Membrane phospholipid composition of Caulobacter crescentus.

The phospholipid composition of Caulobacter crescentus CB13 and CB15 was determined. The acidic phospholipids, phosphatidylglycerol and cardiolipin, comprise approximately 87% of the total phospholipids. Neither phosphatidylethanolamine nor its precursor phosphatidylserine was detected. The outer and inner membranes of C. crescentus CB13 were separated, and phospholipid analysis revealed heterogeneity with respect to the relative amounts of phosphatidylglycerol and cardiolipin in the two membranes. As has been shown to be the case for other bacterial membranes, the concentration of cardiolipin increases and phosphatidylglycerol decreases as cell cultures enter stationary phase.     

Autolysis of Caulobacter crescentus grown in the presence of glycine

Caulobacter crescentus was grown in complex medium supplemented with low (0.05%) concentration of glycine, a component of the murein peptide side chains of this bacterium. Murein synthesized in the presence of glycine was poorly crosslinked and the rate of its synthesis was slowed down compared to the control cells. The glycine-grown cells were considerably more sensitive to the chelating agent EDTA and Tris buffer than the control cells and also lysed faster when incubated with beta-lactam antibiotics. No changes in phospholipid composition in the presence of glycine were observed and the outer membrane protein composition of the glycine-grown cells was altered only in the amount of 130 000 protein which forms the surface array of C. crescentus. The effects of glycine can thus be tentatively put down to the reduced crosslinkage of murein synthesized in its presence.     

Mutants of Caulobacter crescentus resistant to beta-lactam antibiotics

A number of mutants of Caulobacter crescentus CB15 resistant ot ampicillin were isolated. The mutants differred in their resistance to several beta-lactam antibiotics. No differences in composition of the penicillin-binding proteins of the mutants compared to the parental strain, or in the affinity of these proteins to penicillin or ampicillin were found. The mutants were found to differ from the parent and also in many cases from each other in outer membrane protein composition.     

Current thoughts on the phosphatidylinositol transfer protein family

Monomeric transport of lipids is carried out by a class of proteins that can shield a lipid from the aqueous environment by binding the lipid in a hydrophobic cavity. One such group of proteins is the phosphatidylinositol transfer proteins (PITP) that can bind phosphatidylinositol and phosphatidylcholine and transfer them from one membrane compartment to another. PITPs are found in both unicellular and multicellular organisms but not bacteria. In mice and humans, the PITP domain responsible for lipid transfer is found in five proteins, which can be classified into two classes based on sequence. Class I PITPs comprises two family members, alpha and beta, small 35 kDa proteins with a single PITP domain which are ubiquitously expressed. Class IIA PITPs (RdgBalphaI and II) are larger proteins possessing additional domains that target the protein to membranes and are only able to bind lipids but not mediate transfer. Finally, Class IIB PITP (RdgBbeta) is similar to Class I in size (38 kDa) and is also ubiquitously expressed. Class III PITPs, exemplified by the Sec14p family, are found in yeast and plants but are unrelated in sequence and structure to Class I and Class II PITPs. In this review we discuss whether PITP proteins are passive transporters or are regulated proteins that are able to couple their transport and binding properties to specific biological functions including inositol lipid signalling and membrane turnover.     

A Fusion-Inhibiting Peptide against Rift Valley Fever Virus Inhibits Multiple,Diverse Viruses

For enveloped viruses, fusion of the viral envelope with a cellular membrane is critical for a productive infection to occur. This fusion process is mediated by at least three classes of fusion proteins (Class I, II, and III) based on the protein sequence and structure. For Rift Valley fever virus (RVFV), the glycoprotein Gc (Class II fusion protein) mediates this fusion event following entry into the endocytic pathway, allowing the viral genome access to the cell cytoplasm. Here, we show that peptides analogous to the RVFV Gc stem region inhibited RVFV infectivity in cell culture by inhibiting the fusion process. Further, we show that infectivity can be inhibited for diverse, unrelated RNA viruses that have Class I (Ebola virus), Class II (Andes virus), or Class III (vesicular stomatitis virus) fusion proteins using this single peptide. Our findings are consistent with an inhibition mechanism similar to that proposed for stem peptide fusion inhibitors of dengue virus in which the RVFV inhibitory peptide first binds to both the virion and cell membranes, allowing it to traffic with the virus into the endocytic pathway. Upon acidification and rearrangement of Gc, the peptide is then able to specifically bind to Gc and prevent fusion of the viral and endocytic membranes, thus inhibiting viral infection. These results could provide novel insights into conserved features among the three classes of viral fusion proteins and offer direction for the future development of broadly active fusion inhibitors.     

