Characterisation of a mobile protein-binding epitope in the translocation domain of colicin E9

The 61 kDa colicin E9 protein toxin enters the cytoplasm of susceptible cells by interacting with outer membrane and periplasmic helper proteins, and kills them by hydrolysing their DNA. The membrane translocation function is located in the N-terminal domain of the colicin, with a key signal sequence being a pentapeptide region that governs the interaction with the helper protein TolB (the TolB box). Previous NMR studies (Collins et al., 2002 J. Mol. Biol. 318, 787-804) have shown that the N-terminal 83 residues of colicin E9, which includes the TolB box, is largely unstructured and highly flexible. In order to further define the properties of this region we have studied a fusion protein containing residues 1-61 of colicin E9 connected to the N-terminus of the E9 DNase by an eight-residue linking sequence. 53 of the expected 58 backbone NH resonances for the first 61 residues and all of the expected 7 backbone NH resonances of the linking sequence were assigned with 3D (1)H-(13)C-(15)N NMR experiments, and the backbone dynamics of these regions investigated through measurement of (1)H-(15)N relaxation properties. Reduced spectral density mapping, extended Lipari-Szabo modelling, and fitting backbone R(2) relaxation rates to a polymer dynamics model identifies three clusters of interacting residues, each containing a tryptophan. Each of these clusters is perturbed by TolB binding to the intact colicin, showing that the significant region for TolB binding extends beyond the recognized five amino acids of the TolB box and demonstrating that the binding epitope for TolB involves a considerable degree of order within an otherwise disordered and flexible domain. Abbreviations : Im9, the immunity protein for colicin E9; E9 DNase, the endonuclease domain of colicin E9; HSQC, heteronuclear single quantum coherence; ppm, parts per million; DSS, 2,2-(dimethylsilyl)propanesulfonic acid; TSP, sodium 3-trimethylsilypropionate; T(1 - 61)-DNase fusion protein, residues 1-61 of colicin E9 connected to the N-terminus of the E9 DNase by an eight residue thrombin cleavage sequence.     

Structural dynamics of the membrane translocation domain of colicin E9 and its interaction with TolB

In order for the 61 kDa colicin E9 protein toxin to enter the cytoplasm of susceptible cells and kill them by hydrolysing their DNA, the colicin must interact with the outer membrane BtuB receptor and Tol translocation pathway of target cells. The translocation function is located in the N-terminal domain of the colicin molecule. (1)H, (1)H-(1)H-(15)N and (1)H-(13)C-(15)N NMR studies of intact colicin E9, its DNase domain, minimal receptor-binding domain and two N-terminal constructs containing the translocation domain showed that the region of the translocation domain that governs the interaction of colicin E9 with TolB is largely unstructured and highly flexible. Of the expected 80 backbone NH resonances of the first 83 residues of intact colicin E9, 61 were identified, with 43 of them being assigned specifically. The absence of secondary structure for these was shown through chemical shift analyses and the lack of long-range NOEs in (1)H-(1)H-(15)N NOESY spectra (tau(m)=200 ms). The enhanced flexibility of the region of the translocation domain containing the TolB box compared to the overall tumbling rate of the protein was identified from the relatively large values of backbone and tryptophan indole (15)N spin-spin relaxation times, and from the negative (1)H-(15)N NOEs of the backbone NH resonances. Variable flexibility of the N-terminal region was revealed by the (15)N T(1)/T(2) ratios, which showed that the C-terminal end of the TolB box and the region immediately following it was motionally constrained compared to other parts of the N terminus. This, together with the observation of inter-residue NOEs involving Ile54, indicated that there was some structural ordering, resulting most probably from the interactions of side-chains. Conformational heterogeneity of parts of the translocation domain was evident from a multiplicity of signals for some of the residues. Im9 binding to colicin E9 had no effect on the chemical shifts or other NMR characteristics of the region of colicin E9 containing the TolB recognition sequence, though the interaction of TolB with intact colicin E9 bound to Im9 did affect resonances from this region. The flexibility of the translocation domain of colicin E9 may be connected with its need to recognise protein partners that assist it in crossing the outer membrane and in the translocation event itself.     

