Colicin import and pore formation: a system for studying protein transport across membranes?

Pore-forming colicins are a family of protein toxins (M(r) 40-70 kDa) produced by Escherichia coli and related bacteria. They are bactericidal by virtue of their ability to form ion channels in the inner membrane of target cells. They provide a useful means of studying questions such as toxin action, polypeptide translocation across and into membranes, voltage-gated channels and receptor function. These colicins bind to a receptor in the outer membrane before being translocated across the cell envelope with the aid of helper proteins that belong to nutrient-uptake systems and the so-called 'Tol' proteins, the function of which has not yet been properly defined. A distinct domain appears to be associated with each of three steps (receptor binding, translocation and formation of voltage-gated channels). The Tol-dependent uptake pathway is described here. The structures and interactions of TolA, B, Q and R have by now been quite clearly defined. Transmembrane alpha-helix interactions are required for the functional assembly of the E. coli Tol complex, which is preferentially located at contact sites between the inner and outer membranes. The number of colicin translocation sites is about 1000 per cell. The role and the involvement of the OmpF porin (with colicins A and N) have been described in a recent study on the structural and functional interactions of a colicin-resistant mutant of OmpF. The X-ray crystal structure of the channel-forming fragment of colicin A and that of the entire colicin la have provided the basis for biophysical and site-directed mutagenesis studies.(ABSTRACT TRUNCATED AT 250 WORDS)

Insertion and translocation of proteins into and through membranes.

In prokaryotic and eukaryotic organisms, proteins are efficiently sorted to reach their final destinations in a whole range of subcellular compartments. Targeting is mediated by hydrophobic signal sequences or hydrophilic targeting sequences depending upon the compartment, these sequences being often processed. Proteins cannot be translocated through a membrane in a tightly folded stage, they must have a loose conformation, the so-called 'translocation competent state', which is usually kept through interactions with chaperones. In addition to these cytosolic receptor-like components, receptors are also present on the target membranes. Depending upon the organelles and organisms, two different energy sources have been identified, energy rich phosphate bonds (ATP and GTP) and a potential across the target membrane. Besides the signal peptides, various classes of signals have been identified to account for topologies of membrane proteins. Protein secretion in bacterial organisms has been extensively studied. Various classes of proteins use different strategies, some of these may also be used in eukaryotic cells.

The membrane channel-forming colicin A: synthesis, secretion, structure, action and immunity.

The study of colicin release from producing cells has revealed a novel mechanism of secretion. Instead of a built-in 'tag', such as a signal peptide containing information for secretion, the mechanism employs coordinate expression of a small protein which causes an increase in the envelope permeability, resulting in the release of the colicin as well as other proteins. On the other hand, the mechanism of entry of colicins into sensitive cells involves the same three stages of protein translocation that have been demonstrated for various cellular organelles. They first interact with receptors located at the surface of the outer membrane and are then transferred across the cell envelope in a process that requires energy and depends upon accessory proteins (TolA, TolB, TolC, TolQ, TolR) which might play a role similar to that of the secretory apparatus of eukaryotic and prokaryotic cells. At this point, the type of colicin described in this review interacts specifically with the inner membrane to form an ion channel. The pore-forming colicins are isolated as soluble proteins and yet insert spontaneously into lipid bilayers. The three-dimensional structures of some of these colicins should soon become available and site-directed mutagenesis studies have now provided a large number of modified polypeptides. Their use in model systems, particularly those in which the role of transmembrane potential can be tested for polypeptide insertion and ionic channel gating, constitutes a powerful handle with which to improve our understanding of the dynamics of protein insertion into and across membranes and the molecular basis of membrane excitability. In addition, their immunity proteins, which exist only in one state (membrane-inserted) will also contribute to such an understanding.

Pore-forming colicins: synthesis, extracellular release, mode of action, immunity.

