Neuroprotective offerings by agmatine.

Agmatine, an endogenous polyamine in CNS, is derived from arginine by dearboxylation. Like polyamines, agmatine has been studied for its neuroprotetive effects. At present, a large body of experimental evidences has been gathered that demonstrate the neuroprotective effects of agmatine. The neuroprotective effects have been observed in various CNS cell lines and animal models against the excitotocity, oxidative damage, corticosteroidid induced neurotoxicity, ischemic/hypoxic or oxygen-glucose deprivation toxicity, spinal cord injury and traumatic brain injury. The studies have been extended to rescue of retinal ganglion cells from toxicities. The mechanistic studies suggest that neuroprotection offered by agmatine can be assigned to its multimolecular biological effects. These include its action as glutamatergic receptor antagonist, α2-adrenoceptor agonist, imidazoline binding site ligand, NOS inhibitor, ADP ribosylation inhibitor, and blocker of ATP-sensitive potassium and voltage-gated calcium channels, anti-apoptotic and antioxidant. Its action as regulator for polyamine synthesis, insulin release assists the neuroprotection. The cumulative evidences of preclinical studies support the possible use of agmatine as an agent for neuronal damage and neurodegenerative diseases. However, it will be hasty to assert and promote agmatine as a novel therapeutic agent for neuroprotection. The review is focused on the role of agmatine in different types and mechanisms of neural injuries. The aspects of concern like dose range, pharmacokinetics of exogenous agmatine, levels of endogenous agmatine during events of injury etc. has to be addressed.

Agmatine attenuates chronic unpredictable mild stress-induced anxiety, depression-like behaviours and cognitive impairment by modulating nitrergic signalling pathway.

Agmatine, a neurotransmitter/neuromodulator, has shown to exert numerous effects on the CNS. Chronic stress is a risk factor for development of depression, anxiety and deterioration of cognitive performance. Compelling evidences indicate an involvement of nitric oxide (NO) pathway in these disorders. Hence, investigation of the beneficial effects of agmatine on chronic unpredictable mild stress (CUMS)-induced depression, anxiety and cognitive performance with the involvement of nitrergic pathway was undertaken. Mice were subjected to a battery of stressors for 28days. Agmatine (20 and 40mg/kg, i.p.) alone and in combination with NO modulators like L-NAME (15mg/kg, i.p.) and l-arginine (400mg/kg i.p.) were administered daily. The results showed that 4-weeks CUMS produces significant depression and anxiety-like behaviour. Stressed mice have also shown a significant high serum corticosterone (CORT) and low BDNF level. Chronic treatment with agmatine produced significant antidepressant-like behaviour in forced swim test (FST) and sucrose preference test, whereas, anxiolytic-like behaviour in elevated plus maze (EPM) and open field test (OFT) with improved cognitive impairment in Morris water maze (MWM). Furthermore, agmatine administration reduced the levels of acetylcholinesterase and oxidative stress markers. In addition, agmatine treatment significantly increased the BDNF level and inhibited serum CORT level in stressed mice. Treatment with L-NAME (15mg/kg) potentiated the effect of agmatine whereas l-arginine abolished the anxiolytic, antidepressant and neuroprotective effects of agmatine. Agmatine showed marked effect on depression and anxiety-like behaviour in mice through nitrergic pathway, which may be related to modulation of oxidative-nitrergic stress, CORT and BDNF levels.

Chronic agmatine treatment prevents behavioral manifestations of nicotine withdrawal in mice.

Smoking cessation exhibits an aversive withdrawal syndrome characterized by both increases in somatic signs and affective behaviors including anxiety and depression. In present study, abrupt withdrawal of daily nicotine injections (2mg/kg, s.c., four times daily, for 10 days) significantly increased somatic signs viz. rearing, grooming, jumping, genital licking, leg licking, head shakes with associated depression (increased immobility in forced swim test) as well as anxiety (decreased the number of entries and time spent in open arm in elevated plus maze) in nicotine dependent animals. The peak effect was observed at 24h time point of nicotine withdrawal. Repeated administration of agmatine (40-80µg/mouse, i.c.v.) before the first daily dose of nicotine from day 5 to 10 attenuated the elevated scores of somatic signs and abolished the depression and anxiety like behavior induced by nicotine withdrawal in dependent animals. However, in separate groups, its acute administration 30min before behavior analysis of nicotine withdrawal was ineffective. This result clearly shows the role of agmatine in development of nicotine dependence and its withdrawal. In extension to behavioral experiments, brain agmatine analyses, carried out at 24h time point of nicotine withdrawal demonstrated marked decrease in basal brain agmatine concentration as compared to control animals. Taken together, these data support the role of agmatine as common biological substrate for somatic signs and affective symptoms of nicotine withdrawal. This data may project therapies based on agmatine in anxiety, depression and mood changes associated with tobacco withdrawal.

