
227 (1970)
mutations
ofan Hfr strain useful Escherichiu coli
between
G. and Caro, L.: Plasmid
generated
by insertion
T., Fritsch,
A Laboratory Spring Harbor, Mark,
SC.:
E.F. and Sambrook,
Manual.
pSClO1 repli-
of transposon
TnZOOO.
J.: Molecular
Cloning.
Laboratory,
Cold
The y 6 sequence
A., Hack,
of F is an insertion
sequence.
termination
R.P.: Determination
by fluorescence
A.M. and Rupp, of plasmid-coded
densitometry.
of
Plasmid
W.D.:
Simple method
for
proteins.
J. Bacterial.
137
(1979) 692-693. N.G.,
Fairweather,
low-copy-number coli. Gene
murcescens mutant
K-12:
Mapping
M.: Isolation
structure
B.C.:
Versatile
of a versatile cloning
Serrutiu of the
161 (1985) l-6.
I.: Threonine and
locus ofEscherichiu coli
evidence
for an operon.
J.
118 (1974) 990-998. D., Cohen, G.N., Borne, F. and Patte, J.C.:
of the structural
and of two homoserine
genes of the three aspartokinases dehydrogenases
117 (1974) 133-143.
J. Communicated
Spratt,
for cloning in Escherichiu
as a host and molecular
gene. J. Bacterial.
genetic
Bacterial.
and
vectors
18 (1982) 335-341.
T. and Kisumi,
aspartase
N.F.
plasmid
K-12. J. Bacterial.
NY, 1982.
Mol. Biol. 126 (1978) 347-365.
T.:
operon in Escherichiu coli K-12. Nucl.
S. and Novick,
copy number
Theze, J., Margarita,
Cold Spring Harbor
Tazaki,
I. and Cohen, G.N.: Nucle-
of thrC and of the transcription
Theze, J. and Saint-Girons,
143 (1980) 529-530.
J. Mol. Biol. 170 (1983) 287-303. Maniatis,
Sancar,
Takagi,
for transferring
P., Saint-Girons,
S.J., Carleton,
identification
680-685.
strains.
Projan,
Stoker, of structural
K. and
9 (1983) 182-190.
strain of Serrutiu
biol. 45 (1983) 1445-1452. Laemmli,
C., Cossart,
plasmid
I.: Transductional
Appl. Environ.
Suzuki,
Acids Res. 11 (1983) 7331-7345.
of Serrutiu
strain
of a threonine-hyperproducing
and two homoserine
Parsot,
region of the threonine
S., Kisumi,
construction
H.,
cluster ofSerruriu murcescens. Jpn. J. Microbial.
otide sequences
135 (1978b) 318-323. Komatsubara,
H., Hosogaya,
Argininegene
19 (1975) 35-44. I.:
by Serruriu murcescens. J. Bacterial.
degradation
Matsumoto,
by H. Yoshikawa
of Escherichiu coli
151
151-158
57 (1987)
Elsevter GEN 02108
Cloning and characterization of the mutated threonine operon (thrA,SA,5BC) of Sewatia lttarcescens (Recombinant
Takahisa
DNA;
TnlOOO mutagenesis;
Sugita, Sahuro Komatsubara
gene dosage;
and Masahiko
maxicell;
threonine
production)
Kisumi
Research Laboratory of Applied Biochemistry, Tanabe Seiyaku Co., Ltd., Osaka 532 (Japan) Received Revised
25 March
1987
27 May 1987
Accepted
30 May 1987
SUMMARY
The entire threonine operon (thrA,5_4,5BC) of Serratia marcescens TLr156, which lacks threonine-mediated feedback inhibition of both aspartokinase I (AK I) and homoserine dehydrogenase I (HD I), was cloned on a multicopy plasmid pLG339. Hybrid plasmid pSK301 carried a 6.5kb chromosomal DNA. Several derivatives of pSK301 with TnlOOO insertions were obtained. By examining the phenotypes and the physical maps of these plasmids, we could define the loci of the thrA,SA,S, thrB, and thrC genes. The thrA,SA,S and thrC gene products were identified by the maxicell method as proteins with M,s of 85000 and 43000, respectively. The thrA,SA,S genes encode a single polypeptide similar to the thrA,A, genes of Escherichia coli. Plasmid pSK301 was introduced into S. marcescens T-l 112, in which both AK I and HD I are produced constitutively. The resulting transformant carried five to six copies of pSK301 per chromosome and produced the AK I and HD I enzymes at three to four times higher level than control strain T-11 12[pLG339]. Strain T-l 112[pSK301] produced four times higher levels of threonine than strain T-1112[pLG339], yielding about 35 mg of threonine per ml of a medium containing sucrose and urea.
