From the ¶ Institute of Molecular and Cellular Biosciences,
The University of Tokyo, Yayoi, Bunkyo-ku, Tokyo, 113-0032, Japan, the
Department of Microbiology, Faculty of Pharmaceutical
Sciences, Okayama University, Tsushima, Okayama, 700, Japan, the
Department of Biochemistry, Saitama University, Urawa, Saitama,
38, Japan, the
Tokyo Research Laboratories,
Kyowa Hakko Kogyo Co. Ltd., Asahi-machi Machida-shi, Tokyo, 194, Japan,
and §§ the Department of Biological Sciences,
Graduate School of Science, The University of Tokyo, Hongo, Bunkyo-ku,
Tokyo, 113-0033, Japan
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ABSTRACT |
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Formation of giant protoplasts from normal Escherichia coli cells resulted in the formation of giant vacuole-type structures (which we designate as provacuoles) in the protoplasts. Electron microscopic observation revealed that these provacuoles were surrounded by a single membrane. We detected inner (cytoplasmic) membrane proteins in the provacuolar membrane but not outer membrane proteins. Biochemical analyses revealed that the provacuoles consist of everted cytoplasmic membranes. We applied the patch clamp method to the giant provacuoles. We have succeeded in measuring current that represents inward movement of H+ because of respiration and to ATP hydrolysis by the FoF1-ATPase. Such current was inhibited by inhibitors of the respiratory chain or FoF1-ATPase. This method is applicable for analyses of ion channels, ion pumps, or ion transporters in E. coli or other microorganisms.
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INTRODUCTION |
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The patch clamp technique is an excellent method to measure ion movement across cell membranes as current (1). An extremely small glass pipette (about 1 µm in diameter) is attached to the membranes, and activity of ion translocating proteins (ion channels, ion pumps, or ion transporters) is directly measured. So far, however, this important method has been mainly utilized for studies on animal or plant cells but scarcely for bacterial cells (2). Bacterial cells are usually too small to be measured by this method.
Escherichia coli, a Gram-negative bacterium, is the best characterized organism from both biochemical and genetical points of view. Ion pumps and ion transporters in E. coli are biochemically well characterized. Many mutant E. coli cells are available. Thus, genetical manipulations are very easy with this microorganism. Therefore, development of a patch clamp method applicable to E. coli membranes must be extremely valuable. Cells of E. coli are surrounded by an outer membrane and an inner membrane (cytoplasmic membrane) separated by a peptidoglycan layer and a periplasmic space. All of the major ion pumps and ion transporters such as the respiratory chain, FoF1-ATPase, various ion transporters, and ion-coupled solute transporters are located in the cytoplasmic membrane. To measure ion translocation via such ion pumps or transporters of the cytoplasmic membrane, we have to overcome the following three hurdles: 1) we have to prepare giant vesicles, the diameter of which must be at least 10 µm (this is important to get high success rate and accuracy of measurement), 2) the pipette must be directly accessible to the cytoplasmic membrane, and 3) the substrates or effectors of the ion pumps or transporters must be easily accessible to the active site of the proteins and easily removable from the system.
