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.     

Use of a green fluorescent protein gene as a reporter in Zymomonas mobilis and Halomonas elongata

The mtl operon of Klebsiella pneumoniae KAY2026 (formerly Aerobacter aerogenes 1033-5P14) was shown to contain as the promoter-proximal gene mtlA, encoding a D-mannitol-specific enzyme II transporter (IICBA(Mtl)). This gene is followed by mtlD, coding for a mannitol-1-phosphate dehydrogenase (MtlD, 382 amino acid residues), and mtlR (MtlR, 195 amino acid residues) coding for a putative repressor, gene mtlR overlaps the termination codon of mtlD. The DNA and protein sequences are highly similar to the corresponding genes (81% identical bp) and proteins (79-85% identical amino acids) of Escherichia coli K-12. A truncated form of MtlD lacking the 162 C-terminal amino acid residues still shows 10% dehydrogenase activity which may explain the controversy in the literature concerning the properties of mannitol-phosphate and other medium-length dehydrogenases.     

Cloning, expression, and isolation of the mannitol transport protein from the thermophilic bacterium Bacillus stearothermophilus.

A mannitol phosphotransferase system (PTS) was identified in Bacillus stearothermophilus by in vitro complementation with Escherichia coli EI, HPr, and IIA(Mtl). Degenerate primers based on regions of high amino acid similarity in the E. coli and Staphylococcus carnosus EII(Mt1) were used to develop a digoxigenin-labeled probe by PCR. Using this probe, we isolated three overlapping DNA fragments totaling 7.2 kb which contain the genes mtlA, mtlR, mtlF, and mtlD, encoding the mannitol IICB,a regulator, IIA, and a mannitol-1-phosphate dehydrogenase, respectively. The mtl4 gene consists of 1,413 bp coding for a 471-amino-acid protein with a calculated mass of 50.1 kDa. The amino acid sequence shows high similarity with the sequence of IICB(Mtl) of S. carnosus and the IICB part of the IICBA(Mtl)s of E. coli and B. subtilis. The enzyme could be functionally expressed in E. coli by placing it behind the strong tac promoter. The rate of thermal inactivation at 60 degrees C of B. stearothermophilus HCB(Mt1) expressed in E. coli was two times lower than that of E. coli IICB(Mtl). IICB(Mtl) in B. stearothermophilus is maximally active at 85 degrees C and thus very thermostable. The enzyme was purified on Ni-nitrilotriacetic acid resin to greater than 95% purity after six histidines were fused to the C-terminal part of the transporter.     

Reversal of the Mannitol-Sorbitol Diauxie in Escherichia coli

In Escherichia coli K-12 the proteins involved in the dissimilation of mannitol and sorbitol are specified by two separate gene clusters. The mannitol cluster appears to consist of a regulatory gene mtlC, a gene mtlA coding an enzyme II complex of the phosphoenolpyruvate phosphotransferase system, and a gene mtlD coding a mannitol-1-phosphate dehydrogenase. Three corresponding genes, sblC, sblA, and sblD, exist for the sorbitol pathway. In both pathways the hexitol captured from the medium and delivered into the cytoplasm as a phosphorylated compound is dehydrogenated to fructose-6-phosphate. The enzyme II complex for sorbitol is able to catalyze the phosphorylation also of mannitol if this substrate is present at high concentrations. Consequently mtlA(-) mutants lacking the enzyme II complex for mannitol can grow on mannitol either if the sorbitol phosphorylating system is preinduced by sorbitol or if mtlA is suppressed by a mutation of sblC to constitutivity. In wild-type cells, the induction of the enzymes in the mannitol pathway and dissimilation of the substrate are not prevented by glucose. The sorbitol system, however, is sensitive to glucose and to mannitol as well. In the suppressed strains (mtlA(-), sblC(c)) in which mannitol is utilized through the sorbitol enzyme, glucose becomes effective in restraining the consumption of mannitol, causing a definite diauxie. Moreover, in a mixture of mannitol and sorbitol, the latter is utilized preferentially. This reversal of normal diauxic pattern is consequent to the fact that the enzyme II complex for sorbitol has relatively poor affinity for mannitol.     

霍乱弧菌甘露醇PTS操纵子中mtlR为转录抑制基因

产毒和非产毒的El Tor生物型霍乱弧菌对甘露醇发酵利用的速率有明显差别,在霍乱致病株的快速判断中有重要的参考价值。通过比较快发酵菌株(非产毒株)和慢发酵菌株(产毒株)mtlR缺失突变株与野生株在含0.2%甘露醇的M9培养液及甘露醇发酵液中生长、产酸等的变化,定性地证明了mtlR基因的抑制作用;另外通过定量RT-PCR进一步验证了MtlR蛋白在mtlCBA转录水平发挥负调控作用。但是mtlR还不是引起快慢发酵菌株对甘露醇发酵差异的直接原因。本研究也为我们研究霍乱弧菌甘露醇快慢发酵差异机制提供了必要的参考依据。     

