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.     

Control of the sequential utilization of glucose and fructose by Escherichia coli.

In Escherichia coli (ATCCI5224; ML308), glucose and fructose phosphotransferase systems (PT-systems) are constitutive but activities are increased five and 10-fold respectively by aerobic growth on their respective substrates in defined media. In mixtures, glucose is used preferentially and the fructose PT-system activity is kept at its minimum; but, on glucose exhaustion, it overshoots its steady-state level and growth continues on fructose without lag. Cyclic AMP prevents overshoot. Continuous cultures operating as turbidostats on mixtures of glucose and fructose do not use fructose if sufficient glucose is present to support growth. If less glucose is available, it is all used and sufficient fructose is metabolized concurrently to maintain the growth rate characteristic of glucose. Both PT-systems are inhibited by hexose phosphates. Presence of homologous substrate specifically sensitizes each PT-system to inactivation by N-ethylmaleimide (NEM). Glucose diminishes the ability of fructose to sensitize its PT-system to NEM. This effect parallels the inhibition of fructose utilization by glucose and suggests that glucose denies fructose access to the fructose-specific part of the PT-system.     

The roles of HPr and FPr in the utilization of fructose by Escherichia coli

A mutant impaired in FPr activity was isolated. The altered gene (fpr), which was located near min. 44 on the E. coli genome, was transferred by phage-mediated transduction to appropriate recipients that lack HPr (ptsH), or Enzyme IIman (ptsM), or neither. The rates of growth on fructose of such transductants indicate that phosphate from PEP is transferred predominantly via FPr to fructose that enters the cells by Enzyme IIfru, but that HPr can play a role in transferring phosphate to fructose taken up via Enzyme IIman.     

The utilization of fructose by Escherichia coli. Properties of a mutant defective in fructose 1-phosphate kinase activity

1. The isolation and properties of a mutant of Escherichia coli devoid of fructose 1-phosphate kinase activity are described. 2. This mutant grew in media containing any one of a variety of substances, including hexoses, hexose 6-phosphates, sugar acids and glucogenic substrates, at rates not significantly different from those at which the parent organism grew on these substrates. However, only the parent grew on fructose or fructose 1-phosphate. 3. Fructose and fructose 1-phosphate inhibit the growth of the mutant, but not of its parent, on other carbon sources. 4. Even though not previously exposed to fructose, the mutant took up [(14)C]fructose rapidly but to only a small extent: [(14)C]fructose 1-phosphate was identified as the predominant labelled product. In contrast, the equally rapid but more extensive uptake of [(14)C]fructose by the parent organism required prior growth in the presence of fructose.     

Role of the phosphoenolpyruvate-dependent fructose phosphotransferase system in the utilization of mannose by Escherichia coli.

Mutants of Escherichia coli devoid of the membrane-spanning proteins PtsG and PtsMP, which are components of the phosphoenolpyruvate-dependent phosphotransferase system (PTS) and which normally effect the transport into the cells of glucose and mannose, do not grow upon or take up either sugar. Pseudorevertants are described that take up, and grow upon, mannose at rates strongly dependent on the mannose concentration in the medium (apparent Km > 5 mM); such mutants do not grow upon glucose but are derepressed for the components of the fructose operon. Evidence is presented that mannose is now taken up via the fructose-PTS to form mannose 6-phosphate, which is further utilized for growth via fructose 6-phosphate and fructose 1,6-bisphosphate.     

Location and function of fruC, a gene involved in the regulation of fructose utilization by Escherichia coli

Procedures are described for the selection of Escherichia coli mutants that constitutively take up and phosphorylate fructose, and convert it to fructose 1,6-bisphosphate. The phenotype of such mutants is described. The altered regulatory gene, fruC, is highly co-transducible with leu and other markers located at min 2 on the genome. In merozygotes, fruC+ is dominant to fruC. Mutants can be readily isolated that are fruC at 42 degrees C but fruC+ at 30 degrees C; moreover, the integration of a Tn10 transposon in the genome at min 2 converts fruC+ strains to fruC. It is therefore likely that the fruC+ regulatory gene specifies a repressor protein.     