It would be essential to prepare giant protoplasts to overcome the first two hurdles. Many attempts have been made by many research groups to prepare giant bacterial cells or giant protoplasts. So far, however, no giant protoplasts surrounded by cytoplasmic membranes and suitable for patch clamp analysis have been prepared. Giant cells that were large enough for the patch clamp analysis have been prepared from cephalexin-induced filaments (3) or from an osmotic-sensitive mutant (4). However, such cells were not protoplasts surrounded only by the cytoplasmic membrane. Attempts have been made to prepare giant protoplasts from such giant cells (or spheroplasts) by osmotic shock or by treating them with lysozyme (5, 6). It is not clear whether the respiratory chain components and FoF1-ATPase (H+-translocating ATPase) are present in the membrane of such preparations, and therefore origin of the membrane is not clear. On the other hand, large protoplasts have been prepared from a penicillin-resistant mutant (7, 8). Those protoplasts were still too small to apply for the patch clamp method. Thus, these preparations were not suitable for the measurement of ion translocation via proteins of the cytoplasmic membrane by the patch clamp method. Recently we have succeeded in developing a unique method, named the spheroplast incubation method, for the preparation of extremely large giant protoplasts (10-30 µm in diameter). This method was derived from an early observation by Kusaka (9) that large protoplasts are formed after prolonged incubation of spheroplasts formed by treating cells of Bacillus megaterium with lysozyme in the presence of both penicillin G, an inhibitor of peptidoglycan synthesis, and an osmo-protectant. We have applied this method to many Gram-negative and -positive bacteria and succeeded in the formation of giant protoplasts from these types of cells. It is very difficult to overcome the third hurdle. The principal ion pumps in E. coli cells are the respiratory chain and the FoF1-ATPase. Ion movement through these ion pumps can be measured only with the whole cell recording mode of the patch clamp method because of their lower efficiency of ion transport compared with ion channels. Moreover, for the whole cell recording mode, it is not easy to perfuse a buffer inside a cell through a microelectrode pipette (10). A substrate of the respiratory chain, NADH, and a substrate of the FoF1-ATPase, ATP, are accessible only from the cytoplasmic side of the membrane. Thus, giant protoplasts with a right-side-out orientation are not suitable for measurement of H+ translocation because of the respiratory chain or the FoF1-ATPase. If we can prepare everted giant membrane vesicles, this hurdle will be overcome. Although several methods for the preparation of everted membrane vesicles from E. coli cells are available, the size of the vesicles is much smaller than the original cells (11, 12).
Formation of vacuole-like structures in E. coli cells has been reported from two groups. Lederberg and Clair reported that vacuole-like structures appeared in cells after incubation in the presence of penicillin G, which resulted in cell lysis (13). Buechner et al. observed vacuole-like structures in osmotic-sensitive mutant cells by ultra thin section electron microscopy (4). No ribosomes were observed in the vacuole-like structures. Both types of vacuole-like structures were about 3 µm. Unfortunately, further analysis of these vacuole-like structures has not been done. During the course of our studies on the giant protoplasts, we found that extremely large vacuole-type structures (10-20 µm in diameter) were formed in the giant protoplasts.
Here we report the preparation of the giant protoplasts and the giant vacuole-like structures (provacuoles) from E. coli cells. We investigated the properties of the giant provacuoles and measured H+ translocation via the respiratory chain (or by the FoF1-ATPase) using the patch clamp method by applying the whole cell recording mode. These methods could be applied for the direct measurement of ion translocation across the cytoplasmic membrane of E. coli and other bacteria.
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EXPERIMENTAL PROCEDURES |
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Preparation of Giant Protoplasts from E. coli Cells--
Cells
of E. coli K002
(Lpp)1 or K003
(Lpp
,
uncB-C::Tn10) (14) were
grown in a rich medium, beef heart infusion broth (Difco Co.) or LB
broth, containing suitable antibiotics under aerobic conditions. The
cells were harvested in the late exponential phase of growth and
suspended in the same volume of SP buffer (25 mM Tris-HCl,
pH 7.4, and 400 mM sucrose). Lysozyme (200 µg/ml) was added to the cell suspension, and the suspension was shaken at 30 °C
for 10 min at 45 rpm. After this treatment, the cells were harvested
and resuspended in the same volume of the GP medium consisting of
2.75% trypticase soy broth (without dextrose) (BBL Co.), 10 mM MgSO4, and 200 mM sucrose. A
volume of this suspension was diluted into the GP medium
containing 0.7 units/ml of DNase I (TaKaRa Co.) and 800 µg/ml of
penicillin G (potassium salt) (Banyu Pharmaceutical Co.) and shaken at
30 °C for 24 h at 30 rpm. Cells of strain K002 or K003 were
made gigantic in this medium. However, for the preparation of the giant
protoplasts from strain C600, the modified GP medium (50 mM
KCl was added, and the sucrose concentration was 300 mM)
was used. The C600 cells were shaken for 12 h (instead of 24 h) in the medium.
