Nucleotide sequence of the Escherichia coli cad operon: a system for neutralization of low extracellular pH.

Lysine decarboxylase of Escherichia coli has been the subject of enzymological studies, and the gene encoding lysine decarboxylase (cadA) and a regulatory gene (cadR) have been mapped. This enzyme is induced at low pH in the presence of lysine and achieves maximal level under anaerobic conditions. The induction of lysine decarboxylase increases the pH of the extracellular medium and provides a distinctive marker in tests of clinical strains. We report the sequence of the cad operon encoding lysine decarboxylase, a protein of 715 amino acids, and another protein, CadB, of 444 amino acids. The amino acid sequence of lysine decarboxylase showed high homology to that of the lysine decarboxylase of Hafnia alvei with less homology to the sequence of speC, which encodes the biosynthetic ornithine decarboxylase of E. coli. The cadA and cadB genes were separately cloned and placed under the control of lac and tac promoters, respectively, to facilitate independent study of their physiological effects. The cadB gene product had a mobility characteristic of a smaller protein on protein gels, analogous to that found for some other membrane proteins. The CadB sequence showed homology to that of ArcD of Pseudomonas aeruginosa, encoding an arginine/ornithine antiporter. Excretion studies of various strains, the coinduction of cadB and cadA, and the attractive physiological role for an antiport system led to a model for the coupled action of cadA and cadB in uptake of lysine, the reduction of H+ concentration, and excretion of cadaverine.     

Characterization of a second lysine decarboxylase isolated from Escherichia coli.

We report here on the existence of a new gene for lysine decarboxylase in Escherichia coli K-12. The hybridization experiments with a cadA probe at low stringency showed that the homologous region of cadA was located in lambda Kohara phage clone 6F5 at 4.7 min on the E. coli chromosome. We cloned the 5.0-kb HindIII fragment of this phage clone and sequenced the homologous region of cadA. This region contained a 2,139-nucleotide open reading frame encoding a 713-amino-acid protein with a calculated molecular weight of 80,589. Overexpression of the protein and determination of its N-terminal amino acid sequence defined the translational start site of this gene. The deduced amino acid sequence showed 69.4% identity to that of lysine decarboxylase encoded by cadA at 93.7 min on the E. coli chromosome. In addition, the level of lysine decarboxylase activity increased in strains carrying multiple copies of the gene. Therefore, the gene encoding this lysine decarboxylase was designated Idc. Analysis of the lysine decarboxylase activity of strains containing cadA, ldc, or cadA ldc mutations indicated that ldc was weakly expressed under various conditions but is a functional gene in E. coli.     

Excretion and uptake of cadaverine by CadB and its physiological functions in Escherichia coli

The functions of the putative cadaverine transport protein CadB were studied in Escherichia coli. CadB had both cadaverine uptake activity, dependent on proton motive force, and cadaverine excretion activity, acting as a cadaverine-lysine antiporter. The Km values for uptake and excretion of cadaverine were 20.8 and 303 microM respectively. Both cadaverine uptake and cadaverine-lysine antiporter activities of CadB were functional in cells. Cell growth of a polyamine-requiring mutant was stimulated slightly at neutral pH by the cadaverine uptake activity and greatly at acidic pH by the cadaverine-lysine antiporter activity. At acidic pH, the operon containing cadB and cadA, encoding lysine decarboxylase, was induced in the presence of lysine. This caused neutralization of the extracellular medium and made possible the production of CO(2) and cadaverine and aminopropylcadaverine instead of putrescine and spermidine. The induction of the cadBA operon also generated a proton motive force. When the cadBA operon was not induced, the expression of the speF-potE operon, encoding inducible ornithine decarboxylase and a putrescine-ornithine antiporter, was increased. The results indicate that the cadBA operon plays important roles in cellular regulation at acidic pH.     

Cadaverine protects Vibrio vulnificus from superoxide stress

An electron paramagnetic resonance (EPR) signal characteristic of the 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO)-OH spin adduct, which is formed from the reaction of DMPO with superoxide radicals generated by xanthine oxidase-mediated reaction, was significantly reduced by the cadaverine or Escherichia coli Mn-containing superoxide dismutase (MnSOD). Likewise, cytochrome c reduction by superoxide was inhibited by cadaverine, and the inhibition level increased in proportion to the level of cadaverine. The cadA mutant of Vibrio vulnificus, which does not produce cadaverine because of the lack of lysine decarboxylase, exhibits less tolerance to superoxide stress in comparison with wild type. The results indicate that cadaverine scavenges superoxide radicals, and protects cells from oxidative stress.     

