Structure of the malB region in Escherichia coli K12. I. Genetic map of the malK-lamB operon

Obacunone represses Salmonella pathogenicity islands 1 and 2 in an envZ-dependent fashion

Obacunone belongs to a class of unique triterpenoids called limonoids, present in Citrus species. Previous studies from our laboratory suggested that obacunone possesses antivirulence activity and demonstrates inhibition of cell-cell signaling in Vibrio harveyi and Escherichia coli O157:H7. The present work sought to determine the effect of obacunone on the food-borne pathogen Salmonella enterica serovar Typhimurium LT2 by using a cDNA microarray. Transcriptomic studies indicated that obacunone represses Salmonella pathogenicity island 1 (SPI1), the maltose transporter, and the hydrogenase operon. Furthermore, phenotypic data for the Caco-2 infection assay and maltose utilization were in agreement with microarray data suggesting repression of SPI1 and maltose transport. Further studies demonstrated that repression of SPI1 was plausibly mediated through hilA. Additionally, obacunone seems to repress SPI2 under SPI2-inducing conditions as well as in Caco-2 infection models. Furthermore, obacunone seems to repress hilA in an EnvZ-dependent fashion. Altogether, the results of the study seems to suggest that obacunone exerts an antivirulence effect on S. Typhimurium and may serve as a lead compound for development of antivirulence strategies for S. Typhimurium.

Both maltose-binding protein and ATP are required for nucleotide-binding domain closure in the intact maltose ABC transporter

The maltose transporter MalFGK(2) of Escherichia coli is a member of the ATP-binding cassette superfamily. A periplasmic maltose-binding protein (MBP) delivers maltose to MalFGK(2) and stimulates its ATPase activity. Site-directed spin labeling EPR spectroscopy was used to study the opening and closing of the nucleotide-binding interface of MalFGK(2) during the catalytic cycle. In the intact transporter, closure of the interface coincides not just with the binding of ATP, as seen with isolated nucleotide-binding domains, but requires both MBP and ATP, implying that MBP stimulates ATPase activity by promoting the closure of the nucleotide-binding interface. After ATP hydrolysis, with MgADP and MBP bound, the nucleotide-binding interface resides in a semi-open configuration distinct from the fully open configuration seen in the absence of any ligand. We propose that P(i) release coincides with the reorientation of transmembrane helices to an inward-facing conformation and the final step of maltose translocation into the cell.

Crystal structure of a catalytic intermediate of the maltose transporter

The maltose uptake system of Escherichia coli is a well-characterized member of the ATP-binding cassette transporter superfamily. Here we present the 2.8-A crystal structure of the intact maltose transporter in complex with the maltose-binding protein, maltose and ATP. This structure, stabilized by a mutation that prevents ATP hydrolysis, captures the ATP-binding cassette dimer in a closed, ATP-bound conformation. Maltose is occluded within a solvent-filled cavity at the interface of the two transmembrane subunits, about halfway into the lipid bilayer. The binding protein docks onto the entrance of the cavity in an open conformation and serves as a cap to ensure unidirectional translocation of the sugar molecule. These results provide direct evidence for a concerted mechanism of transport in which solute is transferred from the binding protein to the transmembrane subunits when the cassette dimer closes to hydrolyse ATP.

Hexose/Pentose and Hexitol/Pentitol Metabolism

Escherichia coli and Salmonella enterica serovar Typhimurium exhibit a remarkable versatility in the usage of different sugars as the sole source of carbon and energy, reflecting their ability to make use of the digested meals of mammalia and of the ample offerings in the wild. Degradation of sugars starts with their energy-dependent uptake through the cytoplasmic membrane and is carried on further by specific enzymes in the cytoplasm, destined finally for degradation in central metabolic pathways. As variant as the different sugars are, the biochemical strategies to act on them are few. They include phosphorylation, keto-enol isomerization, oxido/reductions, and aldol cleavage. The catabolic repertoire for using carbohydrate sources is largely the same in E. coli and in serovar Typhimurium. Nonetheless, significant differences are found, even among the strains and substrains of each species. We have grouped the sugars to be discussed according to their first step in metabolism, which is their active transport, and follow their path to glycolysis, catalyzed by the sugar-specific enzymes. We will first discuss the phosphotransferase system (PTS) sugars, then the sugars transported by ATP-binding cassette (ABC) transporters, followed by those that are taken up via proton motive force (PMF)-dependent transporters. We have focused on the catabolism and pathway regulation of hexose and pentose monosaccharides as well as the corresponding sugar alcohols but have also included disaccharides and simple glycosides while excluding polysaccharide catabolism, except for maltodextrins.

Evidence for a coupling of synthesis and export of an outer membrane protein in Escherichia coli

We describe a lesion, lamB701-708, affecting the hydrophilic portion of the lambda receptor signal sequence. The C to A transversion of the sixth codon of the signal sequence changes a positively charged arginine to a neutral serine. The phenotype conferred by this alteration is unique among previously described signal sequence mutations. The results suggest an essential role for the charged amino acids of the hydrophilic segment in the initial interaction between a nascent secreted protein and a membrane export site. The results further suggest that synthesis of lambda receptor is coupled to its export.

