Ion channel formation by N-terminal domain: a common feature of OprFs of Pseudomonas and OmpA of Escherichia coli

The proteolytic fragments of OprFs of Pseudomonas aeruginosa and Pseudomonas fluorescens were identified, respectively, as the first 175 and 177 amino acids from the N-terminal domain. They induced ion channels after reincorporation into planar lipid bilayers (85 and 75 pS, respectively, in 1 M NaCl). A similar conductance value (72 pS) was found for the eight beta-strand OmpA N-terminal domain (OmpA171) of Escherichia coli. We conclude that the N-terminal domain of OprFs is sufficient to induce ion channels and the comparison with OmpA171, provides strong evidence of the existence of an eight-stranded beta-barrel in the N-terminal domain of OprFs.     

Channel-forming properties and structural homology of major outer membrane proteins from Pseudomonas fluorescens MFO and OE 28.3

Abstract The major outer membrane proteins (OprF) from Pseudomonas fluorescens MFO and OE 28.3 were purified by a new method involving native electrophoresis in octyl-polyoxyethylene media. Both proteins, characterized by the same size, heat-modifiability and N-terminal sequence were re-incorporated in virtually solvent-free planar lipid bilayers. They displayed very similar channel-forming properties: the major conductance level was between 250 pS and 270 pS in l M NaCl. From experiments of zero-current potential, both porins were determined weakly cation selective. Amplification by PCR and sequencing of the oprF gene of strain MFO allowed to point out 94% identity between the amino acid sequences of these two OprFs isolated from ecological niches as different as milk (strain MFO) and soil (strain OE 28.3).     

Expression and porin activity of P28 and OMP-1F during intracellular Ehrlichia chaffeensis development

Ehrlichia chaffeensis, an obligatory intracellular gram-negative bacterium, must take up various nutrients and metabolic compounds because it lacks many genes involved in metabolism. Nutrient uptake by a gram-negative bacterium occurs primarily through pores or channels in the bacterial outer membrane. Here we demonstrate that isolated E. chaffeensis outer membranes have porin activities, as determined by a proteoliposome swelling assay. The activity was partially blocked by an antibody that recognizes the two most abundant outer membrane proteins, P28/OMP-19 and OMP-1F/OMP-18. Both proteins were predicted to have structural features characteristic of porins, including 12 transmembrane segments comprised of amphipathic and antiparallel beta-strands. The sodium dodecyl sulfate stability of the two proteins was consistent with a beta-barrel structure. Isolated native P28 and OMP-1F exhibited porin activities, with pore sizes similar to and larger than, respectively, that of OprF, which is the porin with the largest pore size known to date. E. chaffeensis experiences temperature changes during transmission by ticks. During the intracellular development of E. chaffeensis, both P28 and OMP-1F were expressed mostly in the mid-exponential growth phase at 37 degrees C and the late-exponential growth phase at 28 degrees C. The porin activity of proteoliposomes reconstituted with proteins from the outer membrane fractions derived from bacteria in the mid- and late-exponential growth phases at 28 degrees C and 37 degrees C correlated with the expression levels of P28 and OMP-1F. These results imply that P28 and OMP-1F function as porins with large pore sizes, suggesting that the differential expression of these two proteins might regulate nutrient uptake during intracellular E. chaffeensis development at both temperatures.     

Pore size dependence on growth temperature is a common characteristic of the major outer membrane protein OprF in psychrotrophic and mesophilic Pseudomonas species

Pseudomonas species adapt well to hostile environments, which are often subjected to rapid variations. In these bacteria, the outer membrane plays an important role in the sensing of environmental conditions such as temperature. In previous studies, it has been shown that in the psychrotrophic strain P. fluorescens MF0, the major porin OprF changes its channel size according to the growth conditions and could affect outer membrane permeability. Studies of the channel-forming properties of OprFs from P. putida 01G3 and P. aeruginosa PAO1 in planar lipid bilayers generated similar results. The presence of a cysteine- or proline-rich cluster in the central linker region is not essential for channel size modulations. These findings suggest that OprF could adopt two alternative conformations in the outer membrane and that folding is thermoregulated. In contrast, no difference according to growth temperature was observed for structurally different outer membrane proteins, such as OprE3 from the Pseudomonas OprD family of specific porins. Our results are consistent with the fact that the decrease in channel size observed at low growth temperature is a particular feature of the OprF porin in various psychrotrophic and mesophilic Pseudomonas species isolated from diverse ecological niches. The ability to reduce outer membrane permeability at low growth temperature could provide these bacteria with adaptive advantages.     