INTRODUCTION
S. marcescens resembles E. coli K-12 in the regulatory mechanism and genetic background for Correspondence Applied Kashima,
to: Dr. S. Komatsubara,
Biochemistry,
Tanabe
Yodogawa-ku,
Abbreviations:
Osaka
AK, aspartokinase;
serine dehydrogenase;
streptomycin; transposon; state;
Laboratory
Co.,
532 (Japan)
Ltd.,
a, sensitivity;
bp, base pair(s);
UV, ultraviolet
electrophoresis;
SDS, sodium
Tc, tetracycline; light;
of
3-16-89,
Tel. (06)300-2571.
kb, 1000 bp; Km, kanamycin;
cation; PAGE, polyacrylamide-gel r, restriction;
Research
Seiyaku
m, modifiR, resistance;
dodecyl
thr, threonine
[ 1,designates
HD, homo-
sulfate; (operon);
Sm, Tn,
plasmid-carrier
::, novel joint.
0378-l 119/87/$03.50
0 1987 Elsevier
Science Publishers
B.V. (Biomedical
threonine biosynthesis. The thr operon is composed of four genes: thrA 1, thrA,, thrB, and thrC, which code for AK I (EC 2.7.2.4), HD I (EC 1.1.1.3), homoserine kinase (EC 2.7.1.39), and threonine synthase (EC 4.2.99.2), respectively (Komatsubara et al., 1979). AK I and HD I are feedback-inhibited by threonine and repressed by threonine plus isoleucine. We have obtained the thrA,S and thrA,S mutants which lacked the feedback inhibition of AK I and HD I by isolating threonine-resistant mutants from a strain sensitive to this amino acid (S.K. and M.K., manuscript in preparation). The hnrA 1 mutant which led to derepressed expression of AK I, HD I, and ilv enzymes was selected among Division)
152
/I-hydroxynorvaline-resistant
mutants
(Komatsu-
bara et al., 1978a; 1979). These regulatory were transductionally tions
releasing
combined
feedback
threonine-producing
to
(a) Strains, plasmids and media
construct
(Komatsubara
Derivatives of E. coli K-12 and S. marcescens Sr41 (Matsumoto et al., 1975) are listed in Table I.
et al.,
1983). To construct
threonine-hyperproducing
strains by
amplifying mechanism
the thr operon and to understand the for feedback controls more clearly, we
intended
to
clone
the
entire
thr
Plasmid
operon
tration at
of
both
AK I and HD I. This paper describes cloning of the entire thr operon of S. marcescens TLr1.56, identitication of the thr operon gene products by the maxicell method, and a gene dosage effect on threonine pro-
obtained
from
Dr.
N.G.
to 0.5%. Required
1 mM.
acids were used
~-amino
DL-/&Hydroxynorvaline
was
used
at
0.1 mM. Antibiotics were added at the specified concentrations: Km, 100 pg/ml; Sm, 50 pg/ml; Tc, 10 pg/ml. The medium for threonine production contained 15% sucrose, 1.5% urea, 0.05 y0 (NH&SO,, 0.1% K,HPO,, 0.1% MgSO, .7H,O, 0.02% corn steep liquor, and 1% CaCO,.
duction.