Mannitol-specific enzyme II of the bacterial phosphotransferase system. III. The nucleotide sequence of the permease gene

The nucleotide sequence of the mtlA gene, which codes for the mannitol-specific Enzyme II of the Escherichia coli phosphotransferase system, is presented. From the gene sequence, the primary translation product is predicted to consist of 637 amino acids (Mr = 67,893). This result is compared to the amino acid composition and molecular weight of the purified mannitol Enzyme II protein. The hydrophobic and hydrophilic properties of the enzyme were evaluated along its amino acid sequence using a computer program (Kyte, J., and Doolittle, R. F. (1982) J. Mol. Biol. 157, 105-132). The computer analysis predicts that the NH2-terminal half of the enzyme resides within the membrane, whereas the COOH-terminal half of the enzyme has the properties of a soluble protein. The possible functions of such a protein structure are discussed. RNA mapping has identified the promoter and mRNA start point for the mtl operon.     

Membrane protein-ligand interactions in Escherichia coli vesicles and living cells monitored via a biosynthetically incorporated tryptophan analogue.

This paper presents a deceptively straightforward experimental approach to monitoring membrane protein-ligand interactions in vesicles and in living Escherichia coli cells. This is achieved via the biosynthetic incorporation of 7-azatryptophan, a tryptophan analogue with a red-shifted absorption spectrum, allowing collection of the emission signal of the target protein in a high tryptophan background via red-edge excitation. The approach is demonstrated for the mannitol permease of E. coli (EII(mtl)), an integral membrane protein of 637 amino acids, including four tryptophans, and single-tryptophan mutants of EII(mtl). By using a tryptophan auxotroph, a high level of 7-azatryptophan incorporation in EII(mtl) was achieved. The change in emission signal of the purified enzyme upon mannitol binding (-28%) was 4-fold larger than with EII(mtl) containing tryptophan, demonstrating the known higher sensitivity of this analogue for changes in the microenvironment [Schlesinger, R. (1968) J. Biol. Chem. 243, 3877-3883]. Changes in emission signal could also be monitored (-5%) when the enzyme was situated in vesicles, although it constituted only 10-15% of the total cytoplasmic membrane fraction. Of the five single-tryptophan mutants, the emission signal of the mutant with 7-azatryptophan at position 198 was the most sensitive for mannitol binding. Changes in emission signal not only were observed in vesicles (-18%) but also could be monitored in viable cells (-5%). The fact that only modest expression levels and no protein purification are needed makes this a useful approach for the characterization of numerous protein systems under in vitro and in vivo conditions.     

Utilisation of glycerol and glycerol 3-phosphate is differently affected by the phosphotransferase system in Bacillus subtilis

Glycerol and glycerol 3-phosphate uptake in Bacillus subtilis does not involve the phosphotransferase system. In spite of this, B. subtilis mutants defective in the general components of the phosphotransferase system, EnzymeI or Hpr, are unable to grow with glycerol as sole carbon and energy source. Here we show that a Hpr mutant can grow on glycerol 3-phosphate and that glycerol 3-phosphate, but not glycerol, can induce glpD encoding glycerol-3-phosphate dehydrogenase. Induction of glpD also requires the glpP gene product which is a regulator of all known glp genes. Thus the phosphotransferase system general components do not interfere with the overall regulation of the glp regulon. Revertants of a Hpr mutant which can grown on glycerol carry mutations closely linked to the glp region at 75 degrees on the B. subtilis chromosomal map. This region contains the glpP, the glpFK and the glpD operons. The glpFK operon encodes the glycerol uptake facilitator (glpF) and glycerol kinase (glpK). The present results demonstrate that one of these genes, or their gene products, is the target for phosphotransferase system control of glycerol utilisation. Furthermore we conclude that utilisation of glycerol and glycerol 3-phosphate is differently affected by the phosphotransferase system in B. subtilis.     

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

The previously published sequences of the operator-promoter region of the mannitol operon of Escherichia coli and of the mtlD gene have been found to contain a number of errors. The major conclusions reported previously were correct, but additionally it is now clear that a C-terminal portion of mannitol-1-phosphate dehydrogenase (the mtlD gene product) exhibits significant sequence identity with an amino-terminal region of human liver fructose-6-phosphate-2-kinase:fructose-2,6-bisphosphatase.     