Isolation and characterization of Chromatium vinosum membranes

A fractionation of Chromatium vinosum into an outer layer (cell wall) and three intracellular membrane fractions by isopycnic sucrose density centrifugation of a total membrane fraction obtained by lysis of lysozyme-EDTA spheroplasts is decribed. The three intracellular fractions (I, II, and III) have apparent densities of 1.11, 1.14, and 1.16, respectively, and contain the bulk of the photosynthetic pigments. Fraction II is enriched in bacteriochlorophyll and contains about 49% of the total membrane protein and 60% of the membrane bacteriochlorophyll. The outer membrane fraction (IV, cell wall) has a density of 1.23 and contains 5% of the membrane protein and 0.8% of the bacteriochlorophyll. Fraction I is enriched in lipids and phosphorus and has only a trace of diaminopimelate (DAP). Fractions II and III both contain a significant content of DAP. Fraction IV has no DAP, but has a fatty acid composition similar to that of the envelope fraction. Electrophoresis of the fractions on sodium dodecylsulfate-containing gels yielded from 8–13 bands of protein. Fractions I, II, and III contained the same series of unique proteins, while fraction IV contained another group of unique proteins. In fraction IV the bulk of the proteins traveled in one band with a molecular weight of 41,500. Examination of the fractions and whole spheroplasts in the electron microscope showed that fractions I, II and III were composed of large membrane structures in the form of membrane reticulum with bud-like appendages, and elongated flattened tubes. Fraction IV was composed of large ovoid structures which were seen to lie on the outer surface of the whole spheroplasts. These results suggest that the normal in vivo state of the intracellular membranes is that of an interconnected series of tubules and vesicles extending throughout the cell cytoplasm.     

The surface properties of Neisseria gonorrhoeae: topographical distribution of the outer membrane protein antigens.

Gonococci were labelled with 125I using the lactoperoxidase system. The amount of label incorporated was similar with all strains including those which appeared capsulated. Electrophoresis on sodium dodecyl sulphate-polyacrylamide gels revealed that the major proteins labelled were those found in outer membrane preparations. Comparison of variants of one strain showed that the major outer membrane protein (protein I) was always present and heavily labelled. The second major protein (protein II) was present in variable amounts but labelling was proportional to the amount present. A third protein (III) was only present in outer membranes from a freshly isolated variant but was present in whole cells of each strain. Protein III was not labelled in whole cells but was labelled in outer membrane preparations suggesting that many membranes have their inner surface exposed. The labelling of a strain adapted to growth in guinea-pig chambers failed to reveal any new major surface proteins. The results demonstrate the variation in surface topography possible with variants of one strain of gonococcus but show that one major protein antigen is always expressed on the surface.     

Analysis of outer membrane proteins which are associated with growth of Bacteroides thetaiotaomicron on chondroitin sulfate.

By analyzing outer membrane proteins of Bacteroides thetaiotaomicron on two-dimensional polyacrylamide gels, we were able to identify 10 protein spots that were associated with growth on chondroitin sulfate but not with growth on glucuronic acid or other monosaccharides. These proteins were distinct from the outer membrane polypeptides that were associated with growth on two other negatively charged polysaccharides, polygalacturonic acid and heparin. Of the 10 protein spots that were associated with growth on chondroitin sulfate, 4 could be detected on immunoblots with antiserum that had been raised against outer membranes from bacteria grown on chondroitin sulfate and then cross-adsorbed with membranes from bacteria grown on glucose. Synthesis of these four proteins appeared to be regulated coordinately with synthesis of the two enzymes that degrade chondroitin sulfate, chondroitin lyase I and II. Although one of the four proteins (Mr 110,000) was similar in molecular weight to the chondroitin lyases, the cross-adsorbed antiserum which detected this outer membrane protein did not cross-react with either of these two enzymes.     