The molecular and metabolic influence of long term agmatine consumption.

Agmatine (AGM), a product of arginine decarboxylation, influences multiple physiologic and metabolic functions. However, the mechanism(s) of action, the impact on whole body gene expression and metabolic pathways, and the potential benefits and risks of long term AGM consumption are still a mystery. Here, we scrutinized the impact of AGM on whole body metabolic profiling and gene expression and assessed a plausible mechanism(s) of AGM action. Studies were performed in rats fed a high fat diet or standard chow. AGM was added to drinking water for 4 or 8 weeks. We used (13)C or (15)N tracers to assess metabolic reactions and fluxes and real time quantitative PCR to determine gene expression. The results demonstrate that AGM elevated the synthesis and tissue level of cAMP. Subsequently, AGM had a widespread impact on gene expression and metabolic profiling including (a) activation of peroxisomal proliferator-activated receptor-α and its coactivator, PGC1α, and (b) increased expression of peroxisomal proliferator-activated receptor-γ and genes regulating thermogenesis, gluconeogenesis, and carnitine biosynthesis and transport. The changes in gene expression were coupled with improved tissue and systemic levels of carnitine and short chain acylcarnitine, increased ß-oxidation but diminished incomplete fatty acid oxidation, decreased fat but increased protein mass, and increased hepatic ureagenesis and gluconeogenesis but decreased glycolysis. These metabolic changes were coupled with reduced weight gain and a curtailment of the hormonal and metabolic derangements associated with high fat diet-induced obesity. The findings suggest that AGM elevated the synthesis and levels of cAMP, thereby mimicking the effects of caloric restriction with respect to metabolic reprogramming.

Additive anticonvulsant effects of agmatine and lithium chloride on pentylenetetrazole-induced clonic seizure in mice: involvement of α2-adrenoceptor.

After 60 years, lithium is still the mainstay in the treatment of mood disorders and widely used in clinic. In addition to its mood stabilizer effects, lithium also shows some anticonvulsant properties. Similar to lithium, agmatine also plays a protective role in the CNS against seizures and has been reported to enhance the effect of different antiepileptic agents. Moreover, both agmatine and lithium have modulatory effects on α(2)-adrenoceptors. So, we designed this study: 1) to investigate whether agmatine and lithium show an additive effect against clonic seizures induced by pentylenetetrazole; 2) to assess whether this additive effect is mediated through the α(2)-adrenoceptor or not. In our study, acute administration of a single effective dose of lithium chloride (30 mg/kg, i.p.) increased the seizure threshold. Pre-treatment with low and, per se, non-effective doses of agmatine (1 and 3mg/kg) potentiated a sub-effective dose of lithium (10mg/kg). Interestingly, the anticonvulsant effects of these effective combinations of lithium and agmatine were prevented by pre-treatment with low and non-effective doses of yohimbine [α(2)-adrenoceptor antagonist] (0.1 and 0.5mg/kg). On the other hand, clonidine [α(2)-adrenoceptor agonist] augmented the anticonvulsant effect of a sub-effective combination of lithium (5mg/kg i.p.) and agmatine (1mg/kg) at relatively low doses (0.1 and 0.25mg/kg). In summary, our findings demonstrate that agmatine and lithium chloride exhibit additive anticonvulsant properties which seem to be mediated through α(2)-adrenoceptor.

Odorant responsiveness of squid olfactory receptor neurons.

