Preparation and properties of active membrane systems from various species of bacteria

Two types of glucose effects on beta-galactosidase synthesis in a membrane fraction of Escherichia coli: correlation with repression observed in intact cells

A membrane fraction obtained from an osmotic lysate of Escherichia coli spheroplasts retains capability to synthesize beta-galactosidase. The system also retains cellular regulatory functions, one of which is known as catabolite repression. Two types of repression of beta-galactosidase synthesis were observed in this membrane system: one was caused by the addition of 2-deoxyglucose or glucose at a low concentration (3 times 10- minus 4 M), and the other was caused by glucose-6-phosphate or glucose at a high concentration (3 times 10- minus 2 M). In the presence of cyclic adenosine 3',5'-monophosphate (10 mM), repression caused by the former was completely reversed, whereas repression by the latter was only partially reversed. Conditions in intact cells causing transient and permanent repression were also investigated. Upon addition of 2-deoxyglucose or glucose at a low concentration to intact cells, only transient repression of beta-galactosidase synthesis was observed. Glucose at a high concentration caused both transient and subsequent permanent repression, and intensity of permanent repression depended upon glucose concentration, whereas duration and intensity of transient repression were independent of glucose concentration. Mutants deficient in phosphoenolpyruvate-phosphotransferase system (Hpr minus and enzyme I minus) showed transient repression but failed to show permanent repression. In mutants deficient in glucose catabolism beyond glucose-6-phosphate, both transient and permanent repression were observed. Correlation between the observations in the membrane system and in intact cells is discussed. The results obtained here strongly suggest that transient repression is caused by glucose itself, and that permanent repression is caused by glucose-6-phosphate of high intracellular levels of glucose.

Effect of glucose and its analogues on the accumulation and release of cyclic adenosine 3',5'-monophosphate in a membrane fraction of Escherichia coli: relation to beta-galactosidase synthesis

Correlation between beta-galactosidase synthesis and cyclic adenosine 3',5'-monophosphate (cAMP) levels in a membrane fraction obtained from disrupted spheroplasts of Escherichia coli was investigated. Repression of beta-galactosidase synthesis in the membrane fraction by glucose-6-phosphate and by 2-deoxyglucose differed in sensitivity to reversal by cAMP. The difference between the two repressions could be due to the fact that glucose-6-phosphate inhibited severely the accumulation of exogenous [3-H]cAMP by the membrane fraction, whereas 2-deoxyglucose had little effect on the accumulation of the nucleotide. On the other hand, a quick decrease in the level of [3-H]cAMP preaccumulated in the membrane fraction resulted from addition of either glucose-6-phosphate or 2-deoxyglucose. Results reported here suggest that repression of beta-galactosidase synthesis is associated with anabrupt decrease in cAMP levels at the intramembranal sites where beta-galactosidase is synthesized, and the major, if not sole, mechanism which leads to instantaneous drop of cAMP level is via the release of cAMP, but not by degradation of the nucleotide since the membrane fraction retained less than 10 percent of cellular cyclic phosphodiesterase and the activity of the enzyme was not affected by repressing sugars.

Evidence for the direct action of colicin K on aerobic 32 P i uptake in Escherichia coli in vivo and in vitro

Pentachlorophenol (PCP)-sensitive incorporation of (32)P-labeled orthophosphate ((32)P(i)) into nucleotides and nucleic acids by disrupted spheroplasts of Escherichia coli was inhibited by addition of colicin K. Incorporation by intact cells was also inhibited by a similar concentration of colicin K. Various colicin K-resistant mutants were isolated, and their ability to incorporate (32)P(i) was tested. When T6(r)-colK(r) mutants (T6 phage-resistant) and tol I mutants (T6-sensitive, colicin E-sensitive) were converted to disrupted spheroplasts, their (32)P(i)-incorporation became sensitive to colicin K. On the contrary, incorporation by disrupted spheroplasts from tol II mutants (T6-sensitive, colicin E-resistant) was fairly resistant to colicin K like that of intact cells. A modification of the cell surface of T6(r)-colK(r) mutants, caused by mutation to novobiocin-permeable, T4 phage-resistant cells, restored the sensitivity of the cells to colicin K. The modified T6(r)-colK(r) cells did not adsorb T6 phage or colicin K, indicating that the receptors for T6 phage or colicin K are not reactivated by this modification. Similar treatment of tol I mutants did not have this effect. These observations strongly suggest that colicin K can act on its target on the cell membrane if it can penetrate the cell surface to reach this target. The receptor for colicin K on the cell surface, which may be part of the T6 phage-receptor, may have some unknown function in relation to the action of colicin K in normal cells, but tends to become dispensable if the cells become permeable to colicin K.