Isoelectric points of membrane surfaces of three spinach chloroplast classes determined by cross-partition

The isoelectric points of the membranes surrounding three classes of spinach chloroplasts have been determined by partition at different pH values in aqueous two-phase systems where the electrical potential differences at the interface are opposite (cross-partition). Class I chloroplasts, intact chloroplasts, have an isoelectric point at pH 3.8–4.1 and class II chloroplasts, broken chloroplasts or intact thylakoid membranes, have an isoelectric point at pH 4.7–4.9. The third class of particles, class III ‘chloroplasts’, that contain one or more chloroplasts, mitochondria, peroxisomes and some cytoplasm all surrounded by a membrane, probably the plasma membrane, have an isoelectric point at pH 3.4–4.0. The partition technique used presumably yields the isoelectric point of the surface of the membranes exposed to the phase system by the three classes of chloroplasts, i.e., the outer envelope membrane, the thylakoid membrane and the plasma membrane, respectively. The isoelectric points obtained with this technique are suggested to reflect protein to charged-lipid differences in the composition of the membranes.     

The Caulobacter crescentus outer membrane protein Omp58 (RsaF) is not required for paracrystalline S-layer secretion

To identify the outer membrane protein component of the Caulobacter crescentus CB2 surface-layer export machinery we used the Serratia marcescens LipD protein to find homologs in the CB2 genome. From two homologous sequences found, one encodes a putative OMP with a predicted molecular mass of 57.5 kDa, termed Omp58 (formerly RsaF). Comparison of membrane protein profiles revealed a protein with an appropriate molecular mass present in wild-type, but not CB2 omp58::kanamycin, a mutant strain with an inactivated omp58 gene. Disruption of omp58 did not affect surface-layer production, suggesting that Omp58 is not involved in surface-layer protein secretion and, thus, may not be the outer membrane protein component of the C. crescentus surface-layer export system.     

Structural comparison of Neisseria gonorrhoeae outer membrane proteins.

Outer membranes from opaque colonia variants of Neisseria gonorrhoeae P9 contain a major outer membrane protein (protein I) together with one or more of a series of heat-modifiable proteins (proteins II). Proteins I. II, and IIa have been isolated by detergent extraction of outer membranes. Amino acid analysis showed proteins II and IIa to have a very similar composition. Cyanogen bromide cleavage of proteins II and IIa produced a pair of fragments with identical molecular weight and a pari which differed by an amount (0.5K) equivalent to the difference between the intact proteins. Tryptic peptide maps of 125I-labeled proteins II, IIa, and IIb showed many similarities, with only a few peptides unique to any one protein. Peptide maps of protein IIa from cells which had been surface labeled showed that the unique peptides were exposed on the surface. The heat-modifiable proteins thus appear to form a family of proteins with closely related structure probably differing in that part which is exposed on the bacterial surface.     

Separation and characterization of the outer membrane of Pseudomonas aeruginosa.

A method is described for the preparation of outer and cytoplasmic membranes of Pseudomonas aeruginosa, and the outer membrane proteins characterized. Isolated outer and cytoplasmic membranes differed markedly in the content of 2-keto-3-deoxyoctonate (lipopolysaccharide) and phospholipid as well as in the localization of certain enzymes (NADH oxidase, succinate dehydrogenase, D-lactate dehydrogenase, malate dehydrogenase, and phospholipase), and also in the microscopic morphology. The outer membrane preparation showed activity neutralizing a certain bacteriocin or bacteriophages, whereas the cytoplasmic membrane preparation showed no neutralizing activity. The protein composition of membrane preparations from five different strains of P. aeruginosa [P14, M92 (PAO1), PAC1, P15, and M2008 (PAT)] were determined by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. More than 50 protein bands were detected in the cytoplasmic membrane preparation. The protein compositions of outer membranes from the five different strains were very similar: at least 6 major bands were found (apparent molecular weights: Band D, 50,000; band E, 45,000; band F, 33,000; bands G and H, 21,000; and band I, 8,000). The protein composition of outer membranes was affected by some physiological growth conditions. Some features of major outer membrane proteins were also studied. Band F showed anomalous migration on SDS polyacrylamide gel electrophoresis depending on the solubilizing conditions or pretreatment with TCA. Band I seemed to be a protein analogous to the lipoprotein which had been found in the outer membrane of Escherichia coli.     