Kinetic basis for the competitive recruitment of TolB by the intrinsically disordered translocation domain of colicin E9

TolB and Pal are members of the Tol-Pal system that spans the cell envelope of Gram-negative bacteria and contributes to the stability and integrity of the bacterial outer membrane (OM). Lipoylated Pal is tethered to the OM and binds the β-propeller domain of periplasmic TolB, which, as recent evidence suggests, disengages TolB from its interaction with other components of the Tol system in the inner membrane. Antibacterial nuclease colicins such as colicin E9 (ColE9) also bind the β-propeller domain of TolB in order to catalyze their translocation across the bacterial OM. In contrast to Pal, however, colicin binding to TolB promotes its interaction with other components of the Tol system. Here, through a series of pre-steady-state kinetic experiments utilizing fluorescence resonance energy transfer pairs within the individual protein-protein complexes, we establish the kinetic basis for such 'competitive recruitment' by the TolB-binding epitope (TBE) of ColE9. Surprisingly, the 16-residue disordered ColE9 TBE associates more rapidly with TolB than Pal, a folded 13-kDa protein. Moreover, we demonstrate that calcium ions, which bind within the confines of the TolB β-propeller domain tunnel and are known to increase the affinity of the TolB-ColE9 complex, do not exert their influence through long-range electrostatic effects, as had been predicted, but through short-range effects that slow the dissociation rate of ColE9 TBE from its complex with TolB. Our study demonstrates that an intrinsically disordered protein undergoing binding-induced folding can compete effectively with a globular protein for a common target by associating more rapidly than the globular protein.     

Minimum length requirement of the flexible N-terminal translocation subdomain of colicin E3

The 315-residue N-terminal T domain of colicin E3 functions in translocation of the colicin across the outer membrane through its interaction with outer membrane proteins including the OmpF porin. The first 83 residues of the T domain are known from structure studies to be disordered. This flexible translocation subdomain contains the TolB box (residues 34 to 46) that must cross the outer membrane in an early translocation event, allowing the colicin to bind to the TolB protein in the periplasm. In the present study, it was found that cytotoxicity of the colicin requires a minimum length of 19 to 23 residues between the C terminus (residue 46) of the TolB box and the end of the flexible subdomain (residue 83). Colicin E3 molecules of sufficient length display normal binding to TolB and occlusion of OmpF channels in vitro. The length of the N-terminal subdomain is critical because it allows the TolB box to cross the outer membrane and interact with TolB. It is proposed that the length constraint is a consequence of ordered structure in the downstream segment of the T domain (residues 84 to 315) that prevents its insertion through the outer membrane via a translocation pore that includes OmpF.     

Self-recognition by an intrinsically disordered protein

The intrinsically disordered translocation domain (T-domain) of the protein antibiotic colicin N binds to periplasmic receptors of target Escherichia coli cells in order to penetrate their inner membranes. We report here that the specific 27 consecutive residues of the T-domain of colicin N known to bind to the helper protein TolA in target cells also interacts intramolecularly with folded regions of colicin N. We suggest that this specific self-recognition helps intrinsically disordered domains to bury their hydrophobic recognition motifs and protect them against degradation, showing that an impaired self-recognition leads to increased protease susceptibility.     

Interactions of TolB with the translocation domain of colicin E9 require an extended TolB box

The mechanism by which enzymatic E colicins such as colicin E3 (ColE3) and ColE9 cross the outer membrane, periplasm, and cytoplasmic membrane to reach the cytoplasm and thus kill Escherichia coli cells is unique in prokaryotic biology but is poorly understood. This requires an interaction between TolB in the periplasm and three essential residues, D35, S37, and W39, of a pentapeptide sequence called the TolB box located in the N-terminal translocation domain of the enzymatic E colicins. Here we used site-directed mutagenesis to demonstrate that the TolB box sequence in ColE9 is actually larger than the pentapeptide and extends from residues 34 to 46. The affinity of the TolB box mutants for TolB was determined by surface plasmon resonance to confirm that the loss of biological activity in all except one (N44A) of the extended TolB box mutants correlates with a reduced affinity of binding to TolB. We used a PCR mutagenesis protocol to isolate residues that restored activity to the inactive ColE9 D35A, S37A, and W39A mutants. A serine residue at position 35, a threonine residue at position 37, and phenylalanine or tyrosine residues at position 39 restored biological activity of the mutant ColE9. The average area predicted to be buried upon folding (AABUF) was correlated with the activity of the variants at positions 35, 37, and 39 of the TolB box. All active variants had AABUF profiles that were similar to the wild-type residues at those positions and provided information on the size, stereochemistry, and potential folding pattern of the residues of the TolB Box.     

