Creating a bifunctional protein by insertion of beta-lactamase into the maltodextrin-binding protein.

Hybrid proteins were generated by inserting the penicillin-hydrolyzing enzyme, TEM beta-lactamase (Bla), into the maltodextrin-binding protein (MalE). The inserted Bla was functionally accommodated by MalE when it was placed within permissive sites. The maltose binding and penicillinase activities of purified hybrids were indistinguishable from those of the wild-type MalE and Bla proteins. Moreover, these hybrids displayed an additional unexpected property: maltose stabilized the active site of inserted Bla.

Silent and functional changes in the periplasmic maltose-binding protein of Escherichia coli K12. I. Transport of maltose.

The malE gene encodes the periplasmic maltose-binding protein (MBP). Nineteen mutations that still permit synthesis of stable MBP were generated by random insertion of a BamHI octanucleotide into malE and six additional mutations by in-vitro recombinations between mutant genes. The sequence changes were determined; in most cases the linker insertion is accompanied by a small deletion (30 base-pairs on average). The mutant MBP were studied for export, growth on maltose and maltodextrins, maltose transport and binding, and maltose-induced fluorescence changes. Sixteen mutant MBP (out of 21 studied in detail) were found in the periplasmic space: 12 of them retained a high affinity for maltose, and 10 activity for growth on maltose. The results show that several regions of MBP are dispensable for stability, substrate binding and export. Three regions (residues 207 to 220, 297 to 303 and 364 to 370) may be involved in interactions with the MalF or MalG proteins. A region near the C-terminal end is important for maltose binding. Two regions of the mature protein (residues 18 to 42 and 280 to 296) are required for export to, or solubility in, the periplasm.

Effect of point mutations on the in-vitro pore properties of maltoporin, a protein of Escherichia coli outer membrane.

Maltoporin (LamB protein), a protein of Escherichia coli outer membrane forms ionic channels with a selectivity for maltose and maltodextrins (Dargent et al., 1987). The effect of different point mutations on maltoporin pore properties was investigated in vitro with planar bilayers. The mutations belong to three classes in terms of selective maltose transport in vivo: class A (substitution at positions 259 and 382) does not affect maltose transport, class B (position 163 and 245) decreases maltose transport down to 20 to 30%, and class C (position 18) almost completely abolishes selective maltose transport. This in-vitro study reveals that class A does not affect the pore properties in contrast to class B substitutions. The class B maltoporins are still able to form channels but display some specific features and altered specificity for maltose and maltodextrins. The substitution (Gly18----Val) alters trimer stability and impedes pore function (class C mutant). Thus, there is a good correlation between the specific transport properties of the mutated maltoporins in vivo and their behavior in vitro. These data, in combination with the asymmetric orientation of the protein within the bilayer and topological considerations, indicate that residues 245 and 163 do not belong to the selectivity filter. Mutations at these sites cause hindrance at the mouth of the pore on the outer domain of maltoporin.

Structure of maltoporin from Salmonella typhimurium ligated with a nitrophenyl-maltotrioside.

The maltodextrin-specific (malto-)porin from Salmonella typhimurium has been crystallized. Its three-dimensional structure was determined at 2.4 A resolution (1 A = 0.1 nm). A comparison with the structure of the homologous porin from Escherichia coli as well as with the sequences of other related porins showed that there are regions of appreciable sequence and structure variability, despite close overall similarity. The maltoporin structure was analyzed with a bound nitrophenyl-maltotrioside as well as without ligand. Maltotrioside binding had a negligible effect on the polypeptide structure. It binds at the pore eyelet assuming a conformation close to the natural amylose helix.

Further sequence analysis of the phage lambda receptor site. Possible implications for the organization of the lamB protein in Escherichia coli K12.

We present the DNA sequence alterations due to seven lamB missense mutations yielding resistance to phages lambda and K10. They reveal five different amino acid positions in the LamB protein. Three positions (245, 247 and 249) define a new region required for phage adsorption. The two other positions (148 and 152) belong to a region where mutations to phage resistance has already been detected. These two regions are hydrophilic and could belong to turns of the protein located at the surface of the cell. All the missense mutational alterations to phage resistance sequenced in the LamB protein correspond to 10 sites located in four different segments of the polypeptide chain. We discuss their location in terms of the notion of phage receptor site and of a working model for the organization of this protein in the outer membrane of Escherichia coli.

malM, a new gene of the maltose regulon in Escherichia coli K12. II. Mutations affecting the signal peptide of the MalM protein.

malM is the last gene of the malK-lamB-malM operon of Escherichia coli K12. It encodes a periplasmic protein. Mutations affecting the hydrophobic core of the N-terminal extension of the MalM protein have been isolated. They result in an increase in amount and specific activity of a MalM-LacZ hybrid protein. This result confirms that the signal peptide of the MalM protein is functional.

malM, a new gene of the maltose regulon in Escherichia coli K12. I. malM is the last gene of the malK-lamB operon and encodes a periplasmic protein.