DNA transposition of bacteriophage Mu. A quantitative analysis of target site selection in vitro

The Mu transpositional DNA recombination machinery selects target sites by assembling a protein-DNA complex that interacts with the target DNA and reacts whenever it locates a favorable sequence composition. Splicing of a transposon into the target generates a 5-bp duplication that reflects the original target site. Preferential usage of different target pentamers was examined with a minimal Mu in vitro system and quantitatively compiled consensus sequences for the most preferred and the least preferred sites were generated. When analyzed as base steps, preferences toward certain steps along the 5-bp target site were detected. We further show that insertion sites can be predicted on the basis of additively calculated base step values. Also surrounding sequences influence the preference of a given pentamer; a symmetrical structural component was revealed, suggesting potential hinges at and around the target site.

Acarbose, a pseudooligosaccharide, is transported but not metabolized by the maltose-maltodextrin system of Escherichia coli

The pseudooligosaccharide acarbose is a potent inhibitor of amylases, glucosidases, and cyclodextrin glycosyltransferase and is clinically used for the treatment of so-called type II or insulin-independent diabetes. The compound consists of an unsaturated aminocyclitol, a deoxyhexose, and a maltose. The unsaturated aminocyclitol moiety (also called valienamine) is primarily responsible for the inhibition of glucosidases. Due to its structural similarity to maltotetraose, we have investigated whether acarbose is recognized as a substrate by the maltose/maltodextrin system of Escherichia coli. Acarbose at millimolar concentrations specifically affected the growth of E. coli K-12 on maltose as the sole source of carbon and energy. Uptake of radiolabeled maltose was competitively inhibited by acarbose, with a Ki of 1.1 microM. Maltose-grown cells transported radiolabeled acarbose, indicating that the compound is recognized as a substrate. Studying the interaction of acarbose with purified maltoporin in black lipid membranes revealed that the kinetics of acarbose binding to LamB is asymmetric. The on-rate of acarbose is approximately 30 times lower when the molecule enters the pore from the extracellular side than when it enters from the periplasmic side. Acarbose could not be utilized as a carbon source since the compound alone was not a substrate of amylomaltase (MalQ) and was only poorly attacked by maltodextrin glucosidase (MalZ).

Maltose/maltodextrin system of Escherichia coli: transport, metabolism, and regulation

The maltose system of Escherichia coli offers an unusually rich set of enzymes, transporters, and regulators as objects of study. This system is responsible for the uptake and metabolism of glucose polymers (maltodextrins), which must be a preferred class of nutrients for E. coli in both mammalian hosts and in the environment. Because the metabolism of glucose polymers must be coordinated with both the anabolic and catabolic uses of glucose and glycogen, an intricate set of regulatory mechanisms controls the expression of mal genes, the activity of the maltose transporter, and the activities of the maltose/maltodextrin catabolic enzymes. The ease of isolating many of the mal gene products has contributed greatly to the understanding of the structures and functions of several classes of proteins. Not only was the outer membrane maltoporin, LamB, or the phage lambda receptor, the first virus receptor to be isolated, but also its three-dimensional structure, together with extensive knowledge of functional sites for ligand binding as well as for phage lambda binding, has led to a relatively complete description of this sugar-specific aqueous channel. The periplasmic maltose binding protein (MBP) has been studied with respect to its role in both maltose transport and maltose taxis. Again, the combination of structural and functional information has led to a significant understanding of how this soluble receptor participates in signaling the presence of sugar to the chemosensory apparatus as well as how it participates in sugar transport. The maltose transporter belongs to the ATP binding cassette family, and although its structure is not yet known at atomic resolution, there is some insight into the structures of several functional sites, including those that are involved in interactions with MBP and recognition of substrates and ATP. A particularly astonishing discovery is the direct participation of the transporter in transcriptional control of the mal regulon. The MalT protein activates transcription at all mal promoters. A subset also requires the cyclic AMP receptor protein for transcription. The MalT protein requires maltotriose and ATP as ligands for binding to a dodecanucleotide MalT box that appears in multiple copies upstream of all mal promoters. Recent data indicate that the ATP binding cassette transporter subunit MalK can directly inhibit MalT when the transporter is inactive due to the absence of substrate. Despite this wealth of knowledge, there are still basic issues that require clarification concerning the mechanism of MalT-mediated activation, repression by the transporter, biosynthesis and assembly of the outer membrane and inner membrane transporter proteins, and interrelationships between the mal enzymes and those of glucose and glycogen metabolism.

The Streptomyces ATP-binding component MsiK assists in cellobiose and maltose transport

Streptomyces reticuli harbors an msiK gene which encodes a protein with an amino acid identify of 90% to a corresponding protein previously identified in Streptomyces lividans. Immunological studies revealed that S. lividans and S. reticuli synthesize their highest levels of MsiK during growth with cellobiose, but not with glucose. Moreover, moderate amounts of MsiK are produced by both species in the course of growth with maltose, melibiose, and xylose and by S. lividans in the presence of xylobiose and raffinose. In contrast, a recently identified cellobiose-binding protein and its distantly related homolog were only found if S. reticuli or S. lividans, respectively, was cultivated with cellobiose. Uptake of cellobiose and maltose was tested and ascertained for S. reticuli and S. lividans, but not for an msiK S. lividans mutant. However, transformants of this mutant carrying the S. reticuli or S. lividans msiK gene on a multicopy plasmid had regained the ability to transport both sugars. The data show that MsiK assists two ABC transport systems.

High pressure represses expression of the malB operon in Escherichia coli

The formation of plaques by lambda phage in Escherichia coli was prevented by elevated hydrostatic pressure; phage plaques were not detected at 30 MPa. Furthermore, using promoter fragments derived from the malB operon, we showed that gene expression initiated from both promoters (malK-lamB and malEFG) was repressed by elevated hydrostatic pressure. Our findings suggest that high pressure affects gene expression directed by the malB regulatory interval, and this may cause a decrease in the quantities of lambda receptor protein, LamB.

