Evidence for an intramural nervous control of epithelial cell migration in the small intestine of the rat

The migration of epithelial cells along the crypt-villus axis in the small intestine of the rat was followed by labelling epithelial cells during mitosis with [3H]thymidine given i.v. Using two different techniques (autoradiography and determination of tissue radioactivity) it was demonstrated that 6-9 h after giving the tracer the labelled cells had migrated longer in intestinal segments exposed to cholera toxin than in control segments. This effect of cholera toxin was abolished by giving hexamethonium. We have earlier shown that cholera toxin induces fluid secretion to a large extent by activating the enteric nervous system and we conclude from the present observations that cholera toxin in a similar fashion exerts a trophic effect on the intestinal epithelium via intramural nervous reflexes. The importance of co-release of several neurotransmitters in explaining the trophic effect is tentatively discussed.     

On the involvement of tachykinin neurons in the secretory nervous reflex elicited by cholera toxin in the small intestine

The possible involvement of tachykinins in the nervous reflex activated by exposing the intestinal mucosa to cholera toxin was investigated in cats and rats. Three types of experiments were performed. In cats the release of tachykinins into blood was followed after placing cholera toxin in the intestinal lumen. In rat experiments a tachykinin receptor antagonist (Spantide II) was given close i.a. and its effect on cholera toxin-evoked fluid secretion was studied. Finally, in rats the effect of cholera toxin on the SP contents in the intestinal mucosa was studied. No release of tachykinins could be demonstrated. Spantide II did not change the rate of cholera toxin induced secretion. The SP content in the intestinal mucosa was not influenced by placing the toxin in the intestinal lumen. Hence, no experimental evidence was obtained for the involvement of a tachykinin neuron in the intestinal secretory nervous reflex activated by cholera toxin. Based on observations reported in the literature the involvement of an acetylcholine/tachykinin neuron in the reflex is tentatively discussed.     

The effects on net fluid transport of noxious stimulation of jejunal mucosa in anaesthetized rats

A major aim of the present study was to investigate whether exposing the jejunal mucosa to a noxious stimulus induces a net fluid secretion by activating the enteric nervous system (ENS) and, if so, to what extent an axon reflex was involved. Net fluid transport was measured in vivo with a gravimetric method. The intestinal mucosa was exposed to an isotonic solution with an unphysiologically low pH (1.0). This evoked a fluid secretion, which was markedly attenuated by giving hexamethonium (nicotinic receptor antagonist) i.v. or exposing the intestinal serosa to lidocaine (local anaesthetic). Atropine (muscarinic receptor antagonist) had no effect. Luminal acid evoked a fluid secretion of the same magnitude in acutely denervated segments and in segments denervated about 3 weeks prior to the experiments. Luminal capsaicin (1.6–16 m M ) did not influence jejunal net fluid transport. A second aim of the study is to investigate the effect of nifedipine (Ca channel blocker of L-type) on the acid-induced fluid secretion. Nifedipine markedly attenuated acid-induced fluid secretion. In contrast to cholera toxin-evoked secretion, the nifedipine effect was not mediated via 5-hydroxytryptamine (5-HT) as judged by measurements of 5-HT release into the intestinal lumen and the lack of effect of granisetron (5-HT₃ receptor antagonist). It is concluded that the net fluid secretion evoked by hydrochloric acid in the small intestine is mainly mediated via an intramural reflex in the ENS. No experimental evidence was obtained for the involvement of an axon reflex. The site of action of the calcium channel blocker is tentatively discussed.     

Potentiating effect of bile on enterotoxin-induced diarrhea.

The influence of bile acids on adenosine 3',5'-phosphate-induced intestinal secretion was studied in mice. Bile flow was stopped by ligation of the common bile duct, and secretion was induced in ligated loops of the small intestine. The decrease of bile led to inhibition of hypersecretion after challenge with heat-labile enterotoxins from Vibrio cholerae and Escherichia coli, as well as with prostaglandin E1. In contrast, the fluid response induced by dibutyryl-adenosine 3',5'-phosphate was unaffected by intestinal bile. Injection of bile or bile acids into intestinal loops before cholera toxin challenge restored the toxin-induced secretion in the bile-depleted intestine. At the subcellular level the decrease of intestinal bile led to inhibition of cholera toxin-activated adenylate cyclase, whereas the bile concentration did not influence the binding of 125I-labeled toxin to the intestinal epithelial cells. The results suggest that intestinal bile interacts with adenylate cyclase in the induction of fluid secretion by enterotoxins and prostaglandin E1.     

