Evidence for the evolutionary relatedness of the proteins of the bacterial phosphoenolpyruvate:sugar phosphotransferase system

Protein:Protein interactions in the cytoplasmic membrane apparently influencing sugar transport and phosphorylation activities of the e. coli phosphotransferase system

The multicomponent phosphoenolpyruvate (PEP)-dependent sugar-transporting phosphotransferase system (PTS) in Escherichia coli takes up sugar substrates from the medium and concomitantly phosphorylates them, releasing sugar phosphates into the cytoplasm. We have recently provided evidence that many of the integral membrane PTS permeases interact with the fructose PTS (FruA/FruB) [1]. However, the biochemical and physiological significance of this finding was not known. We have carried out molecular genetic/biochemical/physiological studies that show that interactions of the fructose PTS often enhance, but sometimes inhibit the activities of other PTS transporters many fold, depending on the target PTS system under study. Thus, the glucose (Glc), mannose (Man), mannitol (Mtl) and N-acetylglucosamine (NAG) permeases exhibit enhanced in vivo sugar transport and sometimes in vitro PEP-dependent sugar phosphorylation activities while the galactitol (Gat) and trehalose (Tre) systems show inhibited activities. This is observed when the fructose system is induced to high levels and prevented when the fruA/fruB genes are deleted. Overexpression of the fruA and/or fruB genes in the absence of fructose induction during growth also enhances the rates of uptake of other hexoses. The β-galactosidase activities of man, mtl, and gat-lacZ transcriptional fusions and the sugar-specific transphosphorylation activities of these enzyme transporters were not affected either by frustose induction or by fruAB overexpression, showing that the rates of synthesis of the target PTS permeases were not altered. We thus suggest that specific protein-protein interactions within the cytoplasmic membrane regulate transport in vivo (and sometimes the PEP-dependent phosphorylation activities in vitro) of PTS permeases in a physiologically meaningful way that may help to provide a hierarchy of preferred PTS sugars. These observations appear to be applicable in principle to other types of transport systems as well.

Phylogenetic characterization of transport protein superfamilies: superiority of SuperfamilyTree programs over those based on multiple alignments

Transport proteins function in the translocation of ions, solutes and macromolecules across cellular and organellar membranes. These integral membrane proteins fall into >600 families as tabulated in the Transporter Classification Database (www.tcdb.org). Recent studies, some of which are reported here, define distant phylogenetic relationships between families with the creation of superfamilies. Several of these are analyzed using a novel set of programs designed to allow reliable prediction of phylogenetic trees when sequence divergence is too great to allow the use of multiple alignments. These new programs, called SuperfamilyTree1 and 2 (SFT1 and 2), allow display of protein and family relationships, respectively, based on thousands of comparative BLAST scores rather than multiple alignments. Superfamilies analyzed include: (1) Aerolysins, (2) RTX Toxins, (3) Defensins, (4) Ion Transporters, (5) Bile/Arsenite/Riboflavin Transporters, (6) Cation:Proton Antiporters, and (7) the Glucose/Fructose/Lactose superfamily within the prokaryotic phosphoenol pyruvate-dependent Phosphotransferase System. In addition to defining the phylogenetic relationships of the proteins and families within these seven superfamilies, evidence is provided showing that the SFT programs outperform programs that are based on multiple alignments whenever sequence divergence of superfamily members is extensive. The SFT programs should be applicable to virtually any superfamily of proteins or nucleic acids.

Cloning and molecular analysis of a mannitol operon of phosphoenolpyruvate-dependent phosphotransferase (PTS) type from Vibrio cholerae O395

A putative mannitol operon of the phosphoenolpyruvate phosphotransferase (PTS) type was cloned from Vibrio cholerae O395, and its activity was studied in Escherichia coli. The 3.9-kb operon comprising three genes is organized as mtlADR. Based on the sequence analysis, these were identified as genes encoding a putative mannitol-specific enzyme IICBA (EII(Mtl)) component (MtlA), a mannitol-1-phosphate dehydrogenase (MtlD), and a mannitol operon repressor (MtlR). The transport of [(3)H]mannitol by the cloned mannitol operon in E. coli was 13.8 ± 1.4 nmol/min/mg protein. The insertional inactivation of EII(Mtl) abolished mannitol and sorbitol transport in V. cholerae O395. Comparison of the mannitol utilization apparatus of V. cholerae with those of Gram-negative and Gram-positive bacteria suggests highly conserved nature of the system. MtlA and MtlD exhibit 75% similarity with corresponding sequences of E. coli mannitol operon genes, while MtlR has 63% similarity with MtlR of E. coli. The cloning of V. cholerae mannitol utilization system in an E. coli background will help in elucidating the functional properties of this operon.