Construction of Plasmids--
Plasmids pMAL-pCm and pMAL-cCm
were constructed by inserting the BsaAI fragment, which
carried the chloramphenicol resistance gene into the unique
ScaI site of pMAL-p2 and pMAL-c2 (New England Biolabs. Co.),
respectively. pMAL-c2 is identical to pMAL-p2 (possessing malE-lacZ fused gene) except for deletion of
the region for MalE (the structural gene for the maltose binding
protein (MBP)) signal peptide. A plasmid pGFP
(CLONTECH Co.) was doubly digested with EcoRI and HindIII, and the resulting fragment
containing the gene for green fluorescence protein (GFP) was blunted
and ligated to the XmnI site of the pMAL-pCm or the
pMAL-cCm. The plasmids constructed were designated as pMAL-pCm-GFP and
pMAL-cCm-GFP. Expression of malE gene carried on the
plasmids is under the control of tac promoter, so that the
protein was induced with IPTG.
Preparation of Provacuoles from Giant Protoplasts-- Giant protoplasts (induced with IPTG when necessary) were harvested by centrifugation at 1,600 × g. The pellet was suspended with Burst buffer consisting of 10 mM Tris HCl, pH 7.4, 10 mM MgCl2, 50 mM sucrose, 0.5 mM phenylmethylsulfonyl fluoride (PMSF), and 17.5 units/ml of DNase I. The suspension was shaken at 30 °C for 20-30 min (45 rpm). After centrifugation at 1,600 × g, the pellet was resuspended in a small volume of Burst buffer containing 20% Percoll (Amersham Pharmacia Biotech). The suspension was placed in a centrifuge tube onto which an equal volume of Burst buffer was overlaid. Percoll density gradient centrifugation was carried out at 400 × g for 30 min. Provacuoles were found in the interfacial layer. The giant provacuoles were washed twice with the Burst buffer and used for further analyses. Membranes of the provacuoles and intraprovacuolar materials were separated as follows. The giant provacuoles were frozen rapidly in liquid N2 and thawed on ice. The provacuoles were completely disrupted by this procedure. After ultracentrifugation at 130,000 × g for 1 h, the pellet (membrane fraction) and the supernatant (intraprovacuolar materials) were recovered. The membrane fraction was washed with Burst buffer and resuspended in the same buffer. All centrifugations were carried out at 4 °C. The fractions (membranes and intravacuolar materials) were used for detection of MBP.
Microscopy and Electronmicroscopy-- For DAPI staining, the giant protoplasts were prepared from cells of E. coli K002. DAPI (final concentration, 1 µM) was added to the suspension of giant protoplasts and incubated at 30 °C for 2-3 h. When necessary, the giant provacuoles were isolated from the protoplasts. Fluorescent micrographs of the protoplasts and the provacuoles were taken with excitation at 350 nm and emission at 430-450 nm. For detection of GFP, the giant protoplasts were prepared from cells of E. coli C600/pMAL-pCm-GFP or C600/pMAL cCm-GFP. IPTG was added to the medium at 0.1 mM and incubated for 2-3 h. The fluorescent micrographs were taken by confocal laser scanning microscopy (TCS4D, Leica Co.) with excitation at 488 nm and emission at 530 nm. Electron micrographs were taken as described previously (15).
Preparation of Membrane Fractions-- Intact cells of E. coli K002 were harvested and suspended in a buffer consisting of 50 mM Tris-HCl, pH 7.4, 5 mM MgCl2, and 1 mM PMSF. The cells were disrupted by sonication. After removal of unbroken cells by low speed centrifugation, the supernatants were centrifuged at 100,000 × g for 1 h at 4 °C. Membrane fractions were recovered in the pellet. The membrane fraction was washed with a buffer consisting of 10 mM Tris-HCl, pH 7.4, and 2 mM EDTA. Membrane fraction from the giant protoplasts was prepared as follows. The giant protoplasts were collected by centrifugation and suspended in a buffer consisting of 50 mM Tris-HCl, pH 7.4, 5 mM MgCl2, 1 mM PMSF, and 280 units/ml of DNase I. The giant protoplasts were completely disrupted by sonication. Unbroken protoplasts were removed by low speed centrifugation. The supernatant was centrifuged at 100,000 × g for 1 h at 4 °C. The pellet was washed as described above. The membrane fractions were resuspended in a buffer consisting of 25 mM Tris-HCl, pH 7.4, and 0.25% Sarcosyl and incubated at 20 °C for 20 min. Outer membrane proteins were not solubilized and could be obtained as pellets after centrifugation. The pellets were washed with a buffer consisting of 10 mM Tris-HCl, pH 7.4, and 5 mM MgCl2 and resuspended in the same buffer.
