Escherichia coli K-12 F? mutants that form mating aggregates but form transconjugants with low frequencies

Summary We have isolated Escherichia coli F^– mutants which, when mated with either Hfr or F, can form stable mating aggregates well but produce transconjugants with reduced frequencies. Selection procedure and other tests rule out the possibility that they are Rec^– strains. These mutants can be classified into two types: type I mutants can induce conjugal DNA replication in the donor, yet form transconjugants poorly; whereas, type II mutants induce conjugal DNA replication with poor efficiencies in the donor. Further tests indicate that type I mutants are very sensitive to lethal zygosis and their membranes, both inner and outer, show alterations in protein composition, whereas type II mutants are insensitive to lethal zygosis, and have an obvious alteration in the protein composition of their outer membrane. These results suggest that type I is defective in transconjugant formation primarily due to a change in the inner membrane, whereas type II is defective in generating a mating signal, which induces donor conjugal DNA replication, due to an alteration in the outer membrane.     

Dissection of functional domains in phage fd adsorption protein. Discrimination between attachment and penetration sites

We constructed a set of deletion mutants in the attachment protein of phage fd. These mutants lack sequences coding for sections in the amino-terminal half. All the mutants that comprise a leader sequence are incorporated into phage particles. Our data strongly suggest a bipartite organization of the amino-terminal domain with (1) a region for receptor recognition and (2) a region that is necessary for penetration of the DNA into the host cell. These regions were mapped. Some evidence suggesting different roles for gene 3 protein in penetration of the outer and inner membrane are discussed. We demonstrate that the phenotypes caused by gene 3 protein in host cells can be subdivided into two groups with different sequence requirements: (1) phenotypes related to outer membrane disturbance; and (2) phenotypes related to the tolQRA transport system.     

Ferric citrate transport in Escherichia coli requires outer membrane receptor protein fecA.

Mutants of Escherichia coli K-12 AB2847 and of E. coli K-12 AN92 were isolated which were unable to grow on ferric citrate as the sole iron source. Of 22 mutants, 6 lacked an outer membrane protein, designated FecA protein, which was expressed by growing cells in the presence of 1 mM citrate. Outer membranes showed an enhanced binding of radioactive iron, supplied as a citrate complex, depending on the amount of FecA protein. The FecA protein was the most resistant of the proteins involved in ferric irion iron translocation across the outer membrane (FhuA = TonA, FepA, Cir, or 83K proteins) to the action of pronase P. It is also shown that previously isolated fec mutants (G. C. Woodrow et al., J. Bacteriol. 133:1524-1526, 1978) which are cotransducible with argF all lack the FecA protein. They were termed fecA to distinguish them from the other ferric citrate transport mutants, now designated fecB, which mapped in the same gene region at 7 min but were not cotransducible with ArgF. E. coli W83-24 and Salmonella typhimurium, which are devoid of a citrate-dependent iron transport system, lacked the FecA protein. It is proposed that the FecA protein participates in the transport of ferric citrate.     

Plasmid mediated alterations in composition and structure of envelopes of Escherichia coli B/r

Seven transmissible (Tra⁺), antibiotic resistance (r) plasmids, which confer sensitivity to the filamentous bacteriophage IKe on an Escherichia coli B/r strain harboring them, have been examined for the changes they evoke in the host cell membranes. The plasmids rR48and rR269, like rRM98 [1], cause a significant reduction in the density of the outer membrane and the virtual elimination of its 36 500 dalton protein. These 2 properties do not appear to be altered when rR45, rR199 or rR205 are the resident plasmids. No changes in the inner membrane proteins are seen in any of these strains. In the case of the rR46-bearing strain, the density of the outer membrane is increased and the level of the 36 500 dalton protein is unaltered; in addition, several changes in both inner and outer membrane proteins are seen. Spontaneous IKe resistant mutants isolated from strains lacking the 36 500 dalton protein are either Tra⁺ or Tra^?. Since most of them also lack this protein, the latter is not important to the expression of inter-bacterial gene transfer and IKe sensitivity.On freeze fracture, strains lacking the 36 500 dalton protein cleave almost exclusively within the outer membrane. The plasmidless host and the remaining plasmid-bearing strains show a strong fracture plane within the cytoplasmic membrane. Despite the fact that most of the plasmid-bearing strains used are proficient in effecting interbacterial plasmid transfer, no morphological differences which can be correlated with this function have been observed between their etched cell surfaces and that of the plasmidless host.     

