Winfried Boos

Formation of large, ion-permeable membrane channels by the matrix protein (porin) of Escherichia coli

One of the major proteins of the outer membrane of Escherichia coli, the matrix protein (porin), has been isolated by detergent solubilisation. When the protein is added in concentrations of the order 10 ng/cm3 to the outer phases of a planar lipid bilayer membrane, the membrane conductance increases by many orders of magnitude. At lower protein concentrations the conductance increases in a stepwise fashion, the single conductance increment being about 2 nS (1 nS = 10(-9) siemens = 10(-9) omega -1) in 1 MKCl. The conductance pathway has an ohmic current vs. voltage character and a poor selectivity for chloride and the alkali ions. These findings are consistent with the assumption that the protein forms large aqueous channels in the membrane. From the average value of the single-channel conductance a channel diameter of about 0.9 nm is estimated. This channel size is consistent with the sugar permeability which has been reported for lipid vesicles reconstituted in the presence of the protein.

Crystal structure of MalK, the ATPase subunit of the trehalose/maltose ABC transporter of the archaeon Thermococcus litoralis

The members of the ABC transporter family transport a wide variety of molecules into or out of cells and cellular compartments. Apart from a translocation pore, each member possesses two similar nucleoside triphosphate‐binding subunits or domains in order to couple the energy‐providing reaction with transport. In the maltose transporter of several Gram‐negative bacteria and the archaeon Thermo coccus litoralis, the nucleoside triphosphate‐binding subunit contains a C‐terminal regulatory domain. A dimer of the subunit is attached cytoplasmically to the translocation pore. Here we report the crystal structure of this dimer showing two bound pyrophosphate molecules at 1.9 Å resolution. The dimer forms by association of the ATPase domains, with the two regulatory domains attached at opposite poles. Significant deviation from 2‐fold symmetry is seen at the interface of the dimer and in the regions corresponding to those residues known to be in contact with the translocation pore. The structure and its relationship to function are discussed in the light of known mutations from the homologous Escherichia coli and Salmonella typhimurium proteins.

Completion of the hook–basal body complex of the Salmonella typhimurium flagellum is coupled to FlgM secretion and fliC transcription

The flhDC operon of Salmonella typhimurium is the master control operon required for the expression of the entire flagellar regulon. The flagellar master operon was placed under the tetracycline‐inducible promoter PtetA using the T‐POP transposon. Cells containing this construct are motile in the presence of tetracycline and non‐motile without inducer present. No flagella were visible under the electron microscope when cells were grown without inducer. The class 1, class 2 and class 3 promoters of the flagellar regulon are temporally regulated. After addition of tetracycline, the class 1 flhDC operon was transcribed immediately. Transcription of flgM (which is transcribed from both class 2 and class 3 promoters) began 15 min after induction. At 20 min after induction, the class 2 fliA promoter became active and intracellular FliA protein levels increased; at 30 min after induction, the class 3 fliC promoter was activated. Induction of fliC gene expression coincides with the appearance of FlgM anti‐sigma factor in the growth medium. This also coincides with the completion of hook–basal body structures. Rolling cells first appeared 35 min after induction, and excess hook protein (FlgE) was also found in the growth medium at this time. At 45 min after induction, nascent flagellar filaments became visible in electron micrographs and over 40% of the cells exhibited some swimming behaviour. Multiple flagella assemble and grow on individual cells after induction of the master operon. These results confirm that the flagellar regulatory hierarchy of S. typhimurium is temporally regulated after induction. Both FlgM secretion and class 3 gene expression occur upon completion of the hook–basal body structure.

Signal transduction between a membrane‐bound transporter, PtsG, and a soluble transcription factor, Mlc, of Escherichia coli

The global regulator Mlc controls several genes implicated in sugar utilization systems, notably the phosphotransferase system (PTS) genes, ptsG, manXYZ and ptsHI, as well as the malT activator. No specific low molecular weight inducer has been identified that can inactivate Mlc, but its activity appeared to be modulated by transport of glucose via Enzyme IICBGlc (PtsG). Here we demonstrate that inactivation of Mlc is achieved by sequestration of Mlc to membranes containing dephosphorylated Enzyme IICBGlc. We show that Mlc binds specifically to membrane fractions which carry PtsG and that excess Mlc can inhibit Enzyme IICBGlc phosphorylation by the general PTS proteins and also Enzyme IICBGlc‐mediated phosphorylation of α‐methylglucoside. Binding of Mlc to Enzyme IICBGlc in vitro required the IIB domain and the IIC–B junction region. Moreover, we show that these same regions are sufficient for Mlc regulation in vivo, via cross‐dephosphorylation of IIBGlc during transport of other PTS sugars. The control of Mlc activity by sequestration to a transport protein represents a novel form of signal transduction in gene regulation.

The ABC maltose transporter

Bacterial ATP‐binding cassette (ABC) transporters and their homologues in eukaryotic cells form one of the largest superfamilies known today. They function as primary pumps that couple substrate translocation across the cytoplasmic membrane to ATP hydrolysis. Although ABC transporters have been studied for more than three decades, the structure of these multicomponent systems is unknown, and the mechanism of transport is not understood. This article reviews one of the most widely studied ABC systems, the maltose transporter of Escherichia coli. A first structural model of the transport channel allows discussion of possible mechanisms of transport. In addition, recent experimental evidence suggests that regulation of gene expression and transport activity is far more complex than expected.