Routes for fructose utilization by Escherichia coli

There are three main routes for the utilization of fructose by Escherichia coli. One (Route A) predominates in the growth of wild-type strains. It involves the functioning of the phosphoenolpyruvate:glycose phosphotransferase system (PTS) and a fructose operon, mapping at min. 48.7, containing genes for a membrane-spanning protein (fruA), a 1-phosphofructose kinase (fruK) and a diphosphoryl transfer protein (fruB), under negative regulation by a fruR gene mapping at min. 1.9. A second route (Route B) also involves the PTS and membrane-spanning proteins that recognize a variety of sugars possessing the 3,4,5-D-arabino-hexoseconfiguration but with primary specificity for mannose(manXYZ), mannitol (mtlA) and glucitol (gutA) and which, if over-produced, can transport also fructose. A third route (Route C), functioning in mutants devoid of Routes A and B, does not involve the PTS: fructose diffuses into the cell via an isoform (PtsG-F) of the major glucose permease of the PTS and is then phosphorylated by ATP and a manno(fructo)kinase (Mak+) specified by a normally cryptic 1032 bp ORF (yajF) of hitherto unknown function (Mak-o), mapping at min. 8.8 and corresponding to a peptide of 344 amino acids. Conversion of the Mak-o to the Mak+ phenotypeinvolves an A24D mutation in a putative regulatory region.     

Mannitol-specific enzyme II of the phosphoenolpyruvate-dependent phosphotransferase system of Staphylococcus carnosus. Sequence and expression in Escherichia coli and structural comparison with the enzyme IImannitol of Escherichia coli.

The enzyme IImannitol (EIImtl) of the phosphoenolpyruvate-dependent phosphotransferase system (PTS) catalyses the uptake and concomitant phosphorylation of mannitol by bacteria; it is specified by the gene mtlA. MtlA is located near the genes mtlF and mtlD in the staphylococcal genome, encoding the enzyme IIImtl and the mannitol-1-phosphate dehydrogenase, respectively. We present the cloning of the whole operon by a novel complementation system which is generally suitable for cloning Gram-positive PTS genes. The nucleotide sequence of a 2.5-kbp subclone spanning mtlA has been determined. From the deduced amino acid sequence, it is predicted that the membrane-protein EIImtl consists of 505 amino acid residues (54112 Da). The protein has the expected hydropathy profile of an integral-membrane protein. The NH2-terminal part of the enzyme resides within the membrane, whereas the COOH-terminus of the enzyme has the properties of a soluble protein. Comparison with the known amino acid sequence of EIImtl of Escherichia coli [Lee, C. A. & Saier, M. H. (1983) J. Biol. Chem. 258, 10761-10767] showed significant similarity. The motif containing the cysteine, which is the putative second phosphorylation site in EIImtl of E. coli [Pas, H. H. & Robillard, G. T. (1988) Biochemistry 27, 5835-5839], is well conserved in EIImtl of Staphylococcus carnosus. Chemical modification of the single active site cysteine residue by Ellman's reagent leads to total inactivation, which can be reversed by treatment with 2-mercaptoethanol.     

Mannitol-specific phosphoenolpyruvate-dependent phosphotransferase system of Enterococcus faecalis: molecular cloning and nucleotide sequences of the enzyme IIIMtl gene and the mannitol-1-phosphate dehydrogenase gene, expression in Escherichia coli, and comparison of the gene products with similar enzymes.

Enzyme IIIMtl is part of the mannitol phosphotransferase system of Enterococcus faecalis. It is phosphorylated in a reaction sequence requiring enzyme I and heat-stable phosphocarrier protein (HPr). The phospho group is transferred from enzyme IIIMtl to enzyme IIMtl, which then catalyzes the uptake and concomitant phosphorylation of mannitol. The internalized mannitol-1-phosphate is oxidized to fructose-6-phosphate by mannitol-1-phosphate dehydrogenase. In this report we describe the cloning of the mtlF and mtlD genes, encoding enzyme IIIMtl and mannitol-1-phosphate dehydrogenase of E. faecalis, by a complementation system designed for cloning of gram-positive phosphotransferase system genes. The complete nucleotide sequences of mtlF, mtlD, and flanking regions were determined. From the gene sequences, the primary translation products are deduced to consist of 145 amino acids (enzyme IIIMtl) and 374 amino acids (mannitol-1-phosphate dehydrogenase). Amino acid sequence comparison confirmed a 41% similarity of E. faecalis enzyme IIIMtl to the hydrophilic enzyme IIIMtl-like portion of enzyme IIMtl of Escherichia coli and 45% similarity to enzyme IIIMtl of Staphylococcus carnosus. The putative N-terminal NAD+ binding domain of mannitol-1-phosphate dehydrogenase of E. faecalis shows a high degree of similarity with the N terminus of E. coli mannitol-1-phosphate dehydrogenase (T. Davis, M. Yamada, M. Elgort, and M. H. Saier, Jr., Mol. Microbiol. 2:405-412, 1988) and the N-terminal part of the translation product of S. carnosus mtlD, which was also determined in this study. There is 40% similarity between the dehydrogenases of E. faecalis and E. coli over the whole length of the enzymes. The organization of mannitol-specific genes in E. faecalis seems to be similar to the organization in S. carnosus. The open reading frame for enzyme IIIMtl E. faecalis is followed by a stem-loop structure, analogous to a typical Rho-independent terminator. We conclude that the mannitol-specific genes are organized in an operon and that the gene order is mtlA orfX mtlF mtlD.