Spectrophotometric assay for ornithine decarboxylase

A rapid and sensitive spectrophotometric assay for ornithine decarboxylase is described. It is based on the observation that the product of ornithine decarboxylase, putrescine, reacts with 2,4,6-trinitrobenzenesulfonic acid to give a colored product soluble in 1-pentanol whereas ornithine does not. The amount of putrescine produced by the enzyme was determined by measuring the absorbance of the 1-pentanol extract of the reaction mixture at 420 nm, and by comparing the results to those obtained by the trapping of 14CO2 and by HPLC assays. The three assays were found to be equivalent in sensitivity, with the spectrophotometric assay having the advantages of being relatively rapid, requiring only common laboratory equipment, and not requiring the use of radioactive isotopes.     

Spectrophotometric and steady-state kinetic analysis of the biosynthetic arginine decarboxylase of Yersinia pestis utilizing arginine analogues as inhibitors and alternative substrates

The PLP-dependent, biosynthetic arginine decarboxylase (ADC) of Yersinia pestis was investigated using steady-state kinetics employing structural analogues of arginine as both alternative substrates and competitive inhibitors. The inhibitor analysis indicates that binding of the carboxyl and guanidinium groups of the substrate, l-arginine, provides essentially all of the free energy change realized upon substrate binding in the ground state. Furthermore, recognition of the guanidinium group is primarily responsible for substrate specificity. Comparison of the steady-state parameters for a series of alternative substrates that contained chemically modified guanidinium moieties provides evidence of a role for induced fit in ADC catalysis. ADC was also characterized by UV/vis and fluorescence spectrophotometry in the presence or absence of a number of arginine analogues. The enzyme complexes formed served as models for the adsorption complex and the external aldimine complex of the enzyme with the substrate.     

Characterization of arginine decarboxylase from Dianthus caryophyllus.

Arginine decarboxylase (ADC, EC 4.1.1.9) is a key enzyme in the biosynthesis of polyamines in higher plants, whereas ornithine decarboxylase represents the sole pathway of polyamine biosynthesis in animals. Previously, we characterized a genomic clone from Dianthus caryophyllus, in which the deduced polypeptide of ADC was 725 amino acids with a molecular mass of 78 kDa. In the present study, the ADC gene was subcloned into the pGEX4T1 expression vector in combination with glutathione S-transferase (GST). The fusion protein GST-ADC was water-soluble and thus was purified by sequential GSTrap-arginine affinity chromatography. A thrombin-mediated on-column cleavage reaction was employed to release free ADC from GST. Hiload superdex gel filtration FPLC was then used to obtain a highly purified ADC. The identity of the ADC was confirmed by immunoblot analysis, and its specific activity with respect to (14)C-arginine decarboxylation reaction was determined to be 0.9 CO(2) pkat mg(-1) protein. K(m) and V(max) of the reaction between ADC and the substrate were 0.077 +/- 0.001 mM and 6.0 +/- 0.6 pkat mg(-1) protein, respectively. ADC activity was reduced by 70% in the presence of 0.1 mM Cu(2+) or CO(2+), but was only marginally affected by Mg(2+), or Ca(2+) at the same concentration. Moreover, spermine at 1 mM significantly reduced its activity by 30%.     

Indications for post-translational regulation of Vitis vinifera L. arginine decarboxylase

In order to study arginine decarboxylase regulation, we produced an antiserum against a hybrid of a 615 amino acid residue fragment of grapevine arginine decarboxylase cDNA with maltose-binding protein. The antiserum generated recognized mainly a protein band of ca. 80 kDa in extracts from grapevine tissues. Extracts from leaves and internodes in different developmental stages showed differences in the quantity of the 80 kDa band recognized by the antiserum. However, these differences did not correspond with changes in arginine decarboxylase specific activity. Furthermore, western blot analysis of extracts from cell cultures, where enzyme-specific activity was induced or repressed, did not reveal respective changes in the quantity of the 80 kDa protein band. Digestion of the hybrid by the specific protease factor Xa resulted in a polypeptide of 90 kDa instead of the expected two polypeptides of 43 and 66 kDa. Finally, western blot analysis of shoot extract incubated with factor Xa or the hybrid protein previously digested by factor Xa revealed that factor Xa-digested hybrid protein cleaved the 80 kDa band, resulting in two bands of ca. 38 and 40 kDa, whereas factor Xa alone did not affect it. These results suggest that arginine decarboxylase protein levels and/or activity is post-translationally regulated, as has been shown for other enzymes of polyamine biosynthesis.     

Biochemical evidence for the presence of arginine decarboxylase activity in Trypanosoma cruzi.

