Role of the TonB amino terminus in energy transduction between membranes.

Escherichia coli TonB protein is an energy transducer, coupling cytoplasmic membrane energy to active transport of vitamin B12 and iron-siderophores across the outer membrane. TonB is anchored in the cytoplasmic membrane by its hydrophobic amino terminus, with the remainder occupying the periplasmic space. In this report we establish several functions for the hydrophobic amino terminus of TonB. A G-26-->D substitution in the amino terminus prevents export of TonB, suggesting that the amino terminus contains an export signal for proper localization of TonB within the cell envelope. Substitution of the first membrane-spanning domain of the cytoplasmic membrane protein TetA for the TonB amino terminus eliminates TonB activity without altering TonB export, suggesting that the amino terminus contains sequence-specific information. Detectable TonB cross-linking to ExbB is also prevented, suggesting that the two proteins interact primarily through their transmembrane domains. In vivo cleavage of the amino terminus of TonB carrying an engineered leader peptidase cleavage site eliminates (i) TonB activity, (ii) detectable interaction with a membrane fraction having a density intermediate to those of the cytoplasmic and outer membranes, and (iii) cross-linking to ExbB. In contrast, the amino terminus is not required for cross-linking to other proteins with which TonB can form complexes, including FepA. Additionally, although the amino terminus clearly is a membrane anchor, it is not the only means by which TonB associates with the cytoplasmic membrane. TonB lacking its amino-terminal membrane anchor still remains largely associated with the cytoplasmic membrane.     

The tonB gene of Serratia marcescens: sequence, activity and partial complementation of Escherichia coli tonB mutants

The TonB protein plays a key role in the energy-coupled transport of iron siderophores, of vitamin B12, and of colicins of the B-group across the outer membrane of Escherichia coli. In order to obtain more data about which of its particular amino acid sequences are necessary for TonB function, we have cloned and sequenced the tonB gene of Serratia marcescens. The nucleotide sequence predicts an amino acid sequence of 247 residues (Mr 27,389), which is unusually proline-rich and contains the tandem sequences (Glu-Pro)5 and (Lys-Pro)5. In contrast to the TonB proteins of E. coli and Salmonella typhimurium, translation of the S. marcescens TonB protein starts at the first methionine residue of the open reading frame, which is the only amino acid removed during TonB maturation and export. Only the N-terminal sequence is hydrophobic, suggesting its involvement in anchoring the TonB protein to the cytoplasmic membrane. The S. marcescens tonB gene complemented an E. coli tonB mutant with regard to uptake of iron siderophores, and sensitivity to phages T1 and phi 80, and to colicins B and M. However, an E. coli tonB mutant transformed with the S. marcescens tonB gene remained resistant to colicins Ia and Ib, to colicin B derivatives carrying the amino acid replacements Val/Ala and Val/Gly at position 20 in the TonB box, and they exhibited a tenfold lower activity with colicin D. In addition, the S. marcescens TonB protein did not restore T1 sensitivity of an E. coli exbB tolQ double mutant, as has been found for the overexpressed E. coli TonB protein, indicating a lower activity of the S. marcescens TonB protein. Although the S. marcescens TonB protein was less prone to proteolytic degradation, it was stabilized in E. coli by the ExbBD proteins. In E. coli, TonB activity of S. marcescens depended either on the ExbBD or the TolQR activities.     

Targeting of signal sequenceless proteins for export in Escherichia coli with altered protein translocase.

Most extracytoplasmic proteins are synthesized with an N-terminal signal sequence that targets them to the export apparatus. Escherichia coli prlA mutants (altered in the secY gene) are able to export cell envelope proteins lacking any signal sequence. In order to understand how such proteins are targeted for export, we isolated mutations in a signal sequenceless version of alkaline phosphatase that block its export in a prlA mutant. The mutations introduce basic amino acyl residues near the N-terminus of alkaline phosphatase. These changes do not disrupt an N-terminal export signal in this protein since the first 25 amino acids can be removed without affecting its export competence. These findings suggest that signal sequenceless alkaline phosphatase does not contain a discrete domain that targets it for export and may be targeted simply because it remains unfolded in the cytoplasm. We propose that basic amino acids near the N-terminus of a signal sequenceless protein affect its insertion into the translocation apparatus after it has been targeted for export. These findings allow the formulation of a model for the entry of proteins into the membrane-embedded export machinery.     