A novel illegitimate recombination event: precise excision and reintegration with the Mu gem mutant prophage

The bacteriophage Mu is known to insert its DNA more or less randomly within the Escherichia coli chromosome, as do transposable elements, but unlike the latter, precise excision of the prophage, thereby restoring the original sequence, is not observed with wild-type Mu, although it has been reported with certain defective mutants. We show here that the mutant prophage Mu gem2ts can excise precisely from at least three separate loci -- malT, lac and thyA (selected as Mal+, Lac+ and Thy+, respectively). This excision occurs under permissive conditions for phage development, is observed in fully immune (c+) lysogens, and is independent of RecA and of Mu transposase. Mu gemts2 excision is invariably accompanied by reintegration of a Mu gem2ts prophage elsewhere in the chromosome. In the case of Mal+ revertants, this prophage is systematically located at 94 min on the E. coli chromosome. Mu gem2ts excision therefore sheds some light on the long-standing paradox of the lack of precise Mu excision.

'Muprints' of the lac operon demonstrate physiological control over the randomness of in vivo transposition

A method called Muprinting has been developed that uses PCR to generate a detailed picture of the bacteriophage Mu transposition sites in chosen domains of the bacterial chromosome. Muprinting experiments in Escherichia coli show that the frequency of phage integration changes dramatically near two repressor binding sites in the lac operon. When the lac operon was repressed, hotspots for Mu transposition were found near the O1 and O2 operators that are proposed to make a repression loop. When cells were grown in lactose, Mu transposition near these operators was greatly diminished. Striking changes in transposition frequencies were limited to the control region and were not found in a region of the lacZ gene lying beyond the O2 operator. Muprints of the bgl operon showed a different pattern; hotspots for Mu transposition detected in sequences upstream of the bglC promoter when the operon was silenced changed when the operon became activated by mutation. By targeting transposition to the regulatory regions around non-expressed genes, Mu may demonstrate a self-restraint mechanism that allows the virus to move through its host genome without disrupting the functions that contribute to a healthy cell physiology.

Sequence-function relationships in MalG, an inner membrane protein from the maltose transport system in Escherichia coli

The malG gene encodes a hydrophobic cytoplasmic membrane protein which is required for the energy-dependent transport of maltose and maltodextrins in Escherichia coli. The MalG protein, together with MalF and MalK proteins, forms a multimeric complex in the membrane consisting of two MalK subunits for each MalF and MalG subunit. Fifteen mutations have been isolated in malG by random linker insertion mutagenesis. Two regions essential for maltose transport have been identified. In particular, a hydrophilic region containing the peptidic motif EAA---G---------I-LP, highly conserved among inner membrane proteins from binding protein-dependent transport systems, is essential for maltose transport. The results also show that several regions of MalG are not essential for function. A region (residues 30-50) encompassing the first predicted transmembrane segment and the first periplasmic loop in MalG may be modified extensively with little effect on maltose transport and no effect on the stability and the localization of the protein. A region located at the middle of the protein (residues 153-157) is not essential for the function of the protein. A region, essential for maltodextrin utilization but not for maltose transport, has been identified near the C-terminus of the protein.

Identification of phosphate starvation-inducible genes in Escherichia coli K-12 by DNA sequence analysis of psi::lacZ(Mu d1) transcriptional fusions

Twenty-four independent phosphate starvation-inducible (psi) transcriptional fusions made with Mu d1(lacZbla) were analyzed by sequencing the psi::lacZ(Mu d1) chromosomal junctions by using DNAs amplified with the polymerase chain reaction or mini-Mu cloning. Our DNA sequence analysis showed that the MuR DNA in Mu d1 has an unexpected structure that is comprised of 104 bases of MuR DNA in the form of a large inverted repeat, which we denoted Mu d1-R. Also, Mu d1s in the phoA and phn (psiD) loci of the phosphate regulon showed regional specificities for the insertion sites despite the randomness of Mu d1 insertions into the genome as a whole. Gene products or open reading frames were identified for seven unknown psi::lacZ(Mu d1) transcriptional fusions by searching DNA data bases with the sequences adjacent and upstream of the Mu d1s. One psiC::lacZ(Mu d1) lies in the ugpB gene of the ugpBAEC operon, which encodes a periplasmic sn-glycerol-3-phosphate-binding protein; two psiQ::lacZ(Mu d1)s lie in the gltB gene, and one psiQ::lacZ(Mu d1) lies in the gltD gene of the gltBDF operon, encoding the large and small subunits of glutamate synthase, respectively; and the psi-51::lacZ(Mu d1) lies in the glpB gene of the glpABC operon, which codes for the anaerobically regulated glycerol-3-phosphate dehydrogenase. psiE and psiF::lacZ(Mu d1)s lie in uncharacterized open reading frames near the xylE and phoA genes, respectively. Six other psi::lacZ(Mu d1)s lie in yet unreported Escherichia coli sequences.

Ion channel activities in the Escherichia coli outer membrane

The electrical properties of Escherichia coli cells were examined by the patch-clamp technique. Giant cells or giant spheroplasts were generated by five different methods. By electron micrographic and other criteria we determined that the patches are most likely from the outer membrane. We regularly observed currents through at least two types of channels in this membrane. The first current is mechanosensitive and voltage-dependent, and can be observed in single gene mutants of the known major porins (ompF, ompC, phoE, lamB); this channel may represent a minor porin or a new class of outer membrane protein. The possible identity of the second, voltage-sensitive channel with one of the known outer membrane proteins is being explored. The high-resistance seals consistently formed on these patches and the presence of gated ion channels suggest that most of the pores of the outer membrane are not statically open, as commonly held, but are closed at rest and may be openable by physiological stimuli.

