Genetic mapping of starch- and Lambda-receptor sites in maltoporin: identification of substitutions causing direct and indirect effects on binding sites by cysteine mutagenesis

Cysteine mutagenesis was used to test the proximity of 16 residues to protein-ligand interaction sites in maltoporin (LamB protein). LamB protein with additional cysteines was incorporated into the outer membrane of Escherichia coli except with a Ser-30----Cys substitution. Phage Lambda and starch binding was assayed before and after incubation of mutants with six thiol-specific reagents. Four categories of mutation were recognized on the basis of phenotype and modification for each of the Lambda- and starch binding sites. The thiol modification experiments helped to clarify whether the phenotype of a mutation was due to a substitution at the binding site or an indirect perturbation of the structure. This study suggests that the cysteine mutagenesis/thiol modification approach may be usefully applied to the operational mapping of surface-accessible binding sites or epitopes.     

A cluster of charged and aromatic residues in the C-terminal portion of maltoporin participates in sugar binding and uptake

The maltoporin LamB of Escherichia coli K12 is a trimeric protein which facilitates the diffusion of maltose and maltodextrins through the bacterial outer membrane, and also acts as a non-specific porin for small hydrophilic molecules as well as a receptor for phages. Loop L9 (residues 375 to 405) is the most distal and largest surface-exposed loop of LamB. It comprises a central portion, which varies in size and sequence in the maltoporins of known sequence, flanked by two conserved regions containing charged and aromatic residues. In order to identify the residues within the proximal region that are specifically involved in sugar utilization, we used site-directed mutagenesis to change, individually, each of the charged (five) and aromatic (three) residues in the region 371 to 379 into alanine. None of the eight single amino acid substitutions affected the phage receptor activity of LamB. In contrast, they all affected, to variable extents, maltoporin functions. For all the mutants, very good correlations were observed between the effects on sugar binding and on in vivo uptake. In no case were maltoporin functions completely abolished. Mutants E374 A and W376 A were the most impaired (with over 60% reduction in dextrin binding and in vivo uptake of maltose and maltopentaose). These two mutations also led to an increased bacterial sensitivity to bacitracin and vancomycin. The functional and structural implications are discussed. Received: 29 April 1998 / Accepted: 23 July 1998     

Site-directed mutagenesis of the greasy slide aromatic residues within the LamB (maltoporin) channel of Escherichia coli: effect on ion and maltopentaose transport

The 3D-structure of the maltooligosaccharide-specific LamB-channel of Escherichia coli (also called maltoporin) is known from X-ray crystallography. The 3D structure suggests that a number of aromatic residues (Y6, Y41, W74, F229, W358 and W420) within the channel lumen are involved in carbohydrate and ion transport. All aromatic residues were replaced by alanine-scanning mutagenesis. Furthermore, LamB mutants were created in which two, three, four, five and all six aromatic residues were replaced to study their effects on ion and maltopentaose transport through LamB. The purified mutant proteins were reconstituted into lipid bilayer membranes and the single-channel conductance of the mutants was studied in conductance experiments. The results suggest that all aromatic residues provide some steric hindrance for ion transport through LamB. Highest impact is provided by Y6 and Y41 that are localized opposite Y118, which form the central constriction of the LamB channel. Stability constants for binding of maltopentaose to the mutant channels were measured using titration experiments with the carbohydrate. The mutation of one or several aromatic residue(s) led to a substantial decrease of the stability constant of binding. The highest effect was observed when all aromatic residues were replaced by alanine because no binding of maltopentaose could be detected in such a case. However, binding was again possible when Y118 was replaced by tryptophan. The carbohydrate-induced block of the channel function could be used also for the study of current noise through the different mutant LamB-channels. The analysis of the power density spectra of some of the mutants allowed the evaluation of the on-rate and off-rate constants (k1 and k(-1)) of carbohydrate binding to the binding site inside the channels. The results suggest that both on-rate and off-rate constants were affected by the mutations. For most mutants, k1 decreased and k(-1) increased. The possible influence of the aromatic residues of the greasy slide on carbohydrate and ion transport through LamB is discussed.     

