Regulation of polyamine biosynthesis in tobacco. Effects of inhibitors and exogenous polyamines on arginine decarboxylase, ornithine decarboxylase, and S-adenosylmethionine decarboxylase

Treatment of tobacco liquid suspension cultures with methylglyoxal bis(guanylhydrazone) (MGBG) an inhibitor of S-adenosylmethionine decarboxylase, resulted in a dramatic overproduction of a 35-kDa peptide on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (Malmberg, R.L., and McIndoo, J. (1983) Nature 305, 623-625). MGBG treatment also resulted in a 20-fold increase in the activity of S-adenosylmethionine decarboxylase. Purification of S-adenosylmethionine decarboxylase from MGBG-treated cultures revealed that the overproduced 35-kDa peptide and S-adenosylmethionine decarboxylase are identical. Precursor incorporation experiments using [3H] methionine and [35S]methionine revealed that MGBG does not induce any increased synthesis of S-adenosylmethionine decarboxylase but rather stabilizes the protein to proteolytic degradation. The half-life of the enzyme activity was increased when MGBG was present in the growth medium. In addition to stabilizing S-adenosylmethionine decarboxylase, MGBG also resulted in the rapid and specific loss of arginine decarboxylase activity with little effect ornithine decarboxylase. The kinetics of this effect suggest that arginine decarboxylase synthesis was rapidly inhibited by MGBG. Exogenously added polyamines had little effect on ornithine decarboxylase, whereas S-adenosylmethionine and arginine decarboxylase activities rapidly diminished with added spermidine or spermine. Finally, inhibition of ornithine decarboxylase was lethal to the cultures, whereas inhibition of arginine decarboxylase was only lethal during initiation of growth in suspension culture.     

Localization of ornithine decarboxylase and changes in polyamine content in root meristems of Zea mays

Polyamine content and the activity of arginine decarboxylase (EC 4.1.1.19) and ornithine decarboxylase (EC 4.1.1.17) were studied with respect to meristematic activity in primary roots and in developing lateral roots of Zea mays L. (cv. Neve Ya'ar 170) seedlings. Comparative localization of active ornithine decarboxylase and of meristematic activity were determined by labelling roots either with α-[5-¹⁴C]-difluoromethyl ornithine or with [³H]-thymidine, respectively.
Lateral roots were formed during the 72 h post-decapitation period, accompanied by an initial decline in putrescine content and by a significant increase in spennidine con-tent at 48–72 h. High levels of spermidine and lower levels of putrescine were found in the primary root apex as well. A marked increase in ornithine and arginine decarboxylase activity, as measured by ¹⁴CO₂ release, was found during the 72 h post-decapitation period of lateral root development. This increase in ornithine decarboxylase activity was confirmed also by a parallel rise in the incorporation of α-[5-¹⁴C]-difluoromethyl ornithine into trichloroacetic acid-insoluble fractions. Microautoradiographs of longitudinal and cross sections of roots, labelled with α-[5-¹⁴C]-difluoromethyl ornithine, showed that ornithine decarboxylase is localized mainly in the meristematic zones, as evidenced by [³H]-thymidine incorporation. A close correlation between meristematic activity and polyamines was demonstrated in situ , suggesting that polyamine content and biosynthesis may have a role in meristematic activity in corn roots.     

Arabidopsis polyamine biosynthesis: absence of ornithine decarboxylase and the mechanism of arginine decarboxylase activity

Unlike other eukaryotes, which can synthesize polyamines only from ornithine, plants possess an additional pathway from arginine. Occasionally non-enzymatic decarboxylation of ornithine could be detected in Arabidopsis extracts; however, we could not detect ornithine decarboxylase (ODC; EC 4. 1.1.17) enzymatic activity or any activity inhibitory to the ODC assay. There are no intact or degraded ODC sequences in the Arabidopsis genome and no ODC expressed sequence tags. Arabidopsis is therefore the only plant and one of only two eukaryotic organisms (the other being the protozoan Trypanosoma cruzi) that have been demonstrated to lack ODC activity. As ODC is a key enzyme in polyamine biosynthesis, Arabidopsis is reliant on the additional arginine decarboxylase (ADC; EC 4.1.1.9) pathway, found only in plants and some bacteria, to synthesize putrescine. By using site-directed mutants of the Arabidopsis ADC1 and heterologous expression in yeast, we show that ADC, like ODC, is a head-to-tail homodimer with two active sites acting in trans across the interface of the dimer. Amino acids K136 and C524 of Arabidopsis ADC1 are essential for activity and participate in separate active sites. Maximal activity of Arabidopsis ADC1 in yeast requires the presence of general protease genes, and it is likely that dimer formation precedes proteolytic processing of the ADC pre-protein monomer.     