The crystal structure of the TolB box of colicin A in complex with TolB reveals important differences in the recruitment of the common TolB translocation portal used by group A colicins

Interaction of the TolB box of Group A colicins with the TolB protein in the periplasm of Escherichia coli cells promotes transport of the cytotoxic domain of the colicin across the cell envelope. The crystal structure of a complex between a 107‐residue peptide (TA_1–107) of the translocation domain of colicin A (ColA) and TolB identified the TolB box as a 12‐residue peptide that folded into a distorted hairpin within a central canyon of the β‐propeller domain of TolB. Comparison of this structure with that of the colicin E9 (ColE9) TolB box–TolB complex, together with site‐directed mutagenesis of the ColA TolB box residues, revealed important differences in the interaction of the two TolB boxes with an overlapping binding site on TolB. Substitution of the TolB box residues of ColA with those of ColE9 conferred the ability to competitively recruit TolB from Pal but reduced the biological activity of the mutant ColA. This datum explains (i) the difference in binding affinities of ColA and ColE9 with TolB, and (ii) the inability of ColA, unlike ColE9, to competitively recruit TolB from Pal, allowing an understanding of how these two colicins interact in a different way with a common translocation portal in E. coli cells.     

The structure of TolB, an essential component of the tol-dependent translocation system, and its protein-protein interaction with the translocation domain of colicin E9

BACKGROUND: E colicin proteins have three functional domains, each of which is implicated in one of the stages of killing Escherichia coli cells: receptor binding, translocation and cytotoxicity. The central (R) domain is responsible for receptor-binding activity whereas the N-terminal (T) domain mediates translocation, the process by which the C-terminal cytotoxic domain is transported from the receptor to the site of its cytotoxicity. The translocation of enzymatic E colicins like colicin E9 is dependent upon TolB but the details of the process are not known. RESULTS: We have demonstrated a protein-protein interaction between the T domain of colicin E9 and TolB, an essential component of the tol-dependent translocation system in E. coli, using the yeast two-hybrid system. The crystal structure of TolB, a procaryotic tryptophan-aspartate (WD) repeat protein, reveals an N-terminal alpha + beta domain based on a five-stranded mixed beta sheet and a C-terminal six-bladed beta-propeller domain. CONCLUSIONS: The results suggest that the TolB-box residues of the T domain of colicin E9 interact with the beta-propeller domain of TolB. The protein-protein interactions of other beta-propeller-containing proteins, the yeast yPrp4 protein and G proteins, are mediated by the loops or outer sheets of the propeller blades. The determination of the three-dimensional structure of the T domain-TolB complex and the isolation of mutations in TolB that abolish the interaction with the T domain will reveal fine details of the protein-protein interaction of TolB and the T domain of E colicins.     

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.     

Assembly of colicin genes from a few DNA fragments. Nucleotide sequence of colicin D

The nucleotide sequence of a 2.4 kb Dral-EcoRV fragment of pColD-CA23 DNA was determined. The segment of DNA contained the colicin D structural gene (cda) and the colicin D immunity gene (cdi). From the nucleotide sequence it was deduced that colicin D had a molecular weight of 74683D and that the immunity protein had a molecular weight of 10057D. The amino-terminal portion of colicin D was found to be 96% homologous with the same region of colicin B. Both colicins share the same cell-surface receptor, FepA, and require the TonB protein for uptake. A putative TonB box pentapeptide sequence was identified in the amino terminus of the colicin D protein sequence. Since colicin D inhibits protein synthesis, it was unexpected that no homology was found between the carboxy-terminal part of this colicin and that of the protein synthesis inhibiting colicin E3 and cloacin DF13. This could indicate that colicin D does not function in the same manner as the latter two bacteriocins. The observed homology with colicin B supports the domain structure concept of colicin organization. The structural organization of the colicin operon is discussed. The extensive amino-terminal homology between colicins D and B, and the strong carboxy-terminal homology between colicins B, A, and N suggest an evolutionary assembly of colicin genes from a few DNA fragments which encode the functional domains responsible for colicin activity and uptake.     