Characterization of the outer membrane protein OprF of Pseudomonas aeruginosa in a lipopolysaccharide membrane by computer simulation

The N-terminal domain of outer membrane protein OprF of Pseudomonas aeruginosa forms a membrane spanning eight-stranded antiparallel beta-barrel domain that folds into a membrane channel with low conductance. The structure of this protein has been modeled after the crystal structure of the homologous protein OmpA of Escherichia coli. A number of molecular dynamics simulations have been carried out for the homology modeled structure of OprF in an explicit molecular model for the rough lipopolysaccharide (LPS) outer membrane of P. aeruginosa. The structural stability of the outer membrane model as a result of the strong electrostatic interactions compared with simple lipid bilayers is restricting both the conformational flexibility and the lateral diffusion of the porin in the membrane. Constricting side-chain interactions within the pore are similar to those found in reported simulations of the protein in a solvated lipid bilayer membrane. Because of the strong interactions between the loop regions of OprF and functional groups in the saccharide core of the LPS, the entrance to the channel from the extracellular space is widened compared with the lipid bilayer simulations in which the loops are extruding in the solvent. The specific electrostatic signature of the LPS membrane, which results in a net intrinsic dipole across the membrane, is found to be altered by the presence of OprF, resulting in a small electrically positive patch at the position of the channel.     

Roles of the Carboxy-Terminal Half of Pseudomonas aeruginosa Major Outer Membrane Protein OprF in Cell Shape, Growth in Low-Osmolarity Medium, and Peptidoglycan Association

OprF, the major outer membrane protein of Pseudomonas aeruginosa, is multifunctional in that it can act as a nonspecific porin, plays a role in the maintenance of cell shape, and is required for growth in a low-osmolarity environment. The latter two structural roles of OprF, and OprF’s association with the peptidoglycan, have been proposed to be localized in the carboxy terminus of the protein, based on this region’s similarity to members of the OmpA family of proteins. To determine if this is correct, we constructed a series of C-terminally truncated OprF derivatives and examined their effects on P. aeruginosa cell length and growth in low-osmolarity medium. While the C terminus of OprF was required for wild-type cell length and growth in low-osmolarity medium, expression of the N terminus (first 163 amino acids [aa]) also influenced these phenotypes (compared with OprF deficiency). The first 154 to 164 aa of OprF seemed required for stable protein expression, consistent with the existence of a β-barrel domain in the N terminus of OprF. Greater than 215 aa of the protein were required for strong peptidoglycan association, confirming that residues in the C-terminal end of OprF are required for peptidoglycan binding. OprF deficiency did not affect the in vivo growth of an OprF-deficient strain in a mouse chamber model. Collectively, these data suggest that the C terminus of OprF plays a role in cell length, growth of P. aeruginosa in low-osmolarity media (but not in vivo), and peptidoglycan association, while the N terminus has an influence on the first two characteristics and is additionally important for stable protein expression.     

