Modulation of ornithine decarboxylase activity in Escherichia coli by positive and negative effectors

Biosynthesis of Arginine and Polyamines

Early investigations on arginine biosynthesis brought to light basic features of metabolic regulation. The most significant advances of the last 10 to 15 years concern the arginine repressor, its structure and mode of action in both E. coli and Salmonella typhimurium, the sequence analysis of all arg structural genes in E. coli and Salmonella typhimurium, the resulting evolutionary inferences, and the dual regulation of the carAB operon. This review provides an overall picture of the pathways, their interconnections, the regulatory circuits involved, and the resulting interferences between arginine and polyamine biosynthesis. Carbamoylphosphate is a precursor common to arginine and the pyrimidines. In both Escherichia coli and Salmonella enterica serovar Typhimurium, it is produced by a single synthetase, carbamoylphosphate synthetase (CPSase), with glutamine as the physiological amino group donor. This situation contrasts with the existence of separate enzymes specific for arginine and pyrimidine biosynthesis in Bacillus subtilis and fungi. Polyamine biosynthesis has been particularly well studied in E. coli, and the cognate genes have been identified in the Salmonella genome as well, including those involved in transport functions. The review summarizes what is known about the enzymes involved in the arginine pathway of E. coli and S. enterica serovar Typhimurium; homologous genes were identified in both organisms, except argF (encoding a supplementary OTCase), which is lacking in Salmonella. Several examples of putative enzyme recruitment (homologous enzymes performing analogous functions) are also presented.

Signal transduction and adaptive regulation through bacterial two-component systems: the Escherichia coli AtoSC paradigm

Adaptive signal transduction within microbial cells involves a multi-faceted regulated phosphotransfer mechanism that comprises structural rearrangements of sensor histidine kinases upon ligand-binding and phosphorylation-induced conformational changes in response regulators of versatile two-component systems (TCS), arisen early in bacterial evolution. In Escherichia coli, cross-talk between the AtoS histidine kinase and the AtoC response regulator, forming the AtoSC TCS, through His --> Asp phosphotransfer, activates AtoC directly to induce atoDAEB operon expression, thus modulating diverse fundamental cellular processes such as short-chain fatty acid catabolism, poly-(R)-3-hydroxybutyrate biosynthesis and chemotaxis. Among the inducers hitherto identified, acetoacetate is the classical activator. The AtoSC TCS functional modulation by polyamines, histamine and Ca(2+), as well as the role of AtoC as transcriptional regulator, add new promising perspectives in the physiological significance and potential pharmacological exploitation of this TCS in cell proliferation, bacteria-host interactions, chemotaxis, and adaptation.

Functional characterization of the histidine kinase of the E. coli two-component signal transduction system AtoS-AtoC

The Escherichia coli AtoS-AtoC two-component signal transduction system regulates the expression of the atoDAEB operon genes, whose products are required for short-chain fatty acid catabolism. In this study purified his-tagged wild-type and mutant AtoS proteins were used to prove that these proteins are true sensor kinases. The phosphorylated residue was identified as the histidine-398, which was located in a conserved Eta-box since AtoS carrying a mutation at this site failed to phosphorylate. This inability to phosphorylate was not due to gross structural alterations of AtoS since the H398L mutant retained its capability to bind ATP. Furthermore, the H398L mutant AtoS was competent to catalyze the trans-phosphorylation of an AtoS G-box (G565A) mutant protein which otherwise failed to autophosphorylate due to its inability to bind ATP. The formation of homodimers between the various AtoS proteins was also shown by cross-linking experiments both in vitro and in vivo.

Effect of histamine on the signal transduction of the AtoS-AtoC two component system and involvement in poly-(R)-3-hydroxybutyrate biosynthesis in Escherichia coli

AtoS-AtoC two-component system acts directly on the atoDAEB operon transcription to regulate the biosynthesis of short-chain poly-(R)-3-hydroxybutyrate. This study sought to investigate the effect of histamine and compound 48/80 on the regulation of AtoS-AtoC two-component system in Escherichia coli K-12 MA255 (speC(-), speB(-)) and the isogenic E. coli strains BW25113 (atoSC(+)) and BW28878 (DeltaatoSC) transformed with plasmids carrying related genes. Histamine or compound 48/80 induced or tended to reduce atoC transcription, respectively, while neither compound showed any effect on atoDAEB operon transcription. Moreover, histamine down-regulated poly-(R)-3-hydroxybutyrate biosynthesis, whereas compound 48/80 up-regulated its biosynthesis, maximal induction being obtained in the presence of multiple copies of AtoS-AtoC. Interestingly, co-administration of histamine counteracted this inductive effect of compound 48/80. The reported data provide the first evidence for a differential modulator role of histamine and compound 48/80 on the AtoS-AtoC two-component system signaling in potentially pathogenic bacteria, leading to a new perspective on their symbiotic behavior.