Rabbit intestinal glycoprotein receptor for Escherichia coli heat-labile enterotoxin lacking affinity for cholera toxin.

The receptors for cholera toxin and Escherichia coli heat-labile toxin (LT) in rabbit small intestinal epithelium were characterized and compared. (i) In vivo studies in ligated intestinal loops showed that whereas LT B subunits could block the fluid secretogenic action of purified LT as well as cholera toxin, cholera toxin B subunits did not inhibit the LT response even when tested in a concentration 100-fold higher than one which gave complete blocking of cholera toxin action. (ii) In vitro studies indicated that isolated intestinal epithelial cells or brush-border membranes could bind about 10-fold more of E. coli LT than of cholera toxin. (iii) All binding sites for cholera toxin in duodenal, jejunal, or ileal mucosal cells or brush-border membranes were extracted by chloroform-methanol-water (4:8:3), which removed lipids quantitatively but did not extract glycoproteins. The extracted cholera toxin binding sites were to greater than 95% recovered in a monosialoganglioside fraction; quantitatively these sites closely corresponded to the concentration of chromatographically identified mucosal GM1 ganglioside (1 nmol of cholera toxin was bound per 1 to 2 nmol of GM1). In contrast, a substantial fraction of mucosal binding sites for E. coli LT remained in the delipidized tissue residue, and these sites had properties consistent with a glycoprotein nature. Thus, whereas cholera toxin appeared to bind highly selectively to GM1 ganglioside receptor sites of rabbit small intestine, E. coli LT bound both to GM1 ganglioside and to a main glycoprotein receptor for which cholera toxin lacks affinity.     

Binding of Cholera Toxin to Mucins and Inhibition by Gastric Mucin

The effects of mucin on cholera toxin induced intestinal secretion was studied in the rat small intestine. Gastric mucin inhibited secretion when premixed with cholera toxin on an equal dry-weight basis. Neither salivary nor intestinal mucin inhibited the toxin's action in the intestine. Inhibition by gastric mucin was not reversed by a mucolytic agent or by hexoses or agents that bind hexoses. Plasma and serum did not inhibit the effects of cholera toxin in the intestine. Choleragen was labeled with (14)C and its binding to mucins and ganglioside was studied. Gastric mucin was shown to bind to choleragen, but less binding was observed when choleragen was dissociated into subunits by acid pH. Salivary and intestinal mucins bound intact choleragen but not the subunits at acid pH. Salivary mucin binding was reversed by N-acetyl neuraminic acid and neuraminidase. Ganglioside bound choleragen in both the intact and dissociated forms. Binding to the dissociated form was reversed by wheat germ agglutinin. Gastric mucin and ganglioside competed for binding to choleragen with the binding of intact choleragen greater for ganglioside and the affinity of the subunits greater for gastric mucin. Electrophoresis of labeled choleragen showed uniform labeling of the subunits dissociated by acid pH, but a major part of cholera toxin was found not to be labeled when fractionated with sodium dodecyl sulfate and 2-mercaptoethanol.     

Changes in cyclic 3'5'-adenosine monophosphate tissue concentration and net fluid transport in the cat's small intestine elicited by cholera toxin, arachidonic acid, vasoactive intestinal polypeptide and 5-hydroxytryptamine

We have analysed tissue cyclic 3'5'-adenosine monophosphate (cAMP) concentration in different fractions of the cat's small intestinal mucosa during secretion elicited in vivo by four different secretagogues: cholera toxin (administered intraluminally), vasoactive intestinal polypeptide (VIP; given i.a.), arachidonic acid (AA; administered intraluminally) and 5-hydroxytryptamine (5-HT; given i.a.). Cholera toxin was found to increase cAMP concentration in the villi but not in the crypts. The VIP, AA and 5-HT did not influence tissue cAMP concentration despite a profuse net fluid secretion. Hexamethonium inhibited secretion elicited by cholera toxin and AA but did not significantly influence tissue cAMP concentration. There is strong evidence for the view that villus and crypt regions of the small intestinal mucosa have different functions, secretion taking place in the crypts and absorption in the villi. However, the lack of cAMP increase in the crypts reported in this study suggests that cholera toxin in this model does not reach the crypts. The results are not in agreement with a role for cAMP in mediating secretion from the crypts, but are compatible with a role of cAMP in inhibiting absorption in the villi. It is suggested that the observed fluid secretion from the crypts elicited by cholera toxin, AA and 5-HT is to a major part mediated by intramural enteric reflexes.     