TABLE
was
Davis and Mingioli (1950) was modified by omitting the Na * citrate and increasing the glucose concen-
threonine-mediated
inhibition
pLG339
Stoker (Stoker et al., 1982). The minimal medium of
(thrA ,5A,5BC) of S. marcescens TLr 156 which lacks feedback
AND METHODS
mutations
with other muta-
controls
strains
MATERIALS
I
Bacterial
strains
used
Strain
Genotype
Source
a
or reference
E. coli Bachmann
thr-1 IeuBl thi-1 supE44 lacy1 tonA
GT12
thrB metLM
IysC pro ser
GT13
thrC metLM
1ysC pro ser
GT15
thrA, metLM
IysC pro ser
Theze et al. (1974)
GT16
thrA , metLM
IysC pro ser
Thbze et al. (1974)
GT121
As GT12 except for SmR
SmR derivative
of GT12
GT131
As GT13 except for SmR
SmR derivative
of GT13
GT151
As GT15 except for SmR
SmR derivative
of GT15
GT161
As GT16 except for SmR
SmR derivative
of GT16
GT1211
As GT121 except for srlC300::Tn10
recA56
Hfr cross: JClO240
x GT121
GT1311
As GT131 except for srlC300::TnZO
recA56
Hfr cross: JC10240
x GT131
GT1515
As GT151
except for srlC300::TnZO
recA56
Hfr cross: JC10240
x GT151
GT1614
As GT161
except for srlC300::TnZO
recA56
Hfr cross: JC10240
x GT161
JC10240
HfrC(P045),
srlC300::TnZO
hsdR hsdM
(1972)
C600r - m
Theze et al. (1974) Thtze
et al. (1974)
Laszlo
recA56 thr-300 ilv-318 rpsE300
and Alvin (1980)
Mark (1978)
MG1063
F’,
MM294
thi hsdR
red1
Backman
N1790
recA99 uwA54
Horii et al. (1981)
et al. (1976)
s. mareeseens D-60
ilvA
Komatsubara
T-1112
thrA,S thrA,5 hnrA 1 ilvA
S.K. and M.K.
TLr156
thrA,S thrA,S ilvA
TT392
NW-
(manuscript
thrA,S, lack of feedback
Takagi
r - ApS Kms
a In E. coli K-12, the thrA gene specifies a single polypeptide (Thtze
inhibition
and Saint-Girons,
in preparation)
SK. and M.K. (manuscript
to AK I and HD I, respectively
et al. (1978b)
chain but is composed 1974). Genotype
of HD I; hnrA 1, derepression
of two cistrons,
designations:
(1985)
thrA, and thrA,, which correspond
thrA,S, lack of feedback
of AK I, HD I, and ilv enzymes.
in preparation)
and Kisumi
inhibition
of AK I;
153
(b) General methods
RESULTS
Standard procedures for DNA manipulations were as described by Maniatis et al. (1982). The maxicell method (Sancar et al., 1979) was employed for labelling proteins encoded by plasmids. SDS-PAGE of proteins was carried out according to Laemmli (1970). Plasmid copy number was determined by fluorescence densitometry as described by Projan et al. (1983). Transformation of E. coli or S. marcescens was carried out following the method of Takagi and Kisumi (1985). Plasmids were introduced into S. marcescens by transformation first into strain TT392, which is deficient in DNA restriction enzymes, but proficient in modification. They were re-isolated and transformed into strains D-60 and T-1112.
(a) Cloning
(c) Assay of enzyme activity and threonine productivity The activities of AK and HD were measured as described by Kisumi et al. (1977). Threonine productivity was determined according to Komatsubara et al. (1979).