The structure and expression of the distal part of the malK-lamB operon in Escherichia coli was studied. DNA sequencing was performed as far as a HinfI restriction site located 1313 base-pairs downstream from gene lamB. The open reading frame, formerly called molA, which begins 245 base-pairs downstream from gene lamB, is longer than was initially thought, and was renamed malM. It could encode a protein of 306 amino acid residues. The complete malM open reading frame was cloned under control of the tac 12 promoter. In maxicells, the resulting plasmid permitted tac12-promoted synthesis of two polypeptides, encoded by gene malM, with apparent molecular weights of 37 X 10(3) and 34.5 X 10(3). We provide strong evidence that the 34.5 X 10(3) Mr protein is derived from the 37 X 10(3) Mr protein by processing at the amino-terminal end, and that this processed form is located in the periplasmic space. We show that the chromosomal malM gene is expressed as part of the malK-lamB operon, and that its product is periplasmic. Finally, we demonstrate with nuclease S1 mapping experiments that the mRNA terminates at a typical rho-independent terminator located about 45 base-pairs beyond the end of gene malM, which is thus the last gene of the malK-lamB operon.

Maltose transport and starch binding in phage-resistant point mutants of maltoporin. Functional and topological implications.

The relationships between the bacteriophage lambda binding site, the starch binding site and the pore formed by maltoporin (LamB protein, lambda receptor protein) were investigated. Bacteria with single amino acid substitutions in the maltoporin sequence, which were previously shown to be strongly reduced in phage lambda sensitivity, were assayed for maltose- (and maltodextrin) selective pore functions. Maltose transport assays was performed at low substrate concentrations, under conditions where LamB is limiting for transport. It revealed three classes of mutants. Class A is composed of mutants with no effect on transport (substitutions at amino acid residues 154, 155, 259, 382 and 401); class B corresponds to mutants with a significant but variable reduction in transport (sites 148, 151, 152, 163, 164, 245, 247 and 250); class C is represented by a single mutant for which transport is almost completely abolished (site 18). Starch binding was assayed by two different methods that gave compatible results. In class A mutants, binding was normal, while no binding was observed in the class C mutant. Binding was impaired to various extents in category B mutants. There was a correlation between the level of impairment of starch binding and impairment of maltose transport, consistent with the notion that the residues influencing starch binding are inside, or in close proximity to, the pore. These results, together with previous data on starch-binding mutants that were not affected in phage binding (substitutions at residues 8, 74, 82, 118 and 121), suggest that the binding sites for starch and phage lambda overlap but are distinct. Mutations affecting transport and starch binding are located in the first third of the protein and in the region of residues 245 to 250. Mutations affecting phage adsorption are located mainly in the last two-thirds of the protein. The topological constraints suggested by the results with the available mutants altered in the lamB gene were used to propose a revised model of maltoporin folding across the outer membrane as well as to define the outlines of footprints of macromolecular binding sites (phage, starch and monoclonal antibodies) on the surface of the protein.

Probing the structural role of an alpha beta loop of maltose-binding protein by mutagenesis: heat-shock induction by loop variants of the maltose-binding protein that form periplasmic inclusion bodies.

The maltose-binding protein (MBP) of Escherichia coli is the periplasmic receptor of the maltose transport system. Previous studies have identified amino acid substitutions in an alpha/beta loop of the structure of MBP that are critical for the in vivo folding. To probe genetically the structural role of this surface loop, we generated a library in which the corresponding codons 32 and 33 of malE were mutagenized. The maltose phenotype, which correlates with a biologically active structure of MBP in the periplasm, indicated a considerable variability in the loop residues compatible with a correct in vivo folding pathway of the protein. By the same genetic screens, we characterized loop-variant MBPs associated with a defective periplasmic folding pathway and aggregated into inclusion bodies. Heat-shock induction with production of misfolded loop variants was examined using both lon-lacZ and htrA-lacZ fusions. We found that the extent of formation of inclusion bodies in the periplasm of E. coli, from misfolded loop variant MBPs, correlated with the level of heat-shock response regulated by the alternate heat-shock sigma factor, sigma 24.

