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.     

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.     

Regulation of the Escherichia coli allantoin regulon: coordinated function of the repressor AllR and the activator AllS

The allantoin regulon of Escherichia coli, formed by three operons expressed from promoters allA(P), gcl(P) and allD(P), is involved in the anaerobic utilization of allantoin as nitrogen source. The expression of these operons is under the control of the repressor AllR. The hyperinduction of one of these promoters (allD(P)) by allantoin in an AllR defective mutant suggested the action of another regulator, presumably of activator type. In this work we have identified ybbS (proposed gene name allS), divergently transcribed from allA, as the gene encoding this activator. Analysis of the expression of the three structural operons in DeltaallS mutant showed that the expression from allD(P) was abolished, suggesting that AllS is essential for the expression of the corresponding operon. In a wild-type strain expression of allS takes place mainly anaerobically and is hyperinduced when the nitrogen source limits growth. However, expression of allS is independent of regulators of the Ntr response, NtrC or Nac. Band shift experiments showed that AllR binds to DNA containing the allS-allA intergenic region and the gcl(P) promoter and its binding is abolished by glyoxylate. Both DNA fragments contain a highly conserved inverted repeat, which after site-directed mutagenesis, has been proven to be the AllR-binding site. This site displays similarity with the IclR family recognized consensus. Interaction of AllR with the single operator present in the allS-allA intergenic region prevented binding of RNA polymerase to either of the two divergent promoters. The regulator AllS interacts only with allD(P) even in the absence of allantoin. Analysis of this promoter allowed us to identify an inverted repeat as a motif for AllS binding. We propose a model for the coordinate control of the allantoin regulon by AllR and AllS.     

The ABC transporter MalFGK(2) sequesters the MalT transcription factor at the membrane in the absence of cognate substrate

MalK, the cytoplasmic component of the maltose ABC transporter from Escherichia coli is known to control negatively the activity of MalT, the activator of the maltose regulon, through complex formation. Here we further investigate this regulatory process by monitoring MalT activity and performing fluorescence microscopy analyses under various conditions. We establish that, under physiological conditions, the molecular entity that interacts with MalT is not free MalK, but the maltose transporter, MalFGK(2) , which sequesters MalT to the membrane. Furthermore, we provide compelling evidence that the transporter's ability to bind MalT is not constitutive, but strongly diminished when MalFGK(2) is engaged in sugar transport. Notably, the outward-facing transporter, i.e. the catalytic intermediate, is ineffective in inhibiting MalT compared to the inward-facing state, i.e. the resting form. Analyses of available genetic and structural data suggest how the interaction between one inactive MalT molecule and MalFGK(2) would be sensitive to the transporter state, thereby allowing MalT release upon maltose entrance. A related mechanism may underpin signalling by other ABC transporters.     

Nucleotide sequence of DNA controlling expression of genes for maltosaccharide utilization in Streptococcus pneumoniae

An analysis of previous data indicated that four structural genes concerned with maltosaccharide utilization in Streptococcus pneumoniae are organized in two operons that are transcribed in opposite directions from a central control region. This region contains two strong promoters subject to repression by a regulatory gene product in the absence of maltose. The nucleotide sequence of the 554-bp control region DNA and adjacent portions of the malX and malM structural genes was determined. Unique reading frames and initiation codons allowed identification of the oppositely oriented structural genes. Putative ribosome binding sites and −10 and −35 RNA-polymerase-binding sites, as well as AT-rich regions farther upstream, were observed proximal to both the X and M genes. The similarity of these sequences to sites found in Escherichia coli and Bacillus subtilis indicated the conservation of control signals in bacteria, both Gram-negative and Gram-positive. A pair of 17-bp hyphenated repeat sequences in the control region may represent repressor binding sites. Two down promoter mutations, V11 and 69, were shown to be deletions in the control region. The V11 mutation, which affected only the MP operon, deleted the promoter adjacent to the M gene. Mutation 69, which reduced both X and M gene functions, deleted the entire segment between the promoters so that they now overlap at their −35 binding sites. As a consequence of this deletion, the AT-rich regions proximal to the promoters were lost. This suggests that the AT-rich regions are important for promoter strength.     

A DNA sequence containing the control sites for gene malT and for the malPQ operon

Summary The order of 802 base pairs was established in a DNA segment containing the promoter for malPQ which is one of the three maltose operons, and the promoter for malT, the positive regulator gene of the maltose regulon. The determination of the amino-terminal sequence of the MalT protein allowed us to identify the beginning of the malT gene on the sequence. The position of the malP gene was deduced from the published amino-terminal sequence of maltodextrin phosphorylase. A total of 611 base pairs separate the initiation codons for these two genes, which are transcribed in opposite directions. This large intergenic region does not code for any polypeptide of significant size. The main features of this sequence are discussed in terms of the regulation known to operate on malT and malPQ expression.