In the olfactory organ of the squid, Lolliguncula brevis there are five morphological types of olfactory receptor neurons (ORNs). Previous work to characterize odor sensitivity of squid ORNs was performed on only two of the five types in dissociated primary cell cultures. Here, we sought to establish the odorant responsiveness of all five types. We exposed live squid or intact olfactory organs to excitatory odors plus the activity marker, agmatine (AGB), an arginine derivative that enters cells through nonselective cation channels. An antibody against AGB was used to identify odorant-activated neurons. We were able to determine the ORN types of AGB-labeled cells based on their location in the epithelium, morphology and immunolabeling by a set of metabolites: arginine, aspartate, glutamate, glycine, and glutathione. Of 389 neurons identified from metabolite-labeled tissue, 3% were type 1, 32% type 2, 33% type 3, 15% type 4, and 17% type 5. Each ORN type had different odorant specificity with type 3 cells showing the highest percentages of odorant-stimulated AGB labeling. Type 1 cells were rare and none of the identified type 1 cells responded to the tested odorants, which included glutamate, alanine and AGB. Glutamate is a behaviorally attractive odorant and elicited AGB labeling in types 2 and 3. Glutamate-activated AGB labeling was significantly reduced in the presence of the adenylate cyclase inhibitor, SQ22536 (80 microM). These data suggest that the five ORN types differ in their relative abundance and odor responsiveness and that the adenylate cyclase pathway is involved in squid olfactory transduction.

Agmatine enhances the anticonvulsant action of phenobarbital and valproate in the mouse maximal electroshock seizure model.

Accumulating evidence indicates that agmatine (AGM--an endogenous neuromodulator/neurotransmitter in the brain) exerts the anticonvulsant action in various in vivo experiments. Therefore, the aim of this study was to assess the influence of AGM on the protective action of numerous conventional and newer antiepileptic drugs [carbamazepine (CBZ), lamotrigine (LTG), oxcarbazepine (OXC), phenobarbital (PB), phenytoin (PHT), topiramate (TPM) and valproate (VPA)] in the mouse maximal electroshock seizure (MES) model. Results indicate that AGM (up to 100 mg/kg, i.p., 45 min before the test) neither altered the threshold for electroconvulsions nor protected the animals against MES-induced seizures in mice. Moreover, AGM (100 mg/kg, i.p.) significantly enhanced the anticonvulsant effects of PB and VPA in the MES test by reducing their ED50 values from 22.54 to 16.82 mg/kg (P < 0.01) for PB, and from 256.1 to 210.6 mg/kg (P < 0.05) for VPA, respectively. In contrast, AGM at 100 mg/kg (i.p.) had no significant effect on the antielectroshock action of the remaining drugs tested (CBZ, LTG, OXC, PHT, and TPM) in mice. Estimation of total brain PB and VPA concentrations revealed that the observed interactions between AGM and PB or VPA in the MES test were pharmacodynamic in nature because neither total brain PB, nor total brain VPA concentrations were altered after i.p. administration of AGM at 100 mg/kg. Moreover, none of the examined combinations of AGM (100 mg/kg) with CBZ, LTG, OXC, PB, PHT, TPM, and VPA (at their ED50 values from the MES test) affected motor coordination in the chimney test, long-term memory in the passive avoidance task, and muscular strength in the grip-strength test in mice, indicating no acute adverse effects in animals. In conclusion, one can ascertain that the selective potentiation of the antielectroshock action of PB and VPA by AGM, lack of any pharmacokinetic interactions between drugs and no acute adverse effects, make the combinations of AGM with PB or VPA of pivotal importance for epileptic patients. It seems that modulation of AGM concentration in the brain may occur favorable in further clinical practice.

Antinociceptive interactions of triple and quadruple combinations of endogenous ligands at the spinal level.