Gene for Heat-Inducible Lysyl-tRNA Synthetase (lysU) Maps near cadA in Escherichia coli

A hybrid ColE1 plasmid from the Clarke-Carbon colony bank with a 7-kilobase insertion was found to encode the inducible lysyl-tRNA synthetase along with the catabolic enzyme lysine decarboxylase. The gene for the inducible synthetase, lysU, must lie within 0.3 min of the lysine decarboxylase gene, cadA, at 92 min on the Escherichia coli genetic map.     

Construction of lac fusions to the inducible arginine-and lysine decarboxylase genes of Escherichia coli K12

The induction of several amino acid decarboxylases under anaerobic conditions at low pH has been known for many years, but the mechanism associated with this type of regulation has not been elucidated. To study the regulation of the biodegradative arginine and lysine decarboxylases of Escherichia coli K12, Mudlac fusions to these genes were isolated. Mudlac fusion strains deficient for lysine decarboxylase or arginine decarboxylase were identified using decarboxylase indicator media and analysed for their regulation of beta-galactosidase expression. The position of the Mudlac fusion in lysine decarboxylase-deficient strains has been mapped to the cadA gene at 93.7 minutes, while the Mudlac fusions exhibiting a deficiency in the inducible arginine decarboxylase have been mapped to 93.4 minutes.     

Formation of a compensatory polyamine by Escherichia coli polyamine-requiring mutants during growth in the absence of polyamines.

The amounts of normal and compensatory polyamines of polyamine-requiring Escherichia coli mutants grown in the absence of polyamines were determined. Although aminopropylcadaverine, a compensatory polyamine, was synthesized by MA135 (speB) and DR112 (speA speB), no aminopropylcadaverine or only small amounts of aminopropylcadaverine were synthesized by EWH319 (speA speB speC speD) and MA261 (speB speC), respectively. The average mass doubling times of MA135, DR112, MA261, and EWH319 grown in the absence of polyamines were 113, 105, 260, and 318 min, respectively. The correlation of these values with the sum of spermidine plus aminopropylcadaverine suggested that aminopropylcadaverine is important for cell growth in the presence of limiting amounts of normal polyamines. This hypothesis is supported by the results of aminopropylcadaverine stimulation of the in vitro synthesis of polyphenylalanine and MS2 RNA replicase and of its stimulation of the growth of MA261. For the following reasons, it was concluded that aminopropylcadaverine was synthesized preferentially from cadaverine made by ornithine decarboxylase: aminopropylcadaverine was synthesized in relatively large amounts in cells (MA135 and DR112) which possess ornithine decarboxylase; ornithine decarboxylase catalyzed the decarboxylation of lysine in vitro, and the in vivo formation of aminopropylcadaverine was inhibited by an inhibitor of ornithine decarboxylase.     

Modulation of acid-induced amino acid decarboxylase gene expression by hns in Escherichia coli.

Biodegradative arginine decarboxylase and lysine decarboxylase, encoded by adi and cadA, respectively, are induced to maximal levels when Escherichia coli is grown anaerobically in rich medium at acidic pH. Mutants formed by transposon mutagenesis, namely, GNB725, GNB729, GNB88, GNB824, and GNB837, exhibited considerably elevated expression at pH 8.0 compared with the corresponding parental strain. Southern hybridization and chromosome mapping showed that the above mutants contained a transposon within the hns gene. Several plasmids from an E. coli library able to complement these mutants by restoring normal pH induction were independently isolated and were found to contain the hns gene. These results suggest a role for the DNA-binding protein H-NS in affecting the activation of these acid-induced genes.     

Metabolic engineering of Corynebacterium glutamicum for cadaverine fermentation

Cadaverine, the expected raw material of polyamides, is produced by decarboxylation of L-lysine. If we could produce cadaverine from the cheapest sugar, and as a renewable resource, it would be an effective solution against global warming, but there has been no attempt to produce cadaverine from glucose by fermentation. We focused on Corynebacterium glutamicum, whose L-lysine fermentation ability is superior, and constructed a metabolically engineered C. glutamicum in which the L-homoserine dehydrogenase gene (hom) was replaced by the L-lysine decarboxylase gene (cadA) of Escherichia coli. In this recombinant strain, cadaverine was produced at a concentration of 2.6 g/l, equivalent to up to 9.1% (molecular yield) of the glucose transformed into cadaverine in neutralizing cultivation. This is the first report of cadaverine fermentation by C. glutamicum.     