Preliminary studies on the inhibition of D-sorbitol-6-phosphate 2–dehydrogenase fromEscherichia coliwith substrate analogues

D-Sorbitol-6-phosphate 2-dehydrogenase catalyzes the NADH-dependent conversion of D-fructose 6-phosphate to D-sorbitol 6-phosphate and improved production and purification of the enzyme from Escherichia coli is reported. Preliminary inhibition studies of the enzyme revealed 5-phospho-D-arabinonohydroxamic acid and 5-phospho-D-arabinonate as new substrate analogue inhibitors of the F6P catalyzed reduction with IC50 values of (40 +/- 1) microM and (48 +/- 3) microM and corresponding Km/IC50 ratio values of 14 and 12, respectively. Furthermore, we report here the phosphomannose isomerase substrate D-mannose 6-phosphate as the best inhibitor of E. coli D-sorbitol-6-phosphate 2-dehydrogenase yet reported with an IC50 = 7.5 +/- 0.4 microM and corresponding Km/IC50 ratio = about 76.

Novel PTS proteins revealed by bacterial genome sequencing: a unique fructose-specific phosphoryl transfer protein with two HPr-like domains in Haemophilus influenzae

The completely sequenced genome of Haemophilus influenzae has been analysed for proteins of the phosphoenolpyruvate: sugar phosphotransferase system (PTS). We show that within the fructose PTS H. influenzae possesses a novel multi-domain phosphoryl transfer protein, not previously recognized, that includes two fructose-specific HPr domains fused in tandem in a single polypeptide chain.

Ketohexokinase (ATP:D-fructose 1-phosphotransferase) from a halophilic archaebacterium, Haloarcula vallismortis: purification and properties

Ketohexokinase (ATP:D-fructose 1-phosphotransferase [EC 2.7.1.3]), detected for the first time in a prokaryote, i.e., the extreme halophile Haloarcula vallismortis, was isolated and characterized from the same archaebacterium. This enzyme was characterized with respect to its molecular mass, amino acid composition, salt dependency, immunological cross-reactivity, and kinetic properties. Gel filtration and sucrose density gradient centrifugation revealed a native molecular mass of 100 kDa for halobacterial ketohexokinase, which is larger than its mammalian counterpart. The enzyme could be labeled by UV irradiation in the presence of [ gamma-32P]ATP, suggesting the involvement of a phosphoenzyme intermediate. Other catalytic features of the enzyme were similar to those of its mammalian counterparts. No antigenic cross-reactivity could be detected between the H. vallismortis ketohexokinase and the ketohexokinases from different rat tissues.

Computer-aided analyses of transport protein sequences: gleaning evidence concerning function, structure, biogenesis, and evolution

Three-dimensional structures have been elucidated for very few integral membrane proteins. Computer methods can be used as guides for estimation of solute transport protein structure, function, biogenesis, and evolution. In this paper the application of currently available computer programs to over a dozen distinct families of transport proteins is reviewed. The reliability of sequence-based topological and localization analyses and the importance of sequence and residue conservation to structure and function are evaluated. Evidence concerning the nature and frequency of occurrence of domain shuffling, splicing, fusion, deletion, and duplication during evolution of specific transport protein families is also evaluated. Channel proteins are proposed to be functionally related to carriers. It is argued that energy coupling to transport was a late occurrence, superimposed on preexisting mechanisms of solute facilitation. It is shown that several transport protein families have evolved independently of each other, employing different routes, at different times in evolutionary history, to give topologically similar transmembrane protein complexes. The possible significance of this apparent topological convergence is discussed.

Comparison of the sequences of the nagE operons from Klebsiella pneumoniae and Escherichia coli K12: enhanced variability of the enzyme IIN-acetylglucosamine in regions connecting functional domains

The nagE operon, encoding the enzyme II specific for N-acetylglucosamine (EIINag), and adjacent DNA from the chromosome of Klebsiella pneumoniae were sequenced and compared with the corresponding sequence from Escherichia coli K12. The deduced EIINag sequences differ in 72 out of 651 amino acids, the K. pneumoniae sequence being three residues longer. The amino acid differences were distributed unevenly, and were most frequent in regions connecting the three functional domains of the protein. In the nagE-nagB intergenic region, two promoter, two operator, and one CAP consensus sequence with regulatory functions were highly conserved. The nag structural genes from both species were very similar (83% DNA similarity; 89% amino acid similarity) except for frequent AT to GC exchanges in the wobble base of codons in K. pneumoniae DNA relative to the E. coli DNA.

Properties of the glucose phosphotransferase system of Clostridium acetobutylicum NCIB 8052

The glucose phosphotransferase system (PTS) of Clostridium acetobutylicum was studied by using cell extracts. The system exhibited a Km for glucose of 34 microM, and glucose phosphorylation was inhibited competitively by mannose and 2-deoxyglucose. The analogs 3-O-methylglucoside and methyl alpha-glucoside did not inhibit glucose phosphorylation significantly. Activity showed no dependence on Mg2+ ions or on pH in the range 6.0 to 8.0. The PTS comprised both soluble and membrane-bound proteins, which interacted functionally with the PTSs of Clostridium pasteurianum, Bacillus subtilis, and Escherichia coli. In addition to a membrane-bound enzyme IIGlc, sugar phosphorylation assays in heterologous systems incorporating extracts of pts mutants of other organisms provided evidence for enzyme I, HPr, and IIIGlc components. The HPr was found in the soluble fraction of C. acetobutylicum extracts, whereas enzyme I, and probably also IIIGlc, was present in both the soluble and membrane fractions, suggesting a membrane location in the intact cell.