Deletion analysis of the 51-kilodalton protein of the Bacillus sphaericus 2362 binary mosquitocidal toxin: construction of derivatives equivalent to the larva-processed toxin.

Bacillus sphaericus 2362 produces a binary toxin consisting of 51- and 42-kDa proteins, both of which are required for toxicity to mosquito larvae. Upon ingestion by larvae, these proteins are processed to 43 and 39 kDa, respectively. Using site-directed mutagenesis, we have obtained N- and C-terminal deletions of the 51-kDa protein and expressed them in B. subtilis by using the subtilisin promoter. Removal of 21 amino acids from the N terminus and 53 amino acids from the C terminus resulted in a protein with the same electrophoretic properties as the 43-kDa degradation product which accumulates in the guts of mosquito larvae. This protein was toxic only in the presence of the 42-kDa protein. A deletion of 32 amino acids at the N terminus combined with a 53-amino-acid deletion at the C terminus resulted in a protein which retained toxicity. Toxicity was lost upon a further deletion of amino acids at potential chymotrypsin sites (41 at the N terminus, 61 at the C terminus). Comparison of the processing of the 51- and the 42-kDa proteins indicated that in spite of their sequence similarity proteolysis occurred at different sites.     

A Common Interaction for the Entry of Colicin N and Filamentous Phage into Escherichia coli

Colicin N is a pore-forming bacteriocin that enters target Escherichia coli cells with the assistance of TolA, a protein in the periplasm of the target cell. The N-terminal domain of the colicin that carries the TolA-binding epitope, the translocation domain (T-domain), is intrinsically disordered. From ¹H-¹³C-¹⁵N NMR studies of isotopically labeled T-domain interacting with unlabeled TolAIII (the C-terminal domain of TolA), we have identified the TolA-binding epitope and have shown that the extent of its disorder is reduced on binding TolA, although it does not fold into a globular structure with defined secondary structure elements. Residues upstream and downstream of the 27-residue TolA-binding epitope remain disordered in the TolA-bound T-domain as they are in the free T-domain. Filamentous phage also exploits TolAIII to enter target cells, with TolAIII retaining its main secondary structure elements and global fold. In contrast to this, binding of the disordered T-domain of colicin A causes dramatic conformational changes in TolAIII marked by increased flexibility and lack of a rigid tertiary structure consistent with at least partial unfolding of TolAIII, suggesting that bacteriocins and bacteriophages parasitize E. coli using different modes of interaction with TolAIII. We have found that the colicin N T-domain-TolAIII interaction is strikingly similar to the previously described g3p-TolAIII interaction. The fact that both colicin N and filamentous phage exploit TolAIII in a similar manner, with one being a bacterial intrinsically disordered protein and the other being a viral structurally well-ordered protein, suggests that these represent a good example of convergent evolution at the molecular level.     

Molecular analysis of the Escherichia coli ferric enterobactin receptor FepA

In Escherichia coli, the outer membrane protein FepA is a receptor for the siderophore complex ferric enterobactin and for colicins B and D. To identify protein domains important for FepA activity, the effects of deletion and linker insertion mutations on receptor structure and function were examined. In-frame internal deletion mutations removing sequences encoding up to 304 amino acid residues resulted in functionally defective FepA polypeptides, although most were translocated efficiently to the outer membrane. One exception, a derivative lacking 87 internal amino acid residues near the N terminus, showed an inability to transport ferric enterobactin but retained limited colicin receptor function. Analysis of cells carrying 3'-terminal fepA deletion mutations suggested that residues within the C terminus of FepA may be involved in secretion and proper translocation of the protein to the outer membrane. Introduction of the peptide Leu-Glu after FepA residues 55, 142, or 324 severely impaired receptor function for all three ligands, while the same insertion after residues 339 or 359 had virtually no detrimental effect on FepA function. Foreign peptides inserted after residues 204 or 635 restricted colicin B and D function only, leaving ferric enterobactin transport ability at near wild-type levels. The results presented in this study have identified key regions of FepA potentially involved in receptor function and demonstrate the presence of both shared and unique ligand-responsive domains.     