Changes in cyclic 3'5‘-adenosine monophosphate tissue concentration and net fluid transport in the cat's small intestine elicited by cholera toxin,arachidonic acid,vasoactive intestinal polypeptide and 5-hydroxytryptamine

We have analysed tissue cyclic 3'5′-adenosine monophosphate (cAMP) concentration in different fractions of the cat's small intestinal mucosa during secretion elicited in vivo by four different secretagogues: cholera toxin (administered intraluminally), vasoactive intestinal polypeptide (VIP; given i.a.), arachidonic acid (AA; administered intraluminally) and 5-hydroxytryptamine (5-HT; given i.a.). Cholera toxin was found to increase cAMP concentration in the villi but not in the crypts. The VIP, AA and 5-HT did not influence tissue cAMP concentration despite a profuse net fluid secretion. Hexamethonium inhibited secretion elicited by cholera toxin and AA but did not significantly influence tissue cAMP concentration. There is strong evidence for the view that villus and crypt regions of the small intestinal mucosa have different functions, secretion taking place in the crypts and absorption in the villi. However, the lack of cAMP increase in the crypts reported in this study suggests that cholera toxin in this model does not reach the crypts. The results are not in agreement with a role for cAMP in mediating secretion from the crypts, but are compatible with a role of cAMP in inhibiting absorption in the villi. It is suggested that the observed fluid secretion from the crypts elicited by cholera toxin, AA and 5-HT is to a major part mediated by intramural enteric reflexes.     

The involvement of intramural nerves in cholera toxin induced intestinal secretion

In previous reports we have suggested that nervous reflexes are involved in the pathophysiology of cholera secretion and that these nervous reflexes involve a cholinergic synapse and a neuron with vasoactive intestinal polypeptide (VIP) as neurotransmitter. These proposals were further analyzed in this study. Tetrodotoxin (TTX) and lidocaine applied on the serosal surface inhibited cholera secretion in segments of rat small intestine. Fluid absorption in control rats was not significantly changed. Hexamethonium given i. v. decreased cholera secretion in the cat. No additional inhibition of cholera secretion was observed after giving TTX close i. a. Furthermore, the intestinal secretion evoked by VIP was not influenced by hexamethonium given i. v. or TTX given close i. a. The present observations support the hypothesis of a role for nervous reflexes in cholera secretion. The results suggest that at least a major part of the proposed nervous reflex(es) in cholera have a cholinergic synapse. Furthermore, the VIP-ergic neuron is situated “distal” to the cholinergic neuron in the reflex(es) closer to the effector cells.     

VIP-induced cyclic AMP formation in the cat submandibular gland Potentiation by carbacholine

The intestinal secretion in cholera is evoked via the action of the cholera toxin on the intestinal mucosa. We have recently presented evidence for the involvement of the enteric nervous system in the induction of this type of secretion (Cassuto et al. 1981). We have also shown that electrical or reflex activation of the sympathetic fibres to the small intestine (Brunsson et al. 1979, Sjövall et al. 1982) increases net fluid absorption in the normal small intestine via an α-adrenergic effect. These two observations led us to investigate the possible effect of adrenergic receptor stimulation on cholera secretion.     

Trichomonas vaginalis polyamine metabolism is linked to host cell adherence and cytotoxicity

Trichomonas vaginalis secretes putrescine that is readily detected in vaginal secretions. We wanted to examine the effect of decreased putrescine synthesis by inhibition of ornithine decarboxylase (ODC) on T. vaginalis. One reason is because inhibition of Tritrichomonas foetus ODC results in growth arrest, destruction of hydrogenosomes, and decreased amounts of hydrogenosomal enzymes. Treatment of T. vaginalis T016 with >/=20 mM 1,4-diamino-2-butanone (DAB) to inhibit ODC resulted in growth arrest, which was reversed by addition of exogenous putrescine. No similar reversal of growth arrest was achieved with the polyamines spermine or spermidine or with iron. Electron microscopic examination of control versus DAB-treated trichomonads did not reveal any adverse effects on the number and integrity of hydrogenosomes. Further, the adhesins AP65, AP51, and AP33 mediating binding to immortalized vaginal epithelial cells (VECs) share identity to enzymes of the hydrogenosome organelle, and there was no difference in amounts of adhesins between control versus DAB-treated T. vaginalis parasites. Likewise, similar patterns and extent of fluorescence were evident for the prominent AP65 adhesin. Surprisingly, DAB treatment increased by 4- to 20-fold above untreated trichomonads handled identically the level of adherence mediated by adhesins. Interestingly, the enhanced attachment to VECs was reversed by exogenous putrescine added to DAB-treated trichomonads. Equally noteworthy was that DAB-treated T. vaginalis with enhanced adherence did not possess the previously reported ability to kill host cells in a contact-dependent fashion mediated by cysteine proteinases, and total cysteine proteinase activity patterns were identical between control and DAB-treated trichomonads. Overall, these data suggest that polyamine metabolism and secreted putrescine are linked to host cell adherence and cytotoxicity.     