Evolutionary relationships among the permease proteins of the bacterial phosphoenolpyruvate: sugar phosphotransferase system. Construction of phylogenetic trees and possible relatedness to proteins of eukaryotic mitochondria

The amino acid sequences of 15 sugar permeases of the bacterial phosphoenolpyruvate-dependent phosphotransferase system (PTS) were divided into four homologous segments, and these segments were analyzed to give phylogenetic trees. The permease segments fell into four clusters: the lactose-cellobiose cluster, the fructose-mannitol cluster, the glucose-N-acetylglucosamine cluster, and the sucrose-beta-glucoside cluster. Sequences of the glucitol and mannose permeases (clusters 5 and 6, respectively) were too dissimilar to establish homology with the other permeases, but short regions of statistically significant sequence similarities were noted. The functional and structural relationships of these permease segments are discussed. Some of the homologous PTS permeases were found to exhibit sufficient sequence similarity to subunits 4 and 5 of the eukaryotic mitochondrial NADH dehydrogenase complex to suggest homology. Moreover, subunits 4 and 5 of this complex appeared to be homologous to each other, suggesting that these PTS and mitochondrial proteins comprise a superfamily. The integral membrane subunits of the evolutionarily divergent mannose PTS permease, the P and M subunits, exhibited limited sequence similarity to subunit 6 of the mitochondrial F1F0-ATPase and subunit 5b of cytochrome oxidase, respectively. These results suggest that PTS sugar permeases and mitochondrial proton-translocating proteins may be related, although the possibility of convergent evolution cannot be ruled out.

The glucose permease of the phosphotransferase system of Bacillus subtilis: evidence for IIGlc and IIIGlc domains

Glucose is taken up in Bacillus subtilis via the phosphoenolpyruvate:glucose phosphotransferase system (glucose PTS). Two genes, orfG and ptsX, have been implied in the glucose-specific part of this PTS, encoding an Enzyme IIGlc and an Enzyme IIIGlc, respectively. We now show that the glucose permease consists of a single, membrane-bound, polypeptide with an apparent molecular weight of 80,000, encoded by a single gene which will be designated ptsG. The glucose permease contains domains that are 40-50% identical to the IIGlc and IIIGlc proteins of Escherichia coli. The B. subtilis IIIGlc domain can replace IIIGlc in E. coli crr mutants in supporting growth on glucose and transport of methyl alpha-glucoside. Mutations in the IIGlc and IIIGlc domains of the B. subtilis ptsG gene impaired growth on glucose and in some cases on sucrose. ptsG mutants lost all methyl alpha-glucoside transport but retained part of the glucose-transport capacity. Residual growth on glucose and transport of glucose in these ptsG mutants suggested that yet another uptake system for glucose existed, which is either another PT system or regulated by the PTS. The glucose PTS did not seem to be involved in the regulation of the uptake or metabolism of non-PTS compounds like glycerol. In contrast to ptsl mutants in members of the Enterobacteriaceae, the defective growth of B. subtilis ptsl mutants on glycerol was not restored by an insertion in the ptsG gene which eliminated IIGlc. Growth of B. subtilis ptsG mutants, lacking IIGlc, was not impaired on glycerol. From this we concluded that neither non-phosphorylated nor phosphorylated IIGlc was acting as an inhibitor or an activator, respectively, of glycerol uptake and metabolism.

Identification of a gene encoding an HPr-like protein in Aspergillus fumigatus

The gene encoding a histidine-containing protein (HPr)-like protein was identified in a cDNA library of Aspergillus fumigatus. The predicted amino acid sequence of the fungal HPr showed greater homology with HPr from Gram-positive bacteria than from Gram-negative bacteria. Since other components of the phosphoenolpyruvate: carbohydrate phosphotransferase system have not been identified in eukaryotes, this raises the question of what regulatory function the HPr-like protein might have evolved in this fungus.

Nucleotide sequence of the fruA gene, encoding the fructose permease of the Rhodobacter capsulatus phosphotransferase system, and analyses of the deduced protein sequence

The nucleotide sequence of the fruA gene, the terminal gene in the fructose operon of Rhodobacter capsulatus, is reported. This gene codes for the fructose permease (molecular weight, 58,575; 578 aminoacyl residues), the fructose enzyme II (IIFru) of the phosphoenolpyruvate-dependent phosphotransferase system. The deduced aminoacyl sequence of the encoded gene product was found to be 55% identical throughout most of its length with the fructose enzyme II of Escherichia coli, with some regions strongly conserved and others weakly conserved. Sequence comparisons revealed that the first 100 aminoacyl residues of both enzymes II were homologous to the second 100 residues, suggesting that an intragenic duplication of about 300 nucleotides had occurred during the evolution of IIFru prior to divergence of the E. coli and R. capsulatus genes. The protein contains only two cysteyl residues, and only one of these residues is conserved between the two proteins. This residue is therefore presumed to provide the active-site thiol group which may serve as the phosphorylation site. IIFru was found to exhibit regions of homology with sequenced enzymes II from other bacteria, including those specific for sucrose, beta-glucosides, mannitol, glucose, N-acetylglucosamine, and lactose. The degree of evolutionary divergence differed for different parts of the proteins, with certain transmembrane segments exhibiting high degrees of conservation. The hydrophobic domain of IIFru was also found to be similar to several uniport and antiport transporters of animals, including the human and mouse insulin-responsive glucose facilitators. These observations suggest that the mechanism of transmembrane transport may be similar for permeases catalyzing group translocation and facilitated diffusion.