Mutational change of membrane architecture. Mutants of Escherichia coli K12 missing major proteins of the outer cell envelope membrane

Mutant of Escherichia coli have been analyzed which miss two of the major proteins of the outer cell envelope membrane. The two proteins I and II1, normally are present at high concentrations (about 10⁵ copies per cell).In such mutants, as compared with wild type, the phospholipid-to-protein ratio in the outer membrane has increased by a factor of 2.3 causing a considerable difference in density between wild type and mutant membranes. The concentrations of two other major components of the outer membrane, lipopolysaccharide and Braun's lipoprotein, did not change.The protein-deficient mutants do not exhibit gross functional defects in vitro. An increased sensitivity to EDTA and a slight such increase to dodecyl sulfate (but not to deoxycholate or Triton X-100) was observed, loss of so-called periplasmic enzymes was not found, and other differences to wild type are marginal. The mutants can grow with normal morphology. It is not possible, however, to prepare “ghosts” (particles of size and shape of the cell without murein, surrounded by a derivative of the outer membrane, and posssessing the major proteins of this membrane) from them. This fact confirms our earlier suggestion that the proteins in question are required for the shape maintenance phenomenon in ghosts, and the mutants reject the speculation that these proteins are involved in the expression of the genetic information specifying cellular shape.Freeze-fracturing showed that in mutant cells, and in sharp contrast to wild type, the far predominant fracture plane is within the outer membrane. The concentration of the well known densely packed particles at the outer, concave leaflet of this fracture plane is greatly reduced. It was not possible, however, to clearly establish that one or the other protein is part of these particles because these ultrastructural differences were not apparent in mutants missing either one of the proteins only. The biochemical and ultrastructural data allow the conclusion that the loss of two major proteins and the concomitant increase of phospholipid concentration has changed the architecture of the outer membrane from a highly oriented structure. with a large fraction of protein-protein interaction, to one predominantly exhibiting planar lipid bilayer characteristics. E. coli thus can assemble rather different outer membranes, afact excluding that outer membrane formatin constitutes a highly ordered or strictly sequential assembly-line process.     

Eyespot-assembly mutants in Chlamydomonas reinhardtii.

Chlamydomonas reinhardtii is a single-celled green alga that phototaxes toward light by means of a light-sensitive organelle, the eyespot. The eyespot is composed of photoreceptor and Ca(++)-channel signal transduction components in the plasma membrane of the cell and reflective carotenoid pigment layers in an underlying region of the large chloroplast. To identify components important for the positioning and assembly of a functional eyespot, a large collection of nonphototactic mutants was screened for those with aberrant pigment spots. Four loci were identified. eye2 and eye3 mutants have no pigmented eyespots. min1 mutants have smaller than wild-type eyespots. mlt1(ptx4) mutants have multiple eyespots. The MIN1, MLT1(PTX4), and EYE2 loci are closely linked to each other; EYE3 is unlinked to the other three loci. The eye2 and eye3 mutants are epistatic to min1 and mlt1 mutations; all double mutants are eyeless. min1 mlt1 double mutants have a synthetic phenotype; they are eyeless or have very small, misplaced eyespots. Ultrastructural studies revealed that the min1 mutants are defective in the physical connection between the plasma membrane and the chloroplast envelope membranes in the region of the pigment granules. Characterization of these four loci will provide a beginning for the understanding of eyespot assembly and localization in the cell.     