A very interesting and rapidly developing field of pain research is related to the roles of different endogenous ligands. This study determined the antinociceptive interactions of triple and quadruple combinations of different endogenous ligands (endomorphin-1, adenosine, agmatine and kynurenic acid) on carrageenan-induced inflammatory pain model at the spinal level. Intrathecal infusion (60 min) of these drugs alone, in double, triple or quadruple combinations, was followed by a 60-min observation period. During the infusion, antihyperalgesic effect of 0.3 microg/min endomorphin-1 was higher in the triple combinations than those in the double combinations. After cessation of drug administration, only the combination of 0.3 microg/min endomorphin-1, 1 microg/min agmatine, and 0.3 microg/min adenosine was more effective than the double combinations. In quadruple combinations, the antinociceptive effects of both 0.1 and 0.3 microg/min endomorphin-1 were significantly potentiated by the otherwise ineffective triple combination of adenosine, agmatine, and kynurenic acid. No side effects could be observed at these doses. These results demonstrate that triple and quadruple combinations of these endogenous ligands caused more effective antihyperalgesia compared with double combinations. Accordingly, the doses of these substances could be further reduced, thus, reinforcing the view that complex activation and/or inhibition of different systems can be sufficiently effective in blocking nociception without adverse effects. Because all of these drugs had effects on various receptors and systems, the possible types of these interactions were discussed.

Prevailingly cationic agmatine-based amphoteric polyamidoamine as a nontoxic, nonhemolytic, and "stealthlike" DNA complexing agent and transfection promoter.

AGMA1, a prevailingly cationic amphoteric polyamidoamine obtained by polyaddition of (4-aminobutyl)guanidine (agmatine) to 2,2-bis(acrylamido)acetic acid, was studied as a potential DNA carrier and transfection promoter. Fluorescein-labeled AGMA1 was prepared by conjugation with fluorescein isothiocyanate and its cell uptake, blood permanence, and body distribution studied. In spite of its cationic character, AGMA1 is neither toxic nor hemolytic in the pH range 4.0-7.4, circulates for a long time in the blood without preferentially localizing in the liver, easily enters HT-29 cells, gives stable complexes with DNA, and is endowed with good transfection efficiency, suggesting the ability to transport in the cytoplasm a DNA payload without any measurable membranolytic activity. If compared with other transfection promoters, including polyamidoamines of different structures, AGMA1 is apparently endowed with a unique combination of desirable requirements for a nonviral DNA polymer carrier and warrants potential as a transfection agent in vivo.

Release of tritiated agmatine from spinal synaptosomes.

Intrathecal agmatine (decarboxylated arginine) moderates induction of neuropathic pain, spinal cord injury, and opioid tolerance in rodents. An endogenous central nervous system molecule and N-methyl-D-aspartate receptor antagonist/nitric oxide synthase inhibitor, agmatine may be a neuromodulator. We evaluated depolarization-induced release of agmatine from purified spinal nerve terminals (synaptosomes). Agmatine immunoreactivity was observed colocalized or closely apposed to some synaptophysin- and/or synaptotagmin-labeled structures. A temperature- and concentration-dependent uptake of [3H]-agmatine into synaptosomes was observed, consistent with an uptake mechanism. Potassium-induced depolarization resulted in release of [3H]-agmatine from the synaptosomes in a Ca2+-dependent manner, consistent with a neuromodulatory function. These results agree with previous reports of agmatine uptake into synaptosomes of the brain and extend those results to include stimulated release and a spinal site of activity.

Synthesis and analgesic activity evaluation of some agmatine derivatives.

A series of N,N'-disubstituted-2-nitroethene-1,1-diamine and N,N'-disubstituted- N''-cyanoguanidine derivatives were prepared and evaluated for in vivo analgesic activity. The blood brain barrier (BBB) VolSurf model was used to predict the BBB permeation profiles of our synthesized compounds. Some compounds show both remarkable analgesic activity and good BBB permeation profiles, and these compounds might be developed for treatment of opioid tolerance and dependence.

Excitation mapping with the organic cation AGB2+.

Excitation mapping is a method of visualizing the signaling history of neurons with permeant organic cations. It is compatible with high-resolution imaging, allowing concurrent visualization of all neuronal classes and their glutamate-gated excitation histories. Excitation mapping documents the stability and precision of neuronal signaling within a given neuronal class, arguing that single unit electrophysiological sampling accurately reflects neuronal diversity. We here review the theory of excitation mapping, provide methods and protocol links; outline imaging concepts; provide parametric data on the temporal range and physiological sensitivity of excitation mapping; and show that immunocytochemical methods for macromolecules are compatible with excitation mapping.

Effects of agmatine accumulation in human colon carcinoma cells on polyamine metabolism, DNA synthesis and the cell cycle.