The utilization of prolyl peptides by Escherichia coli

Peptides that have an N-terminal proline residue are taken up by Escherichia coli and are degraded by intracellular peptidases. A mutant that is unable to transport oligopeptides with N-terminal alpha-amino acids is also unable to transport the peptides with N-terminal proline. Dipeptides and oligopeptides can prevent the uptake of the corresponding prolyl peptides and the converse competitive interactions are also observed. Although the peptide alpha-amino group is essential to the process of peptide transport, the results with the prolyl peptides indicate that the dipeptide and oligopeptide permeases can handle peptides with either an alpha-amino or alpha-imino group.     

Inhibition of Escherichia coli fructose-1,6-bisphosphatase by fructose 2,6-bisphosphate

Fructose 2,6-bisphosphate, a potent inhibitor of fructose-1,6-bisphosphatases, was found to be an inhibitor of the Escherichia coli enzyme. The substrate saturation curves in the presence of inhibitor were sigmoidal and the inhibition was much stronger at low than at high substrate concentrations. At a substrate concentration of 20 μM, 50% inhibition was observed at 4.8 μM fructose 2,6-bisphosphate. Escherichia coli fructose-1,6-bisphosphatase was inhibited by AMP (K_j = 16 μM) and phosphoenolpyruvate caused release of AMP inhibition. However, neither AMP inhibition nor its release by phosphoenolpyruvate was affected by the presence of fructose 2,6-bisphosphate. The results obtained, together with previous observations, provide further evidence for the fructose 2,6-bisphosphate-fructose-1,6-bisphosphatase active site interaction.     

Thialysine utilization by a lysine-requiring Escherichia coli mutant

Summary Thialysine cannot completely substitute lysine as growth factor for a lysine-requiring E. coli mutant. However it can be utilized for growth in the presence of limiting amounts of lysine, in substitution of, and in competition with this latter. The effects of thialysine on growth rate, protein synthesis rate and cell viability, and its incorporation into proteins were studied in function of lysine and thialysine concentration in the culture media. Up to 60% of protein lysine substitution by thialysine is observed, without appreciable effects on cell viability.     

Asparagine utilization in Escherichia coli

Asparagine-requiring auxotrophs of Escherichia coli K-12 that have an active cytoplasmic asparaginase do not conserve asparagine supplements for use in protein synthesis. Asparagine molecules entering the cell in excess of the pool required for use of this amino acid in protein synthesis are rapidly degraded rather than accumulated. Supplements are conserved when asparagine degradation is inhibited by the asparagine analogue 5-diazo-4-oxo-l-norvaline (DONV) or mutation to cytoplasmic asparaginase deficiency. A strain deficient in cytoplasmic asparaginase required approximately 260 mumol of asparagine for the synthesis of 1 g of cellular protein. The cytoplasmic asparaginase (asparaginase I) is required for growth of cells when asparagine is the nitrogen source. This enzyme has an apparent K(m) for l-asparagine of 3.5 mM, and asparaginase activity is competitively inhibited by DONV with an apparent K(i) of 2 mM. The analogue provides a time-dependent, irreversible inhibition of cytoplasmic asparaginase activity in the absence of asparagine.     

Genetical and functional organisation of the Escherichia coli haemolysin determinant 2001

Summary We have identified gene products corresponding to hlyC, hlyA and hlyD encoded by the Escherichia coli haemolytic determinant 2001 of human origin cloned into the recombinant plasmid pLG570. The product of hlyC is required for the activation of the inactive 107K polypeptide encoded by the hlyA gene. the activated 107K protein constitutes the active haemolysin secreted into the medium. hlyB and hlyD are separate regions defined by complementation studies and encode functions essential for the export of haemolysin with hlyD encoding a 53K protein. Complementation studies using subclones and Tn5 insertions into pLG570 have revealed the presence of two major promoters upstream of hlyC and hlyD which transcribe the four hly genes in the same direction. Finally, we were able to reconstitute the complete haemolysin system from three different plasmids encoding hlyC, hlyA and hlyB+hlyD, respectively.