(Received for publication, September 24, 1996, and in revised form, December 11, 1996)
From the Faculty of Pharmaceutical Sciences, Chiba University, 1-33 Yayoi-cho, Inage-ku, Chiba 263, Japan
The structure and function of the polyamine transport protein PotE was studied. Uptake of putrescine by PotE was dependent on the membrane potential. In contrast, the putrescine-ornithine antiporter activity of PotE studied with inside-out membrane vesicles was not dependent on the membrane potential (Kashiwagi, K., Miyamoto, S., Suzuki, F., Kobayashi, H., and Igarashi, K. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 4529-4533). The Km values for putrescine uptake and for putrescine-ornithine antiporter activity were 1.8 and 73 µM, respectively. Uptake of putrescine was inhibited by high concentrations of ornithine. This effect of ornithine appears to be due to putrescine-ornithine antiporter activity because it occurs only after accumulation of putrescine within cells and because ornithine causes excretion of putrescine. Thus, PotE can function not only as a putrescine-ornithine antiporter to excrete putrescine but also as a putrescine uptake protein.
Both the NH2 and COOH termini of PotE were located in the
cytoplasm, as determined by the activation of alkaline phosphatase and
-galactosidase by various PotE-fusion proteins. The activities of
putrescine uptake and excretion were studied using mutated PotE
proteins. It was found that glutamic acid 207 was essential for both
the uptake and excretion of putrescine by the PotE protein and that
glutamic acids 77 and 433 were also involved in both activities. These
three glutamic acids are located on the cytoplasmic side of PotE, and
the function of these three residues could not be replaced by other
amino acids. Putrescine transport activities did not change
significantly with mutations at the other 13 glutamic acid or aspartic
acid residues in PotE.
Polyamines, aliphatic cations present in all living organisms, are known to be necessary for normal cell growth (1, 2). However, accumulation of excess polyamines causes inhibition of cell growth or a decrease in cell viability through inhibition of macromolecules, especially through inhibition of protein synthesis (3, 4). Furthermore, it has been reported that bis(ethyl)polyamine analogues cause inhibition of cell growth (5-8). The analogues could substitute for the functions of polyamines in various aspects, including the stimulation of protein synthesis at low concentrations and the inhibition of protein synthesis at high concentrations of analogues (9). These analogues accumulate in cells because they cannot be metabolized by spermidine/spermine N1-acetyltransferase and polyamine oxidase. Thus, metabolism and excretion of excess polyamines is necessary for cell growth. Indeed, excess polyamines induce spermidine/spermine N1-acetyltransferase (3, 10), and cells excrete any excess amount of polyamines (11, 12).
We obtained and characterized three clones of polyamine transport genes (pPT104, pPT79, and pPT71) in Escherichia coli (13). The putrescine transport system encoded by pPT71 consists of one membrane protein (PotE) with 12 putative transmembrane segments (14) and is active in the excretion of putrescine through putrescine-ornithine antiporter activity (15). Because the PotE protein was first identified as the putrescine uptake protein (13), we studied the detailed mechanism of putrescine uptake and excretion by the PotE protein. We have also carried out site-directed mutagenesis studies to identify amino acid residues that contribute to the transport functions of the PotE protein. The results show that glutamic acids 207, 77, and 433, which are located at the cytoplasmic side of PotE, are involved in both the uptake and excretion of putrescine.
A
polyamine-requiring mutant, E. coli MA261 (16), provided by
Dr. W. K. Maas, New York University School of Medicine, and its
polyamine uptake-deficient mutant KK313 potF::Km
(17) were grown in medium A in the absence of polyamines as described
previously (18). A proton-translocating ATPase mutant, KK313
potF::Km atp, was derived
from E. coli KK313 potF::Km
by transduction of a P1 phage-infected lysate of E. coli DK8
(
(atpB-atpC) ilv::Tn10, Ref. 19) and
was grown in N
C
medium (20) to deplete ATP.
E. coli JM105 (21), TG1 (21), DH5
(21), and CC118 (22)
were cultured in a 19-amino acid supplemented medium (11) containing
1% glycerol, 2YT, LB, and LB medium (21), respectively. Plasmids pPT71
containing speF and potE genes and pPT71.3
containing potE gene were prepared as described previously
(14). pUCpotE was prepared by inserting the
1.6-kb1 PstI-BamHI
fragment of pPT71 into the same restriction site of pUC119 (TaKaRa
Biomedicals, Japan). Then, pMWpotE was prepared by inserting
the 1.6-kb SphI-BamHI fragment of
pUCpotE into the same restriction site of pMW119 (Nippon
Gene, Japan). The strains and plasmids used are listed in
Table I.
