Mutations that alter the transmembrane signalling pathway in an ATP binding cassette (ABC) transporter.

The maltose transport system of Escherichia coli is a well-characterized member of the ATP binding cassette transporter superfamily. Members of this family share sequence similarity surrounding two short sequences (the Walker A and B sequences) which constitute a nucleotide binding pocket. It is likely that the energy from binding and hydrolysis of ATP is used to accomplish the translocation of substrate from one location to another. Periplasmic binding protein-dependent transport systems, like the maltose transport system of E.coli, possess a water-soluble ligand binding protein that is essential for transport activity. In addition to delivering ligand to the membrane-bound components of the system on the external face of the membrane, the interaction of the binding protein with the membrane complex initiates a signal that is transmitted to the ATP binding subunit on the cytosolic side and stimulates its hydrolytic activity. Mutations that alter the membrane complex so that it transports independently of the periplasmic binding protein also result in constitutive activation of the ATPase. Genetic analysis indicates that, in general, two mutations are required for binding protein-independent transport and constitutive ATPase. The mutations alter residues that cluster to specific regions within the membrane spanning segments of the integral membrane components MalF and MalG. Individually, the mutations perturb the ability of MBP to interact productively with the membrane complex. Genetic alteration of this signalling pathway suggests that other agents might have similar effects. These could be potentially useful for modulating the activities of ABC transporters such as P-glycoprotein or CFTR, that are implicated in disease.

Allele-specific malE mutations that restore interactions between maltose-binding protein and the inner-membrane components of the maltose transport system.

Active accumulation of maltose and maltodextrins by Escherichia coli depends on an outer-membrane protein. LamB, a periplasmic maltose-binding protein (MalE, MBP) and three inner-membrane proteins, MalF, MalG and MalK. MalF and MalG are integral transmembrane proteins, while MalK is associated with the inner aspect of the cytoplasmic membrane via an interaction with MalG. Previously we have shown that MBP is essential for movement of maltose across the inner membrane. We have taken advantage of malF and malG mutants in which MBP interacts improperly with the membrane proteins. We describe the properties of malE mutations in which a proper interaction between MBP and defective MalF and MalG proteins has been restored. We found that these malE suppressor mutations are able to restore transport activity in an allele-specific manner. That is, a given malE mutation restores transport activity to different extents in different malF and malG mutants. Since both malF and malG mutations could be suppressed by allele-specific malE suppressors, we propose that, in wild-type bacteria, MBP interacts with sites on both MalF and MalG during active transport. The locations of different malE suppressor mutations indicate specific regions on MBP that are important for interacting with MalF and MalG.

Transport of p-nitrophenyl-alpha-maltoside by the maltose transport system of Escherichia coli and its subsequent hydrolysis by a cytoplasmic alpha-maltosidase.

In wild-type Escherichia coli the activity of the maltose transport system is dependent on a periplasmic maltose-binding protein. It has been possible, however, to isolate mutants in which transport activity is mediated by the membrane components of the system and is no longer dependent on the periplasmic binding protein. In this manuscript we show that in these binding protein-independent strains, p-nitrophenyl-alpha-maltoside is a potent inhibitor of maltose transport. In contrast, p-nitrophenyl-alpha-maltoside is only a weak inhibitor of maltose transport in wild-type bacteria. In addition, we show that p-nitrophenyl-alpha-maltoside is transported by the binding protein-independent strains but not by wild-type bacteria. We were able to detect transport of this compound because there is a cytoplasmic enzyme that cleaves p-nitrophenyl-alpha-maltoside. This enzyme has not previously been described. We show that although the synthesis of this enzyme is subject to the same regulation as the components of the maltose regulon, and is MalT dependent, it is not coded for by a known mal gene. We refer to this enzyme as alpha-maltosidase. These results strengthen our proposal that the membrane components of the maltose transport system comprise a recognition site for maltose and related substrates.

Genetic evidence for substrate and periplasmic-binding-protein recognition by the MalF and MalG proteins, cytoplasmic membrane components of the Escherichia coli maltose transport system.

We isolated mutants of Escherichia coli in which the maltose-binding protein (MBP) is no longer required for growth on maltose as the sole source of carbon and energy. These mutants were selected as Mal+ revertants of a strain which carries a deletion of the MBP structural gene, malE. In one class of these mutants, maltose is transported into the cell independently of MBP by the remaining components of the maltose system. The mutations in these strains map in either malF or malG. These genes code for two of the cytoplasmic membrane components of the maltose transport system. In some of the mutants, MBP actually inhibits maltose transport. We demonstrate that these mutants still transport maltose actively and in a stereospecific manner. These results suggest that the malF and malG mutations result in exposure of a substrate recognition site that is usually available only to substrates bound to MBP.