Individual domains of colicins confer specificity in colicin uptake, in pore-properties and in immunity requirement.

Six different hybrid colicins were constructed by recombining various domains of the two pore-forming colicins A and E1. These hybrid colicins were purified and their properties were studied. All of them were active against sensitive cells, although to varying degrees. From the results, one can conclude that: (1) the binding site of OmpF is located in the N-terminal domain of colicin A; (2) the OmpF, TolB and TolR dependence for translocation is also located in this domain; (3) the TolC dependence for colicin E1 is located in the N-terminal domain of colicin E1; (4) the 183 N-terminal amino acid residues of colicin E1 are sufficient to promote E1AA uptake and thus probably colicin E1 uptake; (5) there is an interaction between the central domain and C-terminal domain of colicin A; (6) the individual functioning of different domains in various hybrids suggests that domain interactions can be reconstituted in hybrids that are fully active, whereas in others that are much less active, non-proper domain interactions may interfere with translocation; (7) there is a specific recognition of the C-terminal domains of colicin A and colicin E1 by their respective immunity proteins.     

Interaction of the Colicin K Bactericidal Toxin with Components of Its Import Machinery in the Periplasm of Escherichia coli

Colicins are bacterial antibiotic toxins produced by Escherichia coli cells and are active against E. coli and closely related strains. To penetrate the target cell, colicins bind to an outer membrane receptor at the cell surface and then translocate their N-terminal domain through the outer membrane and the periplasm. Once fully translocated, the N-terminal domain triggers entry of the catalytic C-terminal domain by an unknown process. Colicin K uses the Tsx nucleoside-specific receptor for binding at the cell surface, the OmpA protein for translocation through the outer membrane, and the TolABQR proteins for the transit through the periplasm. Here, we initiated studies to understand how the colicin K N-terminal domain (KT) interacts with the components of its transit machine in the periplasm. We first produced KT fused to a signal sequence for periplasm targeting. Upon production of KT in wild-type strains, cells became partly resistant to Tol-dependent colicins and sensitive to detergent, released periplasmic proteins, and outer membrane vesicles, suggesting that KT interacts with and titrates components of its import machine. Using a combination of in vivo coimmunoprecipitations and in vitro pulldown experiments, we demonstrated that KT interacts with the TolA, TolB, and TolR proteins. For the first time, we also identified an interaction between the TolQ protein and a colicin translocation domain.Colicins are bacterial toxins produced by Escherichia coli strains and are active against E. coli or related strains (17). These bacterial antibiotic toxins play an important role in the E. coli colonization of environmental niches, including the mammal gastrointestinal tract (25, 32, 49, 50). The classification of colicins is based on differences in the mechanisms of action, such as pore formation (colicins A, B, E1, K, Ia, N, 5, etc.), degradation of nucleic acids (including DNases [colicins E2, E7, and E9], 16S RNases [colicins E3, E4, and E6], or tRNases [colicins D and E5]), or degradation of lipid II (colicin M) (17, 34). Colicins are also categorized depending on their import machines: colicins using the Tol proteins are classified as group A (colicins A, E1 to E9, K, N, etc.), whereas colicins using the ExbBD-TonB proteins are classified as group B (colicins B, D, Ia, M, 5, etc.). However, the transport across the periplasm is only one of the three steps of the mechanism of action. Colicins bind to an outer membrane receptor and are translocated through the outer membrane and the periplasm (14, 35, 55, 56). Finally, the C-terminal domain (responsible for the activity) is translocated to its final destination (inner membrane or cytoplasm) depending on its mechanism of action. Colicins are divided into three different structural and functional domains that correspond to the three steps of the mechanism of action: the N-terminal domain is required for translocation, the central domain is involved in receptor binding, and the C-terminal domain carries the activity (4, 5). During the translocation step, the N-terminal domain of the colicin interacts with components of the import machine: colicins A, E1, and N interact with the TolA protein; colicins A, E3, E7, and E9 interact with the TolB protein; and colicins A and E3 interact with TolR (6, 12, 13, 15, 21, 23, 26, 27, 30, 39, 48, 54). In some cases, the domains of the Tol proteins involved in colicin binding have been identified. Reciprocally, the regions of colicins in interaction with the Tol proteins have been delineated. In colicin A, the TolA binding sequence (ABS) is contained within residues 37 to 98 (13, 30), in which a SYNT motif (residues 57 to 60) has been shown to be essential for TolA binding (18, 46). The TolB box and the TolR binding sequences have also been identified in colicin A (27, 30). The TolB box is well conserved within TolB-dependent colicins, including colicins A and E2 to E9, and is composed of residues DG[T,S]GWSSE (12, 13). These residues form a loop penetrating within the TolB beta-propeller (39, 57), mimicking the TolB-Pal interaction (9, 10). Interestingly, the Tol-dependent, pore-forming colicin K does not possess a TolB box (see Fig. ​Fig.1A),1A), raising the hypothesis that its translocation might be TolB independent or that colicin K interacts with TolB differently than do other TolB-dependent colicins. In this study, we tested the Tol requirements for colicin K translocation and showed that colicin K requires the TolA, TolB, TolQ, and TolR proteins. Production of the N-terminal domain of colicin K in the periplasm of wild-type (WT) cells induces specific tol defects and tolerance to Tol-dependent colicins and bacteriophage, suggesting that the colicin K N-terminal domain binds and titrates the Tol proteins. Further in vivo coimmunoprecipitation and in vitro pulldown experiments demonstrated interactions between the colicin K N-terminal domain and the TolA, TolB, and TolR proteins. For the first time, we also identified an interaction between a colicin translocation domain and the fourth component of the Tol complex, the TolQ protein.Open in a separate windowFIG. 1.In the absence of an identifiable TolB-binding sequence, colicin K translocation is TolB dependent. (A) Sequence alignment of colicin K and three TolB-dependent colicins (A, E2, and E9). Conserved residues are indicated by red letters. The characterized TolB binding sequence is indicated by the green box (defined in references 12 and 27). (B) Colicin spot assays using serial dilutions of colicins A (TolB dependent), E1 (TolB independent), and K on a wild-type (WT) strain and its tolB derivative (from left to right, 100, 10, 1, and 0.1 ng of colicins have been spotted, respectively).     