Pore Size Dependence on Growth Temperature Is a Common Characteristic of the Major Outer Membrane Protein OprF in Psychrotrophic and Mesophilic Pseudomonas Species

Pseudomonas species adapt well to hostile environments, which are often subjected to rapid variations. In these bacteria, the outer membrane plays an important role in the sensing of environmental conditions such as temperature. In previous studies, it has been shown that in the psychrotrophic strain P. fluorescens MF0, the major porin OprF changes its channel size according to the growth conditions and could affect outer membrane permeability. Studies of the channel-forming properties of OprFs from P. putida 01G3 and P. aeruginosa PAO1 in planar lipid bilayers generated similar results. The presence of a cysteine- or proline-rich cluster in the central linker region is not essential for channel size modulations. These findings suggest that OprF could adopt two alternative conformations in the outer membrane and that folding is thermoregulated. In contrast, no difference according to growth temperature was observed for structurally different outer membrane proteins, such as OprE3 from the Pseudomonas OprD family of specific porins. Our results are consistent with the fact that the decrease in channel size observed at low growth temperature is a particular feature of the OprF porin in various psychrotrophic and mesophilic Pseudomonas species isolated from diverse ecological niches. The ability to reduce outer membrane permeability at low growth temperature could provide these bacteria with adaptive advantages.     

Plasticity of Escherichia coli porin channels. Dependence of their conductance on strain and lipid environment.

The conductance properties of three members of the porin family which form channels across the outer membrane of Gram-negative bacteria were compared. With their endogenous lipopolysaccharide (LPS) bound, the closely related porins F and C from Escherichia coli reveal significantly different conductance steps and closing potentials, with values of 0.82 nS (nanosiemens) and 89 mV for F-type channels, and 0.49 nS and 158 mV for C-type pores (1 M NaCl), respectively. On the basis of their closing potentials, the two channel types can be distinguished unequivocally. If reconstituted in asolectin and extraneous LPS, porin C forms F-type in addition to C-type channels. Substitution of asolectin by mitochondrial lipids yields the native C-type pores only. Both channel types can be induced to assume the mutually other channel configuration by variation of ionic strength. A multiplicity of channel subtypes is observed by variation of the pH of the medium. The three channels within a trimer are, however, consistently of the same type. Since structural studies have revealed a single channel per monomer, the several conductance steps observed are likely to reflect distinct configurations of the same channel. Best channel recoveries were observed if endogenous LPS remained associated to porin during purification. Significant yields could nevertheless be obtained also if LPS was removed from porin and replaced with various precursors or chemically synthesized analogues. As function requires the presence of glycolipids, yet crystallization is perturbed by heterodisperse endogenous LPS, the smallest monodisperse analogues yielding good channel recovery were determined. The minimal synthetic moiety is a monoglucosaminetetraacyl compound. The characteristics of porin B from E. coli BE are shown to be indistinguishable from those of porin F. The conductance properties of this porin, refolded from random coil configuration, are indistinguishable from those exhibited by native protein. The formation of channels is thus encoded by the sequence of the mature polypeptide alone.     

A Proteomic Approach to Understand the Role of the Outer Membrane Porins in the Organic Solvent-Tolerance of Pseudomonas aeruginosa PseA

Solvent-tolerant microbes have the unique ability to thrive in presence of organic solvents. The present study describes the effect of increasing hydrophobicity (log P_ow values) of organic solvents on the outer membrane proteome of the solvent-tolerant Pseudomonas aeruginosa PseA cells. The cells were grown in a medium containing 33% (v/v) alkanes of increasing log P_ow values. The outer membrane proteins were extracted by alkaline extraction from the late log phase cells and changes in the protein expression were studied by 2-D gel electrophoresis. Seven protein spots showed significant differential expression in the solvent exposed cells. The tryptic digest of the differentially regulated proteins were identified by LC-ESI MS/MS. The identity of these proteins matched with porins OprD, OprE, OprF, OprH, Opr86, LPS assembly protein and A-type flagellin. The reported pI values of these proteins were in the range of 4.94–8.67 and the molecular weights were in the range of 19.5–104.5 kDa. The results suggest significant down-regulation of the A-type flagellin, OprF and OprD and up-regulation of OprE, OprH, Opr86 and LPS assembly protein in presence of organic solvents. OprF and OprD are implicated in antibiotic uptake and outer membrane stability, whereas A-type flagellin confers motility and chemotaxis. Up-regulated OprE is an anaerobically-induced porin while Opr86 is responsible for transport of small molecules and assembly of the outer membrane proteins. Differential regulation of the above porins clearly indicates their role in adaptation to solvent exposure.     

