A mutant form of maltose-binding protein of Escherichia coli deficient in its interaction with the bacteriophage lambda receptor protein.

In one malE mutant known to be deficient in the transport of maltose and maltodextrins across the outer membrane, the altered MalE protein was shown to be defective in its interaction with the phage lambda receptor, or LamB protein, of the outer membrane.     

Two-dimensional crystals of Escherichia coli maltoporin and their interaction with the maltose-binding protein.

We have reconstituted Escherichia coli maltoporin into phospholipid membranes at low lipid-to-protein ratios to produce two-dimensional crystals of this membrane protein. Electron microscopy of negatively stained membranes showed three different types of arrays, two of them hexagonal and the third rectangular, all diffracting to approximately (2 nm)-1. Furthermore, we have core-constituted maltoporin with the maltose-binding protein from E. coli, a soluble periplasmic protein that has been proposed to interact with maltoporin. One of the hexagonal arrays was found to bind maltose-binding protein molecules in a regular way, while the maltose-binding protein binding sites were not accessible in the other crystal forms. Difference maps from averaged decorated arrays and undecorated controls showed three symmetry-related maltose-binding protein binding sites per maltoporin trimer, of which not more than one is likely to be occupied at a given time. Using multivariate statistical analysis to select similar unit cells of the decorated maltoporin array, we have obtained a map showing the rough outline of a maltose-binding protein molecule interacting with the pore formed by a maltoporin trimer.     

Interaction between maltose-binding protein and the membrane-associated maltose transporter complex in Escherichia coli

Active transport of maltose in Escherichia coli requires the presence of both maltose-binding protein (MBP) in the periplasm and a complex of MalF, MalG, and MalK proteins (FGK2) located in the cytoplasmic membrane. Earlier, mutants in malF or malG were isolated that are able to grow on maltose in the complete absence of MBP. When the wild-type malE+ allele, coding for MBP, was introduced into these MBP-independent mutants, they frequently lost their ability to grow on maltose. Furthermore, starting from these Mal- strains, Mal+ secondary mutants that contained suppressor mutations in malE were isolated. In this study, we examined the interaction of wild-type and mutant MBPs with wild-type and mutant FGK2 complexes by using right-side-out membrane vesicles. The vesicles from a MBP-independent mutant (malG511) transported maltose in the absence of MBP, with Km and Vmax values similar to those found in intact cells. However, addition of wild-type MBP to these mutant vesicles produced unexpected responses. Although malE+ malG511 cells could not utilize maltose, wild-type MBP at low concentrations stimulated the maltose uptake by malG511 vesicles. At higher concentrations of the wild-type MBP and maltose, however, maltose transport into malG511 vesicles became severely inhibited. This behaviour of the vesicles was also reflected in the phenotype of malE+ malG511 cells, which were found to be capable of transporting maltose from a low external concentration (1 microM), but apparently not from millimolar concentrations present in maltose minimal medium. We found that the mutant FGK2 complex, containing MalG511, had a much higher apparent affinity towards the wild-type MBP than did the wild-type FGK2 complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reaction between isolated lambda phage DNA and membrane structures of Escherichia coli cells

The saccharose density gradient (30--55%) centrifugation technique applied to E. coli membrane preparations was used to show that treatment of the bacteria with Ca2+ in the cold results in the redistribution of the absorbed phage DNA from the cell wall to the cytoplasmic membrane while freezing-thawing of the bacteria leads to equal distribution of the infectious DNA among all membrane fractions. Quantitative estimation of such a redistribution is reported.     

Maltose chemoreceptor of Escherichia coli: interaction of maltose-binding protein and the tar signal transducer.

