malB Region in Escherichia coli K-12: Characterization of New Mutations

Phenotypic characterization and mapping of more than 50 Mal(-) mutations located in the malB region lead one to divide the site for Mal(-)lambdas mutations (formerly called gene malB) in that region, into two adjacent genetic segments malJ and malK. malJ and malK are both involved in maltose permeation. It is suggested that (i) malK and lamB, the only known gene specifically involved in phage lambda adsorption (20), constitute an operon of polarity malK lamB. (ii) malJ and malK correspond to two different genes, and (iii) a promoter for the malK lamB operon is located between malJ and malK. Since lambda receptors and maltose permease are inducible by maltose and absent in malT mutants, it is likely that the expression of the malK lamB operon is controlled by the product of gene malT, the positive regulatory gene of the maltose system.     

On Some Genetic Aspects of Phage λ 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.     

Role of the catabolite activator protein in the maltose regulon of Escherichia coli.

The maltose regulon consists of three operons controlled by a positive regulatory gene, malT. Deletions of the gene crp were introduced into strains which carried a malT-lacZ hybrid gene. From the observed reduction in beta-galactosidase activity it was concluded that the expression of malT-lacZ, and therefore of malT, is controlled by the catabolite activator protein (CAP), the product of the gene crp. Mutations were obtained which allowed a malT-lacZ hybrid gene to be expressed at a high level even in the absence of CAP. These mutations were shown to be located in or close to the promoter of the malT gene and were called malTp. The malTp mutations were transferred in the cis position to a wild-type malT gene. In the resulting strains, the expression of two of the maltose operons, malEFG and malK-lamB, still required the action of CAP, whereas that of the third operon, malPQ, was CAP independent. Therefore, in wild-type cells, CAP appears to control malPQ expression mainly, if not solely, by regulating the concentration of MalT protein in the cell. On the other hand, it controls the other two operons more stringently, both by regulating malT expression and by a more direct action, probably exerted in the promoters of these operons.     

Mutations in the promoter regions of the malEFG and malK-lamB operons of Escherichia coli K12

The malB region of Escherichia coli is composed of two operons, malEFG and malK-lamB, transcribed divergently from a control region located between the malE and malK genes. Expression of the malB operons is under the positive control of the malT gene product (MalT) and maltose and of the crp gene product (CRP) and cyclic AMP. Strains in which the lac genes have been fused to malE or malK are unable to use lactose as carbon source if they have been deleted for malT or crp. Mutations in the malB region allowing such fusion strains to grow on lactose have been isolated. These and previously isolated mutations were genetically characterized. As regards the malEp promoter mutations, malEp9, malEp1 and malEp6 create new promoters that are MalT and CRP independent. malEp9 and malEp1 change residues -1 and -2, respectively, of malEp without altering its activity. malEp6 duplicates six base-pairs between residues -22 and -23. malEp3 improves the -10 region hexamer. malEp5 deletes residues -29 to -62. It creates a new promoter that is MalT independent, CRP dependent, likely by fusing together functional regions of malEp that are normally apart. malEp5 also reduces the expression of malK-lamB, suggesting the existence of a link between the malEp and malKp promoters. As regards the malKp mutations, malKp6 changes residue -81 of malKp without altering its activity. It creates a new promoter, which is MalT independent, CRP dependent, likely by using a pre-existing cyclic AMP/CRP binding site. malKp102 changes residue -36, two bases upstream of the -35 region hexamer. It decreases the activity of malKp by at least four orders of magnitude and likely alters the MalT binding site. These results are discussed in terms of regulatory interactions within the malB control region.     

Nucleotide sequence of the regulatory region of malB operons in E. coli

The nucleotide sequence of a cloned section of the Escherichia coli chromosome containing the promoter regions of the malB divergent operons was determined. The region of the proximal gene, malE of the malEFG operon, was identified on the basis of the known amino acid sequence of the precursor molecule of maltose-binding protein. The region of malK, the proximal gene of the malKlamB operon, was deduced from the observation that a cloned segment contains an amino-terminal portion of the malK gene. The non-coding region between malE and malK is 299 base pairs long and contains two long GC clusters. Another feature of this region that may be related to the regulation of gene expression is the presence of two palindromic structures between the GC clusters. The DNA regions binding to cyclic AMP binding protein were determined by a method using polyacrylamide gel electrophoresis. The sites are thought to be located close to GC clusters.     

TGATG vector: a new expression system for cloned foreign genes in Escherichia coli cells

A TGATG vector system was developed that allows for the construction of hybrid operons with partially overlapping genes, employing the effects of translational coupling to optimize expression of cloned cistrons in Escherichia coli. In this vector system (plasmid pPR-TGATG-1), the coding region of a foreign gene is attached to the ATG codon situated on the vector, to form the hybrid operon transcribed from the phage lambda PR promoter. The cloned gene is the distal cistron of this hybrid operon ('overlappon'). The efficiently translated cro'-cat'-'trpE hybrid cistron is proximal to the promoter. The coding region of this artificial fused cistron [the length of the corresponding open reading frame is about 120 amino acids (aa)] includes the following: the N-terminal portions of phage lambda Cro protein (20 aa), the CAT protein of E. coli (72 aa) and 3' C-terminal codons of the E. coli trpE gene product. At the 3'-end of the cro'-cat'-'trpE fused cistron there is a region for efficient translation reinitiation: a Shine-Dalgarno sequence of the E. coli trpD gene and the overlapping stop and start codons (TGATG). In this sequence, the last G is the first nucleotide of the unique SacI-recognition site (GAGCT decreases C) and so integration of the structural part of the foreign gene into the vector plasmid may be performed using blunt-end DNA linking after the treatment of pPR-TGATG-1 with SacI and E. coli DNA polymerase I or its Klenow fragment.(ABSTRACT TRUNCATED AT 250 WORDS)     

The malX malY operon of Escherichia coli encodes a novel enzyme II of the phosphotransferase system recognizing glucose and maltose and an enzyme abolishing the endogenous induction of the maltose system.