Physiological consequences of the complete loss of phosphoryl-transfer proteins HPr and FPr of the phosphoenolpyruvate:sugar phosphotransferase system and analysis of fructose (fru) operon expression in Salmonella typhimurium

Mutants of Salmonella typhimurium defective in the proteins of the fructose operon [fruB(MH)KA], the fructose repressor (fruR), the energy-coupling enzymes of the phosphoenolpyruvate:sugar phosphotransferase system (PTS) (ptsH and ptsI), and the proteins of cyclic AMP action (cya and crp) were analyzed for their effects on cellular physiological processes and expression of the fructose operon. The fru operon consists of three structural genes: fruB(MH), which encodes the enzyme IIIFru-modulator-FPr tridomain fusion protein of the PTS; fruK, which encodes fructose-1-phosphate kinase; and fruA, which encodes enzyme IIFru of the PTS. Among the mutants analyzed were Tn10 insertion mutants and lacZ transcriptional fusion mutants. It was found that whereas a fruR::Tn10 insertion mutant, several fruB(MH)::Mu dJ and fruK::Mu dJ fusion mutants, and several ptsHI deletion mutants expressed the fru operon and beta-galactosidase at high constitutive levels, ptsH point mutants and fruA::Mu dJ fusion mutants retained inducibility. Inclusion of the wild-type fru operon in trans did not restore fructose-inducible beta-galactosidase expression in the fru::Mu dJ fusion mutants. cya and crp mutants exhibited reduced basal activities of all fru regulon enzymes, but inducibility was not impaired. Surprisingly, fruB::Mu dJ crp or cya double mutants showed over 10-fold inducibility of the depressed beta-galactosidase activity upon addition of fructose, even though this activity in the fruB::Mu dJ fusion mutants that contained the wild-type cya and crp alleles was only slightly inducible. By contrast, beta-galactosidase activity in a fruK::Mu dJ fusion mutant, which was similarly depressed by introduction of a crp or cya mutation, remained constitutive. Other experiments indicated that sugar uptake via the PTS can utilize either FPr-P or HPr-P as the phosphoryl donor, but that FPr is preferred for fructose uptake whereas HPr is preferred for uptake of the other sugars. Double mutants lacking both proteins were negative for the utilization of all sugar substrates of the PTS, were negative for the utilization of several gluconeogenic carbon sources, exhibited greatly reduced adenylate cyclase activity, and were largely nonmotile. These phenotypic properties are more extreme than those observed for tight ptsH and ptsI mutants, including mutants deleted for these genes. A biochemical explanation for this fact is proposed.

Structure and evolution of a multidomain multiphosphoryl transfer protein. Nucleotide sequence of the fruB(HI) gene in Rhodobacter capsulatus and comparisons with homologous genes from other organisms

The gene order of the fructose (fru) operon and nucleotide sequence of the first gene (fruB(HI) of Rhodobacter capsulatus are reported, analyzed and compared with homologous genes from other bacteria, and the gene products are identified. Included within the region reported is a gene encoding a multiphosphoryl transfer protein (MTP) of the phosphoenolpyruvate:sugar phosphotransferase system (PTS). MTP consists of three moieties: a fructose-specific enzyme III (IIIfru)-like N-terminal moiety (residues 1 to 143) followed by an FPr(HPr)-like moiety (residues 157 to 245) and an enzyme I-like moiety (residues 273 to 827). The enzyme III-like moiety closely resembles the N-terminal 143 residues of the IIIfru-FPR fusion protein from Salmonella typhimurium (40.6% identity throughout its length) and the C-terminal 145 residues of the mannitol-specific enzyme II (IImtl) (37.8% identity throughout its length with the IIImtl moiety of IImtl). The FPr-like domain of MTP resembles the S. typhimurium FPr (42.4% identity) and the Escherichia coli or S. typhimurium HPr (38.8% identity). The enzyme I-like moiety resembles the E. coli enzyme I (38.9% identity). Predicted phosphorylation sites within the three functional units of MTP (His62 in the IIIfru-like moiety; His171 in the FPr-like moiety and His457 in the enzyme I-like moiety) were identified on the basis of sequence comparisons with the homologous proteins from enteric bacteria. The three functional domains of MTP are joined by two flexible "linkage" regions, rich in alanine, glycine and proline, which show 47% sequence identity with each other. They also exhibit a high degree of sequence identity with the linkage region of the mannose-specific enzyme III (IIIman) of the E. coli PTS as well as several other proteins of bacterial, eukaryotic and viral origin. At the RNA level, these linker regions formed hairpin structures with high (90%) G + C content. Analyses of the IIIfru-FPr fusion protein of S. typhimurium revealed that between the IIIfru and FPr moieties of this protein is a stretch of 142 amino acids that do not show homology to known PTS proteins. This region and the adjacent FPr-like region contain a sequence of 110 residues exhibiting 59% similarity to the receiver consensus motif defined by Kofoid and Parkinson. Because the Salmonella IIIfru-FPr fusion protein has been implicated in transcriptional regulation, this region of the Salmonella protein may prove to have regulatory significance.(ABSTRACT TRUNCATED AT 400 WORDS)