Putrescine, spermidine and spermine are low molecular polycations that play important roles in cell growth and cell cycle progression of normal and malignant cells. Agmatine (1-amino-4-guanidobutane), another polyamine formed through arginine decarboxylation, has been reported to act as an antiproliferative agent in several non-intestinal mammalian cell models. Using the human colon adenocarcinoma HT-29 Glc(-/+) cell line, we demonstrate that agmatine, which markedly accumulated inside the cells without being metabolised, exerted a strong cytostatic effect with an IC50 close to 2 mM. Agmatine decreased the rate of L-ornithine decarboxylation and induced a 70% down-regulation of ornithine decarboxylase (ODC) expression. Agmatine caused a marked decrease in putrescine and spermidine cell contents, an increase in the N1-acetylspermidine level without altering the spermine pool. We show that agmatine induced the accumulation of cells in the S and G2/M phases, reduced the rate of DNA synthesis and decreased cyclin A and B1 expression. We conclude that the anti-metabolic action of agmatine on HT-29 cells is mediated by a reduction in polyamine biosynthesis and induction in polyamine degradation. The decrease in intracellular polyamine contents, the reduced rate of DNA synthesis and the cell accumulation in the S phase are discussed from a causal perspective.

Acute and subchronic effects of agmatine on anxiety tested in the elevated plus maze in male mice / Efectos de la administración aguda y subcrónica de agmatina sobre la ansiedad evaluada en el test del laberinto elevado en cruz en ratones machos (AU)

Agmatine is an endogenous polyamine, identified in mammalian brain, which meets the main criteria to be considered a neurotransmitter. Agmatine-like immunoreactivity has been described in numerous brain regions which have long been implicated in the regulation of anxiety. However, animal preclinical studies investigating effects of agmatine on anxiety are unclear. In this study, an attempt was made to clarify the actions of agmatine (7.5-60 mg/kg, ip) on anxiety tested in the elevated plus maze mice.Moreover, the possible development of tolerance to the effects of agmatine on anxiety after its subchronic administration for 7 consecutive days was also examined. A number of classical parameters were collected (open arm duration and frequency, closed arm duration and frequency and central platform duration and frequency). Different ethological measures were also obtained (rearings, head dipping and stretched attend posture). Results showed that agmatine did not produce any significant behavioural change in any of the parameters examined, suggesting that it might not be involved in the regulation of anxiety in mice (AU)

La agmatina es una poliamina endógena, identificada en el cerebro de mamíferos, que cumple los principales criterios para ser considerada un neurotransmisor. Se ha descrito inmunorreactividad a la agmatina en numerosas regiones cerebrales tradicionalmente implicadas en la regulación de la ansiedad. Sin embargo, los estudios preclínicos con animales de experimentación que han investigado los efectos de la agmatina sobre la ansiedad no son concluyentes. Este trabajo representa un intento por clarificar las acciones de la agmatina (7.5-60mg/kg, ip) sobre la ansiedad evaluada en el laberinto elevado en cruz en ratones. Asimismo, se examinó también el posible desarrollo de tolerancia a sus efectos sobre la ansiedad tras administración subcrónica durante siete días consecutivos. Se analizaron parámetros clásicos (frequencia y duración en brazos abiertos, cerrados y en la plataforma central del laberinto, así como diferentes medidas etológicas («rearings», «head-dipping» y «stretched at tent posture»). Los resultados mostraron que la agmatinano produjo ningún cambio significativo en ninguno de los parámetros examinados, sugiriendo que podría no estar involucrada en la regulación de la ansiedad en ratones (AU)

Pharmacodynamic and pharmacokinetic studies of agmatine after spinal administration in the mouse.