Trypanosoma cruzi was found to release 14CO2 from radiolabeled arginine, and this effect was inhibited by either DL-alpha-difluoromethylarginine or monofluoromethylagmatine, both specific inhibitors of arginine decarboxylase (ADC). Furthermore, agmatine, which can be derived metabolically only by ADC-mediated arginine decarboxylation, was produced when T. cruzi was incubated with radiolabeled arginine, and agmatine production was inhibited in the presence of DL-alpha-difluoromethylarginine. These results constitute direct biochemical evidence for the presence in T. cruzi of ADC, an enzyme that does not occur in mammalian cells.     

Kinetics of the decamer - dimer dissociation of arginine decarboxylase.

Aurintricarboxylic acid inhibited replicative DNA synthesis in nucleotide-permeable mouse ascites sarcoma cells. DNA polymerase activity assayed with activated DNA template and DNA polymerase purified partially from sarcoma cells was also inhibited by aurintricarboxylic acid. The inhibition of DNA polymerase activity was probably due to the inhibitory interaction of aurintricarboxylic acid with DNA polymerase. The replicative DNA synthesis might be inhibited by aurintricarboxylic acid interacting with some essential protein component(s), such as DNA polymerase of the replication machinery.     

Spectrophotometric method for estimation of aliphatic primary amines in biological samples

A method based on Rimini test for aliphatic amines was studied and developed for quantitative estimation of aliphatic primary amines. The method involves action of the amine with acetone to form schiff base which complexes with sodium nitroprusside to give violet colour. The absorption maximum in the visible range of the spectrum, for the reaction mixture was found to be 550 nm. The pH (8–11) and reaction time scan for the assay were optimized. A linear relation of concentration (0.2–3 mg/mL) of amine against absorbance at 550 nm was established. Interference due to other reaction components was negligible (±0.02 mg/mL) as compared to the sample in buffer. 1, 3-dimethyl butylamine was used as the model amine and the method was applied to other amines; it was observed that when electron-withdrawing substituents are present in the molecule the reaction is retarded, as the incubation time was longer. This method is useful for estimation of aliphatic primary amine in biological samples.     

Crenarchaeal arginine decarboxylase evolved from an S-adenosylmethionine decarboxylase enzyme

The crenarchaeon Sulfolobus solfataricus uses arginine to produce putrescine for polyamine biosynthesis. However, genome sequences from S. solfataricus and most crenarchaea have no known homologs of the previously characterized pyridoxal 5'-phosphate or pyruvoyl-dependent arginine decarboxylases that catalyze the first step in this pathway. Instead they have two paralogs of the S-adenosylmethionine decarboxylase (AdoMetDC). The gene at locus SSO0585 produces an AdoMetDC enzyme, whereas the gene at locus SSO0536 produces a novel arginine decarboxylase (ArgDC). Both thermostable enzymes self-cleave at conserved serine residues to form amino-terminal beta-domains and carboxyl-terminal alpha-domains with reactive pyruvoyl cofactors. The ArgDC enzyme specifically catalyzed arginine decarboxylation more efficiently than previously studied pyruvoyl enzymes. alpha-Difluoromethylarginine significantly reduced the ArgDC activity of purified enzyme, and treating growing S. solfataricus cells with this inhibitor reduced the cells' ratio of spermidine to norspermine by decreasing the putrescine pool. The crenarchaeal ArgDC had no AdoMetDC activity, whereas its AdoMetDC paralog had no ArgDC activity. A chimeric protein containing the beta-subunit of SSO0536 and the alpha-subunit of SSO0585 had ArgDC activity, implicating residues responsible for substrate specificity in the amino-terminal domain. This crenarchaeal ArgDC is the first example of alternative substrate specificity in the AdoMetDC family. ArgDC activity has evolved through convergent evolution at least five times, demonstrating the utility of this enzyme and the plasticity of amino acid decarboxylases.     

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     

Expression of human arginine decarboxylase, the biosynthetic enzyme for agmatine

Agmatine, an amine formed by decarboxylation of L-arginine by arginine decarboxylase (ADC), has been recently discovered in mammalian brain and other tissues. While the cloning and sequencing of ADC from plant and bacteria have been reported extensively, the structure of mammalian enzyme is not known. Using homology screening approach, we have identified a human cDNA clone that exhibits ADC activity when expressed in COS-7 cells. The cDNA and deduced amino acid sequence of this human ADC clone is distinct from ADC of other forms. Human ADC is a 460-amino acid protein that shows about 48% identity to mammalian ornithine decarboxylase (ODC) but has no ODC activity. While naive COS-7 cells do not make agmatine, these cells are able to produce agmatine, as measured by HPLC, when transfected with ADC cDNA. Northern blot analysis using the cDNA probe indicated the expression of ADC message in selective human brain regions and other human tissues.     