The maltose chemoreceptor in Escherichia coli consists of the periplasmic maltose-binding protein (MBP) and the Tar signal transducer, which is localized in the cytoplasmic membrane. We previously isolated strains containing malE mutations that cause specific defects in the chemotactic function of MBP. Four of these mutations have now been characterized by DNA sequence analysis. Two of them replace threonine at residue 53 of MBP with isoleucine (MBP-TI53), one replaces an aspartate at residue 55 with asparagine (MBP-DN55), and the fourth replaces threonine at residue 345 with isoleucine (MBP-TI345). The chemotactic defects of MBP-TI53 and MBP-DN55, but not of MBP-TI345, are suppressed by mutations in the tar gene. Of the tar mutations, the most effective suppressor (isolated independently three times) replaces Arg-73 of Tar with tryptophan. Two other tar mutations that disrupt the aspartate chemoreceptor function of Tar also suppress the maltose taxis defects associated with MBP-TI53 and MBP-DN55. One of these mutations introduces glutamine at residue 73 of Tar, the other replaces arginine at residue 69 of Tar with cysteine. These results suggest that regions of MBP that include residues 53 to 55 and residue 345 are important for the interaction with Tar. In turn, arginines at residues 69 and 73 of Tar must be involved in the recognition of maltose-bound MBP and/or in the production of the attractant signal generated by Tar in response to maltose-bound MBP.     

Efficient excision of phage lambda from the Escherichia coli chromosome requires the Fis protein.

The Escherichia coli protein Fis has been shown to bind a single site in the recombination region of phage lambda and to stimulate excisive recombination in vitro (J. F. Thompson, L. Moitoso de Vargas, C. Koch, R. Kahmann, and A. Landy, Cell 50:901-908, 1987). We demonstrate that mutant strains deficient in fis expression show dramatically reduced rates of lambda excision in vivo. Phage yields after induction of a stable lysogen are reduced more than 200-fold in fis cells. The defect observed in phage yield is not due to inefficient phage replication or lytic growth. Direct examination of excisive recombination products reveals a severe defect in the rate of recombination in the absence of Fis. The excision defect observed in fis cells can be fully reproduced in fis+ cells by using phages that lack the Fis binding site on attR, indicating that the entire stimulatory effect of Fis on excisive recombination is due to binding at that site.     

Physical studies of the interaction between the Escherichia coli DNA binding protein and nucleic acids.

The interaction of nucleic acid with the Escherichia coli DNA-binding protein has been studied by fluorescence emission spectroscopy and sedimentation velocity analysis. The protein binds to single-strand DNA with an apparent equilibrium dissociation constant of 2 X 10(-9). It binds to the homopolymers poly (dA) and poly (dT) slightly more tightly, but has a larger apparent equilibrium dissociation constant to poly (dC). The protein also binds tightly to ribohomopolymers and to tRNA, but not to duplex DNA. By the use of defined-length oligonucleotides, it has been shown that the protein binds to DNA in a highly cooperative manner. The extent of cooperativity is seen as the difference in binding between an isolated monomeric protein molecule bound to DNA and two or more molecules binding to contiguous sites.     

The folding properties of the Escherichia coli maltose-binding protein influence its interaction with SecB in vitro.

It has been proposed that the cytoplasmic SecB protein functions as a component of the Escherichia coli protein export machinery by serving as an antifolding factor that retards folding of the precursor maltose-binding protein (preMBP) into a translocation-incompetent form. In this study, it was found that SecB directly interacts with wild-type preMBP and various mutationally altered MBP species synthesized in vitro to form a SecB-MBP complex that can be precipitated with anti-SecB serum. The association of SecB with wild-type preMBP was relatively unstable; such a complex was formed only when SecB was present cotranslationally or after denaturation of previously synthesized preMBP and was detected with only low efficiency. In marked contrast, MBP species that were defective in the ability to assume the stable conformation of wild-type preMBP or that exhibited significantly slower folding kinetics formed much more stable complexes with SecB. In one case, we demonstrated that SecB did not need to be present cotranslationally for complex formation to occur. Formation of a complex between SecB and MBP was clearly not dependent on the MBP signal peptide. However, we were unable to detect complex formation between SecB and MBP lacking virtually the entire signal peptide but having a completely intact mature moiety. This MBP species folded at a rate considerably faster than that of wild-type preMBP. The propensity of this mutant protein to assume the native conformation of mature MBP apparently precludes a stable association with SecB, whereas an MBP species lacking a signal peptide but exhibiting altered folding properties did form a complex with SecB that could be precipitated with anti-SecB serum.     