Spermidine triggering effect to the signal transduction through the AtoS–AtoC/Az two-component system in Escherichia coli

Recent analysis revealed that, in Escherichia coli the AtoS-AtoC/Az two-component system (TCS) and its target atoDAEB operon regulate the biosynthesis of short-chain poly-(R)-3-hydroxybutyrate (cPHB) biosynthesis, a biopolymer with many physiological roles, upon acetoacetate-mediated induction. We report here that spermidine further enhanced this effect, in E. coli that overproduces both components of the AtoS-AtoC/Az TCS, without altering their protein levels. However, bacteria that overproduce either AtoS or AtoC did not display this phenotype. The extrachromosomal introduction of AtoS-AtoC/Az in an E. coli DeltaatoSC strain restored cPHB biosynthesis to the level of the atoSC(+) cells, in the presence of the polyamine. Lack of enhanced cPHB production was observed in cells overproducing the TCS that did not have the atoDAEB operon. Spermidine attained the cPHB enhancement through the AtoC/Az response regulator phosphorylation, since atoC phosphorylation site mutants, which overproduce AtoS, accumulated less amounts of cPHB, compared to their wild-type counterparts. Exogenous addition of N(8)-acetyl-spermidine resulted in elevated amounts of cPHB but at lower levels than those attained upon spermidine addition. Furthermore, AtoS-AtoC/Az altered the intracellular distribution of cPHB according to the inducer recognized by the TCS. Overall, AtoS-AtoC/Az TCS was induced by spermidine to regulate both the biosynthesis and the intracellular distribution of cPHB in E. coli.

Molecular modeling and functional analysis of the AtoS–AtoC two-component signal transduction system of Escherichia coli

The AtoS-AtoC two-component signal transduction system positively regulates the expression of the atoDAEB operon in Escherichia coli. Upon acetoacetate induction, AtoS sensor kinase autophosphorylates and subsequently phosphorylates, thereby activating, the response regulator AtoC. In a previous work we have shown that AtoC is phosphorylated at both aspartate 55 and histidine73. In this study, based on known three-dimensional structures of other two component regulatory systems, we modeled the 3D-structure of the receiver domain of AtoC in complex with the putative dimerization/autophosphorylation domain of the AtoS sensor kinase. The produced structural model indicated that aspartate 55, but not histidine 73, of AtoC is in close proximity to the conserved, putative phosphate-donor, histidine (H398) of AtoS suggesting that aspartate 55 may be directly involved in the AtoS-AtoC phosphate transfer. Subsequent biochemical studies with purified recombinant proteins showed that AtoC mutants with alterations of aspartate 55, but not histidine 73, were unable to participate in the AtoS-AtoC phosphate transfer in support of the modeling prediction. In addition, these AtoC mutants displayed reduced DNA-dependent ATPase activity, although their ability to bind their target DNA sequences in a sequence-specific manner was found to be unaltered.

Effect of polyamines and synthetic polyamine-analogues on the expression of antizyme (AtoC) and its regulatory genes

Background

In bacteria, the biosynthesis of polyamines is modulated at the level of transcription as well as post-translationally. Antizyme (Az) has long been identified as a non-competitive protein inhibitor of polyamine biosynthesis in E. coli. Az was also revealed to be the product of the atoC gene. AtoC is the response regulator of the AtoS-AtoC two-component system and it functions as the positive transcriptional regulator of the atoDAEB operon genes, encoding enzymes involved in short chain fatty acid metabolism. The antizyme is referred to as AtoC/Az, to indicate its dual function as both a transcriptional and post-translational regulator.

Results

The roles of polyamines on the transcription of atoS and atoC genes as well as that of atoDAEB(ato) operon were studied. Polyamine-mediated induction was tested both in atoSC positive and negative E. coli backgrounds by using β-galactosidase reporter constructs carrying the appropriate promoters patoDAEB, patoS, patoC. In addition, a selection of synthetic polyamine analogues have been synthesized and tested for their effectiveness in inducing the expression of atoC/Az, the product of which plays a pivotal role in the feedback inhibition of putrescine biosynthesis and the transcriptional regulation of the ato operon. The effects of these compounds were also determined on the ato operon expression. The polyamine analogues were also tested for their effect on the activity of ornithine decarboxylase (ODC), the key enzyme of polyamine biosynthesis and on the growth of polyamine-deficient E. coli.

Conclusion

Polyamines, which have been reported to induce the protein levels of AtoC/Az in E. coli, act at the transcriptional level, since they cause activation of the atoC transcription. In addition, a series of polyamine analogues were studied on the transcription of atoC gene and ODC activity.