Detection of MBP by Western Blotting-- The giant protoplasts were washed twice with a stabilizing buffer consisting of 10 mM Tris-HCl, pH 7.4, 10 mM MgCl2, 300 mM sucrose, 50 mM KCl, 0.5 mM PMSF, and 17.5 units/ml DNase I and resuspended in the same buffer. Giant provacuoles, the provacuolar membranes, and intraprovacuolar materials were prepared as described above. One-fourth volume of 50% tetrachloroacetic acid was added to the samples and mixed vigorously. After centrifugation at 8,500 × g, the pellets were washed first with acetone and thereafter with diethylether and suspended in a certain volume of the Burst buffer. These fractions were separated electrophoretically in a 12.5% polyacrylamide gel and transferred to a polyvinylidene fluoride membrane. Anti-MBP antiserum and purified MBP were purchased from NEB Co. For detection of the antigen-antibody complex, the ECL system (Amersham Pharmacia Biotech) was used.
Other Western Blot Analyses-- For detection of SecY, proteins were transferred to a polyvinylidene fluoride membrane after polyacrylamide gel electrophoresis. Anti-SecY antiserum and the ECL system were used to detect the SecY. Anti-SecY antiserum and purified SecY protein were generous gifts from Dr. H. Tokuda (University of Tokyo). For detection of cytochrome bo, bd, and F1-ATPase, the proteins were transferred to nitrocellulose membrane. Anti-bd antiserum was a generous gift from Dr. H. Matsuzawa (University of Tokyo). Anti-F1-ATPase antiserum was a generous gift from Dr. M. Futai (Institute of Scientific Industrial Research, Osaka University).
H+ Pumping Activity in Provacuoles-- Measurement of H+ pumping activity was carried out by the quinacrine fluorescence quenching method (16). Provacuoles (20 µg of protein) were added to 2 ml of the assay buffer (10 mM Tris-HCl, pH 7.4, 2 mM MgCl2, 20 mM KCl, and 30 mM sucrose) containing 1 µM quinacrine hydrochloride. After preincubation for 5 min at 25 °C, NADH or ATP was added. After fluorescence quenching had occurred, KCN or DCCD was added as an inhibitor of the respiratory chain or FoF1-ATPase.
Electrical Recording in Provacuoles--
Giant protoplasts were
harvested by centrifugation at 740 × g and gently
suspended in a small volume of the same medium as that used for cell
growth. The giant protoplasts were put on a glass chamber and washed
with GPW buffer (10 mM Tris-HCl, pH 7.4, 10 mM
MgCl2, and 200 mM sucrose). The GPW buffer was
replaced with the Burst buffer containing 210 units/ml of DNase I. After a few minutes, the giant provacuoles were washed again with Burst buffer. The chamber was filled carefully with Burst buffer. The patch
pipettes (Drummond Scientific Co.) were pulled to a diameter with a
resistance of 12.5-25 M (when measured in Burst buffer) using a
puller machine (model PC 10, Narishige) and then heat-polished (model
MF-90, Narishige). The electrode was gently touched to a giant
provacuole with a mild suction (about 200 mmH2O), producing an instantaneous seal of about 10 G
. Thereafter the suction was stopped. A tiny hole was made in the membrane of the giant vacuole with
a ZAP pulse (duration time 3 ms, rising period 10 µs, amplitude 0.8 V). After that, the resistance was 0.5-1 G
. All substrates in the
assay buffer (10 mM Tris-HCl, pH 7.4, 2 mM
MgCl2, 20 mM KCl, and 30 mM
sucrose) were added through tandem six-way bulbs (GL
Sciences Inc.). The Patch amplifier used was CEZ-2400 (NIHON KOHDEN). A
positive current represents positive charges moving from exterior to
interior of the provacuole. All recordings were made using the standard
patch clamp technique at 23 °C (1).