Point mutations in a conserved region (TonB box) of Escherichia coli outer membrane protein BtuB affect vitamin B12 transport.

Uptake of cobalamins and iron chelates in Escherichia coli K-12 is dependent on specific outer membrane transport proteins and the energy-coupling function provided by the TonB protein. The btuB product is the outer membrane receptor for cobalamins, bacteriophage BF23, and the E colicins. A short sequence near the amino terminus of mature BtuB, previously called the TonB box, is conserved in all tonB-dependent receptors and colicins and is the site of the btuB451 mutation (Leu-8----Pro), which prevents energy-coupled cobalamin uptake. This phenotype is partially suppressed by certain mutations in tonB. To examine the role of individual amino acids in the TonB box of BtuB, more than 30 amino acid substitutions in residues 6 to 13 were generated by doped oligonucleotide-directed mutagenesis. Many of the mutations affecting each amino acid did not impair transport activity, although some substitutions reduced cobalamin uptake and the Leu-8----Pro and Val-10----Gly alleles were completely inactive. To test whether the btuB451 mutation affects only cobalamin transport, a hybrid gene was constructed which encodes the signal sequence and first 39 residues of BtuB fused to the bulk of the ferrienterobactin receptor FepA (residues 26 to 723). This hybrid protein conferred all FepA functions but no BtuB functions. The presence of the btuB451 mutation in this fusion gene eliminated all of its tonB-coupled reactions, showing that the TonB box of FepA could be replaced by that from BtuB. These results suggest that the TonB-box region of BtuB is involved in active transport in a manner dependent not on the identity of specific side chains but on the local secondary structure.     

Escherichia coli TonB protein is exported from the cytoplasm without proteolytic cleavage of its amino terminus

The requirement for TonB protein in a variety of membrane-related processes suggests that TonB is an envelope protein. Consistent with this suggestion, the deduced TonB amino acid sequence (Postle, K., and Good, R. F., (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 5235-5239) contains an amino-terminal region similar to leader (signal) sequences of exported proteins, although its charged region falls outside the rules which characterize these sequences (von Heijne, G. (1985) J. Mol. Biol. 184, 99-105). The deduced TonB amino acid sequence contains three potential methionine start codons in the first six codons of the open reading frame. In this report, we show, by Edman degradation of [35S]methionine-labeled protein, that TonB protein synthesized in vitro initiates at the third of these methionine codons. A method for detecting TonB synthesized in vivo has been developed that involves expression of TonB from the lambda PL promoter and pulse labeling with [35S]methionine. TonB synthesized in vivo has a chemical half-life of 10 min at 42 degrees C. It is exported from the cytoplasm, as determined by proteinase K accessibility experiments. It fractionates with spheroplasts under conditions where maltose-binding protein fractionates with the periplasm. It has the same mobility in three different polyacrylamide gel systems as TonB synthesized in vitro. We concluded that the amino terminus of TonB is uncleaved following its export from the cytoplasm and that TonB is a membrane-associated protein. Characterization of a tonB-phoA gene fusion suggests that the amino-terminal 41 amino acids of TonB are sufficient to promote export of the fusion protein and presumably TonB as well. Models for TonB orientation within the cell envelope are presented.     

The adaptive response to alkylation damage. Constitutive expression through a mutation in the coding region of the ada gene

We have shown by genetic mapping, molecular cloning, and DNA sequencing that four Escherichia coli mutants, which express the adaptive response to alkylation damage constitutively, are mutated in the ada gene. All four mutant ada genes have two GC to AT transition mutations in the coding region and encode altered Ada proteins with two amino acid substitutions in the N-terminal domain. E. coli carrying the mutated ada genes on recombinant plasmids overexpressed both the mutated ada gene and the chromosomal alkA gene. This observation indicates that the mutant Ada proteins act as strong positive regulators of the ada and alkA genes in the absence of DNA alkylation. One mutant protein, Ada-11, was shown to be a strong activator of ada gene expression in a cell-free system. An altered pattern of tryptic digestion of the Ada-11 protein compared with the wild-type Ada protein suggested that it has a different conformation. One amino acid substitution, namely methionine residue 126 replaced by isoleucine, occurred in all four mutant Ada proteins, and this mutation alone was sufficient to convert the Ada protein into a strong activator of ada and alkA gene expression in vivo.     