Fine-structure genetic map of the maltose transport operon of Salmonella typhimurium

We have constructed a fine-structure genetic map of the maltose transport operon in Salmonella typhimurium. We have isolated mal mutants by using indicator plates, penicillin selection, or a proton suicide technique. Mutants were obtained as spontaneous events or were induced by chemical mutagenesis and transposon insertion. Tn10 and Mu d(lac Ap)1 insertion mutations were used to create deletions. Mutations were also obtained in a gene that is equivalent to lamB in Escherichia coli, which codes for the lambda bacteriophage receptor. The gene products in the mutants were characterized by sodium dodecyl sulfate-polyacrylamide-gel electrophoresis and immunoblotting. Our data indicate that the location of this operon on the Salmonella chromosome as well as the gene order and its orientation are the same as those in E. coli. This map will be useful in studying the mechanism of periplasmic transport in S. typhimurium.

Comparison of sequences from the malB regions of Salmonella typhimurium and Enterobacter aerogenes with Escherichia coli K12: a potential new regulatory site in the interoperonic region

The malE and malK genes from Salmonella typhimurium, and the malEFG operon and a portion of malK from Enterobacter aerogenes were cloned and sequenced. Plasmid-borne malE genes from both species and the malF and malG genes from E. aerogenes were expressed normally in Escherichia coli, and their products function in maltose transport. This shows that the malB products from the three species are interchangeable, at least in the combinations tested. The general genetic organization of the malB region is conserved. Potential binding sites and distances between them are highly conserved in the regulatory intervals. An unexpected conserved region was detected, which we call the U box, and which could be another target for a regulatory protein. This hypothesis is supported by the presence of the U box in the regulatory region of the pulA-malX operon in Klebsiella pneumoniae. The intergenic region between malE and malF from S. typhimurium and E. aerogenes, contains inverted repeats similar to the palindromic units (PU or REP) found at the same location in E. coli. The predicted amino acid sequence of the encoded proteins showed 90% or more identity in every pairwise comparison of species.

Genetic reconstitution of the high-affinity L-arabinose transport system

Expression plasmids containing various portions of araFGH operon sequences were assayed for their ability to facilitate the high-affinity L-arabinose transport process in a strain lacking the chromosomal copy of this operon. Accumulation studies demonstrated that the specific induction of all three operon coding sequences was necessary to restore high-affinity L-arabinose transport. Kinetic analysis of this genetically reconstituted transport system indicated that it functions with essentially wild-type parameters. Therefore, L-arabinose-binding protein-mediated transport appears to require only two inducible membrane-associated components (araG and araH) in addition to the binding protein (araF).

Absence of insertions among spontaneous mutants of Salmonella typhimurium

While insertion sequences (IS) in Escherichia coli transpose frequently to generate spontaneous insertion mutants, such mutations are rare in Salmonella typhimurium: the only documented insertion mutation is a hisD mutation caused by the Salmonella-specific IS element IS200. To obtain more examples of IS200 insertion mutations and to seek additional types of IS elements in Salmonella, we selected and characterized 422 independent, spontaneous His- mutants and some 2100 additional mutants that are not necessarily independent. None of the mutants showed the absolute polar effect characteristic of insertion mutations or the reversion properties characteristic of insertions (low spontaneous reversion frequency and no reversion induction by chemical mutagens). A few mutants, showing a high spontaneous reversion frequency, were screened physically. No insertion mutations were found. Thus insertion mutations appear to be rare in S. typhimurium, in strong contrast to E. coli and despite the possession in Salmonella of at least one type of insertion element (IS200). These results suggest that in Salmonella transposition of the endogenous elements has been controlled. The transposition ability of the elements may have been reduced or favored target sites removed from the host genome.

Transcriptional occlusion of transposon targets

In Salmonella typhimurium, insertion of transposons Tn5, Tn10 and bacteriophage Mu is inhibited by transcription of some target sequences. The transcription effects on Tn5 are large when the lac operon is a target but are limited to a slight effect on the hisG gene of the his operon. The Tn10 element shows target occlusion in both operons. Phage Mu has been shown previously to be inhibited for insertion into the lac operon. In the his operon Mu is only inhibited for insertion into the hisG gene. The variability of the inhibition effect from one sequence to another suggests site or regional specificity for transcription effects. Reducing the probability of insertion into transcribed sequences may be of selective importance to transposons since it reduces the risk of killing the host while maintaining the ability to transpose.

Bacteriophage Mu sites required for transposition immunity

Plasmids with bacteriophage Mu sequences receive additional Mu insertions 20-700 times less frequently than plasmids without Mu sequences. The Mu sites required for this transposition immunity were mapped near each end, either of which was sufficient. The left site was between 127 and 203 base pairs from the left end, and the right site was between 22 and 93 base pairs from the right end. These sequences include the innermost but not the outermost of the three binding sites for the Mu A transposition protein at each end of Mu. Transposition immunity was cis-acting and independent of its location on a target plasmid. An additional copy of an immunity site reduced transposition a factor of 10 further. Transposition immunity was seen both during full phage lytic growth, with all the bacteriophage Mu genes, and during normal cellular growth, with a mini-Mu element containing only the Mu c and ner regulatory and A and B transposition genes.