Biosynthetic arginine decarboxylase in phytopathogenic fungi

It has been reported that while bacteria and higher plants possess two different pathways for the biosynthesis of putrescine, via ornithine decarboxylase (ODC) and arginine decarboxylase (ADC); the fungi, like animals, only use the former pathway. We found that contrary to the earlier reports, two of the phytopathogenic fungi (Ceratocystis minor and Verticillium dahliae) contain significant levels of ADC activity with very little ODC. The ADC in these fungi has high pH optimum (8.4) and low Km (0.237 mM for C. minor, 0.103 mM for V. dahliae), and is strongly inhibited by alpha-difluoromethylarginine (DFMA), putrescine and spermidine, further showing that this enzyme is probably involved in the biosynthesis of polyamines and not in the catabolism of arginine as in Escherichia coli. The growth of these fungi is strongly inhibited by DFMA while alpha-difluoromethylornithine (DFMO) has little effect.     

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.     

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.     

Analysis of a cDNA encoding arginine decarboxylase from oat reveals similarity to the Escherichia coli arginine decarboxylase and evidence of protein processing

Summary Arginine decarboxylase is the first enzyme in one of the two pathways of putrescine synthesis in plants. We purified arginine decarboxylase from oat leaves, obtained N-terminal amino acid sequence, and then used this information to isolate a cDNA encoding oat arginine decarboxylase. Comparison of the derived amino acid sequence with that of the arginine decarboxylase gene from Escherichia coli reveals several regions of sequence similarity which may play a role in enzyme function. The open reading frame (ORF) in the oat cDNA encodes a 66 kDa protein, but the arginine decarboxylase polypeptide that we purified has an apparent molecular weight of 24 kDa and is encoded in the carboxyl-terminal region of the ORF. A portion of the cDNA encoding this region was expressed in E. coli, and a polyclonal antibody was developed against the expressed polypeptide. The antibody detects 34 kDa and 24 kDa polypeptides on Western blots of oat leaf samples. Maturation of arginine decarboxylase in oats appears to include processing of a precursor protein.     

Molecular forms of arginine decarboxylase in oat leaves

Arginine decarboxylase (ADC, EC 4.1.1.19) is the first enzyme in one of the two biosynthetic pathways of putrescine in plants and has been characterized from a number of species, beginning with the work of Smith (1979; Phytochemistry 18: 1447–1452) who suggested that oat ADC had native sizes of 118 and 195 kDa. There are several studies showing a lack of correlation between changes in enzyme activity and mRNA or protein levels. In oats ( Avena sativa L.) a posttranslational modification of ADC has been described. The protein is synthesized as a 66-kDa precursor that is proteolytically processed into two polypeptides of 42 and 24 kDa with an associated gain of enzyme activity. In the present work, we have studied the existence of different ADC molecular forms in oat leaves by determination of enzymatic activity and using polyclonal antibodies obtained against an amino acid sequence near the C terminus deduced from the nucleotide sequence. In Avena sativa L. cv. Victory, we demonstrate the existence of 5 different molecular forms of ADC, with approximate molecular mass of 195, 115, 66, 38 and 23 kDa, that react with our antibodies and have enzymatic activity. Our results agree with previous work, but this is the first report showing all molecular forms simultaneously and might be a preliminary contribution to solve the question about the distribution of multiple forms of ADC and their importance in the correlation between the enzymatic activity and mRNA levels.     

Lack of arginine decarboxylase in Trypanosoma cruzi epimastigotes

The presence of arginine decarboxylase (ADC) enzymatic activity in Trypanosoma cruzi epimastigotes is still a matter of controversy due to conflicting results published during the last few years. We have investigated whether arginine might indeed be a precursor of putrescine via agmatine in these parasites. We have shown that wild-type T. cruzi epimastigotes cultivated in a medium almost free of polyamines stopped their growth after several repeated passages of cultures in the same medium, and that neither arginine nor omithine were able to support or reinitiate parasite multiplication. In contrast, normal growth was quickly resumed after adding exogenous putrescine or spermidine. The in vivo labelling of parasites with radioactive arginine showed no conversion of this amino acid into agmatine, and attempts to detect ADC activity measured by the release of CO2 under different conditions in T. cruzi extracts gave negligible values for all strains assayed. The described data clearly indicate that wild-type T. cruzi epimastigotes lack ADC enzymatic activity.