Agmatine is an endogenous decarboxylation product of arginine that has been previously shown to antagonize the N-methyl-d-aspartate (NMDA) receptor and inhibit nitric-oxide synthase. Many neuropharmacological studies have shown that exogenous administration of agmatine prevents or reverses biological phenomena dependent on central nervous system glutamatergic systems, including opioid-induced tolerance, opioid self-administration, and chronic pain. However, the central nervous system (CNS) pharmacokinetic profile of agmatine remains minimally defined. The present study determined the spinal cord pharmacokinetics and acute pharmacodynamics of intrathecally administered agmatine in mice. After a single bolus intrathecal injection, agmatine concentrations in spinal cord (cervical, thoracic, and lumbosacral) tissue and serum were quantified by an isocratic high-performance liquid chromatography fluorescence detection system. Agmatine persisted at near maximum concentrations in all levels of the spinal cord for several hours with a half-life of approximately 12 h. Initial agmatine concentrations in serum were 10% those in CNS. However, the serum half-life was less than 10 min after intrathecal injection of agmatine, consistent with previous preliminary pharmacokinetic reports of systemically administered agmatine. The pharmacodynamic response to agmatine in the NMDA-nociceptive behavior and thermal hyperalgesia tests was assessed. Whereas MK-801 (dizocilpine maleate) inhibits these two responses with equal potency, agmatine inhibits the thermal hyperalgesia with significantly increased potency compared with the nociceptive behavior, suggesting two sites of action. In contrast to the pharmacokinetic results, the agmatine inhibition of both behaviors had a duration of only 10 to 30 min. Collectively, these results suggest the existence of a currently undefined agmatinergic extracellular clearance process in spinal cord.

Pharmacological characteristics of the specific transporter for the endogenous cell growth inhibitor agmatine in six tumor cell lines.

BACKGROUND AND AIMS: This study examined agmatine transport into six human intestinal tumor cell lines and compared the pharmacological properties of this transporter with those of the agmatine carrier previously characterized in human glioblastoma cells. METHODS: Carrier-mediated uptake was determined as specific accumulation of [(14)C]agmatine in the cells. The changes in intracellular agmatine concentration in the tumor cells after 24 h incubation with 1 mM agmatine was analyzed by high-performance liquid chromatography. RESULTS: Specific [(14)C]agmatine accumulation was found in the six human intestinal tumor cell lines Caco2, Cx1, Colo320, HT29, Colo205E, and SW480. Specific [(14)C]agmatine accumulation was inhibited by phentolamine, putrescine, spermine, clonidine, and decynium-22 but not by corticosterone, O-methylisoprenaline, or l-carnitine. Incubation with exogenous agmatine for 24 h increased intracellular agmatine content in all cell lines by a multiple of the basal endogenous content. Transfection of HEK293 cells with cDNA encoding either hOCT1, hOCT2, or hOCT3 did not enhance [(14)C]agmatine accumulation compared to nontransfected cells. CONCLUSION: All intestinal tumor cell lines investigated express a functional specific agmatine transporter which exhibit pharmacological characteristics similar to those of the agmatine transporter in glioblastoma cells. This agmatine carrier is not identical with any so far known organic cation transport system.

Agmatine is efficiently transported by non-neuronal monoamine transporters extraneuronal monoamine transporter (EMT) and organic cation transporter 2 (OCT2).

Agmatine has received considerable attention recently. Available evidence suggests that agmatine functions as a neurotransmitter and inhibits, via induction of antizyme, cellular proliferation. Because of its positive charge, agmatine will not appreciably cross cellular membranes by simple diffusion. Indeed, all physiological models require a channel or transporter protein in the plasma membrane to effect inactivation or nonexocytotic release of agmatine. However, a transport mechanism for agmatine has not been identified on a molecular level so far. In the present study, the non-neuronal monoamine transporters, organic cation transporter (OCT) 1, OCT2, and extraneuronal monoamine transporter (EMT) (gene symbols SLC22A1-A3), both from human and rat, were examined, stably expressed in 293 cells, for [(3)H]agmatine transport. Our results indicate that OCT2 and EMT, but not OCT1, efficiently translocate agmatine. The structural homolog putrescine was not accepted as substrate. Uptake of agmatine via EMT and OCT2 was saturable, with K(m) values of 1 to 2 mM. The affinity of OCT1 was 10-fold lower. Carrier-mediated efflux of agmatine was documented in a trans-stimulation experiment. Finally, uptake of agmatine increased dramatically with increasing pH. Thus, only the singly charged species of agmatine is accepted as substrate. In conclusion, both EMT and OCT2 must be considered for the control of agmatine levels in rat and human.

Neuropharmacokinetic and dynamic studies of agmatine (decarboxylated arginine).