Refined structures of two insertion/deletion mutants probe function of the maltodextrin binding protein.

The X-ray structures of the maltose bound forms of two insertion/deletion mutants of the Escherichia coli maltodextrin binding protein, MalE322 and MalE178, have been determined and refined. MalE322 involves a one residue deletion, two residue insertion in a hinge segment connecting the two (N and C) domains of the protein, an area already identified as being critical for the correct functioning of the protein. MalE178 involves a nine residue deletion and two residue insertion in a helix at the periphery of the C-domain. The function of both mutant proteins is similar to the wild-type, although MalE322 increases the ability to transport maltose and maltodextrin whilst inhibiting the ability of the cell to grow on dextrins. Both proteins exhibit very localized and conservative conformational changes due to their mutations. The structure of MalE322 shows some deformation of the third hinge strand, indicating the likely cause of change in its biochemistry. MalE178 is stable and its activity virtually unchanged from the wild-type. This is most likely due to the long distance of the mutation from the binding site and conservation of the number of interactions between the area around the deletion site and the main body of the protein.

Genetic approach to the role of tryptophan residues in the activities and fluorescence of a bacterial periplasmic maltose-binding protein.

The periplasmic maltose-binding protein (MBP or MalE protein) of Escherichia coli is an essential element in the transport of maltose and maltodextrins and in the chemotaxis towards these sugars. On the basis of previous results suggesting their possible role in the activity and fluorescence of MBP, we have changed independently to alanine each of the eight tryptophan residues as well as asparagine 294, which is conserved among four periplasmic sugar-binding proteins. Five of the tryptophan mutations affected activity. In four cases (substitution of Trp62, Trp230, Trp232 and Trp340), there was a decrease in MBP affinity towards maltose correlated with modifications in transport and chemotaxis. According to the present state of the 2.3 A three-dimensional structure of MBP, all four residues are in the binding site. Residues Trp62 and Trp340 are in the immediate vicinity of the bound substrate and appear to have direct contacts with maltose; this is in agreement with the drastic increases in Kd values (respectively 67 and 300-fold) upon their substitution by alanine residues. The modest increase in Kd (12-fold) observed upon mutation of Trp230 would be compatible with the lesser degree of interaction this residue has with the bound substrate and the idea that it plays an indirect role, presumably by keeping other residues involved directly in binding in their proper orientation. Substitution of Trp232 resulted in a small increase in Kd value (2-fold) in spite of the fact that this residue is the closest to the ligand of the tryptophan residues according to the three-dimensional model. In the fifth case, replacement of Trp158, which is distant from the binding site, strongly reduced the chemotactic response towards maltose without affecting the transport parameters or the sugar-binding activities of the mutant protein. Trp158 may therefore be specifically implicated in the interaction of MBP with the chemotransducer Tar, but this effect is likely to be indirect, since Trp158 is buried in the structure of MBP. Of course, some structural rearrangements could be responsible in part for the effects of these mutations. The remaining four mutations were silent. The corresponding residues (Trp10, Trp94, Trp129 and Asn294) are all distant from the sugar-binding site on the crystallographic model of MBP, which is in agreement with their lack of effect on binding. In addition, our results show that they play no role in the interactions with the other proteins of the maltose transport (MalF, MalG or MalK) or chemotaxis (Tar) systems.(ABSTRACT TRUNCATED AT 400 WORDS)

Crystallization of genetically engineered active maltose-binding proteins, including an immunogenic viral epitope insertion.

Three mutants of the maltose- or maltodextrin-binding protein encoded by the malE gene of Escherichia coli, with extensive genetic changes, have been purified and crystallized in different crystal forms. Two of these mutant proteins, MalE178 and MalE341, carry net deletions of seven and 13 residues, respectively, near the surface of the molecule. These mutations have very little effect on either the transport activity of the mutant strains or the sugar-binding activity of the purified mutant proteins. The third mutant protein involves the insertion of an 11-residue peptide of the C3 epitope from type 1 poliovirus VP1 protein into the MalE178 deletion mutant, with retention of essentially all the biological properties of the wild-type and the immunological properties of the C3 epitope. We are undertaking three-dimensional structure analysis in order to understand how the protein accommodates these large changes in its surface structure and how the C3 epitope retains its immunological properties in this new environment. The same system could be used to determine easily the structures of other peptide epitopes, especially those in proteins with unknown structures.

Divergent operons and the genetic structure of the maltose B region in Escherichia coli K12.