Cell-cell interactions in conjugating Escherichia coli: Con? mutants and stabilization of mating aggregates

Summary Conjugation-deficient (Con^-) mutants of Escherichia coli K-12 have been previously described which were defective in recipient ability. Such Con^- mutants were obtained from several laboratories and retested by a standardized set of procedures. Many of the mutants did not satisfy minimal criteria for conjugation-deficiency and were discarded. The remaining mutants included 11 ConF^- mutants mutated in or near the ompA cistron, 3 ConF^- mutants synthesizing a heptose-deficient lipopolysaccharide and 1 ConI^- mutants synthesizing a defective lipopolysaccharide. This set of mutants was tested for resistance to a variety of bacteriophages and colicins; the only phenotype fully correlated with the ConF^- phenotype was that of resistance to colicin L. No simple correlation existed between the protein profile (on SDS polyacrylamide gel electrophoresis) of cell envelope outer membrane preparations and conjugation deficiency. However, many ConF^- mutants did not synthesize detectable levels of outer membrane protein II^* and protein II^* may have been nonfunctional in the remainder. All the ConF^- mutants were conjugation-deficient when matings were conducted in liquid but (with one exception) were conjugation-proficient on the surfaces of membrane filters. None of the ConF^- mutants formed stable mating aggregates in liquid with (Flac)⁺ donor cells although all bound purified F pili. The ConF^- phenotype associated with a II^*-deficient recipient could be mimicked by the addition of purified protein II^* (solubilized with lipopolysaccharide). In both cases, the formation of stable mating aggregates (analyzed with an improved Coulter counter technique) was inhibited whereas unstable mating aggregates were detected by electron microscopy. F pilus and wall to wall contacts were both observed under these conditions by electron microscopy. These results were used to define a stage in F-promoted conjugation, the stabilization stage, which requires the functional interaction of protein II^* and lipopolysaccharide in the outer membrane of the recipient cell.     

Chromosomal location and expression of the structural gene for major outer membrane protein Ia of Escherichia coli K-12 and of the homologous gene of Salmonella typhimurium.

The gene determining the structure of a major outer membrane protein of Escherichia coli, protein Ia, has been located between serC and pyrD, at the min 21 region of the linkage map. This is based on the isolation and characterization of E. coli-Salmonella typhimurium intergeneric hybrids as well as analyses of a mutation (ompF2) affecting the formation of protein Ia. When the serC region of the S. typhimurium chromosome was transduced by phage P1 into E. coli, two classes of transductants were obtained; one produced protein Ia like the parental strain of E. coli, whereas the other produced not protein Ia but a pair of outer membrane proteins structurally related to 35K protein, one of the major outer membrane proteins of S. typhimurium. Furthermore, a strain of S. typhimurium harboring an F' plasmid which carries the ompF region of the E. coli chromosome was found to produce a protein indistinguishable from protein Ia, beside the outer membrane proteins characteristic to the parental Salmonella strain. These results suggest that the structural genes for protein Ia (E. coli) and for 35K protein (S. typhimurium) are homologous to each other and are located at the ompF region of the respective chromosome. The bearing of these findings on the genetic control of protein Ia formation is discussed.     

Fuctional organization of the outer membrane of escherichia coli: Phage and colicin receptors as components of iron uptake systems