TABLE
AND DISCUSSION
of
the
mutated
threonine
operon
(thrA,SA,SBC) The chromosomal DNA of S. marcescens TLr 156, which lacks feedback inhibition of both AK I and HD I, was prepared and hybrid plasmids carrying the chromosomal fragments on the Sal1 site of the cloning vector pLG339 were constructed. E. coli C600r - m - (thrB) was transformed with the mixture of these hybrid plasmids, and then spread on minimal agar plates supplemented with leucine, thiamine, and threonine analog p-hydroxynorvaline. Since thrA,SA,S mutations render strain TLr156 resistant to fi-hydroxynorvaline, /I-hydroxynorvaline-resistant and ThrB + clones were selected as the candidates carrying cloned thrA,SA,SBC genes. Subsequently, these clones were examined for threonine excretion by spotting cells on a minimal agar plate seeded with a threonine auxotroph. Thus, we obtained one transformant showing threonine excretion. This strain was designated C600rm[pSK301] and tested for AK and HD (Table II). These enzymes of C600r-m- [pSK301] were insensitive to feedback inhibition by threonine as were those of strain TLr156. On the contrary, the two enzymes were feedback-inhibited by threonine in strains D-60 (wild type) and C600r-m-[pLG339]. These results convinced us that this transformant carried the chromosomal fragment carrying thrA,5A25 genes.
II
Lack of threonine-mediated
inhibition
of aspartokinase
and homoserine
dehydrogenase
activities
in an Escherichiu coli strain carrying
pSK301 Inhibition
Strain
(%)
Aspartokinase
a
Homoserine
dehydrogenase’
E. coli C600r _ m _ [pLG339]
91
68
C600r -m
11
18
85
19
[pSK301]
S. marcescens D-60
-23
TLr156 a Assayed
as described
lysine-sensitive b L-Threonine
in MATERIALS
AK activity. was added
L-Threonine at 10 mM.
9 AND METHODS, was added
section c. L-Lysine was added at 50 mM to the reaction
at 50 mM.
mixture to inhibit
154
The plasmid from this strain, designated pSK301, was introduced into E. coli MM294(r- m +). It was re-isolated and transferred into E. coli GT16(t/zrA,), GTlS(thrA,), GT12(thrB), and GT13(thrC). The transformants were purified and tested for the presence of the thrA,S, thrA,S, thrB, and thrC genes by complementation tests. Since pSK301 complemented all four mutations, we concluded that the cloned segment carries the entire thr operon (thrA,SA,SBC) of S. marcescens TLr156.
5A25BC
fhrB, and ~/WCgenes
(b) Location of the thrA,5A,5, on pSK301
The restriction map of pSK301, which consists of a 6.5-kb chromosomal DNA fragment and 6.2-kb pLG339 DNA, was constructed (Fig. 1). To locate the thrA,SA,SBC genes on pSK301, its derivatives with TnlOOO insertions were obtained and the sites of insertions were mapped by restriction enzyme cleavage patterns (Fig. 2). The phenotypes of these plasmids were also determined by examining their ability to complement the thrA , , thrA,, thrB, and thrC
h
s2
thrB
\ I
of the thrA,5A,SBC
on plates and pSK301
by Sal1 and Hind111 digestion
are oriented Insertions ThrA,5
Insertions
on pSK301
42 and 43 are pLG339
20-27,
28-37,
and
+ A,5 + B + C + phenotypes,
under the map of TnZOOO insertions. bottom.
orientations
are indicated
SalI,-SalI,
fragment
The positions
insert
from
represents
the
of the genes and their
on the outer circle. pSK304 carries the
on pLG339.
Abbreviations
S, SalI; EI, EcoRI;
tion enzymes:
EV, EcoRV;
for the restricH, HindHI;
M,
MluI; X, XhoI.
pLG339 h
with TnlOOO insertions
38-41
respectively.
were isolated.
of the thr genes on pSK301
Phenotypes
with the yend of the transposon l-19,
pLG339.
sector
gene loci on pSK301. Transposon TnZOOO(y6) was inserted into pSK301 as described by was mated with GT1211, GT1311, GT1515, and GTl614. KmR and SmR exconjugants
derivatives
patterns.
tests. The sites of TnZOOO insertions the plasmid.
vector
and the solid-line
>
thrC
Linder et al. (1983). Strain MGl063[pSK301] were selected
plasmid
TLr156
The double-line
DNA
s4
s3 . I
thrAISA25 Fig. 2. Determination
S. marcescens
and pSK304.