Intestinal changes caused by DL-alpha-difluoromethylornithine (DFMO), an inhibitor of ornithine decarboxylase

Subacute (2 week) oral or intravenous administration of DL-alpha-difluoromethylornithine (DFMO), an irreversible inhibitor of ornithine decarboxylase (ODC), caused diarrhea and frequent emesis as early as 4 to 5 days in dogs (dose greater than or equal to 200 mg/kg/day). Diarrhea also occurred in monkeys after 1 week of treatment with an intravenous dose of 1000 mg/kg/day. Especially evident in the treated dogs with diarrhea were fluid loss, hemoconcentration, and decreased serum sodium and chloride which were findings totally reversible about 2 weeks after cessation of dosing. As a result of treatment with the highest intravenous dosage (1000 mg/kg/day), villous atrophy of the mucosa was observed by light and scanning electron microscopy in the canine small intestine. Transmission electron microscopy demonstrated that the most significant alterations of the canine intestinal tract involved the microvilli of epithelial cells which became shorter and were frequently less numerous or absent along focal areas of the plasma membrane. Intestinal mucosal levels of putrescine, especially in the duodenum and jejunum, were decreased as demonstrated in the monkeys following intravenous treatment with 100, 300, or 1000 mg/kg/day of DFMO. The results of this investigation are consistent with the hypothesis that the inhibition of ODC activity and subsequent altered polyamine metabolism may lead to delayed maturation of the intestinal epithelial cells and the impaired development of their microvilli, causing fluid loss due to reduced absorptive surface area.     

Effects of Clostridium difficile toxins A and B in rabbit small and large intestine in vivo and on cultured cells in vitro.

Clostridium difficile is recognized as the major cause of antibiotic-associated colitis. C. difficile produces two toxins, A (enterotoxin) and B (cytotoxin), that are implicated in the pathogenesis of the colitis. We examined the dose responses, time course, and synergism of these two toxins in ligated rabbit intestinal loops and in tissue culture. In rabbit small intestinal loops, toxin A caused histologically demonstrable intestinal tissue damage as early as 2 h. The secretory response greater than or equal to 8 h was similar to that of a cholera toxin control. The effect of toxin A on tissue damage or secretion was seen even if toxin was removed after 5 min. Purified toxin A caused significant net accumulation of sodium, chloride, potassium, and total protein and slightly increased osmolality of the fluid content at 6 h; these effects were similar to those caused by crude C. difficile culture filtrates containing toxins A and B. Crude C. difficile toxin caused fluid accumulation with a delayed time course in the rabbit large intestine, and in contrast to its effect in small intestine, crude toxin caused net accumulation of bicarbonate and increased pH. In tissue culture, toxin A caused a rounding up of CHO and T-84 colonic carcinoma cells. A monoclonal antibody (PCG-4) that has no effect on tissue culture cytotoxicity with toxins A and B completely inhibited the secretory and tissue-damaging effects in the intestine. Toxins A and B were synergistic in the gut only at high doses of toxin B (greater than or equal to 10 micrograms/ml), and they were additive in tissue culture. The cytopathic effect in tissue culture was not consistently associated with trypan blue uptake. The cytopathic effect of toxin A in tissue culture did not appear to involve inhibitable Ca2+-dependent or prostaglandin synthesis pathways or intact microfilament or microtubule function for its activity and was not inhibited by reducing or lysosomotropic agents. Our results suggest that toxins A and B have independent and distinct effects in vivo and in vitro.     

Cholera toxin effects on fluid secretion, adenylate cyclase, and cyclic AMP in porcine small intestine.