Structures and homologies of carbohydrate: phosphotransferase system (PTS) proteins

The bacterial phosphotransferase system (PTS) is the major transport system for many carbohydrates that are phosphorylated concomitantly with the translocation step through the membrane (group translocation). It consists of two general proteins, enzyme I and histidine protein (HPr), and a series of more than 15 substrate-specific enzymes II (EII). The sequences of several of these derived from Gram-positive and Gram-negative bacteria were compared, which allowed the possible identification of the following functional domains: membrane-bound pore, substrate-binding site, linker domains, transphosphorylation domain and primary phosphorylation site. Several EIIs have been analysed in the meantime, also by topological tests, by sequential deletion of the corresponding structural genes, and by construction of intergenic hybrids between different domains of several EIIs. These data suggest evolutionary relationships between different EIIs; they also enable a general model to be constructed of EIIs as carbohydrate transport systems, phosphotransferases, chemoreceptors in chemotaxis and as part of a global regulatory network.

Fructose transport by Escherichia coli

The utilization of fructose by Escherichia coli involves, as first step, the uptake of the sugar, normally via the phosphoenolpyruvate-dependent phosphotransferase system (PTS). This fructose-specific PTS differs in several ways from that effecting the uptake of other sugars that also possess the 3,4,5-D-arabino-hexose configuration: these differences are discussed. Mutants that lack the genes ptsI and ptsH, which specify components of the PTS common to most PT-sugars, can mutate further to regain the ability to utilize fructose when this is present in relatively high concentration (i.e. greater than 2 mM) in the medium. Some of the properties of this unusual uptake system is discussed.

Metabolite-sensitive, ATP-dependent, protein kinase-catalyzed phosphorylation of HPr, a phosphocarrier protein of the phosphotransferase system in gram-positive bacteria

In this review article we summarize the recent information available concerning important mechanistic and physiological aspects of the protein kinase-mediated phosphorylation of seryl residue-46 in HPr, a phosphocarrier protein of the phosphoenolpyruvate: sugar phosphotransferase system in Gram-positive bacteria. Emphasis is placed upon the information recently obtained in two laboratories through the use of site-specific mutants of the HPr protein. The results show that (i) in contrast to eukaryotic protein kinases, the HPr(ser) kinase recognizes the tertiary structure of HPr rather than a restricted part of the primary sequence of the protein; (ii) like seryl protein kinases of eukaryotes, the HPr(ser) kinase can phosphorylate a threonyl residue, but not a tyrosyl residue when such a residue replaces the regulatory seryl residue in position-46 of the protein; (iii) the regulatory consequences of seryl phosphorylation are due to the introduction of a negative charge at position-46 in the protein rather than the bulky phosphate group; and (iv) PTS protein-HPr interactions influence the conformation of HPr, thereby retarding or stimulating the rate of kinase-catalyzed seryl-46 phosphorylation. The physiological consequences of HPr(ser) phosphorylation in vivo are still a matter of debate.

Involvement of the bacterial phosphotransferase system in diverse mechanisms of transcriptional regulation

A large number of genes in bacteria appear to be expressed in processes regulated by very different mechanisms dependent on the activities of the proteins of the phosphoenolpyruvate/sugar phosphotransferase system. These mechanisms include protein phosphorylation, antitermination, enhancement, antagonistic repression/activation, sensory detection involving two component systems, and other processes not yet understood.

Deletion mutants of the Escherichia coli K-12 mannitol permease: dissection of transport-phosphorylation, phospho-exchange, and mannitol-binding activities

We have constructed a series of deletion mutations of the cloned Escherichia coli K-12 mtlA gene, which encodes the mannitol-specific enzyme II of the phosphoenolpyruvate (PEP)-dependent carbohydrate phosphotransferase system. This membrane-bound permease consists of 637 amino acid residues and is responsible for the concomitant transport and phosphorylation of D-mannitol in E. coli. Deletions into the 3' end of mtlA were constructed by exonuclease III digestion. Restriction mapping of the resultant plasmids identified several classes of deletions that lacked approximately 5% to more than 75% of the gene. Immunoblotting experiments revealed that many of these plasmids expressed proteins within the size range predicted by the restriction analyses, and all of these proteins were membrane localized, which demonstrated that none of the C-terminal half of the permease is required for membrane insertion. Functional analyses of the deletion proteins, expressed in an E. coli strain deleted for the chromosomal copy of mtlA, showed that all but one of the strains containing confirmed deletions were inactive in transport and PEP-dependent phosphorylation of mannitol, but deletions removing up to at least 117 amino acid residues from the C terminus of the permease were still active in catalyzing phospho exchange between mannitol 1-phosphate and mannitol. A deletion protein that lacked 240 residues from the C terminus of the permease was inactive in phospho exchange but still bound mannitol with high affinity. These experiments localize sites important for transport and PEP-dependent phosphorylation to the extreme C terminus of the mannitol permease, sites important for phospho exchange to between residues 377 and 519, and sites necessary for mannitol binding to the N-terminal 60% of the molecule. The results are discussed with respect to the fact that the mannitol permease consists of structurally independent N- and C-terminal domains.