Expression in Caulobacter crescentus of the phosphate-starvation-inducible porin OprP of Pseudomonas aeruginosa

The gene for the phosphate-starvation-inducible outer membrane protein OprP, of Pseudomonas aeruginosa was introduced into Caulobacter crescentus CB2A on a plasmid vector. As is the case in P. aeruginosa and Escherichia coli the oprP gene was inducible under conditions of limiting phosphate in C. crescentus. However, the maximal medium concentration of phosphate which still permitted induction of OprP was lower in C. crescentus (50 microM) than in P. aeruginosa (200 microM). Induction of OprP was coincident with the process of stalk elongation, known to occur in C. crescentus under phosphate starvation conditions. When induced, OprP was localized to the cell envelope and became a major membrane protein, indicating that the Pseudomonas promoter was efficiently recognized in C. crescentus and that the gene product was targeted to the appropriate region of the cell. Our data provide support for the hypothesis that the mechanism for regulation of phosphate-starvation-inducible genes is highly conserved amongst the eubacteria.     

Mutations in genes cpxA and cpxB alter the protein composition of Escherichia coli inner and outer membranes.

Mutations in chromosomal genes cpxA and cpxB altered the protein composition of the inner and outer bacterial membranes. Electrophoretic analyses of membrane proteins from isogenic strains differing only at their cpx loci and of spontaneous cpxA+ revertants of a cpxA cpxB double mutant showed that the alterations define a pattern that is uniquely attributable to the cpx mutations. Two major outer membrane proteins, the OmpF matrix porin and the murein lipoprotein, were deficient or absent from the outer membrane of mutant cells, whereas the quantities of two other major outer membrane proteins, the OmpC matrix porin and the OmpA protein, were not significantly altered. The cpx mutations did not generally alter the functional or chemical properties of the cell envelope. In the electron microscope, mutant cells appeared ovoid, but individual cells showed no surface irregularities to suggest gross defects in the cell envelope. These observations suggest that the primary effect of the mutations is to alter selectively the synthesis or translocation of certain envelope proteins.     

Isolation and characterization of two outer membrane preparations from Escherichia coli

A method was developed for releasing specifically a part of outer membrane during spheroplast formation. A highly purified outer membrane (outer membrane I) was obtained from the spheroplast medium by isopycnic sucrose gradient centrifugation. The remaining outer membrane (outer membrane II) and cytoplasmic membrane was also isolated from the spheroplasts by the isopycnic centrifugation.Two outer membrane preparations were different from the cytoplasmic membrane in protein composition, enzyme localization, phospholipid composition, lipopolysaccharide content and electron micrographs. Although outer membranes I and II were almost the same in various respects, they seemed to be different from each other under electron microscope and in cardiolipin content. It is suggested that the outer membrane I and the outer membrane II, at least a part of the outer membrane II, are integrated in a different fashion in the outer-most layer of Escherichia coli cell surface.     

Biosynthesis of membrane proteins of Pseudomonas aeruginosa: effects of various antibiotics

The biosynthesis of membrane proteins of Pseudomonas aeruginosa was examined using various antibiotics (puromycin, streptomycin, chloramphenicol, tetracycline, and rifampin). Among six major membrane proteins separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the biosynthesis of two membrane proteins (proteins I and II) was found to be unusually resistant to these antibiotics. The biosynthesis of protein I (apparent molecular weight of 6,500) was completely resistant to puromycin, streptomycin, chloramphenicol, and tetracycline at conditions which severely inhibited the biosynthesis of all the other membrane proteins except for protein II. Under the same conditions, the biosynthesis of protein II (apparent molecular weight of 9,000) was also resistant to puromycin, streptomycin, and tetracycline, but was sensitive to chloramphenicol. The effect of rifampin on the biosynthesis of proteins I and II indicated that their messenger RNAs are extremely stable; their functional half-lives are 16 and 8 min for proteins I and II, respectively, in contrast with 2.0 and 3.5 min for the average half-lives of the cytoplasmic and membrane proteins, respectively. Protein II was identified as the lipoprotein of the outer membrane from its amino acid composition and mobility in gel electrophoresis. Protein I is a cytoplasmic membrane protein lacking histidine. From the content of arginine residues, the number of protein I molecules per cell was estimated to be as many as, and most likely more than, that of the lipoprotein (protein II). Therefore, protein I is the most abundant protein in P. aeruginosa.     

