Molecular analysis of sucrose metabolism of Erwinia amylovora and influence on bacterial virulence

Sucrose is an important storage and transport sugar of plants and an energy source for many phytopathogenic bacteria. To analyze regulation and biochemistry of sucrose metabolism of the fire blight pathogen Erwinia amylovora, a chromosomal fragment which enabled Escherichia coli to utilize sucrose as sole carbon source was cloned. By transposon mutagenesis, the scr regulon of E. amylovora was tagged, and its nucleotide sequence was determined. Five open reading frames, with the genes scrK, scrY, scrA, scrB, and scrR, had high homology to genes of the scr regulons from Klebsiella pneumoniae and plasmid pUR400. scrB and scrR of E. amylovora were fused to a histidine tag and to the maltose-binding protein (MalE) of E. coli, respectively. ScrB (53 kDa) catalyzed the hydrolysis of sucrose with a K(m) of 125 mM. Binding of a MalE-ScrR fusion protein to an scrYAB promoter fragment was shown by gel mobility shifts. This complex dissociated in the presence of fructose but not after addition of sucrose. Expression of the scr regulon was studied with an scrYAB promoter-green fluorescent protein gene fusion and measured by flow cytometry and spectrofluorometry. The operon was affected by catabolite repression and induced by sucrose or fructose. The level of gene induction correlated to the sucrose concentration in plant tissue, as shown by flow cytometry. Sucrose mutants created by site-directed mutagenesis did not produce significant fire blight symptoms on apple seedlings, indicating the importance of sucrose metabolism for colonization of host plants by E. amylovora.     

Molecular analysis of two fructokinases involved in sucrose metabolism of enteric bacteria

Sucrose-positive derivatives of Escherichia coli K-12, containing the plasmid pUR400, and of Klebsiella pneumoniae hydrolyse intracellular sucrose 6-phosphate by means of an invertase into D-glucose 6-phosphate and free D-fructose. The latter is phosphorylated by an ATP-dependent fructokinase (gene scrK of an scr regulon) to D-fructose 6-phosphate. The lack of ScrK does not cause any visible phenotype in wild-type strains of both organisms. Using genes and enzymes normally involved in D-arabinitol metabolism from E. coli C and K. pneumoniae, derivatives of E. coli K-12 were constructed which allowed the identification of scrK mutations on conventional indicator plates. Cloning and sequencing of scrK from sucrose plasmid pUR400 and from the chromosome of K. pneumoniae revealed an open reading frame of 924 bp in both cases--the equivalent of a peptide containing 307 amino acid residues (Mr 39 and 34 kDa, respectively, on sodium dodecyl sulphate gels). The sequences showed overall identity among each other (69% identical residues) and to a kinase from Vibrio alginolyticus (57%) also involved in sucrose metabolism, lower overall identity (39%) to a D-ribose-kinase from E. coli, and local similarity to prokaryotic, and eukaryotic phosphofructokinases at the putative ATP-binding sites.     

Nucleotide sequence and analysis of the Vibrio alginolyticus sucrose uptake-encoding region

The nucleotide sequence of the Vibrio alginolyticus sucrose uptake-encoding region was determined, and contained two genes, scrA and scrK. The scrA gene encodes an enzyme IISucrose (EIIScr) protein of the phosphoenolpyruvate dependent phosphotransferase system and the scrK gene encodes a fructokinase. The deduced amino acid (aa) sequence for the V. alginolyticus EIIScr protein was homologous with the EIIScr proteins from Streptococcus mutans, Salmonella typhimurium (pUR400 system) and Bacillus subtilis. The deduced aa sequence for the V. alginolyticus fructokinase was homologous with the Escherichia coli enzymes, 6-phosphofructokinase (isoenzyme 2) and ribokinase. Transposon phoA mutagenesis experiments indicated that the EIIScr protein was a membrane-bound protein with a region that extended into the periplasm.     