chromosomal
1
I I
1 I
Sl
map of pSK301 the 6.5kb
represents
TLr156 chromosome I\
Strain
I
Fig. 1. Restriction sector
or pLG339
The sites of TnZOOO insertions
derivatives
are shown by the vertical
were also determined
lines. Each number
: :T&000 and others are pSK301:: TnZOOO. Insertions to the left. Insertions showed
Appropriate
The direction
shown below the horizontal
ThrA,S-A,S-B+C+, locations
of transcription
and translation
clone number
above the horizontal
line are in the opposite
ThrA,S+A,S+B-C+,
of thrA,SA,5BC
indicates
shown
were determined
by complementation
orientations.
ThrA,S+A,5+B+C-,
genes and Sal1 sites (S,-S,)
of the thr genes is indicated
of line and
are represented
by the arrows
at the
155
mutations. Derivatives with insertion numbers 1 to 19, 20 to 27, 28 to 37, and 38 to 41 showed ThrA,-A,-B’C’, ThrA,+Az+B-C’, ThrA,’ A,+B+C-, and ThrAi+A,‘B+C+ phenotypes, respectively. Based on these results, the correlated physical and genetic map of the cloned thrA ,SA,SBC region was constructed as shown in Fig. 2. The approximate sizes of the zhrA,5A,5, thrB, and thrC genes seemed to be 2.4 kb, 1.0 kb, and 1.3 kb, respectively. Among the 27 independent derivatives, there were none that showed any polar effect although TnlOQO was inserted into the thrA,SA,S or thrB gene. The deletion plasmid pSK304, which carries SatI,-S&I, fragment and lacks most of the thrA 15A,5 genes, also complemented the thrB and thrC mutations. These results indicate that the thrA ,5A,5, thrB, and thrC genes of S. marcescens are transcribed, at least partially, from separate promoters. However, a possibility cannot be ruled out that the promoters on TnlOOO or pLG339 are related to the expression of the downstream thr gene(s).
thrC gene product. Only a small amount of the thrA,SA,5 gene product was produced in the cells bearing the ThrA,+AZ+B+CCplasmids. This might result from the difference of the effects of UV radiation, because, in another expe~ment, the from the thrA,5A,5 gene products ThrA, + A, + B + C - plasmids were expressed at the same level as those produced from other ThrA, + AZ+ plasmids (not shown). Cells bearing the ThrA, + A, + B - C + plasmids produced all of the three kinds of unique proteins as cells bearing pSK301 did (Fig. 3, lanes j and k); an additional 29-kDa protein was produced from the pSK301 derivative with insertion number 24. The maximal size of the coding region of the thrB’ gene on the pSK301 derivative with insertion number 24 is about 800 bp, which is very similar to the deduced size of the coding region of 29-kDa protein. Therefore the 29-kDa protein is likely to be the truncated poly peptide of the thrB gene product. When plasmid pSK30 1 was introduced into S. marcescens T-l 112, in which both AK I and HD I are produced constitutively, the unique proteins with Mrs of 85 000,43 000,
(c) Ide~ti~cation of the br operon gene products To identify the thr operon gene products, proteins encoded by pSK301 and its derivatives were labelled with [ 35S]methionine in maxicells, and the cell extracts were analyzed by SDS-PAGE, followed by &orography. In cells bearing pSK301, unique proteins of 85,43 and 3 1 kDa were synthesized whereas similar proteins were not observed in cells bearing pLG339 or pLG339: : TnfOUO (Fig. 3, lanes a-c). The above proteins are similar in size to the thr operon gene products of E. co&(Parsot et al., 1983). Cells bearing the ThrA, - A, - B + C + plasmids produced unique smaller proteins, which are probably the truncated polypeptides of the 85-kDa protein (Fig. 3, lanes g-i). By correlating the sizes of truncated pol~eptides with the sites of Tn~~U~ insertions, the tr~sc~ption~ direction of the thrA,SA,S genes was determined to be from left to right in Fig. 2. The thrA,SA,S genes could not be further divided into cistrons by TnlOOO insertions. These results suggest that the thrA,SA,S genes encode a single 85-kDa protein. When plasmids in which the TnlOOOinsertion inactivated the thrCgene were used as templates, the 43-kDa protein was not observed (Fig. 3, lanes l-n), suggesting that this protein is the