Mutants lacking MalK, a subunit of the binding protein-dependent maltose-maltodextrin transport system, constitutively express the maltose genes. A second site mutation in malI abolishes the constitutive expression. The malI gene (at 36 min on the linkage map) codes for a typical repressor protein that is homologous to the Escherichia coli LacI, GalR, or CytR repressor (J. Reidl, K. R?misch, M. Ehrmann, and W. Boos, J. Bacteriol. 171:4888-4899, 1989). We now report that MalI regulates an adjacent and divergently oriented operon containing malX and malY. MalX encodes a protein with a molecular weight of 56,654, and the deduced amino acid sequence of MalX exhibits 34.9% identity to the enzyme II of the phosphototransferase system for glucose (ptsG) and 32.1% identity to the enzyme II for N-acetylglucosamine (nagE). When constitutively expressed, malX can complement a ptsG ptsM double mutant for growth on glucose. Also, a delta malE malT(Con) strain that is unable to grow on maltose due to its maltose transport defect becomes Mal+ after introduction of malI::Tn10 and the plasmid carrying malX. MalX-mediated transport of glucose and maltose is likely to occur by facilitated diffusion. We conclude that malX encodes a phosphotransferase system enzyme II that can recognize glucose and maltose as substrates even though these sugars may not represent the natural substrates of the system. The second gene in the operon, malY, encodes a protein of 43,500 daltons. Its deduced amino acid sequence exhibits weak homology to aminotransferase sequences. The presence of plasmid-encoded MalX alone was sufficient for complementing growth on glucose in a ptsM ptsG glk mutant, and the plasmid-encoded MalY alone was sufficient to abolish the constitutivity of the mal genes in a malK mutant. The overexpression of malY in a strain that is wild type with respect to the maltose genes strongly interferes with growth on maltose. This is not the case in a malT(Con) strain that expresses the mal genes constitutively. We conclude that malY encodes an enzyme that degrades the inducer of the maltose system or prevents its synthesis.     

Transposon Tn10-dependent expression of the lamB gene in Escherichia coli.

Among Tn10 insertions isolated in or near the malB region of Escherichia coli, one (zjb-729::Tn10) mapped between malK and lamB or late in malK and allowed MalT-independent expression of lamB. Tn10-dependent expression of a lamB-lacZ protein fusion was 25% of the expression of the fusion from the malK-lamB operon promoter in malTc constitutive strains. The maltoporin content of a strain carrying this Tn10 was about 20% that of a malTc malB+ strain. Transport of maltose at concentrations of below 10(-6) M was reduced about threefold. When maltoporin was present at about 50% of the level of malTc malB+ strains, maltose transport was largely restored. We conclude that maltoporin is not rate limiting for maltose transport in wild-type cells but becomes rate limiting when the ratio of maltoporin to other maltose transport components is reduced more than twofold.     

Mutational alterations of translational coupling in the L11 ribosomal protein operon of Escherichia coli.

The L11 operon in Escherichia coli consists of the genes coding for ribosomal proteins L11 and L1. It is known that translation of L1 does not take place unless the preceding L11 cistron is translated, that is, the two cistrons are translationally coupled, and this is the basis of coregulation of the translation of the two cistrons by a single repressor, L1. Several mutational analyses were carried out to define the region responsible for coupling L1 translation with L11 translation. First, by introducing several amber mutations into the L11 gene by a site-directed mutagenesis technique, it was shown that translation by ribosomes down to a position 21 nucleotides upstream, but not to a position 45 nucleotides upstream, from the end of the L11 cistron allowed the initiation of L11 translation. Second, deletion analysis indicated that a region located 23 to 20 nucleotides from the end of the L11 gene was involved in preventing independent initiation from L1 translation. Third, five different mutations obtained by screening for activation of the masked L1 initiation site were found to be clustered in a small region immediately upstream from the Shine-Dalgarno sequence of L1, and all of them were G-to-A transitions. These results, together with some additional experiments with oligonucleotide-directed mutagenesis, defined the region involved in the coupling and suggest that some special feature of this region, probably different from simple masking of the initiation site by base pairing, is responsible for translational coupling. The present results also suggest that there might be specific differences in the primary nucleotide sequence that distinguish independent translational initiation sites from translationally coupled (i.e., masked) initiation sites.     

An analysis of the structure of the product of the rbsA gene of Escherichia coli K12

The predicted amino acid sequence of rbsA, a gene from the high affinity ribose transport operon (rbs) of Escherichia coli K12, is homologous to the products of hisP, malK, and pstB, components of the histidine, maltose, and phosphate high affinity transport operons. The recent finding by Hobson et al. (Hobson, A. C., Weatherwax, R., and Ames, G.F.-L. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 7333-7337) that the hisP and malK products bind ATP suggests that these four gene products may be involved in coupling the energy from ATP to drive the active transport in their respective transport systems. Each gene product contains a sequence of glycine and basic residues which are characteristic of an ATP-binding site (Walker, J.E., Saraste, M., Runswick, M.J., and Gay, N.J. (1982) EMBO J. 1, 945-951). Interestingly the N- and C-terminal halves of rbsA are also homologous, suggesting that a primordial gene duplication and subsequent fusion of the products occurred.