Negative transcriptional regulation of a positive regulator: the expression of malT, encoding the transcriptional activator of the maltose regulon of Escherichia coli, is negatively controlled by Mlc

The maltose regulon consists of 10 genes encoding a multicomponent and binding protein‐dependent ABC transporter for maltose and maltodextrins as well as enzymes necessary for the degradation of these sugars. MalT, the transcriptional activator of the system, is necessary for the transcription of all mal genes. MalK, the energy‐transducing subunit of the transport system, acts phenotypically as repressor, particularly when overproduced. We isolated an insertion mutation that strongly reduced the repressing effect of overproduced MalK. The affected gene was sequenced and identified as mlc, a known gene encoding a protein of unknown function with homology to the Escherichia coli NagC protein. The loss of Mlc function led to a threefold increase in malT expression, and the presence of mlc on a multicopy plasmid reduced malT expression. By DNaseI protection assay, we found that Mlc protected a DNA region comprising positions + 1 to + 23 of the malT transcriptional start point. Using a mlc–lacZ fusion in a mlc and mlc+ background, we found that Mlc represses its own expression. As Mlc also regulates another operon (manXYZ, see pages 369–379 of this issue), it may very well constitute a new global regulator of carbohydrate utilization.

Evidence of recent lateral gene transfer among hyperthermophilic Archaea

A total of 153 nucleotide differences were found over a contiguous 16 kb region between two hyperthermophilic Archaea, Pyrococcus furiosus and Thermococcus litoralis. The 16 kb region in P. furiosus is flanked by insertion sequence (IS) elements with inverted and direct repeats. Both IS elements contain a single open reading frame (ORF) encoding a putative protein of 233 amino acids identified as a transposase. This 16 kb region has the features of a typical bacterial composite transposon and represents a possible mechanism for lateral gene transfer between Archaea or possibly between Archaea and Bacteria. A total of 23 homologous IS elements was found in the genome sequence of P. furiosus, whereas no full‐length IS elements were identified in the genomes of Pyrococcus abyssi and Pyrococcus horikoshii. Only one IS element was found in T. litoralis. In P. furiosus and T. litoralis, the 16 kb region contains an ABC transport system for maltose and trehalose that was characterized biochemically for T. litoralis. Regulation of expression studies showed that the malE gene, located on the transposon, and the encoded trehalose/maltose‐binding protein (TMBP) are induced in the presence of maltose and trehalose in both P. furiosus and T. litoralis. The implications of transposition as a mechanism for lateral gene transfer among Archaea are discussed.

The ATP-binding cassette subunit of the maltose transporter MalK antagonizes MalT, the activator of the Escherichia coli mal regulon

Transcription of the mal regulon of Escherichia coli K‐12 is regulated by the positive activator, MalT. In the presence of ATP and maltotriose, MalT binds to decanucleotide MalT boxes that are found upstream of mal promoters and activates transcription at these sites. The earliest studies of the mal regulon, however, suggested a negative role for the MalK protein, the ATP‐binding cassette subunit of the maltose transporter, in regulating mal gene expression. More recently, it was found that overexpression of the MalK protein resulted in very low levels of mal gene transcription. In this report we describe the use of tagged versions of MalT to provide evidence that it physically interacts with the MalK protein both in vitro and in vivo. In addition, we show that a novel malK mutation, malK941, results in an increased ability of MalK to down‐modulate MalT activity in vivo. The fact that the MalK941 protein binds but does not hydrolyse ATP suggests that the MalK941 mutant protein mimics the inactive, ATP‐bound form of the normal MalK protein. In contrast, cells with high levels of MalK ATPase show a reduced ability to down‐modulate MalT and express several mal genes constitutively. These results are consistent with a model in which the inactive form of MalK down‐modulates MalT and decreases transcription, whereas the active form of MalK does not. This model suggests that bacteria may be able to couple information about extracellular substrate availability to the transcriptional apparatus via the levels of ATP hydrolysis associated with transport.

Characterization of two genes, glpQ and ugpQ, encoding glycerophosphoryl diester phosphodiesterases of Escherichia coli.

SummaryThe nucleotide sequences of the glpQ and ugpQ genes of Escherichia coli, which both encode glycerophosphoryl diester phosphodiesterases, were determined. The glpQ gene encodes a periplasmic enzyme of 333 amino acids, produced initially with a 25 residue long signal sequence, while ugpQ codes for a cytoplasmic protein of 247 amino acids. Despite differences in size and cellular location, significant similarity in the primary structures of the two enzymes was found suggesting a common evolutionary origin. The 3′ end of the ugpQ gene overlaps an open reading frame that is transcribed in the opposite direction. This open reading frame encodes a polypeptide with an unusual composition, i.e., 46 of the 146 amino acids are Gln or Asn. This polypeptide and the UgpQ protein were identified in an in vitro transcription/translation system as proteins with apparent molecular weights of 19.5 and 27 kDa, respectively.

Nucleotide sequence of the ugp genes of Escherichia coli K‐12: homology to the maltose system

The nucleotide sequence of the ugp genes of Escherichia Coli K‐12, which encode a phosphate‐limitation inducible uptake system for sn‐glycerol‐3‐phosphate and glycerophosphoryl diesters, was determined. The genetic organization of the operon differed from previously published results. A single promoter, containing a putative pho box, was detected by S1‐nuclease mapping. The promoter is followed by four open reading frames, designated ugpB, A, E and C, which encode a periplasmic binding protein, two hydrophobic membrane proteins and a protein that is likely to couple energy to the transport system, respectively. The sequences of the proteins contain the characteristics of several other binding protein‐dependent transport systems, but they seem to be particularly closely related to the maltose system.