Genetic mapping of antigenic determinants on a membrane protein

The antigenic determinants recognized by two monoclonal antibodies were mapped on LamB, an outer membrane protein of Escherichia coli. The procedure consisted of performing immunoprecipitation experiments with extracts of strains which produced truncated fragments of LamB, either in a free form (deletion and nonsense mutants) or fused to another polypeptide (malK-lamB and lamB-lacZ fusion strains). The conclusion is that the two antigenic determinants are located within 70 residues from the COOH-terminal end of LamB, which contains a total of 421 amino acids. Since these two antigenic sites were previously demonstrated to be exposed at the cell surface, it follows that a COOH-terminal portion of LamB must be located on the outer surface of the outer membrane.     

Mutations affecting antigenic determinants of an outer membrane protein of Escherichia coli.

The Escherichia coli LamB protein is located in the outer membrane. It is both a component of the maltose and maltodextrin transport system, and the receptor for phages lambda and K10. It is a trimer composed of three identical polypeptide chains, each containing 421 residues. Six independent mutants have been isolated, in which the LamB protein is altered in its interaction with one or more monoclonal antibodies specific for regions of the protein that are exposed at the cell surface. Some of the mutations also altered the binding site for phage lambda. All of the mutations were clustered in the same region of the lamB gene, corresponding to residues 333-394 in the polypeptide. This and previous results strongly suggest that a rather large segment of the LamB polypeptide, extending from residue 315 to 401, is exposed at the outer face of the outer membrane. This segment would bear the epitopes for the four available anti-LamB monoclonal antibodies that react with the cell surface, and part of the binding site for phage lambda.     

Signal sequence processing is required for the assembly of LamB trimers in the outer membrane of Escherichia coli.

Proteins destined for either the periplasm or the outer membrane of Escherichia coli are translocated from the cytoplasm by a common mechanism. It is generally assumed that outer membrane proteins, such as LamB (maltoporin or lambda receptor), which are rich in beta-structure, contain additional targeting information that directs proper membrane insertion. During transit to the outer membrane, these proteins may pass, in soluble form, through the periplasm or remain membrane associated and reach their final destination via sites of inner membrane-outer membrane contact (zones of adhesion). We report lamB mutations that slow signal sequence cleavage, delay release of the protein from the inner membrane, and interfere with maltoporin biogenesis. This result is most easily explained by proposing a soluble, periplasmic LamB assembly intermediate. Additionally, we found that such lamB mutations confer several novel phenotypes consistent with an abortive attempt by the cell to target these tethered LamB molecules. These phenotypes may allow isolation of mutants in which the process of outer membrane protein targeting is altered.     

Mutant of LolA, a lipoprotein-specific molecular chaperone of Escherichia coli, defective in the transfer of lipoproteins to LolB

The outer membrane-specific lipoproteins of Escherichia coli are released from the inner membrane as a water-soluble complex with LolA and then transferred to the outer membrane receptor, LolB. LolA thus plays a critical role in the sorting and outer membrane localization of lipoproteins. To dissect the LolA function, the highly conserved residues were subjected to random mutagenesis, followed by selection for a growth defect. LolA(R43L), one of mutants thus constructed, possessed Leu in place of Arg at position 43 and caused accumulation of the LolA(R43L)-lipoprotein complex in the periplasm. LolA(R43L) was as active as wild-type LolA as to the release of lipoproteins from spheroplasts. In marked contrast, the transfer of lipoproteins from LolA(R43L) to LolB was completely inhibited, indicating that Arg at position 43 of LolA is involved in the lipoprotein transfer reaction.     

Sucrose transport through maltoporin mutants of Escherichia coli.

Maltoporin (LamB) and sucrose porin (ScrY) reside in the bacterial outer membrane and facilitate the passive diffusion of maltodextrins and sucrose, respectively. To gain further insight into the determinants of solute specificity, LamB mutants were designed to allow translocation of sucrose, which hardly translocates through wild-type LamB. Three LamB mutants were studied. (a) Based on sequence and structure alignment of LamB with ScrY, two LamB triple mutants were generated (R109D, Y118D,D121F; R109N,Y118D,D121F) to mimic the ScrY constriction. The crystal structure of the first of these mutants was determined to be 3.2 A and showed an increased ScrY-like cross-section except for D109 that protrudes into the channel. (b) Based on this crystal structure a double mutant was generated by truncation of the two residues that obstruct the channel most in LamB (R109A,Y118A). Analysis of liposome swelling and in vivo sugar uptake demonstrated substantial sucrose permeation through all mutants with the double alanine mutant performing best. The triple mutants did not show a well-defined binding site as indicated by sugar-induced ion current noise analysis, which can be explained by remaining steric interference as deduced from the crystal structure. Binding, however, was observed for the double mutant that had the obstructing residues truncated to alanines.     