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RESULTS |
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Vacuole-like Structures Surrounded by a Single Membrane-- An electron micrograph of a giant protoplast and a vacuole-like structure formed in the protoplast are shown in Fig. 1A. The diameter of the giant protoplast in the figure is about 13 µm and that of the vacuole-like structure is about 10 µm. The original E. coli cell (1 × 2 µm) is shown in Fig. 1B. The membranes of the giant protoplast (indicated by an arrowhead) and that of the giant vacuole-like structure (indicated by an arrow) are shown in Fig. 1C. Compared with membranes of the original cell shown in Fig. 1D, which consist of two membrane structures (two arrows indicating outer membrane and inner membrane, respectively), both of the membranes of the giant protoplast and the giant vacuole-like structure consist of single membrane (Fig. 1C). We took many electron micrographs of the giant protoplasts and the giant vacuole-like structures and obtained the same results. Thus, we conclude that both the giant protoplasts and the giant vacuole-like structures are surrounded by single membrane. It should be noted that most giant protoplasts contained several vacuole-like structures in one protoplast, as will be shown below. No ribosome-like structures are present inside the giant vacuole-like structures (Fig. 1, A and C). We stained the giant protoplasts and the giant vacuole-like structures with DAPI, which stacks between DNA double strands, and investigated whether DNA exists in the vacuole-like structures (Fig. 2). Our results clearly indicate that there is no detectable DNA in the vacuole-like structures (Fig. 2C). However, DNA is present in the cytoplasm of the giant cells (Fig. 2C). Because the vacuole-like structures do not contain ribosomes, DNA, and any other electron-dense materials, we henceforth refer to the vacuole-like structures as "provacuoles."
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Membranes of the Provacuoles-- The giant protoplasts were lysed by osmotic shock (lowering the osmolarity). The provacuoles were then separated by Percoll density gradient centrifugation. A differential interference contrast (DIC) micrograph of the isolated giant provacuoles is shown in Fig. 2B. Size of the giant provacuoles ranged from 2 to 15 µm. The provacuoles could not be stained with DAPI (Fig. 2D), indicating that DNA was not present in the provacuoles. In any case, we succeeded in isolating the provacuoles.
We analyzed membrane proteins of the provacuoles to determine whether the provacuole membrane is derived from the cytoplasmic membrane, the outer membrane, or both. As shown in Fig. 3, although major outer membrane proteins OmpC/F and OmpA were detected in the Sarcosyl-insoluble fraction of whole membranes of intact cells (Fig. 3, lane 3), they were not detected in the Sarcosyl-insoluble fraction of the whole provacuolar membranes (Fig. 3, lane 6). Almost all of the membrane proteins of the provacuoles were solubilized by Sarcosyl. Absolutely no protein band was detected in the Sarcosyl-insoluble fraction from the isolated provacuoles (data not shown). It has been reported that most cytoplasmic membrane proteins, but not outer membrane proteins, were solubilized by Sarcosyl (17). Thus, we believe that the membrane of the provacuoles was from cytoplasmic membrane. Some difference in the membrane protein patterns was observed between the cytoplasmic membrane of intact cells, giant protoplasts, and provacuoles. This suggests that membrane of the vacuoles is very similar but not completely identical with the cytoplasmic membrane.
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Orientation of the Provacuolar Membranes-- We tested the activity and direction of protein transport via the Sec system in the provacuolar membranes. MBP is a component of the maltose transport system and is located in the periplasmic space of intact E. coli cells. This protein is synthesized by ribosomes in the cytoplasm and excreted to the periplasm through the Sec secretion machinery. A signal peptide at the NH2 terminus of MBP is necessary for the secretion to occur. We constructed a plasmid encoding a fusion protein between MBP and GFP. The GFP portion was attached to the COOH terminus of the MBP. Thus, location of the fused MBP in the cells could easily be detected because of the green fluorescence emitted by GFP. We constructed two types of plasmids that should produce two types of fusion proteins, one possessing no signal peptide (pMAL-cCm-GFP) and the other possessing the signal peptide(pMAL-pCm-GFP). The fusion protein with no signal peptide was detected in the cytoplasm of the giant protoplasts (Fig. 5, A and C). MBP could not be excreted from the cytoplasm without the signal. When the signal peptide is present, the fused MBP was detected mainly inside the provacuoles of the giant protoplasts (Fig. 5, B and D). Faint fluorescent signals were detected in the cytoplasm. This means that the Sec system is functional in the membranes of the provacuoles and that the direction of the secretion (protein transport) is from cytoplasm to the interior of the provacuoles. This indicates that the provacuolar membranes have an everted orientation compared with the cytoplasmic membranes.