Discovery of a novel channel-forming protein in the cell wall of the non-pathogenic Nocardia corynebacteroides

Detergent extracts of whole cells of the Gram-positive, non-pathogenic, strictly aerobic bacterium Nocardia corynebacteroides contain channel-forming activity. The protein responsible for channel formation was identified using lipid bilayer experiments. It was purified to homogeneity and had an apparent molecular mass of about 134 kDa on SDS-PAGE when it was solubilized at 40 degrees C. When the 134 kDa protein was heated to 100 degrees C for 10 min in sample buffer, it dissociated into subunits with a molecular mass of about 23 kDa and focused at pI of 4.5 during isoelectric focusing. The pure 134 kDa protein was able to increase the specific conductance of artificial lipid bilayer membranes from phosphatidylcholine-phosphatidylserine mixtures by the formation of ion-permeable channels. The channels had an average single-channel conductance of 5.5 nS in 1 M KCl and were found to be cation-selective. Asymmetric addition of the 134 kDa protein to lipid bilayer membranes resulted in an asymmetric voltage-dependence. The analysis of the single-channel conductance as a function of cation radii using the Renkin correction factor and the effect of negative charges on channel conductance suggested that the diameter of the cell wall porin is about 1.0 nm. The channel characteristics of the cell wall channel of N. corynebacteroides were compared with those of other members of the mycolata. They share common features because they are composed of small molecular mass subunits and form large and water-filled channels.     

Characterization of Two Pore-Forming Proteins Isolated from the Outer Membrane of Synechococcus PCC 6301

Two major proteins, A and B, were isolated and purified from outer membranes of the unicellular cyanobacterium Synechococcus PCC 6301 by gel filtration, anion-exchange chromatography, and preparative SDS-PAGE. Protein A revealed a single-channel conductance of 0.4 nanoSiemens (nS) in 1 M KCl, whereas preparations containing both proteins showed two different conductance maxima of 0.4 and 0.9 nS, suggesting that B also forms pores. The apparent molecular mass of the two closely migrating proteins was determined as 52 kDa, whereas native porin extracts revealed a relative molecular mass of ca. 140 kDa, indicating trimeric pore-forming units. Partial sequences of both proteins were obtained by N-terminal sequencing of tryptic peptides, and the C-terminal amino acid sequences were derived from the complete proteins. These sequences were aligned to protein sequences available in the databases. The results are discussed. Received: 22 August 1997 / Accepted: 1 October 1997     

Pseudomonas aeruginosa porin OprF exists in two different conformations

The major nonspecific porin of Pseudomonas aeruginosa, OprF, produces a large channel yet allows only a slow diffusion of various solutes. Here we provide an explanation of this apparent paradox. We first show, by introduction of tobacco etch virus protease cleavage site in the middle of OprF protein, that most of OprF population folds as a two-domain protein with an N-terminal beta-barrel domain and a C-terminal periplasmic domain rich in alpha-helices. However, sedimentation of unilamellar proteoliposomes through an iso-osmotic gradient showed that only about 5% of the OprF population produced open channels. Gel filtration showed that the open channel conformers tended to occur in oligomeric associations. Because the open channel conformer is likely to fold as a single domain protein with a large beta-barrel, we reasoned that residues near the C terminus may be exposed on cell surface in this conformer. Introduction of a cysteine residue at position 312 produced a functional mutant protein. By using bulky biotinylation reagents on intact cells, we showed that this cysteine residue was not exposed on cell surface in most of the OprF population. However, the minority OprF population that was biotinylated in such experiments was enriched for the conformer with pore-forming activity and had a 10-fold higher pore-forming specific activity than the bulk OprF population. Finally trypsin treatment, which preferentially cleaves the C-terminal domain of the two-domain conformer, did not affect the pore-forming activity of OprF nor did it digest the minority conformer whose residue 312 is exposed on cell surface.     