Phosphorylation activity of the response regulator of the two-component signal transduction system AtoS–AtoC in E. coli

Antizyme, long known to be a non-competitive inhibitor of ornithine decarboxylase, is encoded by the atoC gene in Escherichia coli. The present study reveals another role for AtoC, that of a response regulator of the AtoS-AtoC two component system regulating the expression of the atoDAEB operon upon acetoacetate induction. This operon encodes enzymes involved in short-chain fatty acid catabolism in E. coli. Evidence is presented to show that AtoS is a sensor kinase that together with AtoC constitutes a two-component signal transduction system. AtoS is a membrane protein which can autophosphorylate and then transfer that phosphoryl group to AtoC. This process can also be reproduced in vitro. AtoC contains in its amino acid sequence a conserved aspartic acid (D55), which is the putative phosphorylation site, as well as an unexpected "H box" consensus sequence (SHETRTPV), common to histidine kinases, with the histidine contained therein (H73) being a second potential target for phosphorylation. Substitution of either D55 or H73 in His10-AtoC diminished but did not abrogate AtoC phosphorylation suggesting that either both residues can be phosphorylated independently or that the phosphate group can be transferred between them. However, the D55 mutation in comparison to H73 had a more pronounced effect in vivo, on the activation of atoDAEB promoter after acetoacetate induction, although it was the presence of both mutations that rendered AtoC totally unresponsive to induction. These data provide evidence that the gene products of atoS and atoC constitute a two-component signal transduction system, with some unusual properties, involved in the regulation of the atoDAEB operon.

The role of bacterial antizyme: From an inhibitory protein to AtoC transcriptional regulator

This review considers the role of bacterial antizyme in the regulation of polyamine biosynthesis and gives new perspectives on the involvement of antizyme in other significant cellular mechanisms. Antizyme is a protein molecule induced by the end product of the enzymic reaction that it inhibits, in a non-competitive manner. The bacterial ornithine decarboxylase is regulated by nucleotides, phosphorylation and antizyme. The inhibition of ornithine decarboxylase by antizyme can be relieved to different degrees by DNA or by a variety of synthetic nucleic acid polymers, attributed to a specific interaction between nucleic acid and antizyme. Recently, this interplay between bacterial antizyme and nucleic acid was determined by discerning an additional function to antizyme that proved to be the atoC gene product, encoding the response regulator of the bacterial two-component system AtoS-AtoC. The gene located just upstream of atoC encodes the sensor kinase, named AtoS, that modulates AtoC activity. AtoC regulates expression of atoDAEB operon which is involved in short-chain fatty acid metabolism. Antizyme is thus referred to as AtoC, functioning both as a post-translational and transcriptional regulator. Also, the AtoS-AtoC signal transduction system in E. coli has a positive regulatory role on poly-(R)-3-hydroxybutyrate biosynthesis. The properties and gene structural similarities of antizymes from different organisms were compared. It was revealed that conserved domains are present mostly in the C-domain of all antizymes. BLAST analysis of the E. coli antizyme protein (AtoC) showed similarities around 69-58% among proteobacteria, g-proteobacteria, enterobacteria and the thermophilic bacterium Thermus thermophilus. A working hypothesis is proposed for the metabolic role of antizyme (AtoC) describing the significant biological implications of this protein molecule. Whether antizymes exist to other enzymes in different tissues, meeting the criteria discussed in the text remains to be elucidated.

Regulation of ornithine decarboxylase in B16 mouse melanoma cells: synergistic activation of melanogenesis by alphaMSH and ornithine decarboxylase inhibition

Ornithine decarboxylase (ODC) is the rate-limiting enzyme in the biosynthesis of polyamines, a family of cationic compounds required for optimal cell proliferation and differentiation. Within mammalian melanocytes, the expression of genes regulating cell growth and/or differentiation can be controlled by alpha-melanocyte-stimulating hormone (alphaMSH) and other melanogenesis modulating agents. In the B16 mouse melanoma model, alphaMSH stimulates melanogenesis by upmodulation of tyrosinase (tyr) activity, whereas the phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA) inhibits melanin synthesis. Therefore, we analyzed the regulation of ODC by these agents, as related to changes in the melanogenic pathway. Treatment of B16 cells with TPA or alphaMSH rapidly stimulated ODC activity. The effect was stronger for TPA and appeared mainly posttranslational. Irreversible inhibition of ODC with the active site-directed inhibitor alpha-difluoromethylornithine (DFMO) did not block TPA-mediated inhibition of tyr. Conversely, prolonged treatment of B16 cells with DFMO stimulated tyr activity by a posttranslational mechanism, probably requiring polyamine depletion. Combination treatment with alphaMSH and DFMO synergistically activated tyr. Therefore, ODC induction is not involved in the melanogenic response of B16 cells to alphaMSH. Rather, increased intracellular concentrations of polyamines following ODC induction might constitute a feedback mechanism to limit melanogenesis activation by alphaMSH.