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Patch Clamp Measurement of Current Because of Respiratory Chain or FoF1-ATPase-- We were able to obtain giant provacuoles possessing activities of the respiratory chain and the FoF1-ATPase. Substrates for the respiratory chain, NADH, and for the FoF1-ATPase, ATP, are accessible to the enzymes responsible for the reactions from exterior of the provacuoles. Thus, it seemed possible to measure current because of H+ transport by the respiratory chain and FoF1-ATPase in the provacuoles by the whole cell recording mode of the patch clamp method. In fact, we detected an inward current larger than 10 pA when NADH (0.25 mM) was added to the assay mixture (Fig. 8A). This current disappeared after NADH was removed from the system. Also we detected a similar current when ATP (1 mM) was introduced; the current disappeared after ATP was removed (Fig. 8B). The ATP-induced current was sensitive to an FoF1-ATPase inhibitor DCCD (30 µM) (Fig. 8C). On the other hand, the NADH-induced current was not sensitive to DCCD (Fig. 8D) but was sensitive to KCN (10 mM) (Fig. 8E). Thus, we have succeeded in measuring current because of H+ transport via the respiratory chain or the FoF1-ATPase in isolated provacuoles of E. coli. These experiments were repeated several times, and very similar results were obtained.
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DISCUSSION |
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Two methods are available for direct measurement of current because of ion transport across membranes: the planar lipid bilayer method and the patch clamp method. The former measures current because of an ion-transporting protein in reconstituted lipid bilayers. Purified protein, partially purified protein, or membrane fragments could be used for this method. If purified protein is available, this method is very valuable for measurement of ion transport and characterization of the protein. Hirata et al. (21) and Muneyuki et al. (22) measured an ATP-induced current from FoF1 ATPase in reconstituted lipid bilayers, estimated the H+/ATP stoichiometry, and analyzed the basic process of the reaction. However, problems exist in this method with the efficiency of protein incorporation into lipid bilayers and with the orientation of the proteins. The patch clamp method, on the other hand, requires neither purified protein nor reconstitution. Only one cell or membrane vesicle that is large enough for microelectrode pipette is necessary. This method is especially powerful because the function of the target ion transporting system is measurable in native membranes. It is inherently difficult to analyze the function of multicomponent systems that cannot easily be purified as whole complexes, such as the respiratory chain, using the planar lipid bilayer method (23, 24). However, the patch clamp method could be applicable even for these complicated systems. Because so many bacterial mutants are available, the patch clamp method could be extremely useful for the analyses of ion transport systems of bacterial cells. The only problem with using bacteria for application of the patch clamp method is their small size. We have developed methods to prepare giant protoplasts that contain giant provacuoles from E. coli cells and to isolate the provacuoles from the protoplasts. The provacuoles proved to be very useful for patch clamp analysis. We have succeeded in measuring H+ transport via the respiratory chain and the FoF1-ATPase of E. coli as an electric current using the provacuoles.
It seems that this method is applicable to the analyses of many other ion transport systems of E. coli such as ion transporters or ion-coupled solute transporters and of other bacteria. Kusaka found that giant protoplasts appeared when spheroplasts of B. megaterium were incubated in the presence of an inhibitor of peptidoglycan synthesis and that contents of DNA and RNA in the protoplasts enormously increased (9). A similar phenomenon was observed with E. coli. DNA of control E. coli cells and of giant protoplasts was stained with DAPI. Intensity of the DAPI fluorescence in the giant protoplasts was similar to that in the control cells (data not shown), indicating that much more DNA is present in a giant protoplast compared with a control cell. Synthesis of most of the cellular constituents including DNA, RNA, membrane proteins, and membrane lipids (except cell wall components) is intact in the enlarged protoplasts. These results support the idea that the ceasing of peptidoglycan synthesis interferes with concomitant occurrence between DNA replication and cell division. It seemed likely that giant protoplasts from many bacteria could be formed by similar methods as described in this paper. In fact, we have prepared giant protoplasts and giant provacuoles from several other bacteria. Measurements of ion transport in such giant provacuoles from several bacterial sources are now in progress.
