Axonal Transport of Polyamines in Intact and Regenerating Axons of the Rat Sciatic Nerve

The axonal transport of putrescine or its polyamine derivatives spermidine or spermine is a subject of some debate. We investigated this question by injecting [3H]putrescine into the lumbar spinal cord of the rat and measuring the accumulation of radioactivity central to ligatures placed on intact and regenerating sciatic nerves. In normal nerves, approximately twice as much radioactivity built up proximal to these ligatures 2 or 3 days after injection than at more distal ligatures used to control for accumulation of radioactivity which might be due to tissue damage alone. In regenerating nerves the amount of radioactivity accumulating at the ligature was approximately five times that at the distal ligature and two to three times greater than in intact nerves. The identity of the radioactivity in regenerating nerves, determined on an amino acid analyzer, was found to be primarily spermidine and an unknown compound that migrated as a frontal elution peak. Autoradiographic analysis showed that the radioactivity was largely confined to axons, but a significant amount of the silver grains was associated with Schwann cells and myelin sheaths surrounding labeled axons in both intact and regenerating nerves. The data indicate that polyamine derivatives of putrescine are transported axonally in rat sciatic nerves, and some of this transported material accumulates in Schwann cells surrounding the labeled axons. These processes are apparently augmented during regeneration of the injured axons.     

Conversion of exogenous spermidine into putrescine after administration to rats

Administration of large, but non-toxic doses of spermidine (0.4–1.25 mmol/kg) led to a substantial increase in putrescine in liver, kidney and a number of other tissues including muscle. The increase in putriscine peaked at 6 h after treatment and was completely prevented by administration of cycloheximide 3 h after the spermidine suggesting that the induction of a new protein was required. This protein is likely to be spermidine N¹-acetyltransferase which was induced by the treatment with spermidine and increased 3–4-fold in liver and kidney within 6 h. N¹-Acetylspermidine was detected in tissues at this time after spermidine treatment and experiments in which labeled spermidine was given indicated that a substantial fraction of the administered spermidine was converted into N¹-acetylspermidine and into putrescine. These results suggest that the rise in putrescine after spermidine treatment is brought about by the production of N¹-acetylspermidine which is converted into putrescine by the action of polyamine oxidase. The limiting step in this conversion is the activity of the acetylase which is induced in response to the rise in spermidine content. The acetylase/oxidase pathway, therefore, provides a means by which polyamine levels can be regulated and excess polyamine disposed of.     

On the turnover of polyamines spermidine and spermine in mouse brain and other organs

The apparent biological half-lives of spermidine and spermine in mouse brain and other organs were determined by measurement of the specific radioactivities of these compounds over long periods of time. The endogenous polyamine pools were labeled by repeated intraperitoneal injections of [1,4-¹⁴C]putrescine·2HCl, [2-¹⁴C]d,l-methionine, [2-³H]l-methionine, andS-adenosyl-[2-³H]l-methionine. Repeated injections were given to ensure labeling of both fast and slow polyamine pools. It was shown that the two parts of the polyamine molecules which derive from ornithine and methionine have significantly different life spans, especially in the brain. Actual turnover rates of polyamines could not be determined because of the active interconversion between spermine and spermidine, and between spermidine and putrescine. The observed reutilization of putrescine originating from spermidine degradation for spermidine biosynthesis, and the analogous reutilization of spermidine in spermine biosynthesis is discussed with respect to its physiological significance and its relationship to cellular organization.     

Levels of Polyamines and Kinetic Characterization of Their Uptake in the Soybean Pathogen Phytophthora sojae