abcdetg‘hi
jklmno
Mrxlo-”
WrMv ‘=‘414yr;u*
-g4thrA,5Ar5 -67
-3
thrC
Fig. 3. [35S]Methionine-labelled proteins produced in maxicells by plasmids derived from pSK30 1or pLG339. Proteins produced in maxi&Is were analyzed by SDS-PAGE, followed by fluorography. E. cob N1790 was used as a host for each plasmid to be tested. Lanes: (a) pLG339; (b) 42; (c) pSK301; (d) 38; (e) 39; (f) 1; (g)5; (h) 11; (i)4; (j)20; (k)24; (1)29; (m)30; (n)31; (a) pSK304. These clone numbers of pSK301::TnlOOO or pLG339 : :TnlOOOare shown in Fig. 2. The arrowheads indicate the truncated polypeptides of the thr gene products (lanes g, h, i, and k). Symbols thrA,SA,5 and thrC represent chrA,SA,S and thrC gene products with M,s of 85 000 and 43 000, respectively. The markers are phosphorylase b (94 kDa), albumin (67 kDa), ovalbumin (43 kDa), and carbonic anhydrase (30 kDa).
156
a
b
c
sis of the nucleotide sequences will provide information for understanding this problem.
d
MKKY3
(d) Expression of the t/w operon genes from plasmid pSK301 in Serratia marcescens
5‘A25
Fig. 4. Overproduction of the thr operon gene products in S. mnrce~cen~ T-l 112. Cell extracts used in Table III were analyzed by SDS-PAGE, followed by Coomassie brilliant blue staining. Lanes: (a) T-l 112; (b) T-l 112[pLG339]; (c)T-l 112[pSK301]; (d)M, markers (see Fig. 3). Symbols thrA,SA,S and thrC represent thrA,SA,S and thrC gene products with M,s of 85 000 and 43 000, respectively.
and 3 1000 were produced in large amounts as seen on an SDS-polyacrylamide gel stained with Coomassie brilliant blue (Fig. 4, lane c). These proteins were not amplified when pSK301 was introduced into D-60, which is of wild type for the thr operon gene expression (not shown). These results suggest that these unique proteins are from the thr operon genes and the 31-kDa protein is likely to be from the thrB gene. But cells bearing the ThrA, + A, + B - C + plasmid produced the 3 l-kDa protein. There is a possibility that another gene which encodes the 31-kDa protein exists on pSK301 and this protein and the thrB gene product comigrate on an SDS-polyacrylamide gel. The analy-
Plasmid pSK301 was introduced into S. marcescens D-60 and T- 1112, which are of wild type and constitutive for the thr operon gene expression, respectively. The AK and HD activities were assessed to see whether the thr operon genes on pSK301 were expressed in these transformants (Table III). When the cells were grown with excess isoleucine, where the wild type thr operon genes are repressible, the HD level of D-60[pSK301] was about five times as much as that of D&O[pLG339]. The HD level of T-1112~pSK301] was about four times as much as that of T-l 112[pLG339] and about 20 times as much as that of D&O[pLG339]. In strain D-60[pSK301], the HD activity was not inhibited by threonine. Similar results were obtained for the AK. Cell extracts of these transformants were analyzed by SDS-PAGE, followed by Coomassie brilliant blue staining (Fig. 4). Strain T-1112[pSK301] produced large amounts of proteins with M,s of 85000, 43 000, and 31000 as mentioned above. The copy number of pSK30 1 was assessed to find the gene dosage of the cloned thr operon. Plasmid pSK301 existed at five to six copies per 5’. marcescens chromosome (Table III). Since strain T-l 112 lacks feedback repression of AK I and HD I, the thr operon genes on pSK301 were expressed at higher levels in this strain, reflecting the gene dosage. (e) Threonine pSK301