Characterization of ornithine decarboxylase and regulation by its antizyme in Thermus thermophilus

Ornithine decarboxylase (ODC), the key enzyme of polyamine biosynthesis was highly purified from the thermophilic bacterium Thermus thermophilus. The enzyme preparation showed a single band on SDS-polyacrylamide gel electrophoresis, a pH optimum of 7.5 and a temperature optimum at 60 degrees C. The native enzyme which is phosphorylated could, upon treatment with alkaline phosphatase, lose all activity. The inactive form could be reversibly activated by nucleotides in the order of NTP>NDP>NMP. When physiological polyamines were added to the purified enzyme in vitro, spermine or spermidine activated ODC by 140 or 40%, respectively, while putrescine caused a small inhibition. The basic amino acids lysine and arginine were competitive inhibitors of ODC, while histidine did not affect the enzyme activity. Among the phosphoamino acids tested, phosphoserine was the most effective activator of purified ODC. Polyamines added at high concentration to the medium resulted in a delay or in a complete inhibition of the growth of T. thermophilus, and in a decrease of the specific activity of ornithine decarboxylase. The decrease of ODC activity resulted from the appearance of a non-competitive inhibitor of ODC, the antizyme (Az). The T. thermophilus antizyme was purified by an ODC-Sepharose affinity column chromatography, as well as by immunoprecipitation using antibodies raised against the E. coli antizyme. The antizyme of E. coli inhibited the ODC of T. thermophilus, and vice versa. The fragment of amino acids 56-292 of the E. coli antizyme, produced as a fusion protein of glutathione S-transferase, did not inhibit the ODC of E. coli or T. thermophilus.

Identification, cloning, and nucleotide sequencing of the ornithine decarboxylase antizyme gene of Escherichia coli

The ornithine decarboxylase antizyme gene of Escherichia coli was identified by immunological screening of an E. coli genomic library. A 6.4-kilobase fragment containing the antizyme gene was subcloned and sequenced. The open reading frame encoding the antizyme was identified on the basis of its ability to direct the synthesis of immunoreactive antizyme. Antizyme shares significant homology with bacterial transcriptional activators of the two-component regulatory system family; these systems consist of a "sensor" kinase and a transcriptional regulator. The open reading frame next to antizyme is homologous to sensor kinases. Antizyme overproduction inhibits the activities of both ornithine and arginine decarboxylases without affecting their protein levels. Extracts from E. coli bearing an antizyme gene-containing plasmid exhibit increased antizyme activity. These data strongly suggest that (i) the cloned gene encodes the ornithine decarboxylase antizyme and (ii) antizyme is a bifunctional protein serving as both an inhibitor of polyamine biosynthesis as well as a transcriptional regulator of an as yet unknown set of genes.

Dose, time and route dependency of the induction of rat hepatic ornithine decarboxylase by 12-tetradecanoylphorbol 13-acetate

Ornithine decarboxylase (ODC) activity, the rate limiting enzyme in polyamine biosynthesis, was determined after 12-O-tetradecanoylphorbol 13-acetate (TPA) administration to female Sprague-Dawley rats. The extent of induction depended on the dose, exposure, time and route of administration. The most effective dose for ODC induction by the intraperitoneal route was 40 ug TPA/kg which caused 3-5 fold ODC induction. Maximal ODC induction occurred in a narrow time band 5 hours after TPA administration. TPA had no adverse effects on hepatic DNA (measured by alkaline elution), cytochrome P-450 content and reduced glutathione content or serum alanine aminotransferase (SGPT) activity.

Transcriptional effects of polyamines on ribosomal proteins and on polyamine-synthesizing enzymes in Escherichia coli

We find that the transcription of various ribosomal proteins can be differentially affected by polyamines and by changes in growth rates. Using strain MG1655 of Escherichia coli K-12 (F-, lambda-), we have determined the effects of polyamines and changes in growth rate on the transcription of several ribosomal genes and the polyamine-synthesizing enzymes ornithine decarboxylase (L-ornithine carboxy-lyase; EC 4.1.1.17) and arginine decarboxylase (L-arginine carboxylyase; EC 4.1.1.19). Ribosomal proteins S20 and L34 can be differentiated from the other ribosomal proteins studied; the transcription of S20 and L34 is especially sensitive to polyamines and less sensitive to changes in growth rates. In contrast, the transcription of S10, S15, S19, L2, L4, L20, L22, and L23 is insensitive to polyamines although it is particularly sensitive to changes in growth rates. Like S20 and L34, the transcription of ornithine decarboxylase and arginine decarboxylase is especially sensitive to polyamines. Polyamines specifically enhance the transcription of ribosomal proteins S20 and L34, and decrease that of ornithine decarboxylase and arginine decarboxylase. It is evident that polyamines can exert both positive and negative regulation of gene expression in E. coli that can be differentiated from the effects caused by changes in growth rates.