Antibodies against synthetic peptides and the topology of LamB, an outer membrane protein from Escherichia coli K12

LamB, an outer membrane protein from Escherichia coli K12, is involved in the transport of maltose and maltodextrins across the outer membrane and constitutes a receptor for a number of bacteriophages. A recent folding model proposes that LamB spans the outer membrane through a number of transmembranous segments separated by regions exposed either to the cell exterior or to the periplasm. This model is essentially based on predictions of structure and genetic arguments relying on the hypothesis that the mutations studied did not alter the folding of the protein. In order to obtain direct evidence with the unaltered protein, we elicited polyclonal antibodies against synthetic peptides corresponding to several LamB sequences. We chose four regions. Three of them [aa 147-161 (peptide 2), aa 371-385 (peptide 3), and aa 399-413 (peptide 4)] are predicted to face the outside of the cell, and the fourth (aa 19-33 (peptide 1)] is predicted to be periplasmic. By immunoblotting against extracts of various mutants, these antibodies were shown to be specific for LamB and targeted to the selected regions. In some cases, the recognition sites for antibodies were narrowed down to parts of a region. In vivo, on intact cells, anti-peptides 2, 3, and 4 reacted with LamB in an ELISA; this confirmed that regions of peptide 2 and 3 are located, at least in part, at the cell exterior and provided the first proof for a similar, situation of the region of peptide 4. Under the same conditions, anti-peptide 1 did not react with LamB.(ABSTRACT TRUNCATED AT 250 WORDS)     

Export-defective lamB protein is a target for translational control caused by ompC porin overexpression.

Overexpression of OmpC protein from an inducible plasmid vector reduced the amount of the precursor form of LamB protein in LamB signal sequence mutants. The stability of the precursor form of LamB protein was not affected, indicating that the effect of OmpC overexpression was on the synthesis of the precursor rather than on degradation. These results indicate that a functional signal sequence is not required on an outer membrane protein for it to be a target for translational control.     

Linker mutagenesis in the gene of an outer membrane protein of Escherichia coli, lamB

In order to identify sequences involved in the localization of LamB, an outer membrane protein from E coli K12, mutagenesis by linker insertion has been performed on a lamB gene copy carried on a plasmid devised for this purpose. An analysis of the first set of 16 clones constructed by this technique shows that, in these clones, the lamB protein is altered either by frameshift mutations leading to abnormal COOH terminal (usually premature termination) or by in-phase deletions or small insertions. Except for two in-phase linker insertions, which only slightly changed the behavior of the protein, the modified proteins are either toxic to cell growth or unstable. In all cases examined so far, the modified proteins were in the outer membrane. We suggest that toxicity is due to incorrect folding, which leads to disruption of the outer membrane. The nature of the genetic alterations leads to the hypothesis that the first 183 amino acids of the LamB mature protein contain, together with the signal sequence, all the instructions needed for proper localization.     

Role of a disulfide bond in the thermal stability of the LamB protein trimer in Escherichia coli outer membrane

In order to understand the unusual heat resistance of LamB protein (the outer membrane component of the maltose transport system in Escherichia coli and its receptor for bacteriophage lambda), we investigated the role of its 2 cysteinyl residues. Our studies show that Cys22 and Cys38 form an intrasubunit disulfide bond which contributes to the heat stability of the LamB protein trimer. Physical evidence for the disulfide was obtained by using site-directed mutagenesis to convert Asn36 to Met, which allowed cyanogen bromide cleavage between the 2 cysteines. Upon reduction one of the N36M fragments migrated as two pieces, resolved by two-dimensional polyacrylamide gel electrophoresis. Other mutagenized LamB proteins, in which 1 or both Cys residues were converted to Ser, exhibited a sharp loss of thermal stability. In contrast to wild-type LamB protein trimer, which does not dissociate to monomers even after 60 min at 100 degrees C, only 10-15% of the mutant LamB proteins remain trimeric after boiling 10 min. The disulfide bond in LamB protein is not required for its transport function, since both mutagenized LamB protein and N-ethylmaleimide-labeled LamB protein exhibit normal uptake of sugars in proteoliposomes. Finally, the disulfide bond must not be between subunits of the LamB trimer since reversible dissociation of trimer is achieved by low pH or denaturants in the absence of reducing agent.     