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.

Replication forks of Escherichia coli are not the preferred sites for lysogenic integration of bacteriophage Mu

The question of whether bacteriophage Mu prefers replication forks for lysogenic integration into Escherichia coli chromosomes was tested by using two different systems. In the first, inactivation of genes was scored in synchronized cultures infected by Mu at various times. No increase in the mutation frequency of a gene was found after infection at the time of its replication. In the second, the composition of colonies formed by bacteria lysogenized by Mu was determined; the newly formed lysogens should give rise to mixed colonies (containing lysogenized as well as nonlysogenized bacteria), uniform colonies, or both, depending on the mode of integration. Both types of colonies were found, and the fraction of uniform colonies was proportional to the relative length of the unreplicated segment of an average chromosome in the culture. The results in both systems clearly preclude the possibility that a lysogenizing Mu integrates with high preference at the chromosome replication forks.

Tn7 transposition: two transposition pathways directed by five Tn7-encoded genes

The bacterial transposon Tn7 is capable of high-frequency transposition to a specific site in the Escherichia coli chromosome, attTn7, and of low-frequency transposition to sites other than attTn7. Using an in vitro insertional mutagenesis procedure, we have identified and characterized five tns (Tn seven) genes that are essential for Tn7 transposition. Three of these genes, tnsA, tnsB, and tnsC, are required, but are not sufficient, for all Tn7 transposition events. In addition, tnsD is specifically required for transposition to attTn7, whereas tnsE is specifically required for transposition to other sites. Thus, Tn7 is an elaborate transposon that encodes two distinct but overlapping transposition pathways.

Signal sequence mutations that alter coupling of secretion and translation of an Escherichia coli outer membrane protein

The lamB701-708 signal sequence mutation reduces expression of LamB, an outer membrane protein of Escherichia coli. To investigate the possibility that synthesis and export of LamB are coupled, as suggested by the expression defect of the lamB701-708 mutation, we isolated intragenic suppressors of the lamB701-708 mutation. The expression defect imposed by the lamB701-708 mutation is suppressed by an export-defective signal sequence mutation, suggesting that translation and export are coupled. The additional observation that not all export-defective signal sequence mutations suppressed the lamB701-708 expression defect suggests that translational arrest can be uncoupled from export.

Mapping of the sor genes for L-sorbose degradation in the chromosome of Klebsiella pneumoniae

A series of mutants was isolated in Klebsiella pneumoniae strain 1033, among them mutants unable to grow on L-sorbose. Different R' plasmids carrying the sor genes and other surrounding chromosomal genes were also isolated. Each plasmid contained the structural genes sorA for an Enzyme II of the phosphoenolpyruvate-dependent carbohydrate:phosphotransferase system, sorD for a D-glucitol 6-phosphate dehydrogenase, sorE for an L-sorbose 1-phosphate reductase, and the corresponding regulator gene sorR. These structural genes are coordinately expressed and inducible by L-sorbose. Cis-dominant and pleiotropic mutations rendering the expression of the sor genes constitutive or eliminating it were isolated. Complementation of a series of mutations in Escherichia coli K12 and K. pneumoniae by various R' and F' plasmids and by P1 transduction in K. pneumoniae located the sor genes within the following gene sequence: rbs rha pfkA metB ppc argH ilv btuB rpoB metA ace sor pgi malB uvrA. The rbs-ilv gene loci tightly linked in E. coli K12 at 84 min, are separated in the map of K. pneumoniae 1033 and located at 86 and 89 min, respectively.

Sequence determinants in the lamB gene of Escherichia coli influencing the binding and pore selectivity of maltoporin

Maltoporin (LamB protein) is a malto-oligosaccharide-selective pore protein in the outer membrane of Escherichia coli. The genetic basis of binding and transport specificity was investigated through cloning, mapping and sequencing lamB genes from seven independent mutants with various changes in maltodextrin binding affinities; these mutants were unchanged in binding phage lambda. Single amino acid substitutions specifically resulting in maltodextrin affinity changes were as follows: Arg8----His in two independent mutants resulted in much reduced affinity for all ligands and a smaller pore no longer selective for maltodextrins. A Trp74----Arg substitution resulted in a lower affinity for starch, a slight increase in maltose affinity but no striking pore changes. An Arg82----Ser resulted in lowered maltodextrin affinity, but increased affinity for sucrose in both binding and pore function. A Tyr118----Phe resulted in a higher affinity for both starch and maltose, a slightly larger pore and increased transport of maltohexaose by the pores. Asp121----Gly in two independent isolates resulted in a higher affinity for large dextrins and a marginally larger pore. These results suggest that the maltodextrin-selective functions reside in the N-terminal sequence of maltoporin and are separate from the phage lambda binding domains.

Comparison of the malA regions of Escherichia coli and Klebsiella pneumoniae

Using the mini-Mu-duction technique, we cloned the malA regions from Escherichia coli K-12 and Klebsiella pneumoniae. A comparison of the structures of the cloned DNAs indicated that the malT, malP, and malQ genes, encoding the transcriptional activator of the maltose regulon, maltodextrin phosphorylase, and amylomaltase, respectively, are similarly organized in both species; malP and malQ constitute an operon divergent from the malT gene. We sequenced 1,200 nucleotides encompassing the beginnings of the malT and malP genes, their promoters, and the intergenic region. The DNA sequences from the two species were very different; the levels of homology ranged from 28 to 80%, depending on the region. The sequences of the coding regions and of elements known to be important for the functions of these two promoters in E. coli were well conserved between the two bacteria, whereas the sequence of the malT-malP intergenic region had totally diverged.