Polyamines are ubiquitous biologically active aliphatic cations that are at least transiently available in the soil from decaying organic matter. Our objectives in this study were to characterize polyamine uptake kinetics in Phytophthora sojae zoospores and to quantify endogenous polyamines in hyphae, zoospores, and soybean roots. Zoospores contained 10 times more free putrescine than spermidine, while hyphae contained only 4 times as much free putrescine as spermidine. Zoospores contained no conjugated putrescine, but conjugated spermidine was present. Hyphae contained both conjugated putrescine and spermidine at levels comparable to the hyphal free putrescine and spermidine levels. In soybean roots, cadaverine was the most abundant polyamine, but only putrescine efflux was detected. The selective efflux of putrescine suggests that the regulation of polyamine availability is part of the overall plant strategy to influence microbial growth in the rhizosphere. In zoospores, uptake experiments with [1,4-¹⁴C]putrescine and [1,4-¹⁴C]spermidine confirmed the existence of high-affinity polyamine transport for both polyamines. Putrescine uptake was reduced by high levels of exogenous spermidine, but spermidine uptake was not reduced by exogenous putrescine. These observations suggest that P. sojae zoospores express at least two high-affinity polyamine transporters, one that is spermidine specific and a second that is putrescine specific or putrescine preferential. Disruption of polyamine uptake or metabolism has major effects on a wide range of cellular activities in other organisms and has been proposed as a potential control strategy for Phytophthora. Inhibition of polyamine uptake may be a means of reducing the fitness of the zoospore along with subsequent developmental stages that precede infection.     

Metabolism of Polyamines in Transgenic Cells of Carrot Expressing a Mouse Ornithine Decarboxylase cDNA

The metabolisms of arginine (Arg), ornithine (Orn), and putrescine were compared in a nontransgenic and a transgenic cell line of carrot (Daucus carota L.) expressing a mouse Orn decarboxylase cDNA. [¹⁴C]Arg, [¹⁴C]Orn, and [¹⁴C]putrescine were fed to cells and their rates of decarboxylation, uptake, metabolism into polyamines, and incorporation into acid-insoluble material were determined. Transgenic cells showed higher decarboxylation rates for labeled Orn than the nontransgenic cells. This was correlated positively with higher amounts of labeled putrescine production from labeled Orn. With labeled Arg, both the transgenic and the nontransgenic cells exhibited similar rates of decarboxylation and conversion into labeled putrescine. When [¹⁴C]putrescine was fed, higher rates of degradation were observed in transgenic cells as compared with the nontransgenic cells. It is concluded that (a) increased production of putrescine via the Orn decarboxylase pathway has no compensatory effects on the Arg decarboxylase pathway, and (b) higher rates of putrescine production in the transgenic cells are accompanied by higher rates of putrescine conversion into spermidine and spermine as well as the catabolism of putrescine.     

Polyamine uptake in carrot cell cultures

Putrescine and spermidine uptake into carrot (Daucus carota L.) cells in culture was studied. The time course of uptake showed that the two polyamines were very quickly transported into the cells, reaching a maximum absorption within 1 minute. Increasing external polyamine concentrations up to 100 millimolar showed the existence of a biphasic system with different affinities at low and high polyamine concentrations. The cellular localization of absorbed polyamines was such that a greater amount of putrescine was present in the cytoplasmic soluble fraction, while spermidine was mostly present in cell walls. The absorbed polyamines were released into the medium in the presence of increasing external concentrations of the corresponding polyamine or Ca²⁺. The effects of Ca²⁺ were different for putrescine and spermidine; putrescine uptake was slightly stimulated by 10 micromolar Ca²⁺ and inhibited by higher concentrations, while for spermidine uptake there was an increasing stimulation in the Ca²⁺ concentration range between 10 micromolar and 1 millimolar. La³⁺ nullified the stimulatory effect of 10 micromolar Ca²⁺ on putrescine uptake and that of 1 millimolar Ca²⁺ on spermidine uptake. La³⁺ at 0.5 to 1 millimolar markedly inhibited the uptake of both polyamines, suggesting that it interferes with the sites of polyamine uptake. Putrescine uptake was affected to a lesser extent by metabolic inhibitors than was spermidine uptake. It is proposed that the entry of polyamines into the cells is driven by the transmembrane electrical gradient, with a possible antiport mechanism between external and internal polyamine molecule.     