The PEP: fructose phosphotransferase system in Salmonella typhimurium: FPr combines enzyme IIIFru and pseudo-HPr activities

We have cloned the fru operon of Salmonella typhimurium, coding for the enzymes of the phosphoenolpyruvate: fructose phosphotransferase system (Fructose PTS). The fruFKA operon consists of three genes: fruF coding for FPr, fruK for fructose 1-phosphate kinase and fruA for Enzyme IIFru. Insertions of Tn5 in the different genes were isolated and the activities of the gene products were measured. Expression of the plasmid-encoded fru operon in the maxicell system resulted in the synthesis of three proteins with molecular weights of 47 kDa (fruA), 39 kDa (fruF) and 32 kDa (fruK). We have sequenced the fruF gene and the regulatory region of the fru operon. In contrast to previously published results, we have found that the fruF gene codes for a 39 kDa protein, FPr, that combines Enzyme IIIFru and pseudo-HPr activities. The N-terminal part of FPr is homologous to the cytoplasmic domain of the Escherichia coli Enzyme IIMtl, as well as several Enzymes IIIMtl from gram-positive bacteria. The C-terminal domain shows homology to HPr of E. coli and several gram-positive organisms. The fru operon is regulated by a repressor, FruR. We have constructed an operon fusion between fru and the galK gene and shown that regulation of the fru operon by FruR takes place at the level of transcription.

Sequence of the nagBACD operon in Escherichia coli K12 and pattern of transcription within the nag regulon

The DNA sequence of a 3.6kb region downstream of the nagB gene (encoding glucosamine-6-PO4-deaminase) in Escherichia coli has been determined. Three open reading frames, which are subsequently referred to as nagA, nagC and nagD, were detected in this sequence. Genetic complementation and enzyme assays have shown that the first of these, nagA, encodes N-acetyl glucosamine-6-phosphate deacetylase. Growth on N-acetyl glucosamine induces the synthesis of a 1900 nucleotide long transcript which covers just nagE, encoding EIINag which is transcribed divergently from nagB, and of a 4200 nucleotide long transcript which covers all four ORFs of the nagB,A,C, D operon. More mRNA corresponding to nagB and nagA is detected than that corresponding to the distal genes, nagC and nagD. Considerable amounts of the induced mRNA are truncated molecules having their 3' ends after nagB and after nagA. Multiple 3' RNA ends have been mapped after nagD and seem to correspond to the ends of transcripts stabilized by mRNA secondary structure (REP sequences) rather than transcription termination sites. A second promoter producing nagD-specific transcripts has been mapped just in front of the nagD gene.

Phosphoenolpyruvate:sugar phosphotransferase system of Bacillus subtilis: nucleotide sequence of ptsX, ptsH and the 5'-end of ptsI and evidence for a ptsHI operon

The nucleotide sequence of a 1689bp fragment of the Bacillus subtilis locus containing ptsX (a crr-like gene), ptsH (coding for HPr), and the 5'-end of ptsI (coding for Enzyme I) was determined. The deduced amino acid sequences of ptsH and the N-terminal part of ptsI were compared to those of Streptococcus faecalis and Escherichia coli. Transcription fusion demonstrated that ptsHI constitutes an operon. An open reading frame overlapping the main part of ptsH in the opposite sense was shown to be expressed in vivo, using protein fusions with beta-galactosidase. The deduced amino acid sequence of ptsX showed significant homology with that of Salmonella typhimurium glucose-specific Enzyme III. ptsX was preceded by an open reading frame whose amino acid sequence showed strong homology with the C-terminal part of E. coli Enzyme IIGlc.

Characterization and sequence analysis of the scrA gene encoding enzyme IIScr of the Streptococcus mutans phosphoenolpyruvate-dependent sucrose phosphotransferase system

The Streptococcus mutans GS-5 scrA gene coding for enzyme IIScr of the phosphoenolpyruvate-dependent sucrose phosphotransferase system (PTS) was localized upstream from the scrB gene coding for sucrose-6-phosphate hydrolase activity after Mu dE transposon mutagenesis of plasmid pMH613. The cloned scrA gene product was identified as a 68-kilodalton protein by minicell analysis after isolation of the gene in plasmid pD4. In addition, the membrane fraction from Escherichia coli cells containing pD4 exhibited sucrose PTS activity upon complementation with enzyme I and HPr from strain GS-5. The nucleotide sequence of the scrA region revealed that this gene was located immediately upstream from the scrB gene and divergently transcribed from the opposite DNA strand. The scrA gene was preceded by potential Shine-Dalgarno and promoterlike sequences and was followed by a transcription terminator-like sequence. The scrA gene coded for an enzyme IIScr protein of 664 amino acid residues with a calculated molecular weight of 69,983. This enzyme IIScr protein was larger than the comparable proteins from Bacillus subtilis and E. coli containing sucrose-metabolizing plasmid pUR400. The 491-amino-acid N-terminal sequence of the S. mutans enzyme IIScr was homologous with the B. subtilis and E. coli sequences, and the 173-amino-acid C-terminal sequence of the S. mutans protein was also homologous with the Salmonella typhimurium enzyme IIIGlc and the 162-amino-acid C terminus of E. coli enzyme IIBgl. These results suggest that the sucrose PTS system of S. mutans is enzyme III independent.