High-resolution crystal structure of a truncated ColE7 translocation domain: implications for colicin transport across membranes

ColE7 is a nuclease-type colicin released from Escherichia coli to kill sensitive bacterial cells by degrading the nucleic acid molecules in their cytoplasm. ColE7 is classified as one of the group A colicins, since the N-terminal translocation domain (T-domain) of the nuclease-type colicins interact with specific membrane-bound or periplasmic Tol proteins during protein import. Here, we show that if the N-terminal tail of ColE7 is deleted, ColE7 (residues 63-576) loses its bactericidal activity against E.coli. Moreover, TolB protein interacts directly with the T-domain of ColE7 (residues 1-316), but not with the N-terminal deleted T-domain (residues 60-316), as detected by co-immunoprecipitation experiments, confirming that the N-terminal tail is required for ColE7 interactions with TolB. The crystal structure of the N-terminal tail deleted ColE7 T-domain was determined by the multi-wavelength anomalous dispersion method at a resolution of 1.7 angstroms. The structure of the ColE7 T-domain superimposes well with the T-domain of ColE3 and TR-domain of ColB, a group A Tol-dependent colicin and a group B TonB-dependent colicin, respectively. The structural resemblance of group A and B colicins implies that the two groups of colicins may share a mechanistic connection during cellular import.     

A hybrid toxin from bacteriophage f1 attachment protein and colicin E3 has altered cell receptor specificity.