Novel regulatory mutants of the phosphate regulon in Escherichia coli K-12

New pleiotropic mutants were isolated that express either the phoA, psiE or psiO promoter constitutively and simultaneously alter bacterial alkaline phosphatase regulation, carbon utilization or ultraviolet light sensitivity. To do this, Lac+ mutants were isolated from strains with the appropriate lacZ transcriptional fusions. Over 300 independent mutants were characterized, and all that constitutively express phoA map in phoR, phoU, the phosphate-specific transport system or a new locus called phoF. However, only phoU mutants express both phoA and psiE constitutively. Carbohydrate-utilizing mutants that show constitutive expression of psiE and psiO map in cya, crp and, possibly, crr. Also, numerous ultraviolet-light-sensitive mutants were discovered that show increased psiO expression and map in lon. Some other mutations that lead to constitutive psiO expression (which is normally induced either by phosphate, nitrogen or carbon starvation or anoxia) show decreased expression of phoA. Also, several mutants were found that show an unusual metastable character affecting psiO or phoA transcription. In these, colonies spontaneously switch between an induced and repressed "state" with respect to lac or bacterial alkaline phosphatase expression. In some, the clonal variation of the lactose phenotype or bacterial alkaline phosphatase synthesis is recA-independent and phenotypically resembles phase variation in Salmonella typhimurium. The latter class are called "phase mutants". The mutants are discussed in terms of protein-nucleic acid interactions and/or possible changes in the DNA, i.e. modifications or rearrangements, within the phosphate gene system, that are physiologically regulated.

Osmoregulation of the maltose regulon in Escherichia coli

The maltose regulon consists of four operons that direct the synthesis of proteins required for the transport and metabolism of maltose and maltodextrins. Expression of the mal genes is induced by maltose and maltodextrins and is dependent on a specific positive regulator, the MalT protein, as well as on the cyclic AMP-catabolite gene activator protein complex. In the absence of an exogenous inducer, expression of the mal regulon was greatly reduced when the osmolarity of the growth medium was high; maltose-induced expression was not affected, and malTc-dependent expression was only weakly affected. Mutants lacking MalK, a cytoplasmic membrane protein required for maltose transport, expressed the remaining mal genes at a high level, presumably because an internal inducer of the mal system accumulated; this expression was also strongly repressed at high osmolarity. The repression of mal regulon expression at high osmolarity was not caused by reduced expression of the malT, envZ, or crp gene or by changes in cellular cyclic AMP levels. In strains carrying mutations in genes encoding amylomaltase (malQ), maltodextrin phosphorylase (malP), amylase (malS), or glycogen (glg), malK mutations still led to elevated expression at low osmolarity. The repression at high osmolarity no longer occurred in malQ mutants, however, provided that glycogen was present.

The nucleotide sequence of the malT gene encoding the positive regulator of the Escherichia coli maltose regulon

The molecular organization of the malT region of the Escherichia coli K-12 chromosome has been elucidated by nucleotide sequence studies. A single open reading frame of 901 codons comprises the malT gene which is separated by a repetitive extragenic palindromic unit from an unidentified gene, orfX, divergently oriented with respect to malT. The predicted Mr of the MalT protein is 102988, making it the largest transcriptional regulatory protein yet described in E. coli. By deleting in vitro the 3'-end of the gene or constructing malT-lacZ gene fusions, it was found that the integrity of the C-terminus of MalT is indispensable for the activity of the protein. Furthermore, it was found that truncated MalT proteins lacking up to 300 amino acids at the C-terminus blocked the activity of the wild type protein. No sequence homology can be found either with the other activators known in E. coli or with the other proteins of the maltose regulon.

Maltose-binding protein does not modulate the activity of maltoporin as a general porin in Escherichia coli

Maltoporin (lambda receptor) is part of the maltose transport system in Escherichia coli and is necessary for the facilitated diffusion of maltose and maltodextrins across the outer membrane. Maltoporin also allows the diffusion of nonmaltodextrin substrates, albeit with less efficiency. The preference of maltoporin for maltodextrins in vivo is thought to be the result of an interaction of maltoporin with the maltose-binding protein, the malE gene product. In a recent report Heuzenroeder and Reeves (J. Bacteriol. 144:431-435, 1980) suggested that this interaction establishes a gating mechanism which inhibits the diffusion of nonmaltodextrin substrates, such as lactose. To reinvestigate this important conclusion, we constructed ompR malTc strains carrying either the malE+ gene, the nonpolar malE444 deletion, or the malE254 allele, which specifies an interaction-deficient maltose-binding protein. Lactose uptake was measured at different concentrations below the Km of this transport system and under conditions where transport was limited by the diffusion through maltoporin. We found no difference in the kinetics of lactose uptake irrespective of the malE allele. We conclude that the maltose-binding protein does not modulate the activity of maltoporin as a general outer membrane porin.

Isolation and characterization of outer membrane permeability mutants in Escherichia coli K-12

Escherichia coli normally requires the lamB gene for the uptake of maltodextrins. We have identified and characterized three independent mutations that allow E. coli to grow on maltodextrin in the absence of a functional lamB gene by allowing maltodextrins with a molecular weight greater than 1,000 to cross the outer membrane barrier. Two of the mutations map to the structural gene for the outer membrane porin OmpF, and the remaining mutation maps to the structural gene for the second major outer membrane porin, OmpC. These mutations increase the permeability of the outer membrane to small hydrophilic substances, antibiotics, and detergents. These mutations alter the electrophoretic mobility of the respective porin proteins.