Identification of Functional Amino Acid Residues Involved in Polyamine and Agmatine Transport by Human Organic Cation Transporter 2

Polyamine (putrescine, spermidine and spermine) and agmatine uptake by the human organic cation transporter 2 (hOCT2) was studied using HEK293 cells transfected with pCMV6-XL4/hOCT2. The Km values for putrescine and spermidine were 7.50 and 6.76 mM, and the Vmax values were 4.71 and 2.34 nmol/min/mg protein, respectively. Spermine uptake by hOCT2 was not observed at pH 7.4, although it inhibited both putrescine and spermidine uptake. Agmatine was also taken up by hOCT2, with Km value: 3.27 mM and a Vmax value of 3.14 nmol/min/mg protein. Amino acid residues involved in putrescine, agmatine and spermidine uptake by hOCT2 were Asp⁴²⁷, Glu⁴⁴⁸, Glu⁴⁵⁶, Asp⁴⁷⁵, and Glu⁵¹⁶. In addition, Glu⁵²⁴ and Glu⁵³⁰ were involved in putrescine and spermidine uptake activity, and Glu⁵²⁸ and Glu⁵⁴⁰ were weakly involved in putrescine uptake activity. Furthermore, Asp⁵⁵¹ was also involved in the recognition of spermidine. These results indicate that the recognition sites for putrescine, agmatine and spermidine on hOCT2 strongly overlap, consistent with the observation that the three amines are transported with similar affinity and velocity. A model of spermidine binding to hOCT2 was constructed based on the functional amino acid residues.     

Polyamine depletion induces enhanced synthesis and accumulation of cadaverine in cultured Ehrlich ascites carcinoma cells

An exposure of cultured Ehrlich ascites carcinoma cells to DL-α-difluoromethyl ornithine, an irreversible inhibitor of ornithine decarboxylase (EC 4.1.1.17), rapidly depleted the tumor cells of putrescine and spermidine. The decrease in the cellular concentrations of these two natural polyamines, however, was accompanied by a striking appearance of two new major amines: cadaverine and a compound tentatively identified as N-3-aminopropyl-1,5-diaminopentane (aminopropylcadaverine). When the cultures were grown in the presence of uniformly labeled [¹⁴C]lysine, tumor cells exposed to difluoromethyl ornithine converted lysine to cadaverine and aminopropyl cadaverine at strikingly enhanced rate. The difluoromethyl ornithine-induced accumulation and synthesis of cadaverine and aminopropylcadaverine were totally prevented by the presence of micromolar concentrations of spermidine (or spermine) in the culture media.     

Polyamine metabolism in ripening tomato fruit : I. Identification of metabolites of putrescine and spermidine

The metabolism of [1,4-¹⁴C]putrescine and [terminal methylene-³H]spermidine was studied in the fruit pericarp (breaker stage) discs of tomato (Lycopersicon esculentum Mill.) cv Rutgers, and the metabolites identified by high performance liquid chromatography and gas chromatography-mass spectrometry. The metabolism of both putrescine and spermidine was relatively slow; in 24 hours about 25% of each amine was metabolized. The ¹⁴C label from putrescine was incorporated into spermidine, γ-aminobutyric acid (GABA), glutamic acid, and a polar fraction eluting with sugars and organic acids. In the presence of gabaculine, a specific inhibitor of GABA:pyruvate transaminase, the label going into glutamic acid, sugars and organic acids decreased by 80% while that in GABA increased about twofold, indicating that the transamination reaction is probably a major fate of GABA produced from putrescine in vivo. [³H]Spermidine was catabolized into putrescine and β-alanine. The conversion of putrescine into GABA, and that of spermidine into putrescine, suggests the presence of polyamine oxidizing enzymes in tomato pericarp tissues. The possible pathways of putrescine and spermidine metabolism are discussed.     