Amplification of ornithine decarboxylase gene in response to polyamine deprivation in Chinese hamster ovary cells

We have isolated from an arginase-deficient polyamine-dependent Chinese hamster ovary cell line a new mutant strain that has greatly increased ornithine decarboxylase activity. This enables the cells, in the absence of ornithine, to decarboxylate lysine into cadaverine (diaminopentane) that is further converted into N-(3-aminopropyl)cadaverine and N,N'-bis(3-aminopropyl)cadaverine. These unusual polyamines can support the growth of the cells without added polyamines derived from ornithine. Immunoreactive ornithine decarboxylase-like protein was clearly increased in the mutant cells but could not solely account for the greatly increased enzyme activity. Southern blot analysis of DNA hybridized to a plasmid carrying ornithine decarboxylase-cDNA revealed at least a 32-fold amplification of the ornithine decarboxylase gene. Ornithine decarboxylase-mRNA concentration was also highly increased in the cells. The half-life of the enzyme and the Km for ornithine were not altered from those of the parental cell line.     

Polyamine-deficient Neurospora crassa mutants and synthesis of cadaverine.

The polyamine path of Neurospora crassa originates with the decarboxylation of ornithine to form putrescine (1,4-diaminobutane). Putrescine acquires one or two aminopropyl groups to form spermidine or spermine, respectively. We isolated an ornithine decarboxylase-deficient mutant and showed the mutation to be allelic with two previously isolated polyamine-requiring mutants. We here name the locus spe-1. The three spe-1 mutants form little or no polyamines and grow well on medium supplemented with putrescine, spermidine, or spermine. Cadaverine (1,5-diaminopentane), a putrescine analog, supports very slow growth of spe-1 mutants. An arginase-deficient mutant (aga) can be deprived of ornithine by growth in the presence of arginine, because arginine feedback inhibits ornithine synthesis. Like spe-1 cultures, the ornithine-deprived aga culture failed to make the normal polyamines. However, unlike spe-1 cultures, it had highly derepressed ornithine decarboxylase activity and contained cadaverine and aminopropylcadaverine (a spermidine analog), especially when lysine was added to cells. Moreover, the ornithine-deprived aga culture was capable of indefinite growth. It is likely that the continued growth is due to the presence of cadaverine and its derivatives and that ornithine decarboxylase is responsible for cadaverine synthesis from lysine. In keeping with this, an inefficient lysine decarboxylase activity (Km greater than 20 mM) was detectable in N. crassa. It varied in constant ratio with ornithine decarboxylase activity and was wholly absent in the spe-1 mutants.     

Isolation, characterization, and mapping of Escherichia coli mutants blocked in the synthesis of ornithine decarboxylase.

Several Escherichia coli K-12 mutants blocked in the synthesis of ornithine decarboxylase (OD) were isolated after transduction for serA+ in a strain (MA197) blocked in agmatine ureohydrolase (AUH) with a mutagenized phage lysate of P1. The new double-polyamine mutants were characterized by an unconditional polyamine dependence; either putrescine or spermidine was required for normal growth. The mutational block was varified by the demonstration of a virtual absence of OD activity in cellular extracts. The mutation, designated speC, was mapped by P1 transduction in several strains and was shown to have a cotransduction frequency of 17.2% with serA. Map order was established as serA speB speC metK. A derivative of one of the OD mutants having wild-type levels of AUH and blocked in OD was utilized along with an OD AUH mutant and an OD+ AUH strain to explore the phenomenon of "pathway selection" using growth rate as a parameter. Polyamine pool studies were carried out simultaneously. The results presented here support the hypothesis of pathway selection, implying a preferential utilization of exogenous arginine rather than endogenously produced arginine in polyamine biosynthesis.     