Association of diamine oxidase and ornithine decarboxylase with maturing cells in rapidly proliferating epithelium

Diamine oxidase and ornithine decarboxylase activities are shown to have a parallel distribution across rat small intestine mucosa; levels of both enzyme activities are sharply higher in mature cells in the villus tip region than in proliferating cells in the crypt areas. Histidine decarboxylase levels were not measurable in the same cell preparations and aromatic-L-amino-acid decarboxylase activity was distributed in an opposite pattern to diamine oxidase and ornithine decarboxylase. The results suggest that intestinal diamine oxidase could be involved with polyamine metabolism. The new findings for ornithine decarboxylase suggest an in vivo role for polyamines in non-proliferative cells; rat small intestinal mucosa may be an excellent model for investigating the function of polyamines in regenerating cells.     

Metabolism of acetylpolyamines by monoamine oxidase,diamine oxidase and polyamine oxidase

N¹-Monoacetylspermine, N¹,N¹²-diacetylspermine and N¹-monoacetylspermidine were found to be good substrates for rat liver polyamine oxidase, but not for rat liver mitochondrial monoamine oxidase. N⁸-Monoacetylspermidine, monoacetylcadaverine, monoacetylputrescine and monoacetyl-1,3-diaminopropane were oxidized by the monoamine oxidase when the substrate concentration was 10.0 mM, but not by the polyamine oxidase. All the acetylpolyamines except N¹,N¹²-diacetylspermine were also oxidized by hog kidney diamine oxidase although their affinities for the oxidase appeared low. The present data suggest that acetylpolyamines are not easily metabolized in vivo by either monoamine oxidase or diamine oxidase in mammalian tissues although N¹-monoacetylspermine, N¹,N¹²-diacetylspermine and N¹-monoacetylspermidine are attacked by polyamine oxidase.     

Association of diamine oxidase and ornithine decarboxylase with maturing cells in rapidly proliferating epithelium.

Diamine oxidase and ornithine decarboxylase activities are shown to have a parallel distribution across rat small intestine mucosa; levels of both enzyme activities are sharply higher in mature cells in the villus tip region than in proliferating cells in the crypt areas. Histidine decarboxylase levels were not measurable in the same cell preparations and aromatic-L-amino-acid decarboxylase activity was distributed in an opposite pattern to diamine oxidase and ornithine decarboxylase. The results suggest that intestinal diamine oxidase could be involved with polyamine metabolism. The new findings for ornithine decarboxylase suggest an in vivo role for polyamines in non-proliferative cells; rat small intestinal mucosa may be an excellent model for investigating the function of polyamines in regenerating cells.     

Regional changes in ornithine decarboxylase activity and polyamine levels during thyroxine-induced cardiac hypertrophy

Ornithine decarboxylase activities (ODC) and polyamine levels were determined in five cardiac regions of the rat heart, following daily administration of 1 mg/kg of thyroxine, in the right and left atria, the right and left ventricles and the septum. The thyroxine stimulated ODC activity in all five regions of the heart. Enzyme activity in the left atrium and the septum peaked a day earlier than in other regions and the decline of ODC activity was slower. Putrescine in control animals was present in all regions except the right atrium, where its content was below detectable levels. Following the administration of thyroxine, the putrescine content of the left atrium, the right ventricle and the septum declined, while spermidine and spermine levels remained unchanged. In direct contrast to the other regions of the heart, thyroxine stimulated an increase in polyamines, as well as in weight which occurred exclusively in the left ventricle. These findings suggest a causal relationship between increased polyamines and hypertrophy.     