Demonstration and characterization of a specific interaction between gonococcal transferrin binding protein A and TonB

Iron scavenging by Neisseria gonorrhoeae is accomplished by the expression of receptors that are specific for host iron-binding proteins, such as transferrin and lactoferrin. Efficient transferrin-iron acquisition is dependent on the combined action of two proteins, designated TbpA and TbpB. TbpA is a TonB-dependent outer membrane receptor, whereas TbpB is lipid modified and serves to increase the efficiency of transferrin-iron uptake. Both proteins, together or separately, can be isolated from the gonococcal outer membrane by using affinity chromatography techniques. In the present study, we identified an additional protein in transferrin-affinity preparations, which had an apparent molecular mass of 45 kDa. The ability to copurify this protein by transferrin affinity was dependent upon the presence of TbpA and not TbpB. The amino-terminal sequence of the 45-kDa protein was identical to the amino terminus of gonococcal TonB, indicating that TbpA stably interacted with TonB, without the addition of chemical cross-linkers. Using immunoprecipitation, we could recover TbpA-TonB complexes without the addition of transferrin, suggesting that ligand binding was not a necessary prerequisite for TonB interaction. In contrast, a characterized TonB box mutant of TbpA did not facilitate interaction between these two proteins such that complexes could be isolated. We generated an in-frame deletion of gonococcal TonB, which removed 35 amino acids, including a Neisseria-specific, glycine-rich domain. This mutant protein, like the parental TonB, energized TbpA to enable growth on transferrin. Consistent with the functionality of this deletion derivative, TbpA-TonB complexes could be recovered from this strain. The results of the present study thus begin to define the requirements for a functional interaction between gonococcal TbpA and TonB.     

Dominant negative mutator mutations in the mutS gene of Escherichia coli.

The MutS protein of Escherichia coli is part of the dam-directed MutHLS mismatch repair pathway which rectifies replication errors and which prevents recombination between related sequences. In order to more fully understand the role of MutS in these processes, dominant negative mutS mutations on a multicopy plasmid were isolated by screening transformed wild-type cells for a mutator phenotype, using a Lac+ papillation assay. Thirty-eight hydroxylamine- and 22 N-methyl-N'-nitro-N-nitrosoguanidine-induced dominant mutations were isolated. Nine of these mutations altered the P-loop motif of the ATP-binding site, resulting in four amino acid substitutions. With one exception, the remaining sequenced mutations all caused substitution of amino acids conserved during evolution. The dominant mutations in the P-loop consensus caused severely reduced repair of heteroduplex DNA in vivo in a mutS mutant host strain. In a wild-type strain, the level of repair was decreased by the dominant mutations to between 12 to 90% of the control value, which is consistent with interference of wild-type MutS function by the mutant proteins. Increasing the wild-type mutS gene dosage resulted in a reversal of the mutator phenotype in about 60% of the mutant strains, indicating that the mutant and wild-type proteins compete. In addition, 20 mutant isolates showed phenotypic reversal by increasing the gene copies of either mutL or mutH. There was a direct correlation between the levels of recombination and mutagenesis in the mutant strains, suggesting that these phenotypes are due to the same function of MutS.     

Mutations that alter the signal sequence of alkaline phosphatase in Escherichia coli.

A phoA-lacZ gene fusion was used to isolate mutants altered in the alkaline phosphatase signal sequence. This was done by selecting Lac+ mutants from a phoA-lacZ fusion strain that produces a membrane-bound hybrid protein and is unable to grow on lactose. Two such mutant derivatives were characterized. The mutations lie within the phoA portion of the fused gene and cause internalization of the hybrid protein. When the mutations were genetically recombined into an otherwise wild-type phoA gene, they interfered with export of alkaline phosphatase to the periplasm. The mutant alkaline phosphatase protein was found instead in the cytoplasm in precursor form. DNA sequence analysis demonstrated that both mutations lead to amino acid alterations in the signal sequence of alkaline phosphatase.     