Temperature-sensitive catabolite activator protein in Escherichia coli BUG6

BUG6 is a temperature-sensitive cell division mutant which forms filaments at the nonpermissive temperature. Synthesis of the maltose- and galactose-binding protein-dependent transport systems is also temperature sensitive in BUG6. Using operon and protein fusions of the maltose transport genes to lacZ, we observed that the temperature-sensitive control of the maltose transport system in BUG6 occurs at the transcriptional level. By P1-mediated transductions, we found that BUG6 contains two independent temperature-sensitive mutations. One maps between 2 and 3 min on the Escherichia coli linkage map, in close proximity to the fts-envA region. This mutation is responsible for temperature-sensitive cell division. The other mutation maps at 73 min in crp, the structural gene of the catabolite activator protein. The latter could be complemented by a hybrid plasmid carrying the wild-type crp as the only gene on a 0.9-kilobase HindIII-AluI restriction fragment. The mutation in crp alone was found to be responsible for the temperature-sensitive synthesis of the maltose transport system. Although it causes a complete block of transcription of the maltose transport genes at 41 degrees C, this mutation had only a marginal effect on the transcription of the lac operon.

Extension of bacteriophage lambda host range: selection, cloning, and characterization of a constitutive lambda receptor gene

A set of plasmids has been constructed that carry a constitutive lamB gene (LamBc phenotype) from Escherichia coli and that confer functional phage lambda receptors to bacteria other than E. coli. This E. coli LamBc strain has been selected to escape both maltose-inducible and glucose-repressible control. Constitutivity results from an IS-3 insertion, carrying a mobile promoter, proximal to lamB. The LamBc DNA has been cloned into both broad and narrow host-range plasmids, and the resulting pTROY plasmids have been transferred to diverse bacteria. Both Salmonella typhimurium/pTROY and Klebsiella pneumoniae/pTROY strains efficiently adsorb phage lambda; Pseudomonas aeruginosa/pTROY strains do not. Introduction of a functional E. coli LamB protein into foreign bacterial will allow these bacteria carrying pTROY plasmids to be infected by phage lambda recombinant DNA libraries, phage lambda::Tn insertion mutagenesis vectors, and in vivo lambda-packaged cosmids.

Assembly pathway of newly synthesized LamB protein an outer membrane protein of Escherichia coli K-12

The assembly of newly induced LamB protein (phage lambda receptor) was investigated in an operon fusion strain of Escherichia coli, in which the lamB gene is expressed under lac promoter control. The induction kinetics both for total cellular and for cell surface-exposed LamB protein were studied by immunochemical detection methods, using two distinct antisera directed against detergent-solubilized LamB trimers and completely denatured LamB monomers, respectively. Anti-trimer antibodies recognized both monomers and trimers, whereas anti-monomer antibodies only reacted with monomers. Provided appropriate solubilization conditions were used, both antisera were able to immunoprecipitate intracellular mature LamB protein quantitatively. Following induction, the first LamB antigenic determinants were detected after 60 to 80 seconds; detection of the newly synthesized protein by anti-monomer antibodies slightly preceded that by anti-trimer antibodies, a finding that could be partly explained by the observation that anti-monomer antibodies recognized a larger fraction of nascent LamB than did anti-trimer antibodies. Exposure of antigenic determinants at the cell surface was delayed for 30 to 50 seconds with respect to their synthesis. Therefore, either translocation or conformational changes must be rate-limiting in the series of processes that eventually convert the newly synthesized protein into its mature outer membrane state. LamB protein was found to occur in at least three clearly distinguishable states. State I is the LamB monomer, state II corresponds to a metastable trimer that dissociates in sodium dodecyl sulphate above 60 degrees C, and state III is the state LamB trimer that dissociates in sodium dodecyl sulphate only at temperatures above 90 degrees C. The chase kinetics of these states showed that conversion of newly synthesized LamB monomers to stable LamB trimers occurred in two stages: state I monomers were chased into metastable state II trimers rapidly (t 1/2 = 20 s), whereas stabilization of state II trimers to state III trimers was a relatively slow (t 1/2 = 5.7 min) process. Based on our results, a timing sequence in the assembly of outer membrane LamB protein is proposed.

Lambda placMu: a transposable derivative of bacteriophage lambda for creating lacZ protein fusions in a single step

We isolated a plaque-forming derivative of phage lambda, lambda placMu1 , that contains sequences from bacteriophage Mu enabling it to integrate into the Escherichia coli chromosome by means of the Mu transposition system. The Mu DNA carried by this phage includes both attachment sites as well as the cI, ner (cII), and A genes. Lambda placMu1 also contains the lacZ gene, deleted for its transcription and translation initiation signals, and the lacY gene of E. coli, positioned next to the terminal 117 base pairs from the S end of Mu. Because this terminal Mu sequence is an open reading frame fused in frame to lacZ, the phage can create lacZ protein fusions in a single step when it integrates into a target gene in the proper orientation and reading frame. To demonstrate the use of this phage, we isolated lacZ fusions to the malB locus. These showed the phenotypes and regulation expected for malB fusions and could be used to isolate specialized transducing phages carrying the entire gene fusion as well as an adjacent gene (malE). They were found to be genetically stable and rarely (less than 10(-7] gave rise to secondary Lac+ insertions. We also isolated insertions into high-copy-number plasmids. The physical structure of these phage-plasmid hybrids was that expected from a Mu-dependent insertion event, with the lambda placMu prophage flanked by the Mu attachment sites. Lac+ insertions into a cloned recA gene were found at numerous positions and produced hybrid proteins whose sizes were correlated with the position of the fusions in recA.