Bacterial proteins with N-terminal leader sequences resembling mitochondrial targeting sequences of eukaryotes

Amphipathic, alpha-helical, leader sequences, analogous to those that direct nuclear-encoded eukaryotic proteins into mitochondria, have been found in one and only one class of bacterial integral membrane proteins. These bacterial proteins are the sugar permeases of the phosphoenolpyruvate-dependent phosphotransferase system. The amphipathic leader sequence in each of these proteins is terminated by a helix breaker, either a prolyl residue or 2 adjacent glycyl residues. Preliminary evidence suggests that these leader sequences function to target the proteins to the envelope fraction of the prokaryotic cell during their biosynthesis.

Staphylococcal phosphoenolpyruvate-dependent phosphotransferase system: purification and characterization of the mannitol-specific enzyme IIImtl of Staphylococcus aureus and Staphylococcus carnosus and homology with the enzyme IImtl of Escherichia coli

Enzyme IIImtl is part of the mannitol phosphotransferase system of Staphylococcus aureus and Staphylococcus carnosus and is phosphorylated by phosphoenolpyruvate in a reaction sequence requiring enzyme I (phosphoenolpyruvate-protein phosphotransferase) and the histidine-containing protein HPr. In this paper, we report the isolation of IIImtl from both S. aureus and S. carnosus and the characterization of the active center. After phosphorylation of IIImtl with [32P]PEP, enzyme I, and HPr, the phosphorylated protein was cleaved with endoproteinase Glu(C). The amino acid sequence of the S. aureus peptide carrying the phosphoryl group was found to be Gln-Val-Val-Ser-Thr-Phe-Met-Gly-Asn-Gly-Leu-Ala-Ile-Pro-His-Gly-Thr-Asp- Asp. The corresponding peptide from S. carnosus shows an equal sequence except that the first residue is Ala instead of Gln. These peptides both contain a single histidyl residue which we assume to carry the phosphoryl group. All proteins of the PTS so far investigated indeed carry the phosphoryl group attached to a histidyl residue. According to sodium dodecyl sulfate gels, the molecular weight of the IIImtl proteins was found to be 15,000. We have also determined the N-terminal sequence of both proteins. Comparison of the IIImtl peptide sequences and the C-terminal part of the enzyme IImtl of Escherichia coli reveals considerable sequence homology, which supports the suggestion that IImtl of E. coli is a fusion protein of a soluble III protein with a membrane-bound enzyme II. In particular, the homology of the active-center peptide of IIImtl of S. aureus and S. carnosus with the enzyme IImtl of E. coli allows one to predict the N-3 histidine phosphorylation site within the E. coli enzyme.

Bacterial phosphoenolpyruvate-dependent phosphotransferase system: mannitol-specific EII contains two phosphoryl binding sites per monomer and one high-affinity mannitol binding site per dimer

The amino acid composition and sequence of EIIMtl is known [Lee, C. A., & Saier, M. H., Jr. (1983) J. Biol. Chem. 258, 10761-10767]. This information was combined, in the present study, with quantitative amino acid analysis to determine the molar concentration of the enzyme. The stoichiometry of phosphoryl group incorporation was then determined by phosphorylation of enzyme II from [14C]-phosphoenolpyruvate (pyruvate burst procedure). The native, reduced enzyme incorporated two phosphoryl groups per monomer. Both phosphoryl groups were shown to be transferred to mannitol. Oxidation or N-ethylmaleimide (NEM) labeling of Cys-384 resulted in incorporation of only one phosphoryl group per monomer, which was unable to be transferred to mannitol. The number of mannitol binding sites on enzyme II was determined by centrifugation using Amicon Centricon microconcentrators. The reduced unphosphorylated enzyme contained one high-affinity binding site (KD = 0.1 microM) per dimer and a second site with a KD in the micromolar range. Oxidation or NEM labeling did not change the number of binding sites.

Complementation of a truncated membrane-bound Enzyme IINag from Klebsiella pneumoniae with a soluble Enzyme III in Escherichia coli K12

Cloning and analysis of the gene nagE encoding Enzyme IINag (EIINag) from Klebsiella pneumoniae revealed strong similarities with the corresponding gene from Escherichia coli K12. Truncated EIINag proteins were generated by inserting a series of Tn1725 transposons into the structural gene; the positions of the insertions were mapped by restriction enzyme analysis, and the activity of the polypeptides determined by in vitro and in vivo tests. Insertions in the region encoding the amino-terminal half of the protein invariably abolished transport and phosphorylation activity, while truncated proteins lacking a C-terminal domain homologous to the soluble Enzyme III (crr gene) could be complemented by this molecule to nearly wild-type activity.