Hybrid protein between ribosomal protein S16 and RimM of Escherichia coli retains the ribosome maturation function of both proteins

The RimM protein in Escherichia coli is associated with free 30S ribosomal subunits but not with 70S ribosomes and is important for efficient maturation of the 30S subunits. A mutant lacking RimM shows a sevenfold-reduced growth rate and a reduced translational efficiency. Here we show that a double alanine-for-tyrosine substitution in RimM prevents it from associating with the 30S subunits and reduces the growth rate of E. coli approximately threefold. Several faster-growing derivatives of the rimM amino acid substitution mutant were found that contain suppressor mutations which increased the amount of the RimM protein by two different mechanisms. Most of the suppressor mutations destabilized a secondary structure in the rimM mRNA, which previously was shown to decrease the synthesis of RimM by preventing the access of the ribosomes to the translation initiation region on the rimM mRNA. Three other independently isolated suppressor mutations created a fusion between rpsP, encoding the ribosomal protein S16, and rimM on the chromosome as a result of mutations in the rpsP stop codon preceding rimM. A severalfold-higher amount of the produced hybrid S16-RimM protein in the suppressor strains than of the native-sized RimM in the original substitution mutant seems to explain the suppression. The S16-RimM protein but not any native-size ribosomal protein S16 was found both in free 30S ribosomal subunits and in translationally active 70S ribosomes of the suppressor strains. This suggests that the hybrid protein can substitute for S16, which is an essential protein probably because of its role in ribosome assembly. Thus, the S16-RimM hybrid protein seems capable of carrying out the important functions that native S16 and RimM have in ribosome biogenesis.     

Identification of a mutation in the arylsulfatase A gene of a patient with adult-type metachromatic leukodystrophy.

To analyze the genetic abnormality in a Japanese patient with adult-type metachromatic leukodystrophy (MLD), we first elucidated the genomic organization of the human arylsulfatase A (ASA) gene and then compared the nucleotide sequences of exons and splice junctions of the mutant ASA gene to those of a normal control. We have identified a new mutation, a G-to-A transition in exon 2, which results in amino acid substitution of Asp for 99Gly. In a transient expression study, COS cells transfected with the mutant cDNA carrying 99Gly----Asp did not show an increase of ASA activity, which confirms that the mutation is a cause of adult-type MLD.     

Mutations in the Escherichia coli receptor FepA reveal residues involved in ligand binding and transport

FepA is the Escherichia coli outer membrane receptor for ferric enterobactin, colicin D and colicin B. The transport processes through FepA are energy-dependent, relying on the periplasmic protein TonB to interact with FepA. Through this interaction, TonB tranduces energy derived from the cytoplasmic membrane across the periplasmic space to FepA. In this study, random mutagenesis strategies were used to define residues of FepA important for its function. Both polymerase chain reaction (PCR)-generated random mutations in the N-terminal 180 amino acids of FepA and spontaneous chromosomal fepA mutations were selected by resistance to colicin B. The PCR mutagenesis strategy targeted the N-terminus because it forms a plug inside the FepA barrel that is expected to be involved in ligand binding, ligand transport, and interaction with TonB. We report the characterization of 15 fepA missense mutations that were localized to three regions of the FepA receptor. The first region was a stretch of eight amino acids referred to as the TonB box. The second region included extracellular loops of both the barrel and the plug. A third region formed a cluster near the barrel wall around positions 75 and 126 of the plug. These mutations provide initial insight into the mechanisms of ligand binding and transport through the FepA receptor.     