Adjustment of polyamine contents in Escherichia coli

Adjustment of polyamine contents in Escherichia coli was studied with strains of Escherichia coli producing normal (DR112) and excessive amounts of ornithine decarboxylase [DR112(pODC)] or S-adenosylmethionine decarboxylase [DR112(pSAMDC)]. Although DR112(pODC) produced approximately 70 times more ornithine decarboxylase than DR112 did, the amounts of polyamines in the cells of both strains did not change significantly. The amounts of polyamines in DR112(pODC) were adjusted by excretion of excessive amounts of putrescine to the medium. When ornithine was deficient in cells, polyamine contents in DR112(pODC) were much higher than those in DR112, although polyamine contents were low in both strains. This indicates that large amounts of ornithine decarboxylase increased the utilization of ornithine for putrescine synthesis. During ornithine deficiency, strain DR112 produced 3.4 times more ornithine decarboxylase. Strain DR112(pSAMDC) produced seven times more S-adenosylmethionine decarboxylase than DR112 did. In DR112(pSAMDC) an increase (40%) in spermidine content, a decrease (35%) in putrescine content, and no significant excretion of putrescine and spermidine were observed. The amount of ornithine decarboxylase in DR112(pSAMDC) was approximately 30% less than that in DR112. In addition, S-adenosylmethionine decarboxylase activity was strongly inhibited by spermidine. A possible regulatory mechanism to maintain polyamine contents in Escherichia coli is discussed based on the results.

Biosynthesis of polyamines in ornithine decarboxylase, arginine decarboxylase, and agmatine ureohydrolase deletion mutants of Escherichia coli strain K-12

Escherichia coli K-12 mutants that carry deletions in their genes for ornithine decarboxylase (L-ornithine carboxy-lyase, EC 4.1.1.17) (speC), arginine decarboxylase (L-arginine carboxy-lyase, EC 4.1.1.19) (speA), and agmatine ureohydrolase (agmatinase or agmatine amidinohydrolase, EC 3.5.3.11) (speB) can still synthesize very small amounts of putrescine and spermidine. The putrescine concentration in these mutants was found to be 1/2500th that in spe+ cells. The pathway of putrescine synthesis appears to be through the biodegradative arginine decarboxylase, which converts arginine to agmatine, in combination with a low agmatine ureohydrolase activity--1/2000th that in spe+ strains. These results suggest that even such low levels of polyamines permit a low level of protein synthesis. Evidence is presented that the polyamine requirement for the growth of the polyamine-dependent speAB, speC deletion mutants, which are also streptomycin resistant, is not due to a decreased ability to synthesize polyamines.

Purification and properties of agmatine ureohydrolyase, a putrescine biosynthetic enzyme in Escherichia coli

The putrescine biosynthetic enzyme agmatine ureohydrolase (AUH) (EC 3.5.3.11) catalyzes the conversion of agmatine to putrescine in Escherichia coli. AUH was purified approximately 1,600-fold from an E. coli strain transformed with the plasmid pKA5 bearing the speB gene encoding the enzyme. The purification procedure included ammonium sulfate precipitation, heat treatment, and DEAE-sephacel column chromatography. The molecular mass of nondenatured AUH is approximately 80,000 daltons as determined by gel-sieving column chromatography, while on denaturing polyacrylamide gels, the molecular mass is approximately 38,000 daltons; thus, native AUH is most likely a dimer. A radiolabeled protein extracted from minicells carrying the pKA5 plasmid comigrated with the purified AUH in both sodium dodecyl sulfate-polyacrylamide and native polyacrylamide gels. The pI of purified AUH is between 8.2 and 8.4, as determined by either chromatofocusing or isoelectric focusing. The Km of purified AUH for agmatine is 1.2 mM; the pH optimum is 7.3. Neither the numerous ions and nucleotides tested nor polyamines affected AUH activity in vitro. EDTA and EGTA [ethylene glycol-bis (beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid] at 1 mM inactivated AUH activity by 53 and 74%, respectively; none of numerous divalent cations tested restored AUH activity. Ornithine inhibited AUH activity noncompetitively (Ki = 6 X 10(-3) M), while arginine inhibited AUH activity competitively (Ki = 9 X 10(-3) M).

