Global gene expression profiling of the polyamine system in suicide completers.

In recent years, gene expression, genetic association, and metabolic studies have implicated the polyamine system in psychiatric conditions, including suicide. Given the extensive regulation of genes involved in polyamine metabolism, as well as their interconnections with the metabolism of other amino acids, we were interested in further investigating the expression of polyamine-related genes across the brain in order to obtain a more comprehensive view of the dysregulation of this system in suicide. To this end, we examined the expression of genes related to polyamine metabolism across 22 brain regions in a sample of 29 mood-disordered suicide completers and 16 controls, and identified 14 genes displaying differential expression. Among these, altered expression of spermidine/spermine N1-acetyltransferase, spermine oxidase, and spermine synthase, has previously been observed in brains of suicide completers, while the remainder of the genes represent novel findings. In addition to genes with direct involvement in polyamine metabolism, including S-adenosylmethionine decarboxylase, ornithine decarboxylase antizymes 1 and 2, and arginase II, we identified altered expression of several more distally related genes, including aldehyde dehydrogenase 3 family, member A2, brain creatine kinase, mitochondrial creatine kinase 1, glycine amidinotransferase, glutamic-oxaloacetic transaminase 1, and arginyl-tRNA synthetase-like. Many of these genes displayed altered expression across several brain regions, strongly implying that dysregulated polyamine metabolism is a widespread phenomenon in the brains of suicide completers. This study provides a broader view of the nature and extent of the dysregulation of the polyamine system in suicide, and highlights the importance of this system in the neurobiology of suicide.

Polyamine accumulation in transgenic tomato enhances the tolerance to high temperature stress.

Polyamines play an important role in plant response to abiotic stress. S-adenosyl-l-methionine decarboxylase (SAMDC) is one of the key regulatory enzymes in the biosynthesis of polyamines. In order to better understand the effect of regulation of polyamine biosynthesis on the tolerance of high-temperature stress in tomato, SAMDC cDNA isolated from Saccharomyces cerevisiae was introduced into tomato genome by means of Agrobacterium tumefaciens through leaf disc transformation. Transgene and expression was confirmed by Southern and Northern blot analyses, respectively. Transgenic plants expressing yeast SAMDC produced 1.7- to 2.4-fold higher levels of spermidine and spermine than wild-type plants under high temperature stress, and enhanced antioxidant enzyme activity and the protection of membrane lipid peroxidation was also observed. This subsequently improved the efficiency of CO(2) assimilation and protected the plants from high temperature stress, which indicated that the transgenic tomato presented an enhanced tolerance to high temperature stress (38 degrees C) compared with wild-type plants. Our results demonstrated clearly that increasing polyamine biosynthesis in plants may be a means of creating high temperature-tolerant germplasm.

BUD2, encoding an S-adenosylmethionine decarboxylase, is required for Arabidopsis growth and development.

Polyamines are implicated in regulating various developmental processes in plants, but their exact roles and how they govern these processes still remain elusive. We report here an Arabidopsis bushy and dwarf mutant, bud2, which results from the complete deletion of one member of the small gene family that encodes S-adenosylmethionine decarboxylases (SAMDCs) necessary for the formation of the indispensable intermediate in the polyamine biosynthetic pathway. The bud2 plant has enlarged vascular systems in inflorescences, roots, and petioles, and an altered homeostasis of polyamines. The double mutant of bud2 and samdc1, a knockdown mutant of another SAMDC member, is embryo lethal, demonstrating that SAMDCs are essential for plant embryogenesis. Our results suggest that polyamines are required for the normal growth and development of higher plants.

Decarboxylases involved in polyamine biosynthesis and their inactivation by nitric oxide.

Polyamines are ubiquitous cellular components that are involved in normal and neoplastic growth. Polyamine biosynthesis is very highly regulated in mammalian cells by the activities of two key decarboxylases acting on ornithine and S-adenosylmethionine. Recent studies, which include crystallographic analysis of the recombinant human proteins, have provided a detailed knowledge of their structure and function. Ornithine decarboxylase is a PLP-requiring decarboxylase, whereas S-adenosylmethionine decarboxylase (AdoMetDC) contains a covalently bound pyruvate prosthetic group. Both enzymes have a key cysteine residue, which is involved in protonation of the Schiff base intermediate C(alpha) to form the product. These residues, Cys360 in ornithine decarboxylase (ODC) and Cys82 in AdoMetDC, react readily with nitric oxide (NO), which is therefore a potent inactivator of polyamine synthesis. The inactivation of these enzymes may mediate some of the antiproliferative actions of NO.

Essential role of S-adenosylmethionine decarboxylase in mouse embryonic development.