A previously unidentified gene in the spc operon of Escherichia coli K12 specifies a component of the protein export machinery

The gene prlA codes for a factor that appears to function in the export of proteins in Escherichia coli. This conclusion is based on the finding that mutations altering the prlA gene product restore export of envelope proteins with defective signal sequences. Previous results showed that the prlA gene lies in an operon (spc) known to code for ten different ribosomal proteins. Our studies show that the prlA gene lies promoter-distal to the last known ribosomal protein gene in this operon. Evidence from gene fusions constructed in vitro suggests that prlA codes for a protein containing at least 300 amino acids. Thus a heretofore unidentified protein specified by a gene within the spc operon appears to be a component of the cellular protein export machinery.     

Identification and characterization of a novel gene, hos3+, the function of which is necessary for growth under high osmotic stress in fission yeast

hos3 mutants of the fission yeast Schizosaccharomyces pombe showed the phenotype of high osmolarity sensitivity for growth. An S. pombe strain carrying the hos3-M26 allele cannot form colonies on agar plates containing 2 M glucose, but the parental strain can do so very well, as demonstrated previously. The hos3+ gene was cloned and identified as one that encodes a small protein of 94 amino acids, which shows no sequence similarity to any other proteins in the current databases. A hos3delta strain, which we then constructed, had the phenotype of high osmolarity sensitivity, as in the case of the original hos3-M26 mutant. More interestingly, when these hos- cells were grown in the non-permissive growth condition in the presence of 2 M glucose, we found that unusually many septated cells were accumulated after a prolonged incubation. A multicopy suppressor gene for hos- mutations was also isolated and identified as the dsk1+ gene encoding a protein kinase, which was previously suggested to be implicated in a process of the mitotic regulation of S. pombe. The function of the hos3+ gene is discussed from these results.     

Suppressor analysis suggests a multistep, cyclic mechanism for protein secretion in Escherichia coli.

The sec/prl gene products catalyze the translocation of precursor proteins from the cytoplasm of Escherichia coli. Recessive, conditionally lethal mutant alleles of these genes (sec mutations) cause a generalized defect in protein secretion; dominant suppressor mutant alleles (prl mutations) restore export of precursor proteins with altered signal sequences. In prl strains, a precursor protein with a defective signal sequence can be selectively targeted to the suppressor gene product. When a precursor LacZ hybrid protein is used, the targeted prl protein is inactivated by the large, toxic hybrid molecule, a result termed suppressor-directed inactivation (SDI). Using SDI, two different secretion-related complexes can be generated: a pretranslocation complex that contains a hybrid protein with an unprocessed signal sequence, and a translocation complex in which the hybrid protein is jammed in transmembrane orientation with the signal sequence cleaved. Additional Sec proteins that are contained within, and thus sequestered by, each of these complexes can be identified when their functional levels are lowered using the conditional lethal sec mutations. Results of this genetic analysis suggest a multistep pathway for protein secretion in which the translocation machinery assembles on demand.     

Insight from TonB hybrid proteins into the mechanism of iron transport through the outer membrane

We created hybrid proteins to study the functions of TonB. We first fused the portion of Escherichia coli tonB that encodes the C-terminal 69 amino acids (amino acids 170 to 239) of TonB downstream from E. coli malE (MalE-TonB69C). Production of MalE-TonB69C in tonB(+) bacteria inhibited siderophore transport. After overexpression and purification of the fusion protein on an amylose column, we proteolytically released the TonB C terminus and characterized it. Fluorescence spectra positioned its sole tryptophan (W213) in a weakly polar site in the protein interior, shielded from quenchers. Affinity chromatography showed the binding of the TonB C-domain to other proteins: immobilized TonB-dependent (FepA and colicin B) and TonB-independent (FepADelta3-17, OmpA, and lysozyme) proteins adsorbed MalE-TonB69C, revealing a general affinity of the C terminus for other proteins. Additional constructions fused full-length TonB upstream or downstream of green fluorescent protein (GFP). TonB-GFP constructs had partial functionality but no fluorescence; GFP-TonB fusion proteins were functional and fluorescent. The activity of the latter constructs, which localized GFP in the cytoplasm and TonB in the cell envelope, indicate that the TonB N terminus remains in the inner membrane during its biological function. Finally, sequence analyses revealed homology in the TonB C terminus to E. coli YcfS, a proline-rich protein that contains the lysin (LysM) peptidoglycan-binding motif. LysM structural mimicry occurs in two positions of the dimeric TonB C-domain, and experiments confirmed that it physically binds to the murein sacculus. Together, these findings infer that the TonB N terminus remains associated with the inner membrane, while the downstream region bridges the cell envelope from the affinity of the C terminus for peptidoglycan. This architecture suggests a membrane surveillance model of action, in which TonB finds occupied receptor proteins by surveying the underside of peptidoglycan-associated outer membrane proteins.     