Synthesis of protein and nucleic acid by disrupted spheroplasts of Pseudomonas schuylkilliensis

Osmotically shocked spheroplasts obtained from Pseudomonas schuylkilliensis strain P contained about 54, 32, 28, and 82% of the total cellular protein, ribonucleic acid (RNA), deoxyribonucleic acid (DNA), and phospholipid, respectively. This preparation was capable of incorporating (32)P-orthophosphate into RNA and DNA, (3)H-adenosine or (3)H-uridine into RNA, and (3)H-leucine or (14)C-phenylalanine into protein. These activities were not found in the cytoplasmic fraction which contained most of the glucose-6-phosphate dehydrogenase activity. The synthesis of RNA by intact and disrupted spheroplast preparations was sensitive to actinomycin D, chromomycin A(3), streptovaricin, rifampin, Lubrol W, Triton X-100, and sodium deoxycholate, whereas RNA synthesis by intact cells was insensitive to these agents. Ethylenediaminetetraacetic acid, porcine pancreatic lipase, the protoplast-bursting factor, high concentrations of salts, and washing the preparation inhibited the synthesis of RNA by disrupted spheroplasts but had little or no effect on intact spheroplasts. Most of the newly synthesized RNA made by disrupted spheroplasts had the characteristics of messenger RNA. The DNA present in this preparation functioned as a template for RNA synthesis; continued protein synthesis was dependent on concomitant RNA synthesis. An unusual feature of the preparation was the finding that the synthesis of macromolecules was completely dependent on oxidative phosphorylation.

Biosynthesis of ubiquinone in non-photosynthetic gram-negative bacteria

1. The polyprenylphenol and quinone complements of the non-photosynthetic Gram-negative bacteria, Pseudomonas ovalis Chester, Proteus mirabilis and ;Vibrio O1' (Moraxella sp.), were investigated. 2. Ps. ovalis Chester and Prot. mirabilis were shown to contain 2-polyprenylphenols, 6-methoxy-2-polyprenylphenols, 6-methoxy-2-polyprenyl-1,4-benzoquinones, 5-demethoxyubiquinones, ubiquinones, an unidentified 1,4-benzoquinone [2-polyprenyl-1,4-benzoquinone (?)] and ;epoxyubiquinones'. ;Vibrio O1' was shown to contain only 5-demethoxyubiquinones, ubiquinones and ;epoxyubiquinones'. 3. It was established that in Ps. ovalis Chester 2-polyprenylphenols, 6-methoxy-2-polyprenylphenols, 6-methoxy-2-polyprenyl-1,4-benzoquinones, 5-demethoxyubiquinones and 2-polyprenyl-1,4-benzoquinones (?) are precursors of ubiquinones. 4. Intracellular distribution studies showed that in Ps. ovalis Chester ubiquinone and its prenylated precursors are localized entirely on the protoplast membrane. 5. Investigations into the oxygen requirements for ubiquinone biosynthesis by Ps. ovalis Chester showed that the organism could not convert p-hydroxybenzoic acid into ubiquinone in the absence of oxygen, although it could convert a limited amount into 2-polyprenylphenols. 6. Attempts were made to prepare cell-free preparations capable of synthesizing ubiquinone. Purified protoplast membranes of Ps. ovalis Chester were found to be incapable of carrying out this synthesis, even when supplemented with cytoplasm. With crushed-cell preparations of Ps. ovalis Chester, organism PC4 (Achromobacter sp.) and Escherichia coli, synthesis was observed, although this was attributable in part to a small number of intact cells present in the preparations.

Inducible synthesis of beta-galactosidase in disrupted spheroplast of Escherichia coli

A membrane preparation obtained from osmotic lysate of spheroplasts of Escherichia coli cells showed an activity of synthesizing beta-galactosidase which was dependent upon oxidative phosphorylation. The synthesis was inhibited by the addition of actinomycin D or of chloramphenicol. The beta-galactosidase synthesized in the membrane preparation was completely released into the medium, while that synthesized in the spheroplasts and intact cells remained within the cells. The minimum concentration of the inducer, methyl-beta-d-thiogalactoside, required for the induction of beta-galactosidase was 5 x 10(-5)m for intact cells, 3 x 10(-4)m for spheroplasts and 1 x 10(-3)m for membrane preparation. Incorporation of labeled glucose into insoluble components in membrane preparation was extremely low compared with that in intact cells or in spheroplasts. Based on these and other observations, the nature of this membrane preparation is discussed in relation to the structure of E. coli cells.

Reduced nicotinamide-adenine dinucleotide oxidation in Escherichia coli particles. 3. Cellular location of menadione reductase and ATPase activities

Sonic extracts of Escherichia coli were fractionated to membrane-wall, small-particle, and soluble fractions. Menadione reductase and ATPase activities were found in all fractions. The menadione reductase activity of the soluble fraction was resolved into three enzymes. Enzymes with properties similar to two of these could be released from the particulate fraction by treatment with sodium dodecyl sulfate or chelating agents. The major ATPase of the particulate fractions was solubilized by detergent. Osmotic shock experiments suggested that it was located outside the plasma membrane in the intact cell. It differed from the ATPase of the soluble fraction. An enzyme resembling the latter ATPase was solubilized from the small-particle fraction by chelating agents and could be rebound in the presence of magnesium ions. Solubilized menadione reductase was not rebound to particulate fractions under these conditions.