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To prepare potE mutants, the 1.6-kb PstI-BamHI fragment of pPT71 was inserted into the same site of M13mp19 (23). Site-directed mutagenesis was carried out by the method of Sayers et al. (24) with a SculptorTM in vitro mutagenesis system (Amersham Corp.), using the oligonucleotides shown in Table II. The mutated 1.6-kb SphI-BamHI fragments were isolated from the replicative form of M13 and religated into the same site of pMW119. Mutations were confirmed by DNA sequencing (25) using the M13 phage system (23) with synthesized primers.
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Plasmid pAP2022 carrying phoA with
a single amino acid substitution at the cleavage site of the signal
sequence (arginine (CGG) at +1 to glycine (GGC)) was supplied by Dr. H. Tokuda, University of Tokyo. Replacement of Arg-1 by Gly-1 of PhoA
protein did not change the activity (26). The phoA gene was
amplified from pAP2022 by PCR (polymerase chain reaction) using the
following primers: (a) potE252-phoA,
5-TGGCGCTAGCCGGCACACCAGAA-3
and 3
-TTGGTCTGAATTACCGCCTAGGGCC-5
(PC1), (b) potE259-phoA,
5
-TCAACGGCCGCCGGCACACCAGAAAT-3
and PC1, and (c)
potE304-phoA, 5
-CTTCTTCGAACGGCACACCAGAAATG-3
and PC1.
These three products (a, b, and c) were digested
with NheI and BamHI, EagI and
BamHI, and Csp45I and BamHI,
respectively. Then, the potE-phoA fusion plasmids that
encode the fusion proteins differing in the number of amino acids in
PotE protein (PotE252-PhoA, PotE259-PhoA, and PotE304-PhoA) were
prepared by inserting the above fragments into the same restriction
sites of pMWpotE E253A, pMWpotE P260A, and
pMWpotE D305N (Table II). Other potE-phoA fusion plasmids (pMWpotE9-phoA, pMWpotE34-phoA,
pMWpotE77-phoA, pMWpotE115-phoA, pMWpotE147-phoA, pMWpotE181-phoA,
pMWpotE216-phoA, pMWpotE348-phoA, pMWpotE380-phoA, pMWpotE410-phoA, and
pMWpotE434-phoA) were made by the following methods. The
truncated potE genes in the different size with
NheI cutting site in the 3
-end were prepared by PCR, using
pMWpotE as template, and PstI-NheI
fragments were isolated. Then the fragment was ligated together with
the 3.1- and 1.1-kb fragments obtained by
PstI-NheI digestion of
pMWpotE252-phoA.
Assay for PhoA activity of E. coli CC118 carrying the fusion
plasmids was performed using 0.1 ml of cell suspension and 0.04% p-nitrophenyl phosphate by the method of Michaelis et
al. (27). The PhoA activities were calculated as follows: unit
activity = 1000 × (A420 1.75 × A550)/(time (min) × A600 × cell suspension volume (ml)).
Plasmid pMC1871 carrying lacZ gene
was obtained from Pharmacia Biotech Inc. The lacZ gene was
amplified from pMC1871 by PCR using the following primers:
(a) potE252-lacZ,
5-TGGCGCTAGCAGATCCCGTCGTTTTACAA-3
and
3
-ATTATTGGCCCGTCCCCCCTAGGCATC-5
(GC1), (b)
potE259-lacZ, 5
-TCAACGGCCGCAGATCCCGTCGTTTTACAA-3
and
GC1, and (c) potE304-lacZ, 5
-CTTCTTCGAACGATCCCGTCGTTTTACAA-3
and GC1. These three products (a, b, and c) were digested with
NheI and BamHI, EagI and
BamHI, and Csp45I and BamHI,
respectively. Then the potE-lacZ fusion plasmids that encode
the fusion protein differing in the number of amino acids in PotE
protein (PotE252-
-GAL, PotE259-
-GAL, and PotE304-
-GAL) were
prepared by inserting the above fragments into the same restriction
sites of pMWpotE E253A, pMWpotE P260A, and
pMWpotE D305N (Table II). Other potE-phoA fusion
plasmids (pMWpotE8-lacZ, pMWpotE78-lacZ,
pMWpotE147-lacZ, pMWpotE182-lacZ, and
pMWpotE216-lacZ) were made by the following methods. The
truncated potE genes in the different sizes with
Csp45I cutting site in the 3
-end were prepared by PCR,
using pMWpotE as template, and SphI-Csp45I fragments were isolated. Then the
fragment was ligated with the 7.4-kb fragment obtained by
SphI-Csp45I digestion of pMWpotE304-lacZ. Assay of
-galactosidase of E. coli DH5
carrying the fusion plasmids was performed by the
method of Miller (28).