production
by
strains
carrying
Threonine production by strains carrying pSK301 was examined (Table IV). Strain T-1112[pSK301] produced 35 mg of threonine per ml, whereas strain T-l 112[pLG339] produced 8 mg of threonine per ml. The threonine productivity was markedly improved by introducing pSK301 into a threonineproducing strain. The fmal cell amount of strain T-l 112 was slightly decreased by introducing pSK301 (Table IV). But even when Km was not added to the medium, pSK301 was almost stably maintained in the cells during the entire period of
157
TABLE
III
Aspartokinase
and homoserine
Strain
dehydrogenase
activities
Specific
a
activity
Aspartokinase
in Serru~iu marcescens strains
carrying
the plasmids
Copy number e
b
Homoserine dehydrogenase
D-60[pLG339]
17 (
7S)C
10 (
D-60[pSK301]
37 (
12)
48 (- 15)
T-l 112[pLG339]
38 (-22)
T-11 12[pSK301]
120 (- 16)
a Assayed
as described
b Assayed
in the presence
in MATERIALS
49 ( 202 ( AND METHODS,
NT NT
4) 1)
5.4 f 0.4
section c and expressed
(%) by 50 mM L-threonine
(minus values might depend
d Inhibition
(%) by 10 mM L-threonine
(minus value might depend
expressed
NT
in nmol product/mg
proteimmin.
of 50 mM L-lysine.
’ Inhibition
e The copy number
77)d
per chromosome
was calculated
on stabilization
of the enzyme
on stabilization
of the enzyme
by t_-threonine). by L-threonine).
by taking the M, of the S. marcescens chromosome
to be 2.5 x 109. The value is
as mean + SD (n = 4). NT, not tested.
incubation (not shown). Strain T-1112[pSK301] is useful for the industrial production of threonine. We have succeeded in constructing S. marcescens strains producing this amino acid in much larger amounts by using the hybrid plasmid described here.
REFERENCES
Bachmann,
B.J.: Pedigrees
coli K-12. Bacterial. Backman,
K., Ptashne,
plasmids Acad. Davis, ACKNOWLEDGEMENTS
carrying
of same mutant
strains ofEscherichiu
Rev. 36 (1972) 525-557. M. and Gilbert,
W.: Construction
the cI gene of bacteriophage
of
1. Proc. Natl.
Sci. USA 73 (1976) 4174-4178.
B.D. and
requiring
Mingioli,
methionine
E.S.:
of Escherichiu co/i
Mutants
or vitamin
B,,. J. Bacterial.
60 (1950)
17-28. Horii, T., Ogawa,
We are grateful to Dr. G.N. Cohen for providing GT12, GT13, GT15, and GT16, to Dr. N.G. Stoker for pLG339 and to Dr. A. Nakata for JC10240 and MG1063. We also thank Dr. I. Chibata and Dr. T. Tosa for encouragement.
TABLE Threonine
T. and Ogawa,
H.: Nucleotide
sequence
of the
IexA gene of E. coli. Cell 23 (1981) 689-697. Kisumi,
M., Komatsubara,
isoleucine
S. and Chibata,
hydroxamate-mediated
provement
of isoleucine-producing
cescens. Appl. Environ.
Microbial.
I.: Enhancement
growth strains
inhibition
of
and im-
of Serratiu mur-
34 (1977) 647-653.
IV production
Strain
D-60[pLG339] D-60[pSK301] T-l 112[pLG339] T-1112[pSK301]
by strains
carrying
Growth
the plasmids
a (mg/ml)
L-Threonine produced b (mg/ml)
120h
144 h
120h
144 h
38 37 36 30
NT” NT 35 31
0 15 8 29
NT” NT 8 35
a A loopful of cells grown overnight on a nutrient agar slant supplemented with Km was inoculated into a 15 ml liquid medium in a 500-ml Sakaguchi shaking flask and was incubated at 30°C with reciprocal shaking (140 rev./min, 7-cm stroke). The growth is expressed as dry cell weight. b L-Threonine was determined by bioassay with Leuconostoc mesenteroides P-60, as described by Komatsubara et al. (1979). ’ NT, not tested.