The effects of cholera toxin on mucosal cyclic nucleotide concentrations and on net fluid secretion in the porcine small intestine are reported. Cholera toxin causes net secretion of fluid into the small intestine of weanling pigs, and secretory rates are dependent on the dose of the toxin placed in intestinal loops. Intestinal secretion due to cholera toxin exposure was not consistently accompanied by elevated concentrations of mucosal cyclic AMP or cyclic GMP. Net fluid fluxes in individual loops did not correlate with mucosal cyclic AMP concentration in the same loop. Jejunal adenylate cyclase was activated to a lesser extent in pigs, compared with rabbits, after in vivo treatment with cholera toxin. In vitro activation in cell-free homogenates was similar for both species. Papaverine was similar to cholera toxin in causing fluid secretion without cyclic AMP accumulations, but 3-isobutyl-1-methyl xanthine significantly increased cyclic AMP concentration and induced fluid secretion in pigs. Weanling pigs appeared to differ from rabbits in having a secretory response to cholera toxin which was independent of elevations in total mucosal cyclic AMP concentration.     

Changes in ornithine decarboxylase activity and putrescine concentrations after spinal cord compression injury in the rat.

Traumatic spinal cord injury results in direct physical damage to structures and the generation of local factors contributing to secondary pathogenesis. In the present study, we investigated changes in polyamine metabolism after spinal cord compression injury in the rat. This is a stress induced metabolic pathway, of which an activation may indicate both, secondary pathogenesis or induction of neuroprotective response. Ornithine decarboxylase (ODC) activity, the rate limiting step of polyamine synthesis, and levels of the diamine putrescine, the product of ornithine decarboxylase reaction, were analyzed in control (non-laminectomized) animals and at 2 and 4 h after laminectomy or compression injury at the L4 segmental level. ODC activity was significantly increased 4 h after laminectomy in L4 and in adjacent L3 and L5 segments and compression to L4 produced a further increase 4 h after injury as compared with the intact control group. Putrescine levels were likewise significantly elevated to the same extend in the laminectomized and injured cord as compared with the intact control group. These findings demonstrate increased ODC and putrescine levels in the laminectomized and traumatized spinal cord and suggest that laminectomy may be an important 'priming event' that contributes to secondary injury after spinal cord compression injury.     

Substance P and vasoactive intestinal peptide influence polyamine metabolism in salivary glands of the rat

In parotid, sublingual and submaxillary glands stimulated by continuous intravenous infusion of the neuropeptides substance P or vasoactive intestinal peptide at various doses for 3 h, the concentrations of the polyamines putrescine, spermidine, spermine and N1-acetylspermidine as well as the activity of ornithine decarboxylase were determined. This enzyme catalyses the synthesis of putrescine and is the key enzyme in polyamine formation. Vasoactive intestinal peptide induced the most marked effects, and the most conspicuous findings were made in the sublingual glands, where the ornithine decarboxylase activity was found to have increased more than 100-fold, accompanied by an increased level of putrescine in those glands which were removed immediately after the end of the infusion. When, instead, the glands were removed 5 h after the end of the infusion there was no longer any increase in the activity of ornithine decarboxylase or in putrescine concentration, but now spermidine and spermine were found to be increased. Interestingly, the parasympathetic non-adrenergic, non-cholinergic regulation of polyamine metabolism in the major salivary glands of the rat is most predominant in the sublingual glands.     

The effects on net fluid transport of noxious stimulation of jejunal mucosa in anaesthetized rats.

A major aim of the present study was to investigate whether exposing the jejunal mucosa to a noxious stimulus induces a net fluid secretion by activating the enteric nervous system (ENS) and, if so, to what extent an axon reflex was involved. Net fluid transport was measured in vivo with a gravimetric method. The intestinal mucosa was exposed to an isotonic solution with an unphysiologically low pH (1.0). This evoked a fluid secretion, which was markedly attenuated by giving hexamethonium (nicotinic receptor antagonist) i.v. or exposing the intestinal serosa to lidocaine (local anaesthetic). Atropine (muscarinic receptor antagonist) had no effect. Luminal acid evoked a fluid secretion of the same magnitude in acutely denervated segments and in segments denervated about 3 weeks prior to the experiments. Luminal capsaicin (1.6-16 mM) did not influence jejunal net fluid transport. A second aim of the study is to investigate the effect of nifedipine (Ca channel blocker of L-type) on the acid-induced fluid secretion. Nifedipine markedly attenuated acid-induced fluid secretion. In contrast to cholera toxin-evoked secretion, the nifedipine effect was not mediated via 5 hydroxytryptamine (5-HT) as judged by measurements of 5-HT release into the intestinal lumen and the lack of effect of granisetron (5-HT3 receptor antagonist). It is concluded that the net fluid secretion evoked by hydrochloric acid in the small intestine is mainly mediated via an intramural reflex in the ENS. No experimental evidence was obtained for the involvement of an axon reflex. The site of action of the calcium channel blocker is tentatively discussed.     