BACKGROUND: S-Adenosylmethionine decarboxylase (AdoMetDC) is one of the key enzymes involved in the biosynthesis of spermidine and spermine, which are essential for normal cell growth. To examine the role of polyamines in embryogenesis, we carried out targeted disruption of the mouse Amd1 gene, encoding AdoMetDC, to generate mice that can not synthesize spermidine and spermine. RESULTS: Amd1 heterozygous mice were viable, normal and fertile. However, homozygous Amd1(-/-) embryos died early in embryonic development, between E3.5 and E6.5 days post-coitus. Homozygous (Amd1(-/-)) blastocysts at E3.5 arrested cell proliferation immediately after the onset of cell culture, and this arrest was rescued by the addition of spermidine. Chromosomal DNA breakage did not occur in Amd1(-/-) blastocysts at E3.5, as determined by TUNEL assay. CONCLUSIONS: These results indicate that AdoMetDC plays an essential role in embryonic development and that polyamines are required for cell proliferation in the embryo after E3.5.

Role of polyamines and ethylene as modulators of plant senescence.

Under optimal conditions of growth, senescence, a terminal phase of development, sets in after a certain physiological age. It is a dynamic and closely regulated developmental process which involves an array of changes at both physiological and biochemical levels including gene expression. A large number of biotic and abiotic factors accelerate the process. Convincing evidence suggests the involvement of polyamines (PAs) and ethylene in this process. Although the biosynthetic pathways of both PAs and ethylene are interrelated, S-adenosylmethionine (SAM) being a common precursor, their physiological functions are distinct and at times antagonistic, particularly during leaf and flower senescence and also during fruit ripening. This provides an effective means for regulation of their biosynthesis and also to understand the mechanism by which the balance between the two can be established for manipulating the senescence process. The present article deals with current advances in the knowledge of the interrelationship between ethylene and PAs during senescence which may open up new vistas of investigation for the future.

Importance of intracellular S-adenosylmethionine decarboxylase activity for the regulation of camostate-induced pancreatic polyamine metabolism and growth: in vivo effect of two novel S-adenosylmethionine decarboxylase inhibitors.

The present study was designed to investigate the inhibitory potency of the two novel S-adenosylmethionine decarboxylase (SAM-DC) inhibitors MDL 73811 and CGP 48664 on the camostate-induced pancreatic polyamine metabolism and especially intracellular spermidine accumulation as well as pancreatic growth in vivo. Male Wistar rats (180 g) were either treated with (1) the synthetic trypsin inhibitor camostate (200 mg/kg b.w. orally twice daily), (2) camostate+MDL 73811 (100 mg/kg b.w. i.p. twice daily), (3) camostate+CGP 48664 (5 mg/kg b.w. i.p. once daily) or (4) saline as controls. Animals (5-9 per group) were sacrificed after 1, 2 and 5 days of treatment. MDL 73811 caused a long-lasting (> 95%; p < 0.005) inhibition of SAM-DC followed by a significant (p < 0.005) increase in ornithine decarboxylase and putrescine, while spermine was decreased (p < 0.005). In contrast to MDL 73811, CGP 48664 had little effect in vivo. Despite potent inhibition of SAM-DC camostate-stimulated intracellular spermidine accumulation was not prevented by the simultaneous administration of MDL 73811. Consequently organ growth was not affected either. Since de novo synthesis of spermidine was effectively inhibited by MDL 73811, counterregulatory mechanisms (i.e. interconversion pathway, extracellular uptake) had to step in to maintain the intracellular balance of spermidine. The present data support the general concept of the importance of intracellular spermidine accumulation for the maintenance of pancreatic growth in vivo.

Regulation of ornithine decarboxylase in the kidney of autoimmune mice with the lpr gene.

The lymphoproliferative lpr gene confers a lupus-like disease with lymphadenopathy, antinuclear antibody production, and glomerulonephritis in MRL-lpr/lpr mice. Upregulation of ornithine decarboxylase (ODC) activity and polyamine levels have been observed in the kidney and lymphoid organs of this strain. Inhibition of ODC with 0.5-1.5% (w/v) difluoromethylornithine (DFMO) in drinking water prolonged life-span and ameliorated renal disease. Glomerulonephritis is a major cause of morbidity and mortality in human and murine lupus. In order to elucidate the mechanism(s) of ODC regulation in lupus nephritis, we characterized ODC at the protein and mRNA levels in 3 strains of autoimmune mice with the lpr genetic background (MRL-lpr/lpr, C3H-lpr/lpr and C57BL/6J-lpr/lpr) using Western blotting, enzyme kinetics, turnover rate measurements, Northern blot hybridization, and reverse transcription-polymerase chain reaction (RT-PCR). Normal BALB/c mice were used as a control. We found that ODC activity in the kidney of lpr strains was 4- to 6-fold higher than that of BALB/c mice. The intensity of the major ODC protein band at 54 kD in Western blot was 4-fold higher in MRL-lpr/lpr and C3H-lpr/lpr kidney compared to that of BALB/c kidney. Putrescine levels were 2- to 4-fold higher in kidney of lpr strains than that of BALB/c and DFMO-treated MRL-lpr/lpr mice. DFMO treatment significantly reduced ODC activity and polyamine levels. The half-life of ODC enzyme in MRL-lpr/lpr, C3H-lpr/lpr, B6-lpr/lpr and BALB/c mouse kidneys was 15, 5, 8 and 23 min, respectively. There was no significant difference in the Km values of different strains, whereas Vmax values differed significantly. There was no difference in the level of SAMDC, another enzyme involved in the polyamine biosynthetic pathway, in various strain. Steady-state levels of ODC mRNA were lower in lpr strains compared to that of BALB/c mouse. Our results suggest that the basis for up-regulation of ODC is not at the transcriptional level, but may involve post-transcriptional modification(s) in lpr strains. The link between aberrant regulation of ODC and the immunopathogenesis of murine lupus nephritis indicates novel targets for lupus therapy.