Association of putrescine,spermidine, spermine,and GABA with structural elements of brain cells

The present experiments are the first survey of the association of endogenous and exogenous putrescine, spermidine, and spermine with subcellular structures of rat brain cortex. The differences of distribution in subfractions obtained from salt-free and salt-containing density gradients were studied, with the following results: (1) In contrast with liver preparation, putrescine and the polyamines spermidine and spermine are not distributed in parallel with RNA. (2) In salt-containing media, putrescine and the polyamines were preferentially associated with synaptosomes and with synaptosomal membranes. Significant association with myelin constituents was observed only in salt-free media. (3) Exogenous putrescine and the polyamines were less firmly attached to synaptosomes and to synaptosomal membrane fractions than the endogenous amines. There is good evidence for similar subcellular localizations of putrescine and GABA. Putrescine seems to be entrapped in the nerve endings. (4) Uptake studies with crude mitochondria under conditions of high-affinity uptake showed no temperature-sensitive component of polyamine accumulation in synaptosomes, in contrast with GABA, monoacetylputrescine, and ornithine. (5) Polyamines bound to myelin constituents or mitochondria could be displaced by a 200-fold concentration of nonradioactive amines; this was not the case with polyamines bound to synaptosomes. Mg²⁺ did not effectively compete with spermine for binding sites at synaptic regions. (6) Electrical stimulation and stimulation by mono- and bivalent cations did not change the concentrations of the polyamines and GABA in guinea pig cortex. (7) There is no evidence for a neurotransmitter role of putrescine, spermidine, or spermine, although these compounds might function as modulators of neurotransmission.     

Changes in polyamine metabolism in WI38 cells stimulated to proliferate.

Quiescent confluent monolayers of WI38 human diploid fibroblasts were stimulated to proliferate by replacement of the exhausted medium with fresh medium containing 10% fetal calf serum. The cellular content of the polyamines, putrescine, spermidine, and spermine was studied at various intervals after the nutritional change. The putrescine content increased during the pre-replicative phase of the cell cycle, whereas the content of spermidine and spermine did not increase until after the initiation of DNA synthesis. By varying the composition of the stimulating medium it was possible to alter the percentage of cells that were stimulated to proliferate. Measurement of the cellular polyamine content and ³H-thymidine (³H-TdR) incorporation into DNA at the time of the maximal rate of DNA synthesis showed that the magnitude of putrescine accumulation depended on the percentage of cells that were stimulated to proliferate. These results indicate that there may be a connection between polyamine synthesis and subsequent DNA replication.     

Occurrence of spermine in chromatin of Zea mays

Chromatin prepared from maize shoot tips using as extraction medium including quinacrine as an inhibitor of polyamine oxidase, contained 1.6 pmol spermidine g DNA^-1 and 14.8 pmol spermine g DNA^-1, respectively. This represented 0.1% spermidine and 3.7% spermine as compared with the content of those amines in the whole tissue. No putrescine was detectable in the chromatin preparation. When contamination of polyamines in the preparation was determined by the addition of labeled polyamines to the extraction medium, the ratio of the polyamines in the preparation to those in the extraction medium was 0.1% spermidine and 0.7% spermine, respectively. Spermine in the chromatin preparation was almost fully solubilized by a DNase-treatment, but spermidine was less easily solubilized. Most of the spermine associated with the chromation is chromatin-specific.     

Synthesis and Content of Polyamines in Bloodstream Trypanosoma brucei*

SYNOPSIS. The sensitive dansyl procedure was used to detect putrescine and spermidine, but not spermine and cadaverine, in pleomorphic Trypanosoma brucei. The polyamines were synthesized in vitro from [³H]ornithine, [¹⁴C]arginine and [¹⁴C]methionine. Proline, agmatine, and citrulline, but not glutamine, glutamic or pyroglutamic acids, stimulated spermidine formation from [¹⁴C]methionine. Putrescine and spermidine synthesis occurred rapidly from ornithine: putrescine synthesis peaked in 0.5 h, spermidine in 1 h. Trypanosoma brucei assimilated exogenous ¹⁴C-labeled putrescine, spermidine, and spermine; spermidine and spermine were taken up 5 times as rapidly as putrescine. Polyamine syntheses may therefore be a practical target for novel trypanocies.     

