The accumulation of diamines and polyamines into rat lung slices

Oral Supplementation with the Polyamine Spermidine Affects Hepatic but Not Pulmonary Lipid Metabolism in Lean but Not Obese Mice

The polyamine spermidine is discussed as a caloric restriction mimetic and therapeutic option for obesity and related comorbidities. This study tested oral spermidine supplementation with regard to the systemic, hepatic and pulmonary lipid metabolism under different diet conditions. Male C57BL/6 mice were fed a purified control (CD), high sucrose (HSD) or high fat (HFD) diet with (-S) or without spermidine for 30 weeks. In CD-fed mice, spermidine decreased body and adipose tissue weights and reduced hepatic lipid content. The HSD induced hepatic lipid synthesis and accumulation and hypercholesterolemia. This was not affected by spermidine supplementation, but body weight and blood glucose were lower in HSD-S compared to HSD. HFD-fed mice showed higher body and fat depot weights, prediabetes, hypercholesterolemia and severe liver steatosis, which were not altered by spermidine. Within the liver, spermidine diminished hepatic expression of lipogenic transcription factors SREBF1 and 2 under HSD and HFD and affected the expression of other lipid-related enzymes. In contrast, diet and spermidine exerted only minor effects on pulmonary parameters. Thus, oral spermidine supplementation affects lipid metabolism in a diet-dependent manner, with significant reductions in body fat and weight under physiological nutrition and positive effects on weight and blood glucose under high sucrose intake, but no impact on dietary fat-related parameters.

Spermidine supplementation and voluntary activity differentially affect obesity-related structural changes in the mouse lung

Obesity is associated with lung function impairment and respiratory diseases; however, the underlying pathophysiological mechanisms are still elusive, and therapeutic options are limited. This study examined the effects of prolonged excess fat intake on lung mechanics and microstructure and tested spermidine supplementation and physical activity as intervention strategies. C57BL/6N mice fed control diet (10% fat) or high-fat diet (HFD; 60% fat) were left untreated or were supplemented with 3 mM spermidine, had access to running wheels for voluntary activity, or a combination of both. After 30 wk, lung mechanics was assessed, and left lungs were analyzed by design-based stereology. HFD exerted minor effects on lung mechanics and resulted in higher body weight and elevated lung, air, and septal volumes. The number of alveoli was higher in HFD-fed animals. This was accompanied by an increase in epithelial, but not endothelial, surface area. Moreover, air-blood barrier and endothelium were significantly thicker. Neither treatment affected HFD-related body weights. Spermidine lowered lung volumes as well as endothelial and air-blood barrier thicknesses toward control levels and substantially increased the endothelial surface area under HFD. Activity resulted in decreased volumes of lung, septa, and septal compartments but did not affect vascular changes in HFD-fed mice. The combination treatment showed no additive effect. In conclusion, excess fat consumption induced alveolar capillary remodeling indicative of impaired perfusion and gas diffusion. Spermidine alleviated obesity-related endothelial alterations, indicating a beneficial effect, whereas physical activity reduced lung volumes apparently by other, possibly systemic effects.

Identification of polyamine transporters in plants: paraquat transport provides crucial clues

Polyamine (PA) transport as well as PA biosynthesis, degradation and conjugation plays a vital role in the regulation of intracellular PA levels, which are essential for cell growth. Generally, PA uptake activity is elevated in rapidly proliferating cells. Previous studies showed that PA uptake in plant cells occurred via energy-dependent, protein-mediated transport systems. Numerous lines of evidence suggest that paraquat (PQ), one of the most widely used herbicides, is transported by the PA transport system in diverse organisms including plants. The PA/PQ transport interactions are proposed to be due to specific structural similarities between PA and PQ. The understanding of PA transport mechanisms has progressed in parallel with that of PQ transport, but the molecular identity of the plant PA/PQ transporter has remained an enigma. Recently, independent studies identified the L-type amino acid transporter (LAT) family transmembrane proteins as transporters of both PA and PQ. Arabidopsis LAT family proteins showed different subcellular localization properties, which suggested that these transporters were involved in intracellular PA trafficking and PA uptake across the plasma membrane. The identification of plant PA transporters is an important step in understanding the mechanism of PA homeostasis in plant cells. In this review, we highlight recent advances in the study of PA transport systems that are linked to the understanding of PQ translocation.

Molecular mechanisms of paraquat-induced acute lung injury: a current review

Paraquat is an organic heterocyclic herbicide that is widely used in agriculture, especially in Asian countries. The prevalence of paraquat poisonings has increased dramatically in the past two decades in China. Nearly all paraquat poisonings resulted from intentional or accidental oral administration leading to acute lung injury and, ultimately, acute respiratory distress syndrome. The mortality rate has been reported to be greater than 90%. However, the exact toxic mechanism remains unclear. Herein, we reviewed and summarized the most recent publications related to the molecular mechanisms of paraquat-induced acute lung injury.

Paraquat Increases Cyanide-insensitive Respiration in Murine Lung Epithelial Cells by Activating an NAD(P)H:Paraquat Oxidoreductase

Pulmonary fibrosis is one of the most severe consequences of exposure to paraquat, an herbicide that causes rapid alveolar inflammation and epithelial cell damage. Paraquat is known to induce toxicity in cells by stimulating oxygen utilization via redox cycling and the generation of reactive oxygen intermediates. However, the enzymatic activity mediating this reaction in lung cells is not completely understood. Using self-referencing microsensors, we measured the effects of paraquat on oxygen flux into murine lung epithelial cells. Paraquat (10-100 microm) was found to cause a 2-4-fold increase in cellular oxygen flux. The mitochondrial poisons cyanide, rotenone, and antimycin A prevented mitochondrial- but not paraquat-mediated oxygen flux into cells. In contrast, diphenyleneiodonium (10 microm), an NADPH oxidase inhibitor, blocked the effects of paraquat without altering mitochondrial respiration. NADPH oxidases, enzymes that are highly expressed in lung epithelial cells, utilize molecular oxygen to generate superoxide anion. We discