Heat-labile enterotoxin in Escherichia coli. Kinetics of association of subunits into periplasmic holotoxin

We have investigated the assembly of the heat-labile enterotoxin (LT) subunits after their processing and segregation into the periplasmic space as mature LT A and LT B polypeptides. LT B starts associating into oligomers during or immediately after translocation through the cytoplasmic membrane. Binding to LT A occurs immediately after oligomerization. Over 80% of the LT B subunits have oligomerized, and over 50% have associated with LT A into holotoxin within 1 min after synthesis. The fate of newly synthesized LT A is totally different. There is an extensive overproduction of LT A relative to LT B and after membrane translocation it becomes part of a periplasmic pool of free LT A. It is then bound by LT B oligomers or degraded at such a rate that the free periplasmic LT A disappears from the pool with a half-time of 20-25 min. About half of the LT A is incorporated into holotoxin, while the other half is degraded. We conclude that LT subunits are translocated and processed in a ratio of about 2 A to 5 B. Since free LT A is either degraded slowly or bound to newly synthesized LT B oligomers, the net result is a steady state of 1.4 to 1.7 A subunits to 5 B subunits in the periplasm. About 60% of this LT A is bound by LT B to form periplasmic holotoxin with a subunit ratio of about 1 A to 5 B. The remaining 40% of periplasmic LT A occurs free.     

Kinetic and Morphological Observations on Saccharomyces cerevisiae During Spheroplast Formation

A strain of Saccharomyces cerevisiae which produced elongated cells under our growth conditions was investigated. By digestion of the cell walls with snail enzyme, the cells became spheroplasts after a transient state which we termed "prospheroplast." The prospheroplast could be lysed like the spheroplast, but it retained the shape of the original yeast cell if osmotically protected. Prospheroplasts and spheroplasts were prepared, and thin sections of samples taken throughout the process of wall removal were studied in the electron microscope, at regular intervals up to the time of complete conversion to spheroplasts. In addition, cell wall remnants recovered from spheroplast preparations were shadow cast for electron microscopy. This material revealed structures resembling bud scars with attached membranous matter. The kinetic studies showed that after a certain period of time all cells were transformed into prospheroplasts, whereas spheroplast formation started later, depending on the enzyme concentration. In sections, the prospheroplasts appeared to be formed by detachment of the cell walls. Both the prospheroplasts and the spheroplasts showed asymmetric cytoplasmic membranes in which the outer leaflets appeared coated with a dense fibrillar layer. The experiments suggest that, after enzyme digestion, the cytoplasmic membrane retains a coating which is rigid in the prospheroplast but which loses rigidity when the cell is transformed into a spheroplast.     

Multiplication of Bacteriophage P22 in Penicillin-Induced Spheroplasts of Salmonella typhimurium

The spheroplasts of Salmonella typhimurium (LT2) prepared by treatment with penicillin were capable of adsorbing phage P22 C(1). The normal multiplication of the phage took place, although the burst size was reduced to one-fourth of that in intact cells. Rate of incorporation of (14)C-thymidine into spheroplasts was increased severalfold on phage infection. Multiplication of C(+) also took place, but no lysogeny could be established in spheroplasts. Furthermore, spheroplasts prepared from cells lysogenized with wild-type phage, LT2 (C(+)), and a temperature-inducible C(2) mutant, LT2(tsC(2)), were not inducible. Unlike normal cells, both mitomycin C and actinomycin D interfered with the phage multiplication in spheroplasts. The spheroplast system offers great advantages in the study of the synthesis of nucleic acids and proteins in phage-infected LT2.     