Polyamines in type 5 adenovirus-infected cells and virions

The incorporation of l-[¹⁴C]ornithine and [¹⁴C]putrescine into putrescine, spermidine, and spermine in type 5 adenovirus-infected KB cells was identical to that in uninfected control cells early in infection, but incorporation into putrescine stopped after 8 to 12 h and the rate of incorporation into spermidine was reduced between 12 and 20 h after infection. The amount of polyamines found associated with purified virus could neutralize a maximum of 3 to 4% of the virus DNA, but the small quantities of polyamines detected could not be distinguished from nonspecific binding of polyamines to virions. These data suggest that polyamines are probably not integral components of adenovirus particles.     

Covalent incorporation of polyamines as γ-glutamyl derivatives into CHO cell protein

The possible role of polyamines in the covalent modification of proteins in CHO cells was investigated by metabolic labeling with [³H]putrescine. A single radiolabeled protein band with an apparent relative molecular mass of 18 000 Da was observed by SDS-polyacrylamide gel electrophoresis. Almost all the radioactivity covalently linked to this protein was recovered as hypusine. The labeling of this protein was increased several-fold when cells were cultured with α-difluoromethylornithine (DFMO) or with this drug plus methylglyoxal bis(guanylhydrazone) (MGBG), as a result of increase in specific radioactivity of the hypusine immediate precursor, spermidine. Also labeled under the latter condition were other cellular proteins. These were aggregates on the top both of the stacking gel and of the running gel, and protein-like materials with relative molecular masses of 36 and 8 kDa. The radioactivity covalently associated with these proteins was recovered after acid hydrolofsis as polyamines. The identification of γ-glutamylputrescine and γ-glutamylspermidines in proteolytic digests of the acid-insoluble fraction of treated cells indicates that polyamines are covalently linked to these cellular protein. Several possible cellular functions of γ-glutamylpolyamine protein components are discussed.     

Metabolism of polyamines in mouse neuroblastoma cells in culture: formation of GABA and putreanine.

—Polyamine metabolism of mouse neuroblastoma cells grown in culture was studied with special reference to the synthesis of GABA from putrescine and putreanine from spermidine. This study shows that neuroblastoma cells in the presence of a complete culture medium containing calf serum readily metabolized [¹⁴C]putrescine to GABA; the rate of synthesis is similar to the rate of synthesis of spermidine from putrescine. In the absence of serum the conversion of putrescine to GABA is minimal. In the presence of serum GABA formation is completely inhibited by the diamine oxidase inhibitor aminoguanidine. GABA synthesis does not occur in the absence of cells. The GABA synthesized is not readily metabolized to succinate or homocarnosine. Mouse neuroblastoma cells metabolized [¹⁴C]ornithine to putrescine, GABA, and spermidine. Spermidine was metabolized to putrescine, putreanine and spermine.     

Feedback regulation of polyamine synthesis in Ehrlich ascites tumor cells. Analysis using nonmetabolizable derivatives of putrescine and spormine

Ornithine decarboxylase (ODC) is subject to feedback regulation by the polyamines. Thus, addition of putrescine, spermidine or spermine to cells causes inhibition of ODC mRNA translation. Putrescine and spermine are readily converted into spermidine. Therefore, it is conceivable that the inhibition of ODC synthesis observed in putrescine- and spermine-supplemented cells is instead an effect of spermidine. To examine this possibility we have used two analogs of putrescine and spermine, namely 1,4-dimethylputrescine and 5,8-dimethylspermine, which cannot be converted into spermidine. Both analogs were found to inhibit the incorporation of [³⁵S]methionine into ODC protein to approximately the same extent, suggesting that putrescine as well as spermine exert a negative feedback control of ODC mRNA translation in the cell. In addition to suppressing ODC synthesis, both analogs were found to increase the turnover rate of the enzyme. 5,8-Dimethylspermine caused a marked decrease in the activity of S-adenosylmethionine decarboxylase (AdoMetDC). This effect was not obtained with 1,4-dimethylputrescine, indicating that spermine, but not putrescien, exerts a negative control of AdoMetDC. Treatment with 1,4-dimethylputrescine caused extensive depletion of the cellular putrescine and spermidine content, but accumulation of spermine. 5,8-Dimethylspermine treatment, on the other hand, effectively depleted the spermine content and had less effect on the putrescine and spermidine content, at least initially. Nevertheless, the total polyamine content was more extensively reduced by treatment with 5,8-dimethylspermine than with 1,4-dimethylputrescine. Accordingly, only 5,8-dimethylspermine treatment exerted a significant inhibitory effect on Ehrlich ascites tumor cell growth.     