Phylogenetic relationships between environmental and clinical isolates of Pseudomonas fluorescens and related species deduced from 16S rRNA gene and OprF protein sequences

The major surface protein of the genus Pseudomonas, OprF, is a non-specific porin that plays an important role in maintenance of cell shape, in growth in a low osmolarity environment, and in adhesion to various supports. The objectives of our study were (i) to carry out a comparative analysis of phylogenies obtained from the OprF protein and from the 16S rRNA gene in 41 isolates from various sources (water, soil, milk and the hospital) and (ii) to investigate the physiological characteristics correlated with the phylogeny of OprF. We report here an important incongruence between the phylogenies of the 16S rRNA gene and the OprF protein. Phylogenetic analysis of 16S rRNA genes grouped Pseudomonas fluorescens isolates into one cluster (termed fluorescens r-cluster) whilst the phylogeny of the OprF protein divided Pseudomonas fluorescens isolates into two quite distinct clusters (termed fluorescens 1 o-cluster and fluorescens 2 o-cluster) that may be related to the original habitat of the strain. The fluorescens 1 o-cluster contained the majority of non-rhizospheric soil isolates, while the fluorescens 2 o-cluster contained all our clinical isolates and most of the rhizospheric isolates (which are fixed to the roots). In order to check this correlation, we studied two physiological characteristics: the range of growth temperature and the capacity for non-specific adhesion to polystyrene. The temperature range study for strains did not explain the existence of the two o-clusters but it did confirm the capacity of certain P. fluorescens strains to grow at 37 degrees C. The adhesion capacities of the isolates in the two o-clusters seems to be correlated with ecological niche.     

The cell wall porin of Nocardia farcinica: biochemical identification of the channel-forming protein and biophysical characterization of the channel properties

A channel-forming protein was identified in cell wall extracts of the Gram-positive, strictly aerobic bacterium Nocardia farcinica . The cell wall porin was purified to homogeneity and had an apparent molecular mass of about 87 kDa on tricine-containing SDS–PAGE. When the 87 kDa protein was boiled for a longer time in sodium dodecylsulphate (SDS) it dissociated into two subunits with molecular masses of about 19 and 23 kDa. The 87 kDa form of the protein was able to increase the specific conductance of artificial lipid bilayer membranes from phosphatidylcholine (PC) phosphatidylserine (PS) mixtures by the formation of ion-permeable channels. The channels had on average a single-channel conductance of 3.0 nS in 1 M KCl, 10 mM Tris-HCl, pH 8, and were found to be cation selective. Asymmetric addition of the cell wall porin to lipid bilayer membranes resulted in an asymmetric voltage dependence. The single-channel conductance was only moderately dependent on the bulk aqueous KCl concentration, which indicated point charge effects on the channel properties. The analysis of the single-channel conductance data in different salt solutions using the Renkin correction factor, and the effect of negative charges on channel conductance suggested that the diameter of the cell wall porin is about 1.4–1.6 nm. Channel-forming properties of the cell wall porin of N. farcinica were compared with those of mycobacteria and corynebacteria. The cell wall porins of these members of the order Actinomycetales share common features because they form large and water-filled channels that contain negative point charges.     

Refolding kinetics of pig muscle and yeast 3-phosphoglycerate kinases and of their proteolytic fragments.

The time course of refolding of both pig muscle and yeast 3-phosphoglycerate kinase (molecular masses about 47 kDa), as well as their proteolytic C-terminal fragments (30 and 33 kDa, respectively) has been investigated. Very similar refolding kinetics (with half-time between 80-120 s, at 20 degrees C) were observed by fluorescence and ultraviolet absorbance spectroscopy, as well as by activity measurements, for the intact enzyme from both sources. This time course appears not to depend on the time the protein spends in the unfolded state, i.e. it is certainly not controlled by proline isomerization. Furthermore, after removal of a large N-terminal part (molecular mass of about 18 kDa for pig muscle enzyme or 13 kDa for yeast enzyme) of the molecule by proteolysis, refolding of the remaining C-terminal fragment of both proteins follows kinetics virtually indistinguishable from those of the intact protein molecule.     