Differential control by IHF and cAMP of two oppositely oriented genes, hpt and gcd, in Escherichia coli: significance of their partially overlapping regulatory elements

The hpt gene, which encodes hypoxanthine phosphoribosyltransferase, is located next to, but transcribed in the opposite direction to, the gcd gene, which codes for a membrane-bound glucose dehydrogenase, at 3.1 min on the Escherichia coli genome. In their promoter-operator region, putative regulatory elements for integration host factor (IHF) and for the complex comprising 3', 5'-cyclic AMP (cAMP) and its receptor protein (CRP) are present, and they overlap the promoters for hpt and gcd, respectively. The involvement of IHF and cAMP-CRP, as well as the corresponding putative cis-acting elements, in the expression of the two genes was investigated by using lacZ operon fusions. In an adenylate cyclase-deficient strain, addition of cAMP increased the expression of hpt and reduced the expression of gcd. In agreement with this observation, the introduction of mutations into the putative binding element for the cAMP-CRP complex enhanced the expression of gcd. In contrast, mutations introduced into the putative IHF-binding elements increased the level of hpt expression. Similar results were obtained with IHF-defective strains. Thus, the expression of the two genes is regulated in a mutually exclusive manner. Additional experiments with mutations at the -10 sequence of the gcd promoter suggest that the binding of RNA polymerase to the hpt promoter interferes with the interaction of RNA polymerase with the gcd promoter, and vice versa.     

Effects of plasmid amplification and recombinant gene expression on the growth kinetics of recombinant E. coli

An experimental study was undertaken to identify and quantitate the effects of plasmid amplification and recombinant gene expression on Escherichia coli growth kinetics. Identification of these effects was possible because recombinant gene expression and plasmid copy number were controlled by different mechanisms on plasmid pVH106/172. Recombinant gene expression of the lactose operon structural genes was under the control of the lac promoter and was activated by the addition of the chemicals, IPTG and cyclic AMP, to the fermentation medium. Plasmid content was amplified in a separate fermentation by increasing culture temperature since the plasmid replicon was temperature-sensitive. A final fermentation was performed in which both plasmid content and recombinant gene expression were induced simultaneously by adding chemicals and raising the culture temperature. Recombinant growth rates were found to be reduced by the expression of high levels of recombinant lac proteins in the chemical induction experiments and by the amplification of plasmid levels in the temperature induction experiment. High expression of recombinant lac proteins following chemical induction was accompanied by a loss in recombinant cell viability. In the plasmid amplification experiment, the recombinant cells did not lose viability but the recombinant product yields were much lower than those achieved in the chemical induction experiments. Combining temperature and chemical induction increased the recombinant product yield by a factor of 4400 but also lowered cellular growth rates by 70%.     

Different cyclic adenosine 3',5'-monophosphate requirements for induction of beta-galactosidase and tryptophanase. Effect of osmotic pressure on intracellular cyclic adenosine 3,5-monophosphate concentrations.

In this study we have tried to answer the following questions: (1) is it possible for different catabolite-repressible genes, although submitted to the same control, to be expressed selectively depending upon the growth conditions, and (2) what is the effect of increasing the osmolarity of the medium on the intracellular level of cAMP? Two conditions were found to cause a continuous variation of intracellular cAMP levels during growth. With different strains, higher cAMP levels are required for induction of the tryptophanase gene than one required for induction of the lactose operon. cAMP has been provided externally in adenyl cyclase minus cells of a mutant that has been made permeable by EDTA treatment. Although external cAMP concentrations, 10 times higher than the usual intracellular levels, are required for induction of beta-galactosidase and tryptophanase, the difference of requirements of cAMP is maintained. An increase in the osmolarity of the medium by sucrose addition causes a fourfold decrease in the intracellular cAMP level. As a consequence this prevents the induction of tryptophanase whereas beta-galactosidase is still inducible. After pulse induction, a difference in the kinetics of expression of the tryptophanase and beta-galactosidase genes was found. Its relationship with the previous results is discussed.     

Genetic inversion in the formation of an Hfr strain from a temperature-sensitive F'' gal strain.

An Hfr strain (PB15) that carries a duplicated copy of the galactose operon genes flanking the integrated sex factor is unusually stable since it does not show excision of the repeated deoxyribonucleic acid segment. The right-hand galactose operon is in the normal orientation. Deletion mutations that eliminate the right-hand galactose genes, the sex factor, and some of the left-hand operon have been isolated. Mutants believed to have their left-hand galactose operon inverted were able to be induced for galactose epimerase synthesis by D-fucose but did not show escape synthesis on induction of bacteriophage lambda. Ribonucleic acid specific for the galactose operon was isolated after induction of lysogenic strains presumed to carry the galactose operon in the normal and inverted orientation. Hybridization to the isolated left and right strands of lambdapgal showed that the noninformational strand of the left-hand galactose operon of the deletion mutant of PB15 was transcribed on escape induction. These results show that inversion has occurred.