A genetic approach for analyzing the pathway of LamB assembly into the outer membrane of Escherichia coli

Results presented in this study demonstrate that a mutation which inserts an additional tyrosine between the 2 tyrosines at residues 118 and 119 of mature LamB protein results in a temperature-dependent assembly defect. This defect leads to the accumulation of an intermediate at the restrictive temperature that is most likely an assembly-defective monomer. These monomers are rapidly degraded in the wild type (htrA+) strain, and the biphasic kinetics of this degradation indicate that the mutation affects the assembly process and not the final product, i.e. stable trimers. In addition, our data show that the temperature-dependent assembly defect in the mutant strain is reversible, and therefore the accumulated monomers represent a true assembly intermediate. Fractionation studies show that the monomers, which can be accumulated in htrA (degP) mutants at the restrictive temperature, are associated with the outer membrane, indicating that trimerization of LamB is not a prerequisite for localization.     

Testing the '+2 rule' for lipoprotein sorting in the Escherichia coli cell envelope with a new genetic selection

We report a novel strategy for selecting mutations that mislocalize lipoproteins within the Escherichia coli cell envelope and describe the mutants obtained. A strain carrying a deletion of the chromosomal malE gene, coding for the periplasmic maltose-binding protein (MalE), cannot use maltose unless a wild-type copy of malE is present in trans. Replacement of the natural signal peptide of preMalE by the signal peptide and the first four amino acids of a cytoplasmic membrane-anchored lipoprotein resulted in N-terminal fatty acylation of MalE (lipoMalE) and anchoring to the periplasmic face of the cytoplasmic membrane, where it could still function. When the aspartate at position +2 of this protein was replaced by a serine, lipoMalE was sorted to the outer membrane, where it could not function. Chemical mutagenesis followed by selection for maltose-using mutants resulted in the identification of two classes of mutations. The single class I mutant carried a plasmid-borne mutation that replaced the serine at position +2 by phenylalanine. Systematic substitutions of the amino acid at position +2 revealed that, besides phenylalanine, tryptophan, tyrosine, glycine and proline could all replace classical cytoplasmic membrane lipoprotein sorting signal (aspartate +2). Analysis of known and putative lipoproteins encoded by the E. coli K-12 genome indicated that these amino acids are rarely found at position +2. In the class II mutants, a chromosomal mutation caused small and variable amounts of lipoMalE to remain associated with the cytoplasmic membrane. Similar amounts of another, endogenous outer membrane lipoprotein, NlpD, were also present in the cytoplasmic membrane in these mutants, indicating a minor, general defect in the sorting of outer membrane lipoproteins. Four representative class II mutants analysed were shown not to carry mutations in the lolA or lolB genes, known to be involved in the sorting of lipoproteins to the outer membrane.     

The development of a thermostable CiP (Coprinus cinereus peroxidase) through in silico design

Protein thermostability is a crucial issue in the practical application of enzymes, such as inorganic synthesis and enzymatic polymerization of phenol derivatives. Much attention has been focused on the enhancement and numerous successes have been achieved through protein engineering methods. Despite fruitful results based on random mutagenesis, it was still necessary to develop a novel strategy that can reduce the time and effort involved in this process. In this study, a rapid and effective strategy is described for increasing the thermal stability of a protein. Instead of random mutagenesis, a rational strategy was adopted to theoretically stabilize the thermo labile residues of a protein using computational methods. Protein residues with high flexibility can be thermo labile due to their large range of movement. Here, residue B factor values were used to identify putatively thermo labile residues and the RosettaDesign program was applied to search for stable sequences. Coprinus cinereus (CiP) heme peroxidase was selected as a model protein for its importance in commercial applications, such as the polymerization of phenolic compounds. Eleven CiP residues with the highest B factor values were chosen as target mutation sites for thermostabilization, and then redesigned using RosettaDesign to identify sequences. Eight mutants based on the redesigns, were produced as functional enzymes and two of these (S323Y and E328D) showed increased thermal stability over the wild‐type in addition to conserved catalytic activity. Thus, this strategy can be used as a rapid and effective in silico design tool for obtaining thermostable proteins. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

A model of maltodextrin transport through the sugar-specific porin, LamB, based on deletion analysis.

LamB facilitates the uptake of maltose and maltodextrins across the bacterial outer membrane and acts as a general porin for small molecules. Using directed deletion mutagenesis we removed several regions of the LamB polypeptide and identified a polypeptide loop that both constricts the maltoporin channel and binds maltodextrins. In conjunction with a second sugar binding site that we identified at the rim of the channel, these data clarify, for the first time, the mechanism of transport through a substrate-specific porin. Furthermore, unlike the transverse loops of general porins, which originate from a central location in their primary structure, the loop that regulates LamB permeability originates from a C-terminal site. Thus LamB represents a second distinct class of porins in the bacterial outer membrane that is differently organized and separately evolved from OmpF-type, general porins.     

Permissive sites and topology of an outer membrane protein with a reporter epitope.

We are developing a genetic approach to study with a single antibody the folding and topology of LamB, an integral outer membrane protein from Escherichia coli K-12. This approach consists of inserting the same reporter foreign antigenic determinant (the C3 epitope from poliovirus) at different sites of LamB so that the resulting hybrid proteins have essentially kept the in vivo biological properties of LamB and therefore its cellular location and structure; the corresponding sites are called permissive sites. A specific monoclonal antibody can then be used to examine the position of the reporter epitope with respect to the protein and the membrane. We present an improved and efficient procedure that led us to identify eight new permissive sites in LamB. These sites appear to be distributed on both sides of the membrane. At one of them (after residue 253), the C3 epitope was detected on intact bacteria, providing the first direct argument for exposure of the corresponding LamB region at the cell surface. At this site as well as at four others (after residues 183, 219, 236, and 352), the C3 epitope could be detected with the C3 monoclonal antibody at the surface of the extracted trimeric LamB-C3 hybrid proteins. We provide a number of convergent arguments showing that the hybrid proteins are not strongly distorted with respect to the wild-type protein so that the conclusions drawn are also valid for this protein. These conclusions are essentially in agreement with the proposed folding model for the LamB protein. They agree, in particular, with the idea that regions 183 and 352 are exposed to the periplasm. In addition, they suggest that region 236 is buried at the external face of the outer membrane and that region 219 is exposed to the periplasm. Including the 3 sites previously determined, 11 permissive sites are now available in LamB, including 3 at the cell surface and most probably at least 3 in the periplasm. We discuss the nature of such sites, the generalization of this approach to other proteins, and possible applications.     

A new suppressor of a lamB signal sequence mutation, prlZ1, maps to 69 minutes on the Escherichia coli chromosome.

Reversion analysis has been employed to isolate suppressors that restore export of a unique LamB signal sequence mutant. The mutation results in a substitution of Arg for Met at position 19, which prevents LamB export to the outer membrane and leads to a Dex- phenotype. Unlike other LamB signal sequence mutants utilized for reversion analysis, LamB19R becomes stably associated with the inner membrane in an export-specific manner. In this study, Dex+ revertants were selected and various suppressors were isolated. One of the extragenic suppressors, designated prlZ1, was chosen for further study. prlZ1 maps to 69 min on the Escherichia coli chromosome. The suppressor is dominant and SecB dependent. In addition to its effect on lamB19R, prlZ1 suppresses the export defect of signal sequence point mutations at positions 12, 15, and 16, as well as several point mutations in the maltose-binding protein signal sequence. prlZ1 does not suppress deletion mutations in either signal sequence. This pattern of suppression can be explained by interaction of a helical LamB signal sequence with the suppressor.     

Two distinct regions of the large serine recombinase TnpX are required for DNA binding and biological function

The large serine recombinase, TnpX, from the Clostridium perfringens integrative mobilizable element Tn 4451 , consists of three domains and has two known DNA binding regions. In this study random and site-directed mutagenesis was used to identify other regions of TnpX that were required for biological activity. Genetic and biochemical analysis of these mutants led to the identification of important TnpX residues in the N-terminal catalytic pocket. In addition, another region of TnpX (aa 243–261), which is conserved within large serine recombinases, was shown to be essential for both excision and insertion. Mutation of charged residues within this region led to a loss of biological activity and aberrant DNA binding. This phenotype was mediated by interaction with the distal DNA binding region (aa 598–707). In these mutants, removal of residues 598–707 resulted in loss of DNA binding, despite the presence of the primary DNA binding region (aa 533–583). Analysis of mutations within the aa 243–261 region indicated that different protein conformations were involved in the insertion and the excision reactions. In summary, we have shown that TnpX is a complex protein that has multiple intra- and intermolecular interaction sites, providing insight into the structural and functional complexity of this important enzyme family.