Polyamines are essential for the formation of plague biofilm

We provide the first evidence for a link between polyamines and biofilm levels in Yersinia pestis, the causative agent of plague. Polyamine-deficient mutants of Y. pestis were generated with a single deletion in speA or speC and a double deletion mutant. The genes speA and speC code for the biosynthetic enzymes arginine decarboxylase and ornithine decarboxylase, respectively. The level of the polyamine putrescine compared to the parental speA+ speC+ strain (KIM6+) was depleted progressively, with the highest levels found in the Y. pestis DeltaspeC mutant (55% reduction), followed by the DeltaspeA mutant (95% reduction) and the DeltaspeA DeltaspeC mutant (>99% reduction). Spermidine, on the other hand, remained constant in the single mutants but was undetected in the double mutant. The growth rates of mutants with single deletions were not altered, while the DeltaspeA DeltaspeC mutant grew at 65% of the exponential growth rate of the speA+ speC+ strain. Biofilm levels were assayed by three independent measures: Congo red binding, crystal violet staining, and confocal laser scanning microscopy. The level of biofilm correlated to the level of putrescine as measured by high-performance liquid chromatography-mass spectrometry and as observed in a chemical complementation curve. Complementation of the DeltaspeA DeltaspeC mutant with speA showed nearly full recovery of biofilm to levels observed in the speA+ speC+ strain. Chemical complementation of the double mutant and recovery of the biofilm defect were only observed with the polyamine putrescine.     

Effects of multicopy LeuO on the expression of the acid-inducible lysine decarboxylase gene in Escherichia coli.

We previously reported that mutations in hns, the structural gene for the histone-like protein H-NS, cause derepressed expression of cadA, which encodes the acid-inducible lysine decarboxylase at noninducing pH (pH 8.0). This study reports the characterization of a plasmid isolated from an Escherichia coli library that suppresses the effect of an hns mutation on cadA expression. A previously sequenced open reading frame, leuO, proves to be the gene that causes the hns-complementing phenotype. The mechanism for this phenotype appears to be overexpression of leuO from a multicopy plasmid, which drastically reduces production of CadC, the essential activator for cadA induction. These results show an in vivo regulatory phenotype for leuO, consistent with its proposed protein sequence.     

Partial characterization of a lysU mutant of Escherichia coli K-12.

The Escherichia coli K-12 strain GNB10181 shows no inducible lysyl-tRNA synthetase (LysRS) activity. Two-dimensional gel electrophoretic analysis of the polypeptides synthesized by this strain indicates that the normal lysU gene product, LysU, is absent. When both GNB10181 and its parent, MC4100, were grown at elevated temperatures (42 to 45 degrees C) no significant difference between their growth rates was observed. The lysU mutation was transferred to other E. coli K-12 backgrounds by using P1 transduction. The lysU transductants behaved comparably to their lysU+ parents at different growth temperatures. Therefore, the LysU proteins does not appear to be essential for growth at high temperatures, at least under the conditions examined here. In addition, lysU transductants were found to be defective for inducible lysine decarboxylase, (LDC), inducible arginine decarboxylase (ADI), and melibiose utilization (Mel), which are all missing in GNB10181. Complementation of the above missing functions was achieved by using the Clarke-Carbon plasmids pLC4-5 (LysU LDC) and pLC17-38 (LysU Mel ADI). From these experiments, it appears that GNB10181 has suffered a chromosomal deletion between 93.4 and 93.7 min, which includes the lysU gene. By using plasmid pLC17-38, the position of ADI on two-dimensional gels was identified. Finally, lysS delta lysU double mutants were constructed which can potentially be used as positive selection agents for the isolation of LysRS genes from other sources.     

Isolation of a metK mutant with a temperature-sensitive S-adenosylmethionine synthetase.

An Escherichia coli metK mutant, designated metK110, was isolated among spontaneous ethionine-resistant organisms selected at 42 degrees C. The S-adenosylmethionine synthetase activity of this mutant was present at lower levels than in the corresponding wild-type strain and was more labile than the wild-type enzyme when heated or dialyzed. A mixture of mutant and wild-type enzyme preparations had an activity equal to the sum of the component activities. These facts strongly suggest that the mutated gene in this strain is the structural gene for this enzyme. Genetic mapping experiments placed the metK110 mutation near or at the site of other known metK mutants (i.e., 63 min), confirming its designation as a metK mutant. A revised gene order has been established for this region, i.e., metC glc speC metK speB serA.