Affinity engineering of maltoporin: variants with enhanced affinity for particular ligands

Affinity-chromatographic selection on immobilized starch was used to selectively enhance the affinity of the maltodextrin-specific pore protein ( maltoporin , LamB protein, or lambda receptor protein) in the outer membrane of E. coli. Selection strategies were established for rare bacteria in large populations producing maltoporin variants with enhanced affinities for both starch and maltose, for starch but not maltose and for maltose but not starch. Three classes of lamB mutants with up to eight-fold increase in affinity for particular ligands were isolated. These mutants provide a unique range of modifications in the specificity of a transport protein.

Intragenic suppressor mutations that restore export of maltose binding protein with a truncated signal peptide

A deletion mutation, malE delta 12-18, removes seven residues from the hydrophobic core of the maltose binding protein (MBP) signal peptide and thus prevents secretion of this protein to the periplasm of E. coli. Intragenic suppressor mutations of malE delta 12-18 have been obtained, some highly efficient in their ability to restore proper MBP export. Twelve independently isolated suppressors represent six unique mutational events. Five result in alterations within the MBP signal peptide; one changes the amino acid at residue 19 of the mature MBP. Analysis of these suppressors indicates that the length of the hydrophobic core is a major determinant of signal peptide function. The experiments further suggest that the hydrophobic core region serves primarily a structural role in mediating protein secretion, and that other sequences outside of this region may be responsible for providing the initial recognition of the MBP nascent chain as a secreted protein.

D-ribose metabolism in Escherichia coli K-12: genetics, regulation, and transport

We have isolated mutants defective in high-affinity D-ribose transport. The mutations map in rbsT or rbsB , the structural gene for ribose binding protein. rbsT consists of at least one gene coding for a protein required for high-affinity transport. The high-affinity transport-defective mutants were able to utilize D-ribose, indicating that at least a second, low-affinity transport system for D-ribose is present in Escherichia coli K-12. rbsT and rbsB are located at min 84 on the E. coli genetic map and, together with rbsK , the gene coding for ribokinase , constitute an rbs operon. The order of genes is rbsP /O rbsT rbsB rbsK . The rbs operon is subject to negative control by the product of the rbsR gene. rbsR is located distal to the rbs operon and appears to form a separate transcriptional unit.

Plasmid insertion mutagenesis and lac gene fusion with mini-mu bacteriophage transposons

Small bacteriophage Mu transposable elements containing the lac operon structural genes were constructed to facilitate the isolation and use of Mu insertions and lac gene fusions. These mini-Mu elements have selectable genes for either ampicillin or kanamycin resistance and can be used to form both transcriptional and translational lac gene fusions. Some of the mini-Mu-lac elements constructed are deleted for the Mu A and B transposition genes and form stable insertions that cannot undergo transposition unless complemented for these functions. A procedure was developed for selecting mini-Mu insertions specifically into plasmids, including commonly used high-copy-number cloning vectors such as pBR322. Mu insertions in pBR322 were found to be distributed around the plasmid, but insertions in certain regions occurred more frequently than in others.

Molecular cloning and characterization of genes required for ribose transport and utilization in Escherichia coli K-12

We isolated spontaneous and transposon insertion mutants of Escherichia coli K-12 that were specifically defective in utilization or in high-affinity transport of D-ribose (or in both). Cotransduction studies located all of the mutations near ilv, at the same position as previously identified mutations causing defects in ribokinase ( rbsK ) or ribose transport ( rbsP ). Plasmids that complemented the rbs mutations were isolated from the collection of ColE1 hybrid plasmids constructed by Clarke and Carbon. Analysis of those plasmids as well as of fragments cloned into pBR322 and pACYC184 allowed definition of the rbs region. Products of rbs genes were identified by examination of the proteins produced in minicells containing various rbs plasmids. We identified four rbs genes: rbsB , which codes for the 29-kilodalton ribose-binding protein; rbsK , which codes for the 34-kilodalton ribokinase ; rbsA , which codes for a 50-kilodalton protein required for high-affinity transport; and rbsC , which codes for a 27-kilodalton protein likely to be a transport system component. Our studies showed that these genes are transcribed from a common promoter in the order rbsA rbsC rbsB rbsK . It appears that the high-affinity transport system for ribose consists of the three components, ribose-binding protein, the 50-kilodalton RbsA protein, and the 27-kilodalton RbsC protein, although a fourth, unidentified component could exist. Mutants defective in this transport system, but normal for ribokinase , are able to grow normally on high concentrations of the sugar, indicating that there is at least a second, low-affinity transport system for ribose in E. coli K-12.

Screening for lamB missense mutations which alter all lambda receptor activities in Escherichia coli K12

Previously described missense mutations in gene lamB, the structural gene for the lambda receptor in Escherichia coli K12, affected only some of the activities of this multifunctional protein. We isolated lamB mutations, some of which could be of the missense type, and which affected all of the activities of the LamB protein. Among 8 of these mutations, 5 affected the stability of the LamB protein and 3 did not markedly decrease the amount of LamB protein in the mutant strains. In these 3 cases, the mutated LamB proteins were recovered with the envelope of the mutants. We briefly discuss the nature of these mutations and their possible effects on LamB protein structure and location.

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.