Biochemical characterization and crystallization of porin from Rhodopseudomonas blastica

Oligomeric porin of the phototrophic bacterium Rhodopseudomonas blastica DSM 2131 was obtained from cell envelopes by differential temperature extraction in the presence of detergent and salt. The isolated porin exhibited strong porin activity after reconstitution into lipid bilayer membranes. The effective channel diameter for the trimer was estimated as 1.5 nm from single channel conductance measurements in the presence of 1 M KCl. Moderate cation-selectivity was observed. Oligomeric porin migrated as a single band (apparent molecular weight 81 kDa) on sodium dodecyl sulfate polyacrylamide gelelectrophoresis when solubilized below 70 °C. The oligomers were converted into monomers on heating to 70 °C or above forming two bands with apparent molecular weight of 36 kDa and 35 kDa. The oligomer was not sensitive to EDTA. Its molecular weight was determined to be 119.3 kDa by analytical ultracentrifugation. The isoelectric point was 5.7. Circular dichroism data indicated a high content of -sheet structure. Gasphase sequencing of the N-terminal residues revealed the sequence: NH₂-Glu-Ile-Ser-Leu-Asn-Gly-Tyr-Gly-Arg-Phe. Crystals with a maximal side length of 300 m and diffracting to 0.32 nm resolution were obtained with the porin oligomer in the presence of C8E4 and 1,2,3-heptanetriol by using the vapor phase equilibration technique.Abbreviations C8E4 n-octyl tetraoxyethylene - M_r apparent molecular weight - Octyl-POE n-octyl polyoxyethylene - LDAO N,N-dimethyl dodecyl aminoxide - LPS lipopolysaccharide - PAGE polyacrylamide gel-electrophoresis - PEG polyethylene glycol     

Properties of the porin of Haemophilus influenzae type b in planar lipid bilayer membranes

The major outer membrane protein (40 kDa) of the bacterium Haemophilus influenzae type b is a porin which forms transmembrane permeability channels. It has an exclusion limit for oligosaccharides of about 1.4 kDa. When this protein was added to the aqueous phase which was bathing a planar lipid bilayer, it caused the conductance of the membrane to increase by several orders of magnitude. At low protein concentrations (2-10 pM), the conductance of the membrane increased in a stepwise fashion with an average single-channel conductance of 1.1 nS in 1 M KCl. Single-channel experiments were performed with a variety of different salts. The conductance of single channels was proportional to the specific conductance of the aqueous solution which was bathing the membrane. Current through the pores was proportional to the applied voltage, indicating that these pores are not voltage-controlled. The 40 kDa porin was very slightly cation-selective: the pores were about 1.6-times more permeable to potassium ions than to chloride ions. These properties of the 40 kDa porin are those of large water-filled channels and are characteristic of most bacterial porins. The single-channel conductance of the porin is, however, much smaller than might be expected from its exclusion limit. A model is proposed which could explain the differences in apparent pore size.     

Characterization of the mitochondrial porin from Drosophila melanogaster

Mitochondrial porin was isolated from the fruit fly Drosophila melanogaster at different developmental stages, starting from whole mitochondria. The porin from adults' mitochondria was fully characterized. The protein had a molecular mass of 31 kDa as judged from sodium dodecylsulfate electrophoretograms. It was very resistive against digestion with V8 proteinase of Staphylococcus aureus and a larger number of fragments were only obtained after digestion with papain. Drosophila porin showed little interaction with antibodies raised against mitochondrial porins from mammalia and Neurospora crassa, but a strong reactivity with antibodies raised against yeast porin. Reconstitution experiments with planar lipid bilayer membranes showed that the protein was able to form ion-permeable pores with a single-channel conductance of 0.41 nS in 0.1 M KCl. At low transmembrane voltages Drosophila porin had the properties of a general diffusion pore with an estimated effective diameter of about 1.7 nm and a small selectivity for anions over cations. Voltages larger than 20 to 30 mV resulted in a closure of the pore. The closed states of the pore were found to be cation-selective. The addition of a synthetic polyanion to the aqueous phase on one side of the membrane resulted in an asymmetric shift of the voltage dependence and the pore became already closed at very small voltages negative at the cis-side (the side of the addition of the polyanion).     