The net fluid secretion caused by cyclic 3'5'-guanosine monophosphate in the rat jejunum in vivo is mediated by a local nervous reflex

The tissue concentration of cyclic 3'5'-guanosine monophosphate (cGMP) has been shown to increase in the small intestine when net fluid secretion is evoked by the heat-stable enterotoxine of Escherichia coli. Lipophilic cGMP analogues are also known to elicit intestinal fluid secretion. It is therefore believed that an increase in intracellular cGMP concentration in enterocytes mediates this secretion. The present study reports that the fluid secretion, elicited by placing two different cGMP analogues, dibutyryl-cGMP and 8-Br-cGMP, in the intestinal lumen of anaesthetized rats in vivo, is significantly inhibited by atropine, hexamethonium and lidocaine. It is proposed that cGMP activates a reflex in the enteric nervous system which, in part, explains the observed fluid secretion.     

Alpha-difluoromethylornithine resistance in Leishmania donovani is associated with increased ornithine decarboxylase activity

The promastigote form of Leishmania donovani is sensitive to growth inhibition by DL-alpha-difluoromethylornithine (DFMO), an inhibitor of ornithine decarboxylase (ODC), the first enzyme of the polyamine biosynthetic pathway, with an EC50 value of approximately 30 microM. Exposure of a wild type (DI700) cell population to gradually increasing concentrations of DFMO resulted in the selection of a strain of Leishmania, DFMO-10, which was capable of proliferating in 10 mM DFMO. DFMO-10 cells possessed an EC50 value for DFMO greater than 4 mM, and were cross-resistant to alpha-methylornithine, alpha-monofluoromethyl-3,4-dehydroornithine methyl ester, and delta-methyl-acetylenic putrescine, three other inhibitors of ODC activity. DI700 and DFMO-10 cells accumulated and/or transported [3H]DFMO and a spectrum of basic, neutral, and acidic amino acids at comparative rates. However, the DFMO-resistant Leishmania, if suspended in culture medium in the absence of DFMO for several days, expressed up to 15-fold greater levels of ODC activity than did wild-type cells. The overexpressed ODC in mutant cells appeared kinetically normal, since the ODC activities from DI700 and DFMO-10 cells possessed similar apparent Km values for ornithine and were equally sensitive to inactivation by DFMO. Incubation of extracts of DFMO-10 cells, but not of wild-type parental cells, with [3H]DFMO for 1 h resulted in the labeling of a polypeptide, presumably ODC, which migrated with a molecular weight of 76,000 +/- 4000 on SDS-gel electrophoretograms. As a consequence of the elevated ODC activities, the levels of putrescine in mutant cells released from DFMO exposure were also elevated by about 15-fold over those of wild-type cells, although spermidine levels in DI700 and DFMO-10 cells were similar. In the absence of prolonged selective pressure, the resistance to DFMO, the ODC activity, and the putrescine levels of DFMO-10 cells all returned to those of wild type cells, indicating that the mutant phenotype of DFMO-selected L. donovani was unstable.     

Polyamine metabolism in prostaglandin E2-treated human T lymphocytes

The effects of Prostaglandin (PG) E2 treatment of human T lymphocytes on polyamine metabolism were investigated. PGE2 is known to inhibit lymphocyte proliferation, while polyamines play an important role in several biochemical processes leading to increased cell growth. Preincubation of T lymphocytes with PGE2 (10^-6 M) for 10 min. was able to increase ornithine decarboxylase (ODC) activity and putrescine as well as spermine levels, while spermidine concentration was drastically reduced. After 30 and 60 min of treatment, a decrease in ODC activity and putrescine concentration was observed. On the contrary, the initial inhibition of sperrnine-NI-acetyl-transferase (SAT) activity was followed by a progressive increase of this catabolic enzyme. These changes were related to modifications of cAMP concentrations. Our data may help clarify the mechanisms underlying the biphasic effect of PGE2, which ultimately leads to inibition of cell proliferation.