The functional interaction of outer memberane proteins of E. coli can be studied using phage and colicin receptors which are essential components of penetration systems. The uptake of ferric iron in the form of the ferrichrome complex requires the ton A and ton B functions in the outer membrane of E. coli. The ton A gene product is the receptor protein for phage T5 and is required together with the ton B function by the phages T1 anf ?80 to infect cells and by colicin M and the antibiotic albomycin, a structural analogue of ferrichrome, to kill cells. The ton B function is necessary for the uptake of ferric iron complexed by citrate. Iron complexed by enterochelin is only transported in the presence of the ton B and feu functions. Cells which have lost the feu function are resistant to the colicins B, I or V while ton B mutants are resistant to all colicins. The interaction of the ton A, Ton B, and feu functions apparently permits quite different “substrates” to overcome the permeablility barrier of the outer membrane. It was shown for ferrichrome dependent iron uptake that the complexing agent was not altered and could be used repeatedly. Only very low amounts of ³H-labeled ferrichrome were found in the cell. It is possible that the iron is mobilized in the membrane and that desferriferrichrome is released into the medium without having entered the cytoplasm. Growth on ferrichrome as the sole iron source waw used to select revertants of T5 resistant ton A mutants. All revertants exhibited wild-type properties with the exception of partial revertants. In these 4 strains, as in the ton A mutants, the ton A protein was not detectable by SDS polyacrylamide gel electrophoreses of outer membranes. Albomycin resistant mutants were selected and shown to fall into 5 categories: (1) ton A; (2) ton B mutants; (3) mutants with no iron transport defects and normal ton A/ton B functions, which might be target site mutants; (4) mutants which were deficient in ferrichrome-mediated iron uptake but had normal ton A/ton B functions. We tentatively consider that the defect might be located in the active transport system of the cytoplasmic membrane; (5) a variety of mutants with the following general properties: most of them were resistant to colicin M, transported iron poorly, and, like ton B mutants, contained additional proteins in the outer membrane. The outer membrane protein patterns of wild-type and ton B mutant strains were compared by slab gel electrophoresis in an attempt to identify a ton B protein. It was observed that under most growth conditions, ton B mutants overproduced 3 proteins of molecular weights 74,000–83,000. In extracted, iron-deficient medium, both the wild-type and ton B mutant strains had similar large amounts of these proteins in their outer membranes. The appearance of these proteins was suppressed by excess iron in both wild-type and mutant. From this evidence it is apparent that the proteins appear as a response to low intracellular iron rather than being controlled by the ton B gene. The nature of these proteins and their possible role in iron transport is disussed.     

The relationship of protein and lipid synthesis during the biogenesis of mitochondrial membranes

Summary Rat liver mitochondria were fractionated into inner and outer membrane components at various times after the intravenous injection of¹⁴C-leucine or¹⁴C-glycerol. The time curves of protein and lecithin labeling were similar in the intact mitochondria, the outer membrane fraction, and the inner membrane fraction. In rat liver slices also, the kinetics of³H-phenylalanine incorporation into mitochondrial KCl-insoluble proteins was identical to that of¹⁴C-glycerol incorporation into mitochondrial lecithin. These results suggest a simultaneous assembly of protein and lecithin during membrane biogenesisThe proteins and lecithin of the outer membrane were maximally labeledin vivo within 5 min after injection of the radioactive precursors, whereas the insoluble proteins and lecithin of the inner membrane reached a maximum specific acitivity 10 min after injection.Phospholipid incorporation into mitochondria of rat liver slices was not affected when protein synthesis was blocked by cycloheximide, puromycin, or actinomycin D. The injection of cycloheximide 3 to 30 min prior to¹⁴C-choline did not affect thein vivo incorporation of lecithin into the mitochondrial inner or outer membranes; however treatment with the drug for 60 min prior to¹⁴C-choline resulted in a decrease in lecithin labeling. These results suggest that phospholipid incorporation into membranes may be regulated by the amount of newly synthesized protein available.When mitochondria and microsomes containing labeled phospholipids were incubated with the opposite unlabeled fractionin vitro, a rapid exchange of phospholipid between the microsomes and the outer membrane occurred. A slight exchange with the inner membrane was observed.     

TraT lipoprotein, a plasmid-specified mediator of interactions between gram-negative bacteria and their environment.