E. coli KK313 potF::Km/ pMWpotE cells grown in medium A were suspended in buffer 1 containing 0.4% glucose, 62 mM potassium phosphate, pH 7.0, 1.7 mM sodium citrate, 7.6 mM (NH4)2SO4, and 0.41 mM MgSO4 to yield a protein concentration of 0.1 mg/ml. The cell suspension (0.48 ml) was preincubated at 30 °C for 5 min, and the reaction was started with the addition of 20 µl of 0.25 mM [14C]putrescine (370 MBq/mmol). After incubation at 30 °C for 30 s to 6 min, the cells were collected on membrane filters (cellulose acetate, 0.45 µm; Advantec Toyo), and the filters were washed three times with a total of 12 ml of buffer 1. The radioactivity on the filters was assayed with a liquid scintillation spectrometer.
Putrescine Uptake by Inside-out Membrane VesiclesE.
coli JM105/pMWpotE cells were cultured in the presence
of 0.5 mM
isopropyl--D-thiogalactopyranoside. Inside-out membrane vesicles were prepared by French press treatment of the cells suspended
in 100 mM potassium phosphate buffer, pH 6.6, 10 mM EDTA containing 2.5 mM ornithine (15). The
reaction mixture (0.1 ml) for the uptake by inside-out membrane
vesicles contained 10 mM Tris-HCl, pH 8.0, 10 mM potassium phosphate buffer, pH 8.0, 0.14 M
KCl, 50 µM [14C]putrescine (1.48 GBq/mmol),
and 100 µg of inside-out membrane vesicle protein. The reaction
mixture was incubated at 22 °C for 5 min without the substrate, and
the reaction was started by the addition of the substrate. After
incubation at 22 °C for 20 s to 1 min, membrane vesicles were
collected on membrane filters (cellulose nitrate, 0.45 µm; Advantec
Toyo) and washed, and their radioactivities were measured with a liquid
scintillation spectrometer (15).
The polyamine content in E. coli was determined by high performance liquid chromatography as described previously (29). Protein content was determined by the method of Lowry et al. (30).
Western Blot Analysis of PotE ProteinRabbit antibody for the PotE protein was prepared according to the method of Posnett et al. (31) using the multiple antigenic peptide, SDEGYFPKIFSRVTK, which corresponds to amino acids 304-318 of the PotE protein (14). For Western blot analysis of PotE, inside-out membrane vesicles (20 µg protein) were separated by SDS-polyacrylamide gel electrophoresis on a 12% acrylamide gel and transferred to Immobilon transfer membranes (Millipore). The PotE protein was detected with ProtoBlot Western blot AP System (Promega), except that 0.2% Triton X-100 was used instead of 0.05% Tween 20 (32).
Measurement of ATP Content,Assay of ATP
was performed by the luciferase enzyme system (33). ATP was extracted
with 0.2 M HClO4 and measured after
neutralization with 1 M KOH containing 50 mM
K2HPO4. and
pH were measured in
parallel experiments by determining the relative distribution of
[3H]tetraphenylphosphonium bromide and
[7-14C]benzoic acid, respectively, across the membrane
according to the method of Joshi et al. (34). Correction for
the nonspecific binding of tetraphenylphosphonium bromide or benzoic
acid was made by treating a sample with 10 µM carbonyl
cyanide m-chlorophenylhydrazone and subtracting this
value from that of the experimental samples. The Nernst equation and
the HendersonHasselbalch equations were used to calculate
(mV, negative inside) and
pH (mV, alkaline inside) (35).
The properties of
putrescine uptake by the PotE protein were compared with those of
putrescine excretion by the putrescine-ornithine antiporter activity of
the PotE protein. We previously reported that energy is not required
for the excretion of putrescine (15). The energy requirement of
putrescine uptake by the PotE protein was examined using the mutant
E. coli KK313 potF::Km
atp, transformed with pMWpotE. In
this mutant, the proton-translocating ATPase (19) and spermidine and
putrescine uptake systems encoded by potABCD genes (36) and
by potFGHI genes (17) are lacking. Thus, putrescine uptake
of the cells was catalyzed by the PotE protein, and the cells were
energized by the addition of glucose or succinate. As shown in Fig.
1, putrescine uptake was dependent on the membrane
potential, because the uptake activity and the membrane potential were
similarly affected by the addition of glucose and succinate. This
contrasts with the effect of glucose and succinate on the ATP content
of cells because glucose increases ATP levels by 10-fold, whereas
succinate slightly increases ATP content (37). The membrane potential
dependence was also confirmed by the inhibition of putrescine uptake by
carbonyl cyanide m-chlorophenylhydrazone, an inhibitor of
proton circulation (Fig. 1).
Ornithine uptake by PotE protein was not observed when a low concentration of ornithine (10 µM) was used as substrate (data not shown). However, uptake of putrescine was inhibited by high concentrations of ornithine (100-250 µM) after accumulation of putrescine within cells. The Km value for the putrescine uptake was 1.8 µM, whereas the Km values for antiporter activities of putrescine and ornithine were 73 and 108 µM, respectively, when measured in inside-out membrane vesicles that contained 2.5 mM ornithine or putrescine. Thus, inhibition by ornithine was probably based on the putrescine-ornithine antiporter activity.
Although the uptake of putrescine was inhibited by NEM (N-ethylmaleimide) (Fig. 1), the putrescine-ornithine antiporter activity was not inhibited by NEM.2 The results suggest that NEM affects the membrane potential but does not directly alter the function of the PotE protein. The optimal pH of putrescine uptake by intact cells was 6.5 and that of the antiporter activity by inside-out membrane vesicles was 9.2. The results suggest that the excretion of putrescine is not so effective when the difference between intracellular and extracellular pH is small. It may be that protons enter the cell together with ornithine when the PotE protein functions as an antiporter.
Next, we examined whether putrescine uptake by the PotE protein can stimulate cell growth of the polyamine-requiring mutant KK313 potF::Km by culturing the mutant, and the mutant expressing PotE after transformation with pPT71.3, in the absence and presence of 5 µM putrescine. As shown in Table III, the PotE protein caused the accumulation of polyamines (putrescine and spermidine) in cells and the stimulation of cell growth (1.94-fold), determined from the decrease in the generation time.
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It has been reported that fusions of
the secreted protein alkaline phosphatase (PhoA) to an integral
cytoplasmic membrane protein of E. coli show different
activities depending on where the PhoA was fused to the membrane
protein. Fusions to positions in or near the periplasmic domain led to
high PhoA activity, whereas those to positions in the cytoplasmic
domain gave low activity (22). As shown in Table IV,
PotE34-, PotE115-, PotE181-, PotE252-, PotE259-, PotE348-, and
PotE410-PhoA fusion proteins showed high PhoA activity, whereas PotE9-,
PotE77-, PotE147-, PotE216-, PotE304-, PotE380-, and PotE434-PhoA
proteins gave low activity. In contrast, -galactosidase fusion
proteins lose activity if the cells attempt to export them (38).
Although PotE8-, PotE78-, PotE147-, PotE216-, and PotE304-
-GAL
fusion proteins showed high activity, PotE182-, PotE252-, and
PotE259-
-GAL proteins gave low activity. The results indicate that
both the NH2 and COOH termini are located in the cytoplasm
(see Fig. 5) and that PotE has the same topology as other membrane
proteins having 12 transmembrane segments such as lactose permease
(39), melibiose permease (40), and the metal-tetracycline/H+ antiporter (41).
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Identification of Amino Acids Involved in the Transport Activity
There are 12 glutamic acids and 4 aspartic acids in the
PotE protein. In the PotD protein, which is a substrate binding protein of the spermidine-preferential uptake system encoded by the
potABCD operon, four acidic amino acids are involved in
binding of spermidine (42, 43). To identify the amino acids involved in
the transport activity of PotE, we prepared mutated PotE proteins in
which acidic amino acids were replaced by neutral amino acids using
site-directed mutagenesis. Putrescine uptake activity was measured with
E. coli KK313
potF::Km/pMWpotE or pMW mutated
potE, and putrescine excretion activity
(putrescine-ornithine antiporter activity) was measured with inside-out
membrane vesicles prepared from E. coli
JM105/pMWpotE or pMW mutated potE. As shown in
Fig. 2, putrescine uptake activity decreased greatly
with mutated PotE proteins E207Q3 and
E207A. Residue Glu-207 is located in the hydrophilic region between
transmembrane segments VI and VII. The uptake activity also decreased
significantly with mutated PotE proteins E77Q, E77A, E433Q, and E433A.
Residues Glu-77 and Glu-433 are located in the hydrophilic region
between transmembrane segments II and III and in the COOH-terminal,
respectively (see Fig. 5). We constructed a double mutated PotE protein
(E77Q and E433Q) and examined its putrescine uptake activity. The
decreased activity was additive in the double mutant (data not shown).