Nucleotide sequence of the mannitol (mtl) operon in Escherichia coli

The nucleotide sequence of the known portions of the mannitol operon in Escherichia coli (mtlOPAD) has been determined. Both the operator-promoter region and the intercistronic region between the mtlA and mtlD genes (encoding the mannitol-specific Enzyme II of the phosphotransferase system and mannitol-1-phosphate dehydrogenase, respectively) show parallels with corresponding regions of the glucitol (gut) operon, but neither the mtlA nor the mtlD gene products show obvious homology with the corresponding gene products of the glucitol operon. Five potential cyclic AMP receptor protein binding sites were identified in the mtlOP region, all showing near identity with the consensus sequence. Four regions of dyad symmetry (four to seven bases in length), serving as potential repressor binding sites, overlap with the potential cyclic AMP receptor protein binding sites. Repetitive extragenic palindromic (REP) sequences, forming stem-loop structures in the intercistronic region between mtlA and mtlD and following the mtlD gene were identified. Probable terminator sequences were not found in any of these three regulatory regions. Mannitol-1-phosphate dehydrogenase exhibits two overlapping, potential NAD+ binding sites near the N-terminus of the protein. Computer techniques were used to analyse the mtlD gene and its product.

Properties of a Tn5 insertion mutant defective in the structural gene (fruA) of the fructose-specific phosphotransferase system of Rhodobacter capsulatus and cloning of the fru regulon

In photosynthetic bacteria such as members of the genera Rhodospirillum, Rhodopseudomonas, and Rhodobacter a single sugar, fructose, is transported by the phosphotransferase system-catalyzed group translocation mechanism. Previous studies indicated that syntheses of the three fructose catabolic enzymes, the integral membrane enzyme II, the peripheral membrane enzyme I, and the soluble fructose-1-phosphate kinase, are coordinately induced. To characterize the genetic apparatus encoding these enzymes, a Tn5 insertion mutation specifically resulting in a fructose-negative, glucose-positive phenotype was isolated in Rhodobacter capsulatus. The mutant was totally lacking in fructose fermentation, fructose uptake in vivo, phosphoenolpyruvate-dependent fructose phosphorylation in vitro, and fructose 1-phosphate-dependent fructose transphosphorylation in vitro. Extraction of the membrane fraction of wild-type cells with butanol and urea resulted in the preparation of active enzyme II free of contaminating enzyme I activity. This preparation was used to show that the activity of enzyme I was entirely membrane associated in the parent but largely soluble in the mutant, suggesting the presence of an enzyme I-enzyme II complex in the membranes of wild-type cells. The uninduced mutant exhibited measurable activities of both enzyme I and fructose-1-phosphate kinase, which were increased threefold when it was grown in the presence of fructose. Both activities were about 100-fold inducible in the parental strain. Although the Tn5 insertion mutation was polar on enzyme I expression, fructose-1-phosphate kinase activity was enhanced, relative to the parental strain. ATP-dependent fructokinase activity was low, but twofold inducible and comparable in the two strains. A second fru::Tn5 mutant and a chemically induced mutant selected on the basis of xylitol resistance showed pleiotropic loss of enzyme I, enzyme II, and fructose-1-phosphate kinase. These mutants were used to clone the fru regulon by complementing the negative phenotype with a wild-type cosmid bank.

Genetic analyses of the mannitol permease of Escherichia coli: isolation and characterization of a transport-deficient mutant which retains phosphorylation activity

Three positive selection procedures were developed for the isolation of plasmid-encoded mutants which were defective in the mannitol enzyme II (IIMtl) of the phosphotransferase system (mtlA mutants). The mutants were characterized with respect to the following properties: (i) fermentation, (ii) transport, (iii) phosphoenolpyruvate(PEP)-dependent phosphorylation, and (iv) mannitol-1-phosphate-dependent transphosphorylation of mannitol. Cell lysis in response to indole acrylic acid, which causes the lethal overexpression of the plasmid-encoded mtlA gene, was also scored. No correlation was noted between residual IIMtl activity in the mutants and sensitivity to the toxic effect of indole acrylic acid. Plasmid-encoded mutants were isolated with (i) total or partial loss of all activities assayed, (ii) nearly normal rates of transphosphorylation but reduced rates of PEP-dependent phosphorylation, (iii) nearly normal rates of PEP-dependent phosphorylation but reduced rates of transphosphorylation, and (iv) total loss of transport activity but substantial retention of both phosphorylation activities in vitro. A mutant of this fourth class was extensively characterized. The mutant IIMtl was shown to be more thermolabile than the wild-type enzyme, it exhibited altered kinetic behavior, and it was shown to arise by a single nucleotide substitution (G-895----A) in the mtlA gene, causing a single amino acyl substitution (Gly-253----Glu) in the permease. The results show that a single amino acyl substitution can abolish transport function without abolishing phosphorylation activity. This work serves to identify a site which is crucial to the transport function of the enzyme.