The mature portion of Escherichia coli maltose-binding protein (MBP) determines the dependence of MBP on SecB for export.

The product of the secB gene is required for export of a subset of secreted proteins to the outer membrane and periplasm of Escherichia coli. Precursor maltose-binding protein (MBP) accumulates in the cytoplasm of secB-carrying mutants, but export of alkaline phosphatase is only minimally affected by secB mutations. When export of MBP-alkaline phosphatase hybrid proteins was analyzed in wild-type and secB-carrying mutant strains, the first third of mature MBP was sufficient to render export of the hybrid proteins dependent on SecB. Substitution of a signal sequence from a SecB-independent protein had no effect on SecB-dependent export. These findings show that the first third of mature MBP is capable of conferring export incompetence on an otherwise competent protein.     

Rous sarcoma virus variants that encode src proteins with an altered carboxy terminus are defective for cellular transformation.

The src gene of Rous sarcoma virus (v-src) and its cellular homolog, the c-src gene, share extensive sequence homology. The most notable differences between these genes reside in the region encoding the carboxy terminus of the src proteins. We constructed mutations within the 3' end of the v-src gene to determine the significance of this region to the transforming potential of the v-src protein, pp60v-src. The mutants CHdl300 and CHis1511 contain mutations that alter the last 23 amino acids of pp60v-src, whereas the mutant CHis1545-C contains a linker insertion that alters the last 11 amino acids of pp60v-src, and the mutant CHis1545-H contains a linker insertion that results in a 9-amino-acid insertion at position 415. Plasmids bearing each of these mutations were unable to transform chicken cells when introduced into these cells by DNA transfection. In addition, the structurally altered src proteins encoded by the mutants had much-reduced levels of tyrosine protein kinase activity in vivo, as measured by autophosphorylation and phosphorylation of the 34,000-Mr cellular protein, and in vitro, as determined by measuring the level of pp60src autophosphorylation. These data indicate that the carboxy-terminal amino acid sequences play an important role in maintaining the structure of the catalytic domain of pp60v-src. In contrast, the transfection of chicken cells with plasmid DNA containing a chimeric v-c-src gene resulted in morphological cell transformation and the synthesis of an enzymatically active hybrid protein. Therefore, the carboxy-terminal sequence alterations observed in the c-src protein do not alone serve to alter the functional activity of a hybrid v-c-src protein appreciably.     

Interaction of the Extreme N-Terminal Region of FliH with FlhA Is Required for Efficient Bacterial Flagellar Protein Export

The flagellar type III protein export apparatus plays an essential role in the formation of the bacterial flagellum. FliH forms a complex along with FliI ATPase and is postulated to provide a link between FliI ring formation and flagellar protein export. Two tryptophan residues of FliH, Trp7 and Trp10, are required for the effective docking of the FliH-FliI complex to the export gate made of six membrane proteins. However, it remains unknown which export gate component interacts with these two tryptophan residues. Here, we performed targeted photo-cross-linking of the extreme N-terminal region of FliH (FliH(EN)) with its binding partners. We replaced Trp7 and Trp10 of FliH with p-benzoyl-phenylalanine (pBPA), a photo-cross-linkable unnatural amino acid, to produce FliH(W7pBPA) and FliH(W10pBPA). They were both functional and were photo-cross-linked with one of the export gate proteins, FlhA, but not with the other gate proteins, indicating that these two tryptophan residues are in close proximity to FlhA. Mutant FlhA proteins that are functional in the presence of FliH and FliI but not in their absence showed a significantly reduced function also by N-terminal FliH mutations even in the presence of FliI. We suggest that the interaction of FliH(EN) with FlhA is required for anchoring the FliI hexamer ring to the export gate for efficient flagellar protein export.