What is (are) the role(s) of the giant provacuoles? In giant cells or protoplasts, if additional membranes are not present, the cells or protoplasts will suffer from shortage of energy or materials produced by membranes, because the ratio of membrane to cell volume becomes very small. During enlargement of the protoplasts, additional membrane structures, provacuoles, were formed. The larger the protoplasts, the more numerous and the larger the provacuoles appeared. Membranes of the provacuoles showed the ability to transduce energy. Activity of H+ transport in the provacuoles was fairly high. The estimated turn over rate of H+ transport via the FoF1-ATPase in the provacuolar membranes was about 600/s, calculating from the current (0.1 pA/µm2) and the amount of enzyme (25). This value is comparable with that (480/s) of ATP hydrolysis by F1-ATPase (26). Based on the fact that an active respiratory chain and FoF1-ATPase exist in the provacuolar membrane, we believe that oxidative phosphorylation takes place in the provacuolar membranes. We observed an increase in the amount of cytochrome bo, which possesses vectorial H+ pump activity (27) in provacuoles from mutant K003 (FoF1-ATPase negative) compared with those from the wild type K002 (Fig. 4). It looks as if the absence of the FoF1-ATPase is compensated for by the increase in the cytochrome bo.
Because the provacuolar membranes have an everted orientation, the interior of the provacuoles corresponds to the periplasmic space of intact cells. There are many proteins in the periplasmic space including binding proteins for solute transport, endoproteases such as DegP (28) and Tsp (29) that hydrolyze proteins damaged by heat shock and so on, and exoprotease, which cleaves degraded peptides to amino acids (30). The amino acids thus produced will be transported to the cytoplasm. Our results suggest the presence of peptidase in the provacuoles (Fig. 6). Vacuoles of Saccharomyces cerevisiae are organelles that have the ability to degrade and recycle unnecessary macromolecular constituents (31, 32). For example, addition of glucose to a yeast culture growing on acetate as a carbon source results in rapid inactivation of gluconeogenic enzymes followed by proteolytic degradation of the inactivated enzymes. The degradation of fructose 1,6-bisphosphatase, a gluconeogenic enzyme, depends on PrA, which is an endoprotease found in vacuoles (33). It is known that vacuoles possess two endoproteases, PrA and PrB, and five exoproteases, ApY, ApI CpY, CpI, and DAPB-B (32).
The peptidoglycan layer and the outer membrane are present outside of the periplasm in cells. No such structure is present inside of the provacuolar membranes. It is not yet clear whether peptidoglycan is synthesized in the vacuoles in the presence of penicillin, which is necessary for the formation of the giant protoplasts under our conditions, or because of some other unknown reasons. Also it is not clear whether the membrane corresponding to the outer membrane is constructed in the provacuoles because of the absence of the peptidoglycan or for some other unknown reasons. The absence of both the peptidoglycan layer and the outer membrane-like membranes in the provacuoles makes the provacuoles an ideal source of cytoplasmic membranes with an everted orientation.
The provacuoles could be regarded as a reservoir for membrane constituents. Too many cellular constituents will be synthesized in the giant protoplasts. Perhaps the rate of membrane lipid synthesis and the rate of membrane protein synthesis are well balanced in the protoplasts. Unbalanced overproduction of membrane proteins would result in formation of inclusion bodies. It is likely that concomitant overproduction of both membrane lipids and membrane proteins results in the formation of intracellular membrane structures such as provacuoles.
The provacuoles may be a sort of super organelle that is formed under certain conditions unfavorable for cells. The fact that even prokaryotic cells have the potential ability to form vacuoles may provide a clue to the origin of vacuoles in eukaryotes such as S. cerevisiae (34, 35).
E. coli is the best characterized microorganism. Many ion
transport systems are known in E. coli. Extensive
biochemical and genetical analyses of such systems, including gene
cloning and sequencing have been done. However, electrophysiological
analysis has never been done with E. coli cells except for
the investigation on the mechanochemical channel by Kung and co-workers
(2). The methods described in this paper have opened a new field of electrophysiology in E. coli cells. Although we mainly used
an E. coli mutant K002 that lacks Lpp for the preparation of
giant protoplasts and vacuoles, C600 cells, a wild type strain with respect to the Lpp, were also successfully used as shown in this paper.