Putrescine uptake activity did not change significantly with other
mutated PotE proteins (Fig. 2). The amount of mutated PotE on membranes
measured by Western blot analysis was almost the same as that of normal
PotE protein (data not shown). Thus, mutations at Glu-77, Glu-207, and
Glu-433 affect the activity of PotE and not the expression of the
protein in membranes. The amount of PotE protein in E. coli
cells transformed with the vector pMW119 was negligible, suggesting
that the genomic speF-potE operon located at 16 min on
E. coli chromosome (14) is not expressed efficiently at
neutral extracellular pH.
Putrescine excretion (putrescine-ornithine antiporter activity) was
measured using inside-out membrane vesicles (Fig. 3). Excretion decreased greatly with mutated PotE E207Q, and significantly with mutated PotE E77Q and E433Q, similar to effects of these mutants
on putrescine uptake (Fig. 2). Excretion did not change significantly
with other mutated PotE proteins (Fig. 3).
To confirm the importance of glutamic acids Glu-207, Glu-77, and
Glu-433, each was replaced by several amino acids (A, D, N, and Q). As
shown in Fig. 4, even aspartic acid could not substitute for glutamic acid at these positions. A secondary structure model of
PotE protein is shown in Fig. 5. The three critical
glutamic acid residues on the PotE protein are located on the
cytoplasmic side.
It has been reported that there are three basic amino acid/decarboxylated derivative antiporters on prokaryotic membranes, they are the ornithine-putrescine (15), lysine-cadaverine (44), and histidine-histamine (45) antiporters. These proteins play important roles in the generation of a proton motive force (45), neutralization of low extracellular pH (44), and supply of carbon dioxide (46). In this study, we clarified that the ornithine-putrescine antiporter also functions as a putrescine uptake system that is dependent on the membrane potential.
It is of interest to know how the uptake and excretion of putrescine are regulated by the PotE protein. It is already known that there are two ATP-dependent putrescine uptake systems: the spermidine-preferential and putrescine-specific uptake systems (13, 17, 47). Furthermore, the expression of speF-potE operon is weak at neutral extracellular pH (Fig. 2 and Ref. 48). Thus, the contribution of the PotE protein to putrescine uptake is small under standard culture conditions. On the other hand, the PotE protein is the only protein known to be involved in the excretion of putrescine. The protein functions as an antiporter for ornithine (or lysine)-putrescine and putrescine-putrescine (15). Thus, PotE has broad substrate specificity from the outside. When putrescine had accumulated in cells, putrescine was actually excreted from the cells by the PotE protein to maintain the optimal amount of polyamines (15). It remains to be clarified, however, why the Km values for uptake of putrescine (1.8 µM) and excretion of putrescine (73 µM) are so different.
Our results clearly show that Glu-207, -77, and -433, which are located at the cytoplasmic side of PotE, are involved in both the uptake and excretion of putrescine. The functions of Glu-207, -77, and -433 in the PotE protein could not be replaced by any of four other amino acids, including aspartic acid. These residues may contribute directly to a binding site for putrescine and/or ornithine on PotE. Because the amino acid sequence of a putative PotE protein in Hemophilus influenzae has been reported recently (49), the sequence homology between the two PotE proteins was compared. As shown in Fig. 5, glutamic acids 207 and 77 and their surrounding amino acid sequences were conserved between two proteins (bold letters, Fig. 5). However, glutamic acid 433 was replaced by aspartic acid, and the surrounding amino acid sequence was different, in the PotE protein of H. influenzae (outline letters, Fig. 5). Thus, putrescine may recognize these acidic amino acids and their surrounding amino acids in each PotE protein. It has also been shown that main functional amino acids of the lactose/H+ symporter (50, 51) and metal tetracycline/H+ antiporter (52) are located on the cytoplasmic side of the proteins.
The amino acid sequence homology between the PotE protein from E. coli and that from H. influenzae (49) was 77%. The homology was more strongly observed in the NH2-terminal region (especially the hydrophilic regions) than in the COOH-terminal region (Fig. 5). As for the transmembrane segments, the segments I and VII were identical, and segments II, III, VIII, and XII were well conserved between E. coli and H. influenzae. According to the model of the lactose/H+ symporter (53), six transmembrane segments among the 12 segments may form the transport passage. If this is applicable to the PotE protein, segments I, II, III, VII, VIII, and XII may form the transport passage for putrescine and ornithine.
We thank Dr. K. Williams for his help in preparing the manuscript. Thanks are also due to Dr. H. Tokuda for providing E. coli CC118 and plasmid pAP2022.