Regulation of polyamine biosynthesis by antizyme and some recent developments relating the induction of polyamine biosynthesis to cell growth. Review

This review considers the role of antizyme, of amino acids and of protein synthesis in the regulation of polyamine biosynthesis. The ornithine decarboxylase of eukaryotic cells and of Escherichia coli can be non-competitively inhibited by proteins, termed antizymes, which are induced by di- and poly- amines. Some antizymes have been purified to homogeneity and have been shown to be structurally unique to the cell of origin. Yet, the E. coli antizyme and the rat liver antizyme cross react and inhibit each other's biosynthetic decarboxylases. These results indicate that aspects of the control of polyamine biosynthesis have been highly conserved throughout evolution. Evidence for the physiological role of the antizyme in mammalian cells rests upon its identification in normal uninduced cells, upon the inverse relationship that exists between antizyme and ornithine decarboxylase as well as upon the existence of the complex of ornithine decarboxylase and antizyme in vivo. Furthermore, the antizyme has been shown to be highly specific; its Keq for ornithine decarboxylase is 1.4 X 10(11) M-1. In addition, mammalian cells contain an anti-antizyme, a protein that specifically binds to the antizyme of an ornithine decarboxylase-antizyme complex and liberates free ornithine decarboxylase from the complex. In E. coli, in which polyamine biosynthesis is mediated both by ornithine decarboxylase and by arginine decarboxylase, three proteins (one acidic and two basic) have been purified, each of which inhibits both these enzymes. They do not inhibit the biodegradative ornithine and arginine decarboxylases nor lysine decarboxylase. The two basic inhibitors have been shown to correspond to the ribosomal proteins S20/L26 and L34, respectively. The relationship of the acidic antizyme to other known E. coli proteins remains to be determined. In mammalian cells, ornithine decarboxylase can be induced by a broad spectrum of compounds. These range from hormones and growth factors to natural amino acids such as asparagine and to non-metabolizable amino acid analogues such as alpha-amino-isobutyric acid. The amino acids that induce ornithine decarboxylase as well as those that promote polyamine uptake utilize the sodium dependent A and N transport systems. Consequently, they act in concert and increase intracellular polyamine levels by both mechanisms. The induction of ornithine decarboxylase by growth factors, such as NGF, EGF, and PDGF as well as by insulin requires the presence of these same amino acids and does not occur in their absence. However, the inducing amino acid need not be incorporated into protein nor covalently modified.(ABSTRACT TRUNCATED AT 400 WORDS)

Antagonistic transcriptional regulation of the putrescine biosynthetic enzyme agmatine ureohydrolase by cyclic AMP and agmatine in Escherichia coli

The putrescine biosynthetic enzyme agmatine ureohydrolase (AUH) (agmatinase; EC 3.5.3.11) catalyzes the conversion of agmatine to putrescine in Escherichia coli. The specific activity of AUH was determined in crude extracts prepared from wild-type strains and from strains with mutations in the adenylate cyclase gene (cya) or the cAMP receptor protein gene (crp) or both. In glucose minimal medium, a delta cya strain exhibited 70 to 90% higher AUH activity than a cya+ strain. Addition of 1 to 10 mM cAMP to cya+ and delta cya strains cultured in glucose repressed AUH activity in a dose-dependent manner. Addition of 1 to 10 mM cAMP to a delta crp strain failed to repress AUH activity. Addition of agmatine resulted in a three- to fourfold induction of AUH in delta cya and delta crp strains. This induction could be blocked by the addition of chloramphenicol. Simultaneous additions of various proportions of cAMP and agmatine resulted in reduced levels of induction and repression of AUH activity. This antagonistic regulation was shown to be exerted by independent mechanisms since AUH activity could be induced by agmatine in a delta crp strain supplemented with cAMP. These results suggest that both agmatine and cAMP antagonistically regulate AUH activity at the level of transcription. In minimal medium supplemented with 1 mM putrescine, the strains did not exhibit repression of AUH activity. In contrast, in minimal medium supplemented with 1 mM ornithine or arginine, cya+ or delta cya strains exhibited induced AUH activity as a result of conversion of these substrates to agmatine. Further experiments in vitro demonstrated that the effects observed with cAMP, agmatine, and arginine were not post-translationally mediated.

Regulation of polyamine biosynthesis in Escherichia coli by basic proteins

In Escherichia coli, the biosynthetic ornithine and arginine decarboxylases (EC 4.1.1.17 and 4.1.1.19, respectively) are responsible for the biosynthesis of polyamines from ornithine and arginine, respectively. When E. coli cells are grown in the presence of increasing amounts of polyamines, a progressive increase in the amount of antizyme 1 and antizyme 2 occurs. The amino acid compositions of antizymes 1 and 2 show them to be basic proteins; antizyme 1 has an amino acid composition similar to that of the E. coli histone-like protein HU and of the eukaryotic histone H2B; antizyme 2 is characterized by an unusually high arginine content. We find these proteins to be specific inhibitors of both the biosynthetic ornithine decarboxylase and the biosynthetic arginine decarboxylase. They do not inhibit the corresponding biodegradative ornithine and arginine decarboxylases, nor do they inhibit lysine decarboxylase or S-adenosylmethionine decarboxylase. These properties of the antizymes favor their function in the regulation of polyamine biosynthesis in E. coli. The ability of the purified antizymes to inhibit the ornithine and arginine decarboxylases is stabilized in acidic buffers and is lost upon prolonged exposure to solutions at neutral or basic pH.

