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 F o F 1 -ATPase. Such current was inhibited by inhibitors of the respiratory chain or F o F 1 -ATPase. This method is applicable for analyses of ion channels, ion pumps, or ion transporters in E. coli or other microorganisms.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 m 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, F o F 1 -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 m (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....
Complete inhibition at higher concentrations indicated that any other ATP-driven transport systems were not expressed under the present incubation conditions. This current was not observed in the vacuoles prepared from a mutant that disrupted a catalytic subunit of the V-type ATPase (RH105(⌬vma1::TRP)). The K m value for the ATP dose response of the current was 159 M and the H ؉ /ATP ratio estimated from the reversible potential of the V-I curve was 3.5 ؎ 0.3. These values agreed well with those previously estimated by measuring the V-type ATPase activity biochemically. This method can potentially be applied to any type of ion channel, ion pump, and ion transporter in S. cerevisiae, and can also be used to investigate gene functions in various organisms by using yeast cells as hosts for homologous and heterogeneous expression systems.
Bacillus subtilis is a representative Gram-positive bacterium. In aerobic conditions, this bacterium can generate an electrochemical potential across the membrane with aerobic respiration. Here, we developed the patch clamp method to analyze the respiratory chain in B. subtilis. First, we prepared giant protoplasts (GPs) from B. subtilis cells. Electron micrographs and fluorescent micrographs revealed that GPs of B. subtilis had a vacuole-like structure and that the intravacuolar area was completely separated from the cytoplasmic area. Acidification of the interior of the isolated and purified vacuole-like structure, due to H(+) translocation after the addition of NADH, revealed that they consisted of everted cytoplasmic membranes. We called these giant provacuoles (GVs) and again applied the patch clamp technique. When NADH was added as an electron donor for the respiratory system, a significant NADH-induced current was observed. Inhibition of KCN and 2-heptyl-4-hydroxyquinoline-N-oxide (HQNO) demonstrated that this current is certainly due to aerobic respiration in B. subtilis. This is the first step for more detailed analyses of respiratory chain in B. subtilis, especially H(+) translocation mechanism.
Protoplasts of Bacillus megaterium grew well and divided in nutrient broth containing 0.5 M NaCl as the stabilizer. Protoplasts also grew when sucrose or succinate was used instead of NaCl; however, no division phenomena were observed. The sequence of growth and division was similar to the results obtained by McQuillen. Protoplasts enlarged from 1.8 to 3.5 ,u in diameter, and then a small protuberance formed in the enlarged cells. The nodules enlarged until eventually symmetrical dumbbell-shaped bodies were formed, which then separated into two daughter protoplasts having a diameter of about 2.5 ,. Deoxyribonucleic acid and ribonucleic acid were halved during division. Penicillin inhibited the division of protoplasts, though the growth was not influenced by the drug. Membrane-bound amino sugar content was considerably reduced when the cells were grown in the presence of penicillin. These results suggest that organized murein formed on the protoplasts membrane may play an important role in the septation process.
The events which occur in the early stages of the mating process of the yeast Rhodosporidium toruloides between strains M-919 (mating type A) and M-1057 (mating type a) were investigated. In preliminary experiments we determined the frequency of mating by two newly designed methods: the liquid culture method and the membrane-filter microculture method. The mating frequencies of strains M-919 and M-1057 were 89% in the liquid culture method and 62% in the membrane-filter microculture method. The early stages in the mating process included the following events: (i) M-919 cells produce constitutively the extracellular inducing substance (A factor), (ii) M-1057 cells receive A factor, and in response to it they form mating tubes and secrete another inducing substance (a factor), (iii) M-919 cells receive a factor, and in response to it they form mating tubes, (iv) mating tubes elongate to the cells or the tubes of mating partner, (v) tips of the growing tubes recognize the opposite mating type cells or their tubes, followed by cell-to-cell fusion.
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