Oxygen toxicity in a polyamine-depleted spe2 delta mutant of Saccharomyces cerevisiae.

When a mutant of Saccharomyces cerevisiae (spe2 delta) that cannot make spermidine or spermine was incubated in a polyamine-deficient medium in oxygen, there was a rapid cessation of cell growth and associated cell death. In contrast, when the mutant cells were incubated in the polyamine-deficient medium in air or anaerobically, the culture stopped growing more gradually, and there was no significant loss of cell viability. We also found that the polyamine-deficient cells grown in air, but not those grown anaerobically, showed a permanent loss of functional mitochondria ("respiratory competency"), as evidenced by their inability to grow on glycerol as the sole carbon source. These data support the postulation that polyamines act, in part, by protecting cell components from damage resulting from oxidation. However, since the mutant cells still required spermidine or spermine for growth when incubated under strictly anaerobic conditions, polyamines must also have other essential functions.

Polyamines: from molecular biology to clinical applications.

The polyamines putrescine, spermidine and spermine represent a group of naturally occurring compounds exerting a bewildering number of biological effects, yet despite several decades of intensive research work, their exact physiological function remains obscure. Chemically these compounds are organic aliphatic cations with two (putrescine), three (spermidine) or four (spermine) amino or amino groups that are fully protonated at physiological pH values. Early studies showed that the polyamines are closely connected to the proliferation of animal cells. Their biosynthesis is accomplished by a concerted action of four different enzymes: ornithine decarboxylase, adenosylmethionine decarboxylase, spermidine synthase and spermine synthase. Out of these four enzyme, the two decarboxylases represent unique mammalian enzymes with an extremely short half life and dramatic inducibility in response to growth promoting stimuli. The regulation of ornithine decarboxylase, and to some extent also that of adenosylmethionine decarboxylase, is complex, showing features that do not always fit into the generally accepted rules of molecular biology. The development and introduction of specific inhibitors to the biosynthetic enzymes of the polyamines have revealed that an undisturbed synthesis of the polyamines is a prerequisite for animal cell proliferation to occur. The biosynthesis of the polyamines thus offers a meaningful target for the treatment of certain hyperproliferative diseases, most notably cancer. Although most experimental cancer models responds strikingly to treatment with polyamine antimetabolites--namely, inhibitors of various polyamine synthesizing enzymes--a real breakthrough in the treatment of human cancer has not yet occurred. It is, however, highly likely that the concept is viable. An especially interesting approach is the chemoprevention of cancer with polyamine antimetabolites, a process that appears to work in many experimental animal models. Meanwhile, the inhibition of polyamine accumulation has shown great promise in the treatment of human parasitic diseases, such as African trypanosomiasis.

Polyamine biosynthesis and interconversion in rodent tissues.

Polyamine levels in rodent tissues are regulated by the activities of three enzymes: ornithine decarboxylase, S-adenosylmethionine decarboxylase, and spermidine/spermine N1-acetyltransferase. These enzymes are present in the cell in very small amounts, have very short half-lives, and are highly inducible. Ornithine decarboxylase was purified to homogeneity (about 10,000-fold) from androgen-treated mouse kidneys, which have enzyme levels several hundred times higher than those in other fully induced mammalian tissues. This decarboxylase could be specifically labeled either in vitro or in vivo by reaction with radioactive alpha-difluoromethylornithine, an enzyme-activated irreversible inhibitor. Such covalent binding of alpha-difluoromethylornithine was used to titrate the number of molecules of the enzyme and to estimate its purity. It was also used for autoradiographic localization of the enzyme within tissues and to follow the degradation of the protein in vivo. S-Adenosylmethionine decarboxylase has been purified from rat liver and psoas muscle, and significant differences between the enzyme forms present in these tissues were observed. The rate-limiting enzyme in the interconversion of the polyamines, spermidine/spermine N1-acetyltransferase was purified more than 100,000-fold from carbon tetrachloride-induced rat liver. This acetylase acts on both spermine and spermidine to form N1-acetyl derivatives, which are then oxidized by polyamine oxidase forming spermidine and putrescine, respectively.