The TraT protein is a cell-surface-exposed, outer membrane lipoprotein specified by large, usually conjugative, F-like plasmids. Two biological activities have been associated with the protein: (i) prevention of self-mating of cells carrying identical or closely related conjugative plasmids, by blocking the formation of stable mating aggregates; and (ii) resistance to the bactericidal activities of serum, possibly by inhibiting the correct assembly or efficient functioning of the terminal membrane attack complex of complement. The protein therefore interacts not only with components of the outer membrane but also with specific external agents. In conjugative plasmids the traT gene lies within the region necessary for the conjugal transfer of DNA (tra), although its expression is not necessarily dependent on the expression of other tra genes. Recently, however, the gene has been discovered in isolation from other tra genes in nonconjugative virulence-associated plasmids, providing further evidence that the TraT protein may have a role in pathogenesis. The nucleotide sequences of several traT genes have been determined, and comparison of the corresponding amino acid sequences suggests that a central region of five amino acid residues flanked by hydrophobic domains determines the specificity of the protein in surface exclusion. Additionally, studies of mutants with different amino acid alterations within the hydrophobic domains have shown that insertion of charged residues disrupts normal outer membrane integrity. This review considers our current knowledge of the distribution, structure, and biological role(s) of the protein. Recent applications of the protein in studies of the unusual permeability properties of the outer membrane and for the transport of foreign antigenic determinants to the bacterial cell surface are also discussed.     

Internal deletions in the FhuA receptor of Escherichia coli K-12 define domains of ligand interactions.

The ferrichrome-iron receptor encoded by the fhuA gene of Escherichia coli K-12 is a multifunctional outer membrane receptor required for the binding and uptake of ferrichrome and bacteriophages T5, T1, phi 80, and UC-1 as well as colicin M. To identify domains of the protein which are important for FhuA activities, a library of 31 overlapping deletion mutants in the fhuA gene was generated. Export of FhuA deletion proteins to the outer membrane and receptor functions of the deletion proteins were analyzed. All but three of the deletion mutant FhuA proteins cofractionated with the outer membrane; no FhuA proteins were detected in outer membrane preparations or in cell extracts when the deletions spanned amino acids 418 to 440. Most deletion proteins were susceptible to cleavage by endogenous proteolytic activity; some degradation products were detected on Coomassie blue-stained gels and on Western blots (immunoblots). Receptor functions were measured with the mutated genes present on multicopy plasmids. Two deletion mutants, FhuA delta 060-069 and FhuA delta 129-168, conferred wild-type phenotypes: they demonstrated growth promotion by ferrichrome and the same efficiency of plating of bacteriophages as that of wild-type FhuA; killing by colicin M was also unaffected. For FhuA delta 021-128 and FhuA delta 406-417, reduced sensitivity to colicin M was detected; wild-type phenotypes were observed for all other FhuA functions. Deletions from amino acids 169 to 195 slightly reduced sensitivities to bacteriophages and to colicin M; ferrichrome growth promotion was unaffected. When deletions extended into the region of amino acids 196 to 405, all FhuA functions were either reduced or abolished. The results indicate that selected regions of the FhuA protein have receptor activities and demonstrate the presence of both shared and unique ligand-responsive domains.     

Insertion of newly synthesized proteins into the outer membrane of Escherichia coli

The insertion of newly synthesized proteins into the outer membrane of Escherichia coli has been examined. The results show that there is no precursor pool of outer membrane proteins in the cytoplasmic membrane because first, the incorporation of a [³⁵S]methionine pulse into outer membrane proteins completely parallels its incorporation into cytoplasmic membrane proteins, and second, under optimal isolation conditions, no outer membrane proteins are found in the cytoplasmic membrane, even when the membranes are analysed after being labeled for only 15 s.The [³⁵S]methionine present in the outer membrane after a pulse of 15 s was found in protein fragments of varying sizes rather than in specific outer membrane proteins. This label could however be chased into specific proteins within 30–120 s, depending on the size of the protein, indicating that although unfinished protein fragments were present in the outer membrane, they were completed by subsequent chain elongation.Thus, outer membrane proteins are inserted into the outer membrane while still attached to ribosomes. Since ribosomes which are linked to the cell envelope by nascent polypeptide chains are stationary, the mRNA which is being translated by these ribosomes moves along the inner cell surface.     