Effect of salt and osmotic stress on changes in polyamine content and arginine decarboxylase activity in Lupinus luteus seedlings

The effects of NaCl (260 mM) and sorbitol (360 mM) isoosmotic stresses on polyamine titers in lupin (Lupinus luteus L. var. Ventus) in relation to organ-specific responses were investigated. Analysis showed that during the first few hours (4 h) of salt and osmotic stress higher amounts of putrescine (Put) and spermidine (Spd) were accumulated in the roots and leaves of lupin seedlings. After exposing the plants to a longer duration (24 h) of exposure to NaCl, the level of free Put decreased in roots and cotyledons by about 48% and 54%, respectively, and increased in hypocotyls and leaves by about 27% and 73%, respectively. The Level of free Spd also decreased in roots by about 50%, in contrast to the increase of Spd observed in hypocotyls and leaves by about 50% and 70%, respectively. The effect of non-ionic stress on the level of Put and Spd in studied organs of lupin was similar to that of NaCl. Free spermine was at an undetectable level in examined organs. However, in the roots of lupin growing for 24 h in the presence of NaCl and/or sorbitol, the activity of arginine decarboxylase (ADC) (EC 4.1.1.19) increased by about 66% and 80%, respectively. ADC activity in leaves was similar to that observed in the control. Additionally, in the roots and leaves of lupin growing under the stress condition (NaCl or sorbitol), a higher level of polyamines (PAs) bound to microsomal membranes was observed. It is probable that PAs bound to microsomal membranes prevent stress-induced damage. We conclude that both stresses induce biosynthesis of Put and other PAs in the roots, as well as Put accumulation in the leaves, and this may indicate translocation of Put from the roots to the shoot. The possible role of PAs in adaptive mechanisms to stress is discussed.     

Stereochemistry of reactions catalysed by arginine decarboxylase and ornithine decarboxylase

The decarboxylations of l-arginine, catalysed by arginine decarboxylase (EC 4.1.1.19) and of l-ornithine, catalysed by ornithine decarboxylase     

Changes of ornithine decarboxylase activity and polyamine content upon differentiation of mouse NB-15 neuroblastoma cells

The possible functions of ornithine decarboxylase (ODC) and polyamines in the differetiation of mouse NB-15 neuroblastoma cells were investigated by examining the changes of these parameters in the differentiaton and nondifferentiating NB-15 cells over a 5-day culture period. Differentiation of NB-15 cells was induced by the addition of dibutyryl cyclic AMP and 3-isobutyl-1-methylxanthin (IBMX) to the growth medium and was monitored by neurite outgrowth, increase of acetylcholinesterase (AChE), and R_I cAMP-binding protein. Plating of NB-15 cells in fresh serum-containing growth medium was accompanied by rapid growth and a marked increase of ODC activity, this early increase of ODC activity was attenuated, both in duration and in magnitude, in the differentiating cells. The spermidine content of the differentiating neuroblastoma cell was significantly lower than that of the nondifferentiating cells. In the fully differentiated neuroblastoma cells, the ODC activity and spermidine content were lower than that of the undifferentiated cells by approximately 15-fold and five-fold, respectively. Based on these results it is proposed that changes of polyamine metabolism may be of significance in the differentiation of mouse neuroblastoma cells.     

Localization of arginine decarboxylase in tobacco plants

The lack of knowledge about the tissue and subcellular distribution of polyamines (PAs) and the enzymes involved in their metabolism remains one of the main obstacles in our understanding of the biological role of PAs in plants. Arginine decarboxylase (ADC; EC 4.1.1.9) is a key enzyme in polyamine biosynthesis in plants. We have characterized a cDNA coding for ADC from Nicotiana tabacum L. cv. Petit Havana SR1. The deduced ADC polypeptide had 721 amino acids and a molecular mass of 77 kDa. The ADC cDNA was overexpressed in Escherichia coli , and the ADC fusion protein obtained was used to produce polyclonal antibodies. Using immunological methods, we demonstrate the presence of the ADC protein in all plant organs analysed: flowers, seeds, stems, leaves and roots. Moreover, depending on the tissue, the protein is localized in two different subcellular compartments, the nucleus and the chloroplast. In photosynthetic tissues, ADC is located mainly in chloroplasts, whereas in non-photosynthetic tissues the protein appears to be located in nuclei. The different compartmentation of ADC may be related to distinct functions of the protein in different cell types.     

Correlation between K+ content, activities of arginine and ornithine decarboxylase, and levels of putrescine and nicotine in cultured tobacco callus