Catabolism of polyamines in the rat: Polyamines and their non-α-amino acid metabolites

The metabolic fate of stable isotopically labeled polyamines was investigated after their first and second intraperitoneal injection in rats. Using gas chromatographic and mass fragmentographic analyses of acid-hydrolyzed 24-h urines, some aspects of the polyamine metabolism could be elucidated. After the injections with hexadeutero-1,3-diaminopropane, obly labeled 1,3-diaminopropane was recovered from the urine samples. The rat injected with tetradeuteroputrescine excreted labeled putrescine excreted labeled putrescine, γ-amino-n-butyric acid, 2-hydroxyputrescine and spermidine, while the urine samples of the rat after the injections with tetradeuterocadaverine contained labeled cadaverine and δ-aminovaleric acid. The injections of hexadeuterospermidine led to the appearance of labeled spermidine, isoputreanine, putreanine, N-(2-carboxyethyl)-4-amino-n-butyric acid, putrescine, γ-amino-n-butyric acid, 1,3-diaminopropane, β-alanine and spermine. After the injections with octadeuterospermine, labeled spermine, N-(3-aminopropyl)-N′-(2-carboxyethyl)-1,4-diaminobutane, N,N′-bis(2-carboxyethyl)-1,4-diaminobutane, spermidine, isoputreanine, putreanine, N-(2-carboxyethyl)-4-amino-n-butyric acid, putrescine, 1,3-diaminopropane, β-alanine, 2-hydroxyputrescine and possibly γ-amino-n-butyric acid were recovered. Clear differences between the metabolism after the first and second injection were noted for putrescine, spermidine and spermine, which is suggestive for enzyme induction and/or the existence of salvage pathways.     

The synthesis and turnover of spermidine and spermine in mouse brain

Following the administration to mice of radiolabeled putrescine by intraventricular injection, changes in the specific radioactivity of putrescine, spermidine, and spermine have been measured. Putrescine decline was biphasic, being more rapid over the first 12 hr(t _1/2=5 hr) than over the remainder of the 48-hr period (t _1/2=11 hr) that significant labeling was detected. Spermidine was rapidly labeled during the decline in putrescine radioactivity and maximum incòrporation of label occurred at 18 hr. Subsequently, spermidine specific activity declined with a half-life of 22 days. Spermine synthesis was slower, with maximum labeling occurring after 4 days. Spermine turnover, measured at a time when spermidine radioactivity had substantially declined, was extremely slow (t _1/2=92 days). The data supports the view that putrescine is a precursor of spermidine which in turn is required for spermine synthesis.     

Metabolism and axonal transport of polyamines in a single identified neuron of Aplysia californica

Abstract: The metabolism of polyamines was investigated by injecting purified [³H]putrescine directly into the soma of the giant neuron R2 of Aplysia . Injected putrescine was rapidly metabolized to spermidine, spermine, and several catabolites, including GABA and monoacetylputrescine. Identification of these products was by comparison with the authentic compound using ion exchange chromatography. When R2 was injected with amounts of [³H]putrescine determined so that the intracellular content of labeled precursor was less than 6 × 10-⁶ M , metabolism was rapid and occurred via pathways similar to those in mammalian tissues. At concentrations of labeled precursor greater than 2 × 10⁻⁴ M , relatively little putrescine was converted to product. By 4 h after injection, putrescine and its labeled products appeared in R2's axon, where additional metabolism occurred. These results indicated that the enzymes involved in polyamine interconversion are not restricted to R2's cell body, and this suggestion was corroborated by finding ornithine decarboxylase and S -adenosylmethionine decarboxylase activities in Aplysia nerves. The distribution of the polyamines along R2's axon was compared with that of ³H-glycoproteins, with the finding that while the acid-soluble polyamines move by diffusion, labeled polyamines associated with protein are rapidly transported.