Role of the Cytoplasmic Membrane in the Synthesis of Ribonucleic Acid by Disrupted Spheroplasts of Pseudomonas schuylkilliensis

Disrupted spheroplast preparations of Pseudomonas schuylkilliensis strain P contained fragments of cytoplasmic membrane and approximately 82% of the total cellular phospholipid. The protoplast-bursting factor (PB-factor), partially purified from pig pancreas, and a heat-treated pancreatic lipase fraction both inhibited ribonucleic acid (RNA) synthesis by disrupted spheroplasts but did not inhibit or only slightly inhibited RNA synthesis by intact cells or intact spheroplasts. The PB-factor preparation and the heat-treated pancreatic lipase fraction catalyzed partial (15 to 50%) deacylation of diphosphatidylglycerol, phosphatidylglycerol, and phosphatidylethanolamine in disrupted spheroplasts but not in intact spheroplasts. Phospholipase A activity was demonstrated in the PB-factor preparation by use of isolated phospholipids as substrates. Treatment of disrupted spheroplasts with the PB-factor preparation caused a 70% inhibition in oxidative phosphorylation and RNA synthesis, but had little effect on electron transport. Addition of adenosine-5'-triphosphate or adenosine-5'-diphosphate and a mixture of ribonucleosides after treatment with the PB-factor preparation partially restored oxidative phosphorylation but did not relieve the inhibition in RNA synthesis. The most reasonable explanation for the latter observation appears to be that the concentrations of newly synthesized nucleotides retained by the preparations with partially deacylated membrane phospholipids were insufficient to permit the synthesis of RNA.     

The biosynthesis, processing, and secretion of laminin by human choriocarcinoma cells

Laminin, a glycoprotein component of basal laminae, is synthesized and secreted in culture by a human malignant cell line (JAR) derived from gestational choriocarcinoma. Biosynthetically labeled human laminin subunits A (Mr approximately 400,000) and B (Mr = 200,000 doublet) are glycoslyated with asparagine-linked high mannose oligosaccharides that are processed to complex oligosaccharides before the laminin molecule is externalized by the cell. The rate-limiting step in the processing of the asparagine-linked glycans of laminin is at the point of action of alpha-mannosidase I since the principal laminin forms that accumulate in JAR cells contain Man9GlcNAc2 and Man8GlcNAc2 oligosaccharide units. The combination of subunits to form the disulfide-linked laminin molecule (Mr approximately 950,000) occurs rapidly within the cell at a time when the subunits contain these high mannose oligosaccharides. The production of laminin is limited by the availability of the A subunit such that excess B subunit forms accumulate intracellularly as uncombined B and a disulfide-linked B dimer. Pulse-chase kinetic studies establish these B forms as intermediates in the assembly of the laminin molecule. The fully assembled laminin undergoes further oligosaccharide processing and translocation to the cell surface, but uncombined B and B dimer are neither processed nor secreted to any significant extent. Therefore, laminin subunit combination appears to be a prerequisite for intracellular translocation, processing, and secretion. The mature laminin that contains complex oligosaccharides does not accumulate intracellularly but is rapidly externalized upon completion, either secreted into the culture medium (25%) or associated with the cell surface (75%) as determined by susceptibility to degradation by trypsin. About one-third of the laminin molecules secreted or shed by JAR cells into the chase medium contain a smaller A subunit form that appears to have been modified by limited proteolytic cleavage. The putative proteolytic event is closely timed to the release of the laminin into the culture medium.     

Interactions of alkaline phosphatase and the cell wall of Pseudomonas aeruginosa

Spheroplasts prepared by lysozyme treatment of cells of Pseudomonas aeruginosa, suspended in 20% sucrose or 0.2 m MgCl(2), were examined in detail. Preparation of spheroplasts in the presence of 0.2 m Mg(2+) released periplasmic alkaline phosphatase, whereas preparation in the presence of 20% sucrose did not, even though untreated cells released phosphatase when suspended in sucrose in the absence of lysozyme. Biochemical characterizations of the sucrose-lysozyme preparations indicated that lysozyme mediated a reassociation of the released phosphatase with the spheroplasts. In addition, the enzyme released from whole cells suspended in 20% sucrose (which represents 20 to 40% of the cell-bound phosphatase) reassociates with the cells in the presence of lysozyme. Electron microscopic examinations of various preparations revealed that phosphatase released in sucrose reassociated with the external cell wall layers in the presence of lysozyme, that sucrose-lysozyme prepared spheroplasts did not dissociate phosphatase which remained in the periplasm of sucrose-washed cells, and that phosphatase was never observed to be associated with the cytoplasmic membrane. A model to account for the binding of P. aeruginosa alkaline phosphatase to the internal portion of the tripartite layer of the cell wall rather than to the cytoplasmic membrane or peptidoglycan layer is presented.     

Transient entry of enterotoxin subunits into the periplasm occurs during their secretion from Vibrio cholerae.

Cholera toxin and heat-labile enterotoxin (LT) are structurally similar oligomeric proteins which are capable of being efficiently secreted from Vibrio cholerae. Here we report that these proteins transiently enter the periplasm of V. cholerae as they traverse the cell envelope to reach the extracellular milieu. Pulse-chase experiments on V. cholerae TRH7000 harboring an LT-encoding plasmid revealed that radiolabeled LT A and B subunits entered the periplasm rapidly, followed by their slow efflux (half-time, 13 min) into the medium. LT B-subunit efflux from the periplasm was calculated to be at a rate of ca. 170 monomers per min per cell (which is equivalent to 34 assembled LT holotoxin molecules per min per cell). These values were estimated to be sufficient to account for the increase in extracellular enterotoxin concentration during exponential cell growth. Thus, all enterotoxin subunits which are secreted into the medium can be assumed to be channelled via the periplasm. These findings led to an improved model of the pathway of toxin secretion by V. cholerae.     

Properties of Infectious T1 Deoxyribonucleic Acid

T1 deoxyribonucleic acid (DNA) infection of spheroplasts was characterized by the following. A small number of the DNA molecules initiated infectious centers, and a small number of the spheroplasts were infected by T1 DNA. Once a favorable encounter of T1 DNA with spheroplast occurred, a minimum of 20 to 30 min was required for T1 DNA to enter the spheroplast. The mature T1 particles produced in the infection of spheroplasts by T1 DNA were released in a burst, but the average burst size was quite small compared with a normal burst of the phage-infected bacteria. T1 DNA preparations, capable of causing viral growth in spheroplasts, did not require detectable amounts of protein for infectivity, were homogeneous in band and boundary sedimentation, and had a guanine plus cytosine content of 48% and a minimal molecular weight of 35 x 10(6). Denatured T1 DNA, like denatured lambdaDNA, did not infect spheroplasts. Renatured T1 DNA was not infectious; this was in marked contrast to renatured lambdaDNA.     

Responses of enzymically isolated aleurone cells of oat to gibberellin a(3)

Oat (Avena sativa L.) aleurone layer cells (spheroplasts) were isolated by maceration of the aleurone layer with a mixture of commercially available cellulase and pectinase. About 20% of the cells present in intact layers were released as spheroplasts and 79 +/- 9% of the spheroplast population was viable as judged by methylene blue staining. The spheroplasts became disorganized in solutions containing less than 0.4 md-mannitol. When the spheroplasts were incubated for 48 hours, total activities of acid p-nitrophenyl phosphatase and acid proteinase increased and protein levels decreased. These changes were not effected by gibberellin A(3). Isolated aleurone layers incubated under the same conditions as the spheroplasts showed reduced responses to gibberellin A(3). It is concluded that the necessary presence of an osmoticum limits the value of spheroplasts as a system for studying the mechanism of action of gibberellin A(3) in the aleurone cell.     

A structural comparison of the A and B subunits of Griffonia simplicifolia I isolectins

A structural comparison between the A and B subunits of the five tetrameric Griffonia simplicifolia I isolectins (A4, A3B, A2B2, AB3, B4) was undertaken to determine the extent of homology between the subunits. The first 25 N-terminal amino acids of both A and B subunits were determined following the enzymatic removal of N-terminal pyroglutamate blocking groups with pyroglutamate aminopeptidase. Although 21 amino acids were common to both subunits, there were four unique amino acids in the N-terminal sequence of A and B. Residues 8, 9, 17, and 19 were asparagine, leucine, lysine, and asparagine in subunit A and threonine, phenylalanine, glutamic acid, and serine in subunit B. The last six C-terminal amino acids, released by digestion with carboxypeptidase Y, were the same for both subunits: Arg-(Phe, Val)-Leu-Thr-Ser-COOH. Subunit B, which contains one methionyl residue, was cleaved by cyanogen bromide into two fragments, a large (Mr = 31,000) and a small (Mr = 2700) polypeptide. Failure of the small fragment to undergo manual Edman degradation indicated an N-terminal blocking group, presumably pyroglutamate. Both subunits were digested with trypsin and the tryptic peptides were analyzed using reverse-phase HPLC. Tryptic glycopeptides were identified by labeling the carbohydrate moiety of the A and B subunit using sodium [3H] borohydride. Cysteine-containing tryptic peptides were similarly identified by using [1-14C]iodoacetamide. Approximately 30% of the tryptic peptides were common to both subunits. Thus, although the N- and C-terminal regions of A and B are similar, the subunits each possess unique sequences.     

Biosynthesis and maturation of the Lyt-2/3 molecular complex in mouse thymocytes

The biosynthesis and maturation of the three subunits alpha (Mr = 37,000), beta (Mr = 32,000), and gamma (Mr = 27,000) of the mouse Lyt-2/3 antigenic complex have been studied by using two monoclonal antibodies directed against a monomorphic determinant of the Lyt-2 antigen. Short time-pulse labeling of thymocytes reveals three different high mannose intermediates that give rise upon endo-beta-N-acetyl-glucosaminidase H digestion to three distinct precursor polypeptides of Mr = 22,000 (alpha P), Mr = 18,000 (beta P), and Mr = 19,500 (gamma P). Pulse-chase analysis indicates rapid posttranslational processing, because mature forms already appear after 10 min of chase. The half-life of the endo-H-sensitive early forms are in the range of 20 to 30 min. Both the alpha and beta subunits are suggested to contain three N-asparagine-linked oligosaccharides, one of which is of the high mannose type. In contrast, the gamma-chain contains only one such glycan unit of the complex type. Moreover, the results presented show that all three chains undergo additional posttranslational modifications. Finally, the data suggest that the cytoplasmic domains of these chains are of different size.     

Mutant analysis and cellular localization of the AlgI,AlgJ, and AlgF proteins required for O acetylation of alginate in Pseudomonas aeruginosa

Alginate is an extracellular polysaccharide produced by mucoid strains of Pseudomonas aeruginosa that are typically isolated from the pulmonary tracts of chronically infected cystic fibrosis patients. Alginate is a linear polymer of D-mannuronate and L-guluronate with O-acetyl ester linkages on the O-2 and/or O-3 position of the mannuronate residues. The presence of O-acetyl groups plays an important role in the ability of the polymer to act as a virulence factor, and the algF, algJ, and algI genes are known to be essential for the addition of O-acetyl groups to alginate. To better understand the mechanism of O acetylation of alginate, the cellular locations of the AlgI, AlgJ, and AlgF proteins were determined. For these studies, defined nonpolar algI, algJ, and algF deletion mutants of P. aeruginosa strain FRD1 were constructed, and each mutant produced alginate lacking O-acetyl groups. Expression of algI, algJ, or algF in trans in the corresponding mutant complemented each O acetylation defect. Random phoA (alkaline phosphatase [AP] gene) fusions to algF, algJ, and algI were constructed. All in-frame fusions to algF and algJ had AP activity, indicating that both AlgF and AlgJ were exported to the periplasm. Immunoblot analysis of spheroplasts and periplasmic fractions showed that AlgF was released with the periplasmic contents but that AlgJ remained with the spheroplast fraction. An N-terminal sequence analysis of AlgJ showed that its putative AlgJ signal peptide was not cleaved, suggesting that AlgJ is anchored to the cytoplasmic membrane by its uncleaved signal peptide. AP gene fusions were also used to map the membrane topology of AlgI, and the results suggest that it is an integral membrane protein with seven transmembrane domains. These results suggest that AlgI-AlgJ-AlgF may form a complex in the membrane that is the reaction center for O acetylation of alginate.     

Interaction of the isolated DNA of lambda phage with spheroplasts of E. coli treated with sturine]

The method of centrifugation in sucrose density gradient (30-55%) of the spheroplast membrane preparations treated and untreated with sturine and infected with phage lambda DNA demonstrated that sturine, treatment increased the phage lambda DNA absorption three-fold. About 50% of the lambda DNA molecules adsorbed by spheroplasts are bound with the cytoplasmic membrane of spheroplasts treated with sturine; 50% of the lambda DNA molecules are bound with the cell wall membrane on the sturine-untreated spheroplasts. The data obtained allow to conclude that the stimulating effect of sturine in E. coli spheroplasts transfection by lambda DNA is connected with redistribution of phage DNA absorbed on spheroplasts from the cell wall to the cytoplasmic membrane facilitating the penetration of DNA and its fastening on the membrane.     

Effect of Substitution for Arginine Residues near Position 146 of the A Subunit of Escherichia coli Heat-Labile Enterotoxin on the Holotoxin Assembly

Escherichia coli heat-labile enterotoxin (LT) is a holotoxin which consists of one A and five B subunits. Although B subunit monomers released into periplasm can associate into pentameric structures in the absence of the A subunit, the A subunit accelerates the assembly. To express the function, A subunit constructs the proper spatial structure. However, the regions involved in the construction are unknown. To identify the regions, we substituted arginine residues near position 146 of the A subunit with glycine by oligonucleotide-directed site-specific mutagenesis and obtained the mutants expressing LT(R141G), LT(R143G), LT(R146G), LT(R143G, R146G), LT(R141G, R143G, R146G) and LT(R143G, R146G, R148G). We purified these mutant LTs by using an immobilized d -galactose column and analyzed the purified mutant LTs by SDS-PAGE to examine the amount of A subunit associated with B-subunit oligomer. The substitution of an arginine residue at any position did not induce a significant alteration in the amount of A subunit associated with B-subunit oligomer. However, the substitution of more than two arginine residues induced a significant decrease in the amount of A subunits associated with the B-subunit oligomer. Subsequently, we measured the level of the intracellular B-subunit oligomer of these mutant strains. The measurement revealed that the amount of B-subunit oligomer in cells decreased as the number of substituted arginine residues increased. These results show that all arginine residues near position 146 are important for the construction of the functional A subunit, and thus for holotoxin formation, although each individual arginine residue is not an absolute requirement.     

Clostridium botulinum C3 ADP-ribosyltransferase gene. Cloning, sequencing, and expression of a functional protein in Escherichia coli

C3 ADP-ribosyltransferase is an exoenzyme produced by certain strains of Clostridium botulinum types C and D, which specifically ADP-ribosylates rho and rac proteins in eukaryotic cells. The enzyme was purified from a culture filtrate of C. botulinum type C strain 003-9, and the amino acid sequence from the amino-terminal Ser to Asn192 was determined by Edman degradation. Using a set of degenerate primers based on the sequence, we amplified a part of the gene for this enzyme by polymerase chain reaction. A 2.1-kilobase pair HincII fragment of C. botulinum DNA containing the whole structural gene was then identified by Southern analysis with the polymerase chain reaction product as a probe, and the complete nucleotide structure of the gene together with flanking regions was determined by cloning and DNA sequencing the HincII fragment. The gene encodes a protein of 244 amino acids with a Mr of 27,362 which begins with a putative signal peptide of 40 amino acids. Escherichia coli carrying this gene produced the active enzyme, and about 60% of it was found in the culture medium. Immunoblot analysis with antiserum against the enzyme revealed the presence of two immunoreactive proteins of 27 and 23 kDa in the cytoplasmic/membrane fraction and only the 23-kDa protein in the periplasm and the medium, suggesting that the enzyme expressed is processed in the E. coli, exported into the periplasm and released into the culture medium.     

Genetic recombination in fused spheroplasts of Providence alcalifaciens.

Spheroplasts of Providence alcalifaciens strain P29 auxotrophs were prepared by combined treatment with glycine and lysozyme-EDTA. About 15% of spheroplasts had areas of cytoplasmic membrane exposed where cell wall was absent. The spheroplasts of different auxotrophs were mixed pairwise and fusion was attempted with polyethylene glycol or nascent calcium phosphate. After spheroplasts had regenerated to bacterial forms selection was made for recombinants. Recombinants arose at frequencies of 3.8 X 10(-6) to 1.7 X 10(-7) per spheroplast initially present, by both methods of fusion. The frequency was strongly dependent on the number of chromosomal loci used in selection. The possible order of five loci was determined and this corresponded to that on the closely related Proteus mirabilis chromosome. Control experiments excluded possibilities of auxotrophic reversion, conjugation, transformation, transfection or transduction as explanations of the results. Analysis of prototrophic clones yielded stable prototrophs or mixtures of stable prototrophs and stable recombinants. Parental types were not encountered. Unselected markers segregated among recombinants. It was concluded that the formation of recombinant bacteria was due to spheroplast fusion and that only stable products of the very temporary heteroploid state were haploid recombinants. The low frequency of recombination was ascribed to the limited number of spheroplasts with areas of exposed cytoplasmic membrane.     

Secretion of Alkaline Phosphatase Subunits by Spheroplasts of Escherichia coli

Under conditions that permitted continued protein synthesis, spheroplasts of Escherichia coli were unable to form active alkaline phosphatase, although they synthesized protein that was antigenically related to alkaline phosphatase subunits. This cross-reacting protein was primarily detected in the medium of the spheroplast culture, and it had properties that closely resembled those of the alkaline phosphatase subunit. These results suggest that formation of the active alkaline phosphatase dimer by intact E. coli cells proceeds by a pathway in which inactive subunits released from polyribosomes diffuse through the bacterial cell membrane to a periplasmic space where subsequent dimerization to active enzyme occurs. This pathway provides a possible mechanism for the specific localization of this enzyme to the E. coli periplasmic space.     

Physical Properties of Escherichia coli Spheroplast Membranes

We investigated the physical properties of bacterial cytoplasmic membranes by applying the method of micropipette aspiration to Escherichia coli spheroplasts. We found that the properties of spheroplast membranes are significantly different from that of laboratory-prepared lipid vesicles or that of previously investigated animal cells. The spheroplasts can adjust their internal osmolality by increasing their volumes more than three times upon osmotic downshift. Until the spheroplasts are swollen to their volume limit, their membranes are tensionless. At constant external osmolality, aspiration increases the surface area of the membrane and creates tension. What distinguishes spheroplast membranes from lipid bilayers is that the area change of a spheroplast membrane by tension is a relaxation process. No such time dependence is observed in lipid bilayers. The equilibrium tension-area relation is reversible. The apparent area stretching moduli are several times smaller than that of stretching a lipid bilayer. We conclude that spheroplasts maintain a minimum surface area without tension by a membrane reservoir that removes the excessive membranes from the minimum surface area. Volume expansion eventually exhausts the membrane reservoir; then the membrane behaves like a lipid bilayer with a comparable stretching modulus. Interestingly, the membranes cease to refold when spheroplasts lost viability, implying that the membrane reservoir is metabolically maintained.     

Characteristics of chromosomal DNA isolated from Escherichia coli spheroplasts

The chromosomal DNA of Escherichia coli spheroplasts induced by penicillin G was studied biochemically and electron microscopically. Although the spheroplasts were unable to divide, they continued to synthesize chromosomal DNA for several hours even in the presence of penicillin G. Some differences were observed between the chromosomal DNA of the parent cells and that of the spheroplasts in sucrose gradient centrifugation and electron microscopy; two types of chromosomal DNA, a slower sedimenting form and a faster sedimenting form, were released from the gently lysed parent cells. The former was membrane-free folded chromosome and the latter was membrane-associated chromosome. In contrast, the chromosome from the spheroplast showed a single intermediate value of sedimentation coefficient between those of the chromosomal DNA from the parent cell. Cytochrome spreading for electron microscopy showed that the spheroplast chromosomal DNA formed an aggregated mass consisting of several chromosome-molecules of the parent cell.