Ultrastructure of the outer membrane of Salmonella typhimurium bacteriocin-resistant mutants deficient in the 33K protein.

Outer membrane mutants of Salmonella typhimurium deficient in one, two, or three of the 33,000-dalton (33K), 34K, and 36K outer membrane proteins (7) were studied by using thin sectioning and freeze-fracturing electron microscopy techniques. The outer concave fracture face of all mutants deficient in the 33K protein had numerous particleless patches. In contrast to all previously examined 34K to 36K-deficient mutants, the 33K-deficient mutants showed marked heterogeneity in the size and distribution of such "empty" patches between cells of a culture. One mutant was deficient in both the 33K and the 34K to 36K "porin" protein complex; its outer membrane had very large particleless smooth areas. It is concluded that the 33K protein on one hand and the porin on the other are both able to form intramembraneous particles.     

Targeting and Import Mechanism of Coiled-coil Helix Coiled-coil Helix Domain-containing Protein 3 (ChChd3) into the Mitochondrial Intermembrane Space

Coiled-coil helix coiled-coil helix domain-containing protein 3 (ChChd3) is a mitochondrial inner membrane (IM) protein facing toward the intermembrane space (IMS). In the IMS, ChChd3 complexes with multiple proteins at the crista junctions and contact sites and plays a key role in maintaining crista integrity. ChChd3 is myristoylated at the N terminus and has a CHCH domain with twin CX₉C motifs at its C terminus. The CHCH domain proteins are traditionally imported and trapped in the IMS by using a disulfide relay system mediated by Mia40 and Erv1. In this study, we systematically analyzed the role of the myristoylation and the CHCH domain in the import and mitochondrial localization of ChChd3. Based on our results, we predict that myristoylation promotes binding of ChChd3 to the outer membrane and that the CHCH domain translocates the protein across the outer membrane. By analysis of the CHCH domain cysteine mutants, we further show that they have distinct roles in binding to Mia40 in the IMS and proper folding of the protein. The transient disulfide-bonded intermediate with Mia40 is formed preferentially between the second cysteine in helix 1, Cys¹⁹³, and the active site cysteine in Mia40, Cys⁵⁵. Although each of the four cysteines is essential for folding of the protein and binding to mitofilin and Sam50, they are not involved in import. Together our results indicate that both the myristoylation and the CHCH domain are essential for the import and mitochondrial localization of ChChd3. Once imported, ChChd3 binds to Mia40 for further folding and assembly into macromolecular complexes.     

The TolA-recognition site of colicin N. ITC, SPR and stopped-flow fluorescence define a crucial 27-residue segment

Colicins translocate across the Escherichia coli outer membrane and periplasm by interacting with several receptors. After first binding to the outer membrane surface receptors via their central region, they interact with TolA or TonB proteins via their N-terminal region. Colicin N residues critical to TolA binding have been discovered, but the full extent of any colicin TolA site is unknown. We present, for the first time, a fully mapped TolA binding site for a colicin. It was determined through the use of alanine-scanning mutants, glutathione S-transferase fusion peptides and Biacore/fluorescence binding studies. The minimal TolA binding region is 27 residues and of similar size to the TolA binding region of bacteriophage g3p-D1 protein. Stopped-flow kinetic studies show that the binding to TolA follows slow association kinetics. The role of other E. coli Tol proteins in colicin translocation was also investigated. Isothermal titration microcalorimetry (ITC) and in vivo studies conclusively show that colicin N translocation does not require the presence of TolB. ITC also demonstrated colicin A interaction with TolB, and that colicin A in its native state does not interact with TolAII-III. Colicin N does not bind TolR-II. The TolA protein is shown to be unsuitable for direct immobilisation in Biacore analysis.     

New locus (ttr) in Escherichia coli K-12 affecting sensitivity to bacteriophage T2 and growth on oleate as the sole carbon source.