Factors influencing the in vitro translocation of the Escherichia coli maltose-binding protein

An in vitro system has been utilized to study the translocation of newly synthesized Escherichia coli maltose-binding protein (MBP) into inverted membrane vesicles. Approximately 40% of precursor MBP (pMBP) synthesized with a wild-type signal peptide was imported into vesicles. However, MBP species with even minor alterations in the signal peptide hydrophobic core were imported into vesicles with an efficiency much lower than predicted from in vivo studies. Posttranslational import of wild-type pMBP into vesicles could be demonstrated if membranes were added after the termination of protein synthesis. However, if vesicles were present throughout the synthesis reaction, most pMBP import occurred either cotranslationally or very soon after completion of synthesis. The wild-type pMBP rapidly became incompetent for posttranslational translocation upon continued incubation in the absence of membranes, whereas pMBP species with altered folding properties remained competent for significantly longer periods. The rate of in vitro pMBP folding was affected by the nature of the signal peptide. The evidence suggests that one or more soluble factors may interact with the newly synthesized pMBP to help maintain it in a translocation-competent state and to promote its entrance into the export pathway.     

Bacteriophage lambda receptor site on the Escherichia coli K-12 LamB protein.

We have analyzed eight new phage-resistant missense mutations in lamB. These mutations identify five new amino acid residues essential for phage lambda adsorption. Two mutations at positions 245 and 382 affect residues which were previously identified, but lead to different amino acid changes. Three mutations at residues 163, 164, and 250 enlarge and confirm previously proposed phage receptor sites. Two different mutations at residue 259 and one at 18 alter residues previously suggested as facing the periplasmic face. The mutation at residue 18 implicates for the first time the amino-terminal region of the LamB protein in phage adsorption. The results are discussed in terms of the topology of the LamB protein.     

Interaction of the maltose-binding protein with membrane vesicles of Escherichia coli.

The interaction of the radioactively labeled purified maltose-binding protein of Escherichia coli with membrane vesicles was studied. The maltose-binding protein bound specifically to the vesicles, in the presence of maltose, on few sites. Under conditions in which a potential was imposed across the membrane, the specific binding was (i) increased, (ii) dependent on maltose, and (iii) abolished in a mutant defective in the tar gene product, one of the methyl-accepting chemotaxis proteins. At least 1,300 binding sites were present in the membrane fraction of logarithmically growing cells.     

Essential interaction between lambdoid phage 21 terminase and the Escherichia coli integrative host factor

Lambdoid phage 21 requires the Escherichia coli integrative host factor (IHF) for growth. lambda-21 hybrids that have 21 DNA packaging specificity also require IHF. IHF-independent (her) mutants have been isolated. her mutations map in the amino-terminal half of the 21 1 gene. The 1 gene encodes the small subunit of the 21 terminase, and the amino-terminal half of the 1 polypeptide is a functional domain for specifically binding 21 DNA. Hence changes in the DNA-binding domain of terminase, her mutations, render 21 terminase able to function in the absence of IHF. Three of four her mutations studied are trans-dominant. An in vitro system was used to show that packaging of 21 DNA is IHF-dependent. IHF is directly required during the early, terminase-dependent steps of assembly. It is concluded that IHF is a host factor required for function of the 21 terminase. It is proposed, in analogy to the role of IHF in lambda integration, that IHF facilitates proper binding of 21 terminase to phage DNA. Consistent with this proposal, possible IHF-binding sites are present in the 21 cohesive end site.