Complementation and polarity suppression data are interpreted in terms of the genetic structure of the maltose B region. It is proposed that this region comprises two divergent operons. One operon includes malK, a cistron involved in maltose permeation, and lamB the only known cistron specifically involved in lambda receptor synthesis. The other operon includes malJ(1) and malJ(2) which are most probably two different cistrons, both involved in maltose permeation*. It is further assumed that expression of the two operons is controlled by malT, the positive regulatory gene of the maltose system, located in the malA region. The target(s) for the action of the malT product is (are) most likely to be located between malJ(1) and malK. There is an indication that the two operons might overlap in the region of their promoters. The structure of such an overlap as well as the possible function of the products of the different cistrons in malB are briefly discussed.

On some genetic aspects of phage lambda resistance in E. coli K12.

Most mutations rendering E. coli K12 resistant to phage lambda, map in two genetic regions malA and malB.-The malB region contains a gene lamB specifically involved in the lambda receptor synthesis. Twenty-one independent lamB mutations studied by complementation belonged to a single cistron. This makes it very likely that lamB is monocistronic. Among the lamB mutants some are still sensitive to a host range mutant of phage lambda. Mutations mapping in a proximal gene essential for maltose metabolism inactivate gene lamB by polarity confirming that both genes are part of the same operon. Because cases of intracistronic complementation have been found, the active lamB product may be an oligomeric protein.-Previously all lambda resistant mutations in the malA region have been shown to map in the malT cistron. malT is believed to be a positive regulatory gene necessary for the induction of the "maltose operons" in the malA region and in the malB region of the E. coli K12 genetic map. No trans dominant malT mutation have been found. Therefore if they exist, they occur at a frequency of less than 10(-8), or strongly reduce the growth rate of the mutants.

Bacterial interspersed mosaic elements (BIMEs) are a major source of sequence polymorphism in Escherichia coli intergenic regions including specific associations with a new insertion sequence.

A significant fraction of Escherichia coli intergenic DNA sequences is composed of two families of repeated bacterial interspersed mosaic elements (BIME-1 and BIME-2). In this study, we determined the sequence organization of six intergenic regions in 51 E. coli and Shigella natural isolates. Each region contains a BIME in E. coli K-12. We found that multiple sequence variations are located within or near these BIMEs in the different bacteria. Events included excisions of a whole BIME-1, expansion/deletion within a BIME-2 and insertions of non-BIME sequences like the boxC repeat or a new IS element, named IS 1397. Remarkably, 14 out of IS 1397 integration sites correspond to a BIME sequence, strongly suggesting that this IS element is specifically associated with BIMEs, and thus inserts only in extragenic regions. Unlike BIMEs, IS 1397 is not detected in all E. coli isolates. Possible relationships between the presence of this IS element and the evolution of BIMEs are discussed.

Modulating the immunological properties of a linear B-cell epitope by insertion into permissive sites of the MalE protein.

In a previous study, a set of positions in the MalE protein from Escherichia coli were identified, which tolerated short insertions or deletions without compromising the maltose binding activity of the protein. It is now shown that these sites accommodate an insert of 13 amino acids and are, therefore, permissive. Eleven sites were used, including eight permissive sites, to display a linear neutralization B-cell epitope of poliovirus (C3 epitope) at different positions on the surface of MalE. The affinity of a monoclonal neutralizing anti-poliovirus antibody (anti-C3 mAb) for the hybrid proteins varied from undetectable, to more than 1000 times higher than for the synthetic peptide. Therefore, some MalEC3 proteins mimic interactions of the viral epitope with the monoclonal antibody more efficiently than the free peptide. The results are interpreted in terms of the mobility of the insert and its flanking regions. It was further shown that some of the purified hybrid proteins are able to induce high titer anti-C3-peptide antibodies in mice. A strong correlation exists between the capacity of a MalEC3 protein to induce anti-C3-peptide antibodies and the antigenicity of the inserted peptide, measured with a polyclonal serum raised against the synthetic peptide.

Immunodominance of a recombinant T-cell epitope depends on its molecular environment.

In the present study, we have investigated the influence of the molecular environment of a T-cell epitope on its immunogenicity. We genetically inserted into different sites of two bacterial recipient proteins, LamB or MalE, an immunodominant T-cell epitope: the 120-132 T-cell epitope from the PreS2 region of HBV. The T-cell epitope was introduced, either alone (PreS:T) or with an adjacent B-cell epitope (PreS:TB). After purification, the hybrid proteins were injected into mice and we studied the immunogenicity of recombinant T-cell epitopes by analyzing the in vitro proliferative responses of LN cells from these mice to the inserted peptides. The immunization of mice with recombinant MalE protein containing the PreS:T or PreS:TB peptides at two different sites induced strong peptide-specific proliferative responses, indicating that the insertion sites did not affect the immunodominance of the inserted T-cell epitope. A strong T-cell proliferative response was also obtained after immunization of mice with hybrid LamB protein containing the PreS:TB epitope at position 153. In contrast, the recombinant proteins which contained only the PreS:T epitope at positions 153 or 374 failed to stimulate T-cell responses. Therefore, this study demonstrates that the immunogenicity of recombinant T-cell epitopes may be strongly affected both by the insertion site and by inserted adjacent residues.