A hybrid protein was constructed in vitro which consists of the first 372 amino acids of the attachment (gene III) protein of filamentous bacteriophage f1 fused, in frame, to the carboxy-terminal catalytic domain of colicin E3. The hybrid toxin killed cells that had the F-pilus receptor for phage f1 but not F- cells. The activity of the hybrid protein was not dependent upon the presence of the colicin E3 receptor, BtuB protein. The killing activity was colicin E3 specific, since F+ cells expressing the colicin E3 immunity gene were not killed. Entry of the hybrid toxin was also shown to depend on the products of tolA, tolQ, and tolR which are required both for phage f1 infection and for entry of E colicins. TolB protein, which is required for killing by colicin E3, but not for infection by phage f1, was also found to be necessary for the killing activity of the hybrid toxin. The gene III protein-colicin E3 hybrid was released from producing cells into the culture medium, although the colicin E3 lysis protein was not present in those cells. The secretion was shown to depend on the 18-amino-acid-long gene III protein signal sequence. Deletion of amino acids 3 to 18 of the gene III moiety of the hybrid protein resulted in active toxin, which remained inside producing cells unless it was mechanically released.     

A 76-residue polypeptide of colicin E9 confers receptor specificity and inhibits the growth of vitamin B12-dependent Escherichia coli 113/3 cells

The mechanism by which E colicins recognize and then bind to BtuB receptors in the outer membrane of Escherichia coli cells is a poorly understood first step in the process that results in cell killing. Using N- and C-terminal deletions of the N-terminal 448 residues of colicin E9, we demonstrated that the smallest polypeptide encoded by one of these constructs that retained receptor-binding activity consisted of residues 343-418. The results of the in vivo receptor-binding assay were supported by an alternative competition assay that we developed using a fusion protein consisting of residues 1-497 of colicin E9 fused to the green fluorescent protein as a fluorescent probe of binding to BtuB in E. coli cells. Using this improved assay, we demonstrated competitive inhibition of the binding of the fluorescent fusion protein by the minimal receptor-binding domain of colicin E9 and by vitamin B12. Mutations located in the minimum R domain that abolished or reduced the biological activity of colicin E9 similarly affected the competitive binding of the mutant colicin protein to BtuB. The sequence of the 76-residue R domain in colicin E9 is identical to that found in colicin E3, an RNase type E colicin. Comparative sequence analysis of colicin E3 and cloacin DF13, which is also an RNase-type colicin but uses the IutA receptor to bind to E. coli cells, revealed significant sequence homology throughout the two proteins, with the exception of a region of 92 residues that included the minimum R domain. We constructed two chimeras between cloacin DF13 and colicin E9 in which (i) the DNase domain of colicin E9 was fused onto the T+R domains of cloacin DF13; and (ii) the R domain and DNase domain of colicin E9 were fused onto the T domain of cloacin DF13. The killing activities of these two chimeric colicins against indicator strains expressing BtuB or IutA receptors support the conclusion that the 76 residues of colicin E9 confer receptor specificity. The minimum receptor-binding domain polypeptide inhibited the growth of the vitamin B12-dependent E. coli 113/3 mutant cells, demonstrating that vitamin B12 and colicin E9 binding is mutually exclusive.     

Mutual induced fit binding of Xenopus ribosomal protein L5 to 5S rRNA

A library of random mutations in Xenopus ribosomal protein L5 was generated by error-prone PCR and used to delineate the binding domain for 5S rRNA. All but one of the amino acid substitutions that affected binding affinity are clustered in the central region of the protein. Several of the mutations are conservative substitutions of non-polar amino acid residues that are unlikely to form energetically significant contacts to the RNA. Thermal denaturation, monitored by circular dichroism (CD), indicates that L5 is not fully structured and association with 5S rRNA increases the t(m) of the protein by 16 degrees C. L5 induces changes in the CD spectrum of 5S rRNA, establishing that the complex forms by a mutual induced fit mechanism. Deuterium exchange reveals that a considerable amount of L5 is unstructured in the absence of 5S rRNA. The fluorescence emission of W266 provides evidence for structural changes in the C-terminal region of L5 upon binding to 5S rRNA; whereas, protection experiments demonstrate that the N terminus remains highly sensitive to protease digestion in the complex. Analysis of the amino acid sequence of L5 by the program PONDR predicts that the N and C-terminal regions of L5 are intrinsically disordered, but that the central region, which contains three essential tyrosine residues and other residues important for binding to 5S rRNA, is likely to be structured. Initial interaction of the protein with 5S rRNA likely occurs through this region, followed by induced folding of the C-terminal region. The persistent disorder in the N-terminal domain is possibly exploited for interactions between the L5-5S rRNA complex and other proteins.