Outer cell envelope membrane and shape of Spirillum serpens.

“Ghosts” have been isolated from Spirillum serpens that are free of murein, are surrounded by a unit membrane (derived from the outer membrane of the cell envelope), have lost all intracellular material (except for some poly-β-hydroxybutyrate), and still maintain Spirillum's shape.The ghost membrane contains about 50% protein which is resolved by sodium dodecyl sulphate-polyacrylamide gel electrophoresis into three bands corresponding to apparent molecular weights between 21,000 and 40,000, and the major protein band I (40,000) consists of at least two (Ia and Ib) but not many more polypeptide chains. HP-layer protein (hexagonally packed surface protein) is absent. At least one of the latter polypeptide chains is required for the establishment of the long-range order apparent in ghosts since proteases degrade band I proteins and concomitantly destroy the ghost. The other polypeptides (II and III) do not appear to be required for maintenance of shape of the Spirillum ghost since their amounts can vary widely from preparation to preparation. Ghosts as well as cells can be cross-linked with dimethyl diimidoesters. Such ghosts proved to be cross-linked over their entire surface, and a covalently closed macromolecule of the size of the cell had been created. Under certain conditions of cross-linking these ghosts upon extraction with hot sodium dodecyl sulphate were pure protein. Ammonolysis of this material liberated band I protein.These findings strongly suggest that there is a rather dense packing of the protein in the ghost membrane, and proteins Ia and Ib may be arranged as repeating subunits in the sense that protein-protein interaction exists along the whole membrane. Several observations also suggest that the ghost membrane concerning the arrangement of these proteins does not represent a gross artifact regarding the outer cell envelope membrane. The possibility exists that the assembly of polypeptides Ia and Ib participates in the determination of cellular shape.     

Characterization of a Helical Morphological Mutant of Caulobacter crescentus

Screening of poorly growing colonies following EMS treatment of Caulobacter crescentus culture revealed several mutants with altered cell morphology. One of these (CB15-UW.5) grew as elongated, helically twisted cells which were more susceptible to autolysis than the wild type. The mutant cells were found to have higher transglycosylase activity, this being reflected by shorter chain length of their murein. A second difference between the murein of the mutant and the parent was lower trimer content in the former, although in both cases the degree of crosslinkage was similar.     

Light-induced dephosphorylation of two proteins in frog rod outer segments: influence of cyclic nucleotides and calcium

Two minor proteins of frog rod outer segments become phosphorylated when retinas are incubated in the dark with 32Pi. The proteins, designated component I (13,000 daltons) and component II (12,000 daltons), are dephosphorylated when retinas are illuminated. The dephosphorylation is reversible; the two proteins are rephosphorylated when illumination ceases. Each outer segment contains approximately 10(6( molecules of components I and II. These remain associated with both fragmented and intact outer segments but dissociate from the outer segment membranes under hypoosmotic conditions. The extent of the light-induced dephosphorylation increases with higher intensities of illumination and is maximal with continuous illumination which bleaches 5.0 x 10(5) rhodopsin molecules/outer segment per second. Light which bleaches 5.0 x 10(3) rhodopsin molecules/outer segment per second causes approximately half-maximal dephosphorylation. This same intermediate level of illumination causes half-suppression of the light-sensitive permeability mechanism in isolated outer segments (Brodie and Bownds. 1976. J. Gen Physiol. 68:1-11) and also induces a half-maximal decrease in their cyclic GMP content (Woodruff et al. 1977. J. Gen. Physiol. 69:667-679). The phosphorylation of components I and II is enhanced by the addition of cyclic GMP or cyclic AMP to either retinas or isolated rod outer segments maintained in the dark. Several pharmacological agents which influence cyclic GMP levels in outer segments, including calcium, cause similar effects on the phosphorylation of components I and II and outer segment permeability. Although the cyclic nucleotide-stimulated phosphorylation can be observed either in retinas or isolated rod outer segments, the light-induced dephosphorylation is observed only in intact retinas.