The nature of resistance to phage T2 in Escherichia coli K-12 was investigated by analyzing a known phage T2-resistant mutant and by isolating new T2-resistant mutants. It was found that mutational alterations at two loci, ompF (encoding the outer membrane protein OmpF) and ttr (T-two resistance), are needed to give full resistance to phage T2. A ttr::Tn10 mutation was isolated and was mapped between aroC and dsdA, where the fadL gene (required for long-chain fatty acid transport) is located. The receptor affected by ttr was the major receptor used by phage T2 and was located in the outer membrane. Phage T2 was thus able to use two outer membrane proteins as receptors. All strains having a ttr::Tn10 allele and most of the independently isolated phage T2-resistant mutants were unable to grow on oleate as the sole carbon and energy source, i.e., they had the phenotype of fadL mutants. The gene fadL is known to encode an inner membrane protein. The most likely explanation is that fadL and ttr are in an operon and that ttr encodes an outer membrane protein which functions in translocating long-chain fatty acids across the outer membrane and also as a receptor for phage T2.     

PilP, a pilus biogenesis lipoprotein in Neisseria gonorrhoeae, affects expression of PilQ as a high-molecular-mass multimer

Studies of gonococcal pilus biogenesis are fundamental to understanding organelle structure/function relationships and identifying new approaches to controlling disease. This area of research is also relevant to elucidating the basic mechanisms of outer membrane translocation of macromolecules, which requires components highly related to those involved in type IV pilus expression. Previous studies have shown that products of several ancillary pil genes are required for organelle biogenesis but of these only PilQ, a member of the GspD protein family, is a component of the outer membrane. DNA sequencing of the region upstream of pilQ revealed the presence of two open reading frames (ORFs) whose deduced polypeptides shared significant identities with proteins required for pilus expression in Pseudomonas aeruginosa and Pseudomonas syringae, the genes for which are arrayed upstream of a gene encoding a PilQ homologue. Gonococcal mutants bearing transposon insertions in these ORFs were non-piliated and failed to express pilus-associated phenotypes, and the corresponding genes were designated pilO and pilP. The piliation defects in the mutants could not be ascribed to polarity on distal pilQ expression as shown by direct measurement of PilQ antigen in those backgrounds and the use of a novel technique to create tandem duplications in the gonococcus (Gc) genome. As predicted by the presence of a consensus lipoprotein signal sequence, PilP expressed in both Escherichia coli and Gc could be labelled with [³H]-palmitic acid. PilP^? as well as PilQ^? mutants shed PilC, a protein which facilitates pilus assembly and is implicated in epithelial cell adherence, in a soluble form. Combined with the finding that levels of multimerized PilQ were greatly reduced in PilP^? mutants, the results suggest that PilP is required for PilQ function and that PilQ and PilC may interact during the terminal stages of pilus biogenesis. The findings also support the hypothesis that the Gc PilQ multimer corresponds to a physiologically relevant form of the protein required for pilus biogenesis.     

Use of GFP fusions for the isolation of Escherichia coli strains for improved production of different target recombinant proteins

High level expression of a recombinant gene results in growth arrest, followed by overgrowth by non-productive derivatives. Two methods are described for the isolation of E. coli BL21* strains that are improved hosts for recombinant protein production. Both are based upon the observations (i) that fluorescence of a C-terminal GFP tag is a reliable reporter of the production and correct folding of the N-terminal target domain; and (ii) rare mutants arise spontaneously that remain productive during long periods of high level recombinant protein production. The first method relies upon identifying these mutants amongst colonies on agar plates; the other exploits fluorescence activated cell sorting. Although identical mutations in the regulatory region of the T7 polymerase gene were found in all of the improved host strains isolated, they differed in their ability to accumulate the outer membrane protein, Ccp, or a cytoplasmic protein, CheY-GFP. Cytochrome c peroxidase activity of recombinant Ccp from one of these strains was demonstrated. Changes in levels of T7 polymerase expression are therefore insufficient to ensure increased accumulation of all recombinant proteins. We demonstrate that the methods described allow strains to be isolated that carry other, currently uncharacterised mutations that are required depending on the target protein.