In callus cultures of Nicotiana tabacum L. cv. Burley 21 we have examined the effect of two auxin concentrations (1 and 11.5 μ M α-naphthaleneacetic acid) in the culture medium on K⁺, putrescine and nicotine levels and activities of putrescine-biosyn-thetic enzymes l -arginine decarboxylase (EC 4.1.1.19) and l -ornithine decarboxylase (EC 4.1.1.17). The calli grown on the low-auxin medium (with optimal auxin concentration for nicotine synthesis) had significantly lower concentrations of K⁺ and higher concentrations of nicotine than those grown on the high-auxin medium (with a supraoptimal auxin concentration). Furthermore, in the calli grown on both culture media, there was a positive correlation between the levels of HCIO₄-soluble free putrescine and nicotine, as well as a negative correlation between those of HCIO₄-soluble bound putrescine and the alkaloid. The results suggest that in tobacco callus K⁺ uptake, the accumulation of HCIO₄-soluble free putrescine and nicotine synthesis are related processes that depend upon the concentration of auxin in the culture medium; a concentration of 1 μ M NAA would increase HCIO₄-soluble free putrescine level to a greater degree than that of 11,5 μ M NAA, and consequently lead to a higher production of the alkaloid. Although both putrescine-biosynthetic enzymes are active in our callus cultures, ornithine decarboxylase activity was considerably greater. This interpretation is supported by the enhancement of the 35.5 kDa band and 38.9 kDa band (detected by SDS-PAGE) which showed ornithine and arginine decarboxylase activity, respectively.     

Management of polyamine pools and the regulation of ornithine decarboxylase

The management of polyamine synthesis and polyamine pools differs fundamentally from that of most other small molecular-weight endproducts. The polyamines are vital to growth and important cellular functions, but they are toxic in excess. I argue here that their multivalent cationic character, leading to binding to cell constituents, precludes fluent feedback inhibition of synthesis. This has led to the development of elaborate alternative regulatory mechanisms controlling ornithine decarboxylase, the key initial enzyme of the pathway. Poorly regulated polyamine synthesis and the toxicity of polyamines impose upon cells a need to control uptake and to dispose of excess polyamines. Recent data on polyamine transport suggest unorthodox mechanisms of accomplishing these functions.     

Characterization of arginine decarboxylase in rat brain and liver: distinction from ornithine decarboxylase

We compared the properties of mammalian arginine decarboxylase (ADC) and ornithine decarboxylase (ODC) in rat liver and brain. Mammalian ADC is thermally unstable and associated with mitochondrial membranes. ADC decarboxylates both arginine (Km = 0.75 mM) and ornithine (Km = 0.25 mM), a reaction not inhibited by the specific ODC inhibitor, difluoromethylomithine. ADC activity is inhibited by Ca2+, Co2+, and polyamines, is present in many organs being highest in aorta and lowest in testis, and is not recognized by a specific monoclonal antibody to ODC. In contrast, ODC is thermally stable, cytosolic, and mitochondrial and is expressed at low levels in most organs except testis. Although ADC and ODC are expressed in cultured rat C6 glioma cells, the patterns of expression during growth and confluence are very different. We conclude that mammalian ADC differs from ADC isoforms expressed in plants, bacteria, or Caenorhabditis elegans and is distinct from ODC. ADC serves to synthesize agmatine in proximity to mitochondria, an organelle also harboring agmatine's degradative enzyme, agmatinase, and a class of imidazoline receptor (I2) to which agmatine binds with high affinity.     

Methanococcus jannaschii uses a pyruvoyl-dependent arginine decarboxylase in polyamine biosynthesis

The genome sequence of the hyperthermophilic methanogen Methanococcus jannaschii contains homologs of most genes required for spermidine polyamine biosynthesis. Yet genomes from neither this organism nor any other euryarchaeon have orthologs of the pyridoxal 5'-phosphate-dependent ornithine or arginine decarboxylase genes, required to produce putrescine. Instead, as shown here, these organisms have a new class of arginine decarboxylase (PvlArgDC) formed by the self-cleavage of a proenzyme into a 5-kDa subunit and a 12-kDa subunit that contains a reactive pyruvoyl group. Although this extremely thermostable enzyme has no significant sequence similarity to previously characterized proteins, conserved active site residues are similar to those of the pyruvoyl-dependent histidine decarboxylase enzyme, and its subunits form a similar (alphabeta)(3) complex. Homologs of PvlArgDC are found in several bacterial genomes, including those of Chlamydia spp., which have no agmatine ureohydrolase enzyme to convert agmatine (decarboxylated arginine) into putrescine. In these intracellular pathogens, PvlArgDC may function analogously to pyruvoyl-dependent histidine decarboxylase; the cells are proposed to import arginine and export agmatine, increasing the pH and affecting the host cell's metabolism. Phylogenetic analysis of Pvl- ArgDC proteins suggests that this gene has been recruited from the euryarchaeal polyamine biosynthetic pathway to function as a degradative enzyme in bacteria.