Colicins are bacterial toxins encoded by plasmids which also confer immunity to producing cells. In a first stage, colicins are synthesized in the cytoplasm of colicinogenic cells. Subsequently they are released into the extracellular medium following the action of a small protein synthesized coordinately with the colicins. This protein is a lipoprotein and causes a non-specific increase in the envelope permeability, in particular, through the activation of an outer membrane phospholipase. After release into the medium, colicins kill sensitive cells in 3 defined steps: adsorption onto a specific receptor at the surface of the bacterium, translocation across the outer membrane and action. A specific domain of the colicin molecule is responsible for each of these steps. The most common colicins are those which kill by depolarizing the cytoplasmic membrane with the formation of voltage-dependent ionic channels. Immunity is conferred to producing cells by a membrane protein which interacts with the colicin and prevents formation or functioning of these ionic channels formed by its C-terminal domain.

Nucleotide sequence of the gene for the immunity protein to colicin A. Analysis of codon usage of immunity proteins as compared to colicins.

The nucleotide sequence of the structural gene for the immunity protein to colicin A (cai) has been established. This sequence consists of 534 base pairs. According to the predicted amino acid sequence, the polypeptide chain of this immunity protein comprises 178 amino acids and has a relative molecular mass of 20462. As expected from its localization in the inner membrane, large hydrophobic fragments are found along the polypeptide chain that also contains clusters of mostly positively charged residues. The cai like the ceiA genes encode proteins that are weakly expressed as compared to the corresponding colicins (A and E1). Codon usage reflects this difference. In contrast, the four genes for immunity to cloacin DF13 and to colicin E3 and for these bacteriocins, all of which are highly expressed and are organized in operon, display similar codon usage. These results are discussed with regards to the possible relationship between expressivity and codon usage.

A protease as a possible sensor of environmental conditions in E. coli outer membrane.

A mutant strain devoid of the colicin A protease activity (cpr) located at the external face of the outer membrane has been isolated. The location of the mutation (about 74 min on the genetic map), its pleiotropic effects concerning mainly the protein composition of the outer membrane and sensitivity to phages and colicins, are very similar in cpr and in tpo, envZ, perA strains that are affected in the ompB locus. Conditions resulting in inhibition of the colicin A protease activity also result in transcriptional regulation of OmpF, OmpC, and LamB protein synthesis. The possibility for this protease as an osmosensor of the cell's external environment is discussed.

Purification and molecular properties of a new colicin.

The process of isolation and purification of a new colicin isolated from a Citrobacter strain is described. Escherichia coli sensitive cells are protected by vitamin B12 from the action of this bacteriocin; this suggests that it belongs to the E group of colicins. Therefore, we have called it colicin E4. It has a molecular weight of 56 000 and two molecular forms of isoelectric points 9.4 and 8.2 are separated in electrofocusing on polyacrylamide gels. It has a sedimentation coefficient of 3.4 S and the absorption coefficient A1(280%) nm is 6.23 cm(-1). Using an antibody raised against pure colicin E4, no cross-reaction was detected against colicins A, E1 or K. The physiological effect of colicin E4 on sensitive cells is very similar to that of colicins E1, K or I which disrupt the energized membrane state.

Spreading of biomembranes at the air/water interface.

This paper presents the compression isotherms obtained by spreading membranes of intestinal brush border, human erythrocyte and Escherichia coli (cytoplasmic) at the air/water interface. Unilamellar membrane films were formed, with a good yield, at zero surface pressure, whereas multilamellar structures were formed at high surface pressure. Once formed, the films were particularly stable and could be manipulated without any detectable loss. With doubly-labelled E. coli cytoplasmic membrane, we could show that phospholipids and proteins spread, with the same yield, as a single unit. Moreover, we studied the influence of hydrolytic enzymes, chemical agents and cations on the compression isotherm of biomembranes. The resultant changes in architecture of membrane films can provide a very simple method of studying the influence of membrane packing on catalytic activity and protein conformation of membrane-bound proteins.