Negative control of ornithine decarboxylase and arginine decarboxylase by adenosine-3':5'-cyclic monophosphate in Escherichia coli

The polyamine biosynthetic enzymes, ornithine decarboxylase (EC 4.1.1.17) (ODC) and arginine decarboxylase (EC 4.1.1.19) (ADC), are negatively controlled by cAMP in Escherichia coli. The specific activities of ODC and ADC were determined in crude extracts prepared from E. coli strains carrying a mutation in the adenylate cyclase (EC 4.6.1.1) structural gene (cya) and wildtype strains. These strains were cultured on various carbon sources in the presence and absence of cAMP. In wild-type strains, ODC and ADC activities were diminished in cells grown on glycerol compared to these strains cultured on glucose. When cya strains were grown on glucose or glycerol, ODC and ADC activities were the same. Addition of 1 mM cAMP to glucose-based medium repressed ODC and ADC activities in both the wild-type and cya strains. Furthermore, cAMP exerts its negative control through the cAMP receptor protein, since strains carrying a mutation in the crp structural gene fail to repress ODC and ADC activities in response to increased cAMP obtained by carbon source manipulation or cAMP supplementation of the growth medium. This evidence suggests that negative control of ODC and ADC by cAMP occurs at the level of transcription.

A macromolecular inhibitor of the antizyme to ornithine decarboxylase

A macromolecular factor that inhibits the activity of the antizyme to ornithine decarboxylase (ODC) was found in rat liver extracts. The factor, 'antizyme inhibitor', was heat-labile, non diffusable and of similar molecular size to ODC. The antizyme inhibitor re-activated ODC that had been inactivated by antizyme, apparently by replacing ODC in a complex with antizyme. Therefore the antizyme inhibitor can be used to assay the amount of inactive ODC-antizyme complex formed in vitro. When assayed by this method, the complex was shown to be eluted before ODC from a Sephadex G-100 column. Significant increase in ODC activity was observed when the antizyme inhibitor was added to crude liver extracts from rats that had been injected with 1,3-diaminopropane to cause decay of ODC activity, suggesting the presence of inactive ODC-antizyme complex in the extracts.

Osmotically induced changes in the ornithine decarboxylase activity of Dictyostelium discoideum

Myxamoebae of Dictyostelium discoideum from exponentially growing cultures showed altered ornithine decarboxylase activity upon external osmotic perturbation. On transfer to hypotonic NaCl solutions (20 mosmol/kg), cells showed high enzyme activity which was relatively independent of the concentration of the coenzyme pyridoxal phosphate (assay concentrations, 5 and 200 microM). In hypertonic solution (400 mosmol/kg) cells had a reduced level of ornithine decarboxylase activity which was dependent on the coenzyme concentration. The changes in activity were freely reversible in further external osmotic manipulation. The response to osmotic change occurred rapidly, within a few minutes. The changes still occurred at 7 degrees C but 2 mM sodium azide prevented the formation of the high activity form, although this effect was reversed when azide was removed. Cycloheximide had no effect on the osmotically induced changes. Addition of putrescine caused ornithine decarboxylase eventually to the converted to the low-activity form regardless of the osmolality of the solution. The characteristic cofactor concentration dependence of the high- and low-activity form were retained on storage of the cell extracts. No evidence was found for diffusible effectors which stabilized one or the other form of the activity. The enzymes responsible for the two forms were of the same molecular size as judged by gel filtration, and the activities had similar thermostabilities. The results are interpreted in terms of an osmotically induced interconversion of two forms of a single ornithine decarboxylase.