Isolation and preliminary characterization of wild-type OmpC porin dimers from Escherichia coli K-12

Escherichia coli K-12 strain PLB3255 contains a mutation in the ompF gene that results in a 15 amino acid deletion in the porin protein. The mutation (dex) appears to increase the OmpF channel size, allowing the PLB3255 cells to grow on maltodextrins in the absence of a functional maltoporin. Porin isolated from strain PLB3255, which contains a wild-type ompC gene, was separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and shown to contain 50-60% trimer aggregates and 35-40% of a 50-kDa "dimer". When the porin isolate was heated to 100 degrees C and separated on SDS gels containing 8 M urea, both the trimer and the "dimer" were recovered in a single band at 36 kDa that corresponded in mobility to wild-type OmpC porin. An analysis of the temperature stability of the isolate showed that the OmpC "dimer" was less stable and denatured at 66 degrees C compared to 81 degrees C for the trimer. To separate these aggregates, the unheated porin was suspended in 30% SDS, applied to a Sephadex G-200 gel filtration column, and eluted with 0.5% sodium deoxycholate. Two peaks were recovered containing separated trimers and "dimers". Circular dichroism spectra of isolated dimers and trimers indicated similar amounts of beta-structure. The isolated dimers and trimers were reconstituted into artificial membranes. Electrical conductance across planar bilayer lipid membranes and liposome swelling assays showed that the two isolates had similar channel-forming activity. Four other ompF deletion mutants of the same phenotype were also shown to produce 50-kDa OmpC porin "dimers".(ABSTRACT TRUNCATED AT 250 WORDS)     

Incomplete refolding of a fragment of the N-terminal domain of pig muscle 3-phosphoglycerate kinase that lacks a subdomain. Comparison with refolding of the complementary C-terminal fragment.

Refolding of pig muscle 3-phosphoglycerate kinase (PGK) from a mixture of its complementary proteolytic fragments that did not correspond to the individual domains resulted in a high degree of reactivation [Vas, M., Sinev, M.A., Kotova, N. & Semisotnov, G.V. (1990) Eur. J. Biochem. 189, 575--579]. An independent refolding of the 27.7 kDa C-terminal proteolytic fragment (which encompasses the whole C domain) has been noted, but the refolding ability of the 16.8-kDa N-terminal proteolytic fragment, which lacks a single subdomain from the N domain, remained to be seen. Here the refolding processes of the isolated fragments are compared. Within the first few seconds of initiation of refolding, pulse-proteolysis experiments show the formation of a structure with moderate protease resistance for both fragments. This structure, however, remains unchanged upon further incubation of the N-terminal fragment, whereas refolding of the C-terminal fragment continues as detected by a further increase in proteolytic resistance. The non-native character of the folding intermediate of the N fragment is indicated by the elevated fluorescence intensity of the bound hydrophobic probe 8-anilino-1-naphtalene sulphonate. Its CD spectrum shows the formation of secondary structure distinct from the native one. The noncooperative phase-transition observed in microcalorimetry indicates the absence of a rigid tertiary structure, in contrast with the refolded C-terminal fragment for which a cooperative transition is seen. Size-exclusion chromatography supported the globular character of the intermediate, and showed its propensity to form dimers. No binding of the substrate, 3-phosphoglycerate (3-PGri), to the isolated N-terminal fragment, could be detected but the presence of the complementary C-terminal fragment led to restoration of the substrate binding ability of the N domain. Thus, refolding of the isolated N-terminal fragment yields a highly flexible, globular, potentially productive intermediate with non-native secondary structure and highly exposed hydrophobic clusters, which favour dimerization.