Agmatine has been previously proposed to represent a novel neurotransmitter. One of the criteria required to test that hypothesis is that the exogenously administered chemical produces pharmacological effects similar to the physiological effects of the putative neurotransmitter. Since agmatine was first identified in brain, approximately sixty studies of the in vivo effects of exogenously administered agmatine have been reported. Despite the assertion that agmatine functions as a neuromodulator/neurotransmitter, the vast majority of experiments have administered agmatine through systemic (rather than central) routes of administration. Systemic delivery of agmatine for studies of centrally mediated phenomenon (e.g., pain, spinal cord injury, cardiovascular responses) relies on the presumption that agmatine (a polar compound) gains appreciable access to the CNS. The mechanism by which agmatine crosses the blood-brain barrier is not well understood. A number of studies have examined the in vivo effects of agmatine following central administration (e.g., intracerebroventricular and intrathecal). This paper summarizes and provides a comparison between the systemic versus central routes of administration for delivery of agmatine in experimental subjects.

Regulation of urea synthesis by agmatine in the perfused liver: studies with 15N.

Administration of arginine or a high-protein diet increases the hepatic content of N-acetylglutamate (NAG) and the synthesis of urea. However, the underlying mechanism is unknown. We have explored the hypothesis that agmatine, a metabolite of arginine, may stimulate NAG synthesis and, thereby, urea synthesis. We tested this hypothesis in a liver perfusion system to determine 1) the metabolism of l-[guanidino-15N2]arginine to either agmatine, nitric oxide (NO), and/or urea; 2) hepatic uptake of perfusate agmatine and its action on hepatic N metabolism; and 3) the role of arginine, agmatine, or NO in regulating NAG synthesis and ureagenesis in livers perfused with 15N-labeled glutamine and unlabeled ammonia or 15NH4Cl and unlabeled glutamine. Our principal findings are 1) [guanidino-15N2]agmatine is formed in the liver from perfusate l-[guanidino-15N2]arginine ( approximately 90% of hepatic agmatine is derived from perfusate arginine); 2) perfusions with agmatine significantly stimulated the synthesis of 15N-labeled NAG and [15N]urea from 15N-labeled ammonia or glutamine; and 3) the increased levels of hepatic agmatine are strongly correlated with increased levels and synthesis of 15N-labeled NAG and [15N]urea. These data suggest a possible therapeutic strategy encompassing the use of agmatine for the treatment of disturbed ureagenesis, whether secondary to inborn errors of metabolism or to liver disease.

Exposure of rat isolated stomach and rats in vivo to [(14)C]agmatine: accumulation in the stomach wall and distribution in various tissues.

The aims of the present study were: (i) to investigate the accumulation of radioactivity in the stomach wall after luminal exposure of the rat isolated stomach to[(14)C]agmatine and (ii) to determine the distribution of radioactivity in various tissues after oral administration of this radiolabelled polyamine to rats in vivo. In isolated rat stomach, [(14)C]agmatine was accumulated in part by an energy-dependent uptake process that could be inhibited by phentolamine. These findings correspond to properties of the recently identified specific agmatine transporter in human glioma cells, suggesting that in rat stomach [(14)C]agmatine is taken up by such a carrier. In in vivo experiments, rats received 0.5 microCi [(14)C]agmatine adsorbed to 5 g rat standard chow after a fasting period of 24 h. After oral ingestion of [(14)C]agmatine, radioactivity was recovered in all organs investigated as well as in blood and urine. Radioactivity also seemed to be secreted into the pancreaticobiliary fluid, as it was recovered in the luminal content of distal ileum and sigmoid colon. Accumulation of radioactivity in organs and distal gut luminal content was dose-dependently decreased by simultaneous administration of putrescine. In conclusion, the present data are compatible with the view that agmatine can be absorbed in rat at least from the stomach and probably also from the gut by means of an energy-dependent agmatine transport mechanism. Agmatine itself and/or its degradation products, which also have the potential to be pharmacologically active, are unevenly distributed between the organs. Putative secretion of radioactivity into the pancreaticobiliary fluid suggests the potential for an enterohepatic circulation of agmatine. In view of the high intraluminal concentration of agmatine in the stomach and distal gut and the operation of an agmatine transporter, it is rather likely that agmatine in the chyme of the gut represents an important source for agmatine detected in the tissues of the organism.