Phosphorylation of ornithine decarboxylase by a polyamine-dependent protein kinase

This paper presents evidence that a polyamine-dependent protein kinase (EC 2.7.1.37) purified from nuclei of the slime mold Physarum polycephalum catalyzes phosphorylation of ornithine decarboxylase (OrnDCase; L-ornithine carboxy-lyase, EC 4.1.1.17). The protein kinase had properties similar to OrnDCase antizyme. Phosphocellulose chromatography of nuclear preparations from P. polycephalum yielded the polyamine-dependent protein kinase of subunit Mr 26,000 that was resolved from a second fraction in which the protein kinase copurified with a phosphate-acceptor protein of subunit Mr 70,000. At Na+ concentrations less than approximately 150 mM, a complex formed between the protein kinase and the phosphate-acceptor protein. The complex did not demonstrate protein kinase or OrnDCase activity. The complex was dissociated by greater than 150 mM Na+ into its constituent proteins. The dissociated complex catalyzed phosphorylation of the Mr 70,000 component in the presence of spermidine and spermine, and it also demonstrated OrnDCase activity. The purified Mr 70,000 component from the complex and authentic OrnDCase, purified by procedures previously reported, were virtually identical with respect to OrnDCase activity, capacity to be phosphorylated by the polyamine-dependent protein kinase, amino acid composition, and immunological crossreactivity. Phosphorylation of OrnDCase by the polyamine-dependent protein kinase sharply inhibited OrnDCase activity. Thus, this is an example of posttranslational covalent modification of OrnDCase with concurrent alteration of its catalytic function. It is also an unusual example of control of the first enzyme in a biosynthetic pathway by a protein kinase that is, in turn, modulated by the immediate end products of the pathway.

Cellular control of ornithine decarboxylase activity by its antizyme

Conditions have been established under which the antizyme of ornithine decarboxylase (E.C. 4.1.1.17, L-ornithine carboxy-lyase, ODC) a non-competitive protein inhibitor of ODC, can be detected in cells in response to as little as 10(-7) M putrescine. The maintenance of intracellular antizyme activity depends upon the continued presence of putrescine in the medium. Removal of putrescine results in a rapid decline of antizyme activity. These phenomena are unaffected by the presence of cycloheximide and are comparable to the requirement of L-asparagine for the maintenance of ODC activity. The extent to which the antizyme level is increased is inversely related to the preexisting level of intracellular ODC at the time of addition of putrescine. The time of appearance of free antizyme is delayed in cells that have high levels of ODC; the amount of free antizyme that can be assayed for in these cells, at any particular time is correspondingly less. The converse is also true. In cells that have high levels of antizyme, the delay in appearance of ODC is greater and the amount of ODC that can be assayed for is correspondingly less than in cells with low levels of antizyme. These experiments, as well as others, indicate that the ODC antizyme and ODC interact in vivo with each other to modify their respective activities.

Studies on the control of plasminogen activator production by cultured human embryonic lung cells: requirements for inhibition by corticosteroids

The ability of actinomycin D to interfere with the dexamethasone-mediated inhibition of plasminogen activator (PA) production by human-embryonic lung (HuEL) cells has been examined. The enzyme produced by HuEL cells in the presence of both dexamethasone and actinomycin D appears to be the product of de novo protein synthesis, as determined by the dependence of PA production on active protein synthesis and the net increase in total PA during the course of an experiment. Inhibition of RNA synthesis must be continuous to maintain PA production in the presence of dexamethasone, since reinitiation of RNA synthesis causes an immediate loss of PA activity in the cells. Cordycepin and alpha-amanitin also prevent dexamethasone-mediated inhibition of PA in HuEL cells, indicating that the RNA whose synthesis must be prevented is of the mRNA class. These experiments imply that PA production in HuEL cells may be under translational as well as transcriptional control.

Inhibition of ornithine decarboxylase of HeLa cells by diamines and polyamines. Effect on cell proliferation

1. Ornithine decarboxylase activity is stimulated in high-density HeLa-cell cultures by dilution of or replacement of spent culture medium with fresh medium containing 10% (v/v) horse serum. 2. After stimulation, ornithine decarboxylase activity reaches a peak at 4-6h, then rapidly declines to the low enzyme activity characteristic of quiescent cultures, where it remains during the remainder of the cell cycle. 3. The stimulation of ornithine decarboxylase is eliminated by the addition of 0.5mum-spermine or -spermidine or 10mum-putrescine to the HeLa-cell cultures at the time of re-feeding with fresh medium. Much higher concentrations (1mm) of the non-physiological diamines, 1,3-diamino-propane or 1,3-diamino-2-hydroxypropane, are required to eliminate the stimulation of ornithine decarboxylase in re-fed HeLa-cell cultures. 4. A heat-labile, non-diffusible inhibitor, comparable with the inhibitory protein ornithine decarboxylase antizyme, is induced in HeLa cells by the addition of exogenous diamines or polyamines. 5. Intracellular putrescine is eliminated, intracellular spermidine and spermine are severely decreased and proliferation of HeLa cells is inhibited when cultures are maintained for 48h in the presence of the non-physiological inducer of ornithine decarboxylase antizyme, 1,3-diamino-2-hydroxypropane. Exogenous putrescine, a physiological inducer of the antizyme, does not decrease intracellular polyamines or interfere with proliferation of HeLa cells.