158
Komatsubara,
S., Kisumi,
Threonine
production
M., Murata,
K. and
by regulatory
mutants
marcescens. Appl. Environ. Komatsubara,
S., Murata,
Threonine
Microbial.
Chibata,
35 (1978a)
K., Kisumi,
I.:
of Serruriu
M. and
834-840.
Chibata,
M. and Chibata,
I.: Transductional
of a threonine-producing
murcescens. Appl. Environ. Komatsubara,
S., Kisumi,
construction
Microbial.
38 (1979) 1045-1051.
M. and Chibata,
murcescens: lack of feedback
controls
dehydrogenases.
U.K.:
assembly
Cleavage
of three aspartokinases
of the head of bacteriophage
proteins
Micro-
during
T4. Nature
Laszlo, N.C. and Alvin, J.C.: Construction recA
J. Bacterial.
Linder, P., Churchward, cation mutants
the
227 (1970)
mutations
ofan Hfr strain useful Escherichiu coli
between
G. and Caro, L.: Plasmid
generated
by insertion
T., Fritsch,
A Laboratory Spring Harbor, Mark,
SC.:
E.F. and Sambrook,
Manual.
pSClO1 repli-
of transposon
TnZOOO.
J.: Molecular
Cloning.
Laboratory,
Cold
The y 6 sequence
A., Hack,
of F is an insertion
sequence.
termination
R.P.: Determination
by fluorescence
A.M. and Rupp, of plasmid-coded
densitometry.
of
Plasmid
W.D.:
Simple method
for
proteins.
J. Bacterial.
137
(1979) 692-693. N.G.,
Fairweather,
low-copy-number coli. Gene
murcescens mutant
K-12:
Mapping
M.: Isolation
structure
B.C.:
Versatile
of a versatile cloning
Serrutiu of the
161 (1985) l-6.
I.: Threonine and
locus ofEscherichiu coli
evidence
for an operon.
J.
118 (1974) 990-998. D., Cohen, G.N., Borne, F. and Patte, J.C.:
of the structural
and of two homoserine
genes of the three aspartokinases dehydrogenases
117 (1974) 133-143.
J. Communicated
Spratt,
for cloning in Escherichiu
as a host and molecular
gene. J. Bacterial.
genetic
Bacterial.
and
vectors
18 (1982) 335-341.
T. and Kisumi,
aspartase
N.F.
plasmid
K-12. J. Bacterial.
NY, 1982.
Mol. Biol. 126 (1978) 347-365.
T.:
operon in Escherichiu coli K-12. Nucl.
S. and Novick,
copy number
Theze, J., Margarita,
Cold Spring Harbor
Tazaki,
I. and Cohen, G.N.: Nucle-
of thrC and of the transcription
Theze, J. and Saint-Girons,
143 (1980) 529-530.
J. Mol. Biol. 170 (1983) 287-303. Maniatis,
Sancar,
Takagi,
for transferring
P., Saint-Girons,
S.J., Carleton,
identification
680-685.
strains.
Projan,
Stoker, of structural
K. and
9 (1983) 182-190.
strain of Serrutiu
biol. 45 (1983) 1445-1452. Laemmli,
C., Cossart,
plasmid
I.: Transductional
Appl. Environ.
Suzuki,
Acids Res. 11 (1983) 7331-7345.
of Serrutiu
strain
of a threonine-hyperproducing
and two homoserine
Parsot,
region of the threonine
S., Kisumi,
construction
H.,
cluster ofSerruriu murcescens. Jpn. J. Microbial.
otide sequences
135 (1978b) 318-323. Komatsubara,
H., Hosogaya,
Argininegene
19 (1975) 35-44. I.:
by Serruriu murcescens. J. Bacterial.
degradation
Matsumoto,
by H. Yoshikawa
of Escherichiu coli