Removal of the outer membranes from the giant protoplasts was easier in
the Lpp mutant cells than in the wild type cells (36,
37).2 However, we confirmed
many times that even wild type E. coli cells including cells
of strain Q13 (38), the parent of K002 possessing normal Lpp, were also
suitable for the preparation of the giant protoplasts and the giant
provacuoles. This means that many E. coli mutants isolated
or constructed in the world could be used for the preparation of the
giant provacuoles and could be used for electrophysiological
studies.
It is possible to enlarge cells harboring plasmid carrying gene(s) of
interest and a gene for drug resistance (except the gene for
-lactamase) by our method. Transformant cells harboring a plasmid
sometime lose the plasmid during the growth. The gene product(s) of
interest is(are) not present in such cells. If the gene(s) of interest
is(are) on the plasmid, it is crucial for patch clamp analysis that
giant protoplast or giant provacuole attached to the microelectrode
pipette is derived from a cell carrying the plasmid. Addition of a
pertinent drug to the medium for giant protoplast preparation can solve
this problem.
Induction of gene expression is possible with the giant protoplasts as with the intact E. coli cells. It is often important to overproduce the ion transport protein of interest to measure currents using the patch clamp method, especially when the turnover number of ion transporter is not high enough. Induction of the gene as well as the use of high copy plasmid is valuable for overproduction of proteins. We detected fluorescence because of the MAL-GFP gene product 3-5 h after induction by IPTG with giant protoplasts of C600/pMAL-cCm-GFP. The gene for the fusion protein between MBP and GFP is located downstream from the tac promoter in this plasmid.
Thus, our methods for the preparation of giant protoplasts or giant provacuoles can be applied to wild type cells, mutant cell, and plasmid-harboring cells of E. coli. On the other hand, it is easy to construct a gene-disrupted mutant of E. coli. Many genes encoding ion transport proteins have been cloned and sequenced. It is easy to construct site-directed mutants in the genes. Wild type or mutant genes on plasmids can be easily introduced into the gene-disrupted cells. Thus, structure-function relationship could be investigated by the patch clamp method with the provacuoles derived from cells harboring mutant-type gene. These methods are also applicable to some, perhaps many, other bacteria.
Furthermore, it is possible to inject the giant protoplasts or giant provacuoles with effectors such as inhibitors, stimulators, modifiers, or even antibodies. We can observe their effects directly. Of course, we can inject plasmid DNA into the giant protoplasts. Thus, it is possible to use the giant protoplasts or giant provacuoles as biologically active test tubes or to use E. coli as a living test tube. Biochemically and genetically, E. coli is the best characterized organism. The DNA sequence of the whole genome of this organism has been determined. We believe that the development and establishment of the methods described in this paper are invaluable for studies on ion transport systems and ion channels in E. coli and other bacteria. New ion channels may be discovered in bacterial cells.
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ACKNOWLEDGEMENTS |
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We thank Drs. S. Makino, H. Matsuzawa, H. Tokuda, and K. Nishiyama of the University of Tokyo and Dr. M. Futai of Osaka University for purified proteins, antibodies, and helpful discussions. We also thank the late Dr. S. Mizushima and Dr. Y. Anraku of the University of Tokyo for stimulating discussions. We thank Dr. Manuel F. Varela of Eastern New Mexico University for critically reading the manuscript.
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FOOTNOTES |
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* This work was supported by grants from the Ministry of Education, Science, and Culture of Japan.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§ Research Fellow of the Japan Society for the Promotion of Science.
** Present address: Dept. Pharmacology., Faculty of Medicine, The University of Tokyo, Hongo, Bunkyo-ku, Tokyo, 113, Japan.
¶¶ To whom correspondence should be addressed. Tel.: 81-3-3812-2111 (Ext. 7860); Fax: 81-3-3812-0192; E-mail: yabe{at}bio.t.u-tokyo.ac.jp.
1
The abbreviation used are: Lpp,
lipoprotein; MBP, maltose-binding protein; GFP, green fluorescence
protein; IPTG, isopropyl--D-thiogalactopyranoside; PMSF,
phenylmethylsulfonyl fluoride; DAPI, 4'-6-diamidino-2-phenylindole dihydrochloride; DCCD, dicyclohexyl carobodiimide; DIC, differential interference contrast.
2 S. Mizushima, personal communication.
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REFERENCES |
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