Immunogenicity and antigenicity of conserved peptides from the envelope of HIV-1 expressed at the surface of recombinant bacteria.

We expressed peptides from the HIV-1 envelope protein at the surface of Escherichia coli by genetic insertions into an exposed loop of the outer membrane protein LamB. Recombinant bacteria expressing eight peptides from gp110 (pep1-pep8), conserved between HIV-1 and HIV-2, were used as live immunogens in rabbits by the intravenous route. The eight constructions elicited anti-LamB antibodies, showing that the hybrid proteins were immunogenic. One of them, LamB-pep8, gave rise to antibodies able to react with gp160 and to neutralize HIV-1 in vitro. We also show that this type of recombinant E. coli can provide a convenient reagent to monitor and characterize specific antibodies. Recombinant clones were used to test sera of seropositive individuals, as well as to narrow down the monoclonal antibody 110-1 recognition site to a cluster of eight residues at the carboxy-terminal end of gp110.

Residues in the alpha helix 7 of the bacterial maltose binding protein which are important in interactions with the Mal FGK2 complex.

The periplasmic maltose binding protein, MalE, is a major element in maltose transport and in chemotaxis towards this sugar. Previous genetic analysis of the MalE protein revealed functional domains involved in transport and chemotactic functions. Among them the surface located alpha helix 7, which is part of the C-lobe, one of the two lobes forming the three dimensional structure of MalE. Small deletions in this region abolished maltose transport, although maintaining wild-type affinity and specificity as well as a normal chemoreceptor function. It was suggested that alpha helix 7 may be implicated in interactions between the maltose binding protein and the membrane-bound protein complex (Duplay P, Szmelcman S. 1987. Silent and functional changes in the periplasmic maltose binding protein of Escherichia coli K12. II. Chemotaxis towards maltose. J Mol Biol 194:675-678: Duplay P, Szmelcman S, Bedouelle H, Hofnung M. 1987. Silent and functional changes in the periplasmic maltose binding protein of Escherichia coli K12. I: Transport of maltose. J Mol Biol 194:663-673). In this study, we submitted a region of 14 residues--Asp 207 to Gly 220--encompassing alpha helix 7, to genetic analysis by oligonucleotide mediated random mutagenesis. Out of 127 identified mutations, twelve single and five double mutants with normal affinities towards maltose were selected for further investigation. Two types of mutations were characterized, silent mutations that did not affect maltose transport and mutations that heavily impaired transport kinetics, even thought the maltose binding capacity of the mutant proteins remained normal. Three substitutions at Tyr 210 (Y210S, Y210L, Y210N) drastically reduced maltose transport. One substitution at Ala 213 (A213I) and one substitution at Glu 214 (E214K) also impaired transport. These three identified residues, Tyr 210, Ala 213, and Glu 214, which are constituents of alpha helix 7, therefore seem to play some important role in maltose transport, most probably in a productive interaction between the MalE protein and the membrane bound MalFGK2 complex.

Tertiary structure-dependence of misfolding substitutions in loops of the maltose-binding protein.

We previously identified and characterized amino acid substitutions in a loop connecting helix I to strand B, the alphaI/betaB loop, of the N-domain that are critical for in vivo folding of the maltose-binding protein (MalE31). The tertiary context-dependence of this mutation in MalE folding was assessed by probing the tolerance of an equivalent alphabeta loop of the C-domain to the same amino acid substitutions (MalE219). Moving the loop mutation from the N- to the C-domain eliminated the in vivo misfolding step that led to the formation of inclusion bodies. In vitro, both loop variants exhibited an important decrease of stability, but their intrinsic tendency to aggregate was well correlated with their periplasmic fates in Escherichia coli. Furthermore, the noncoincidence of the unfolding and refolding transition curves and increase of light scattering during the refolding of MalE31 indicate that a competing off-pathway reaction could occurs on the folding pathway of this variant. These results strongly support the notion that the formation of super-secondary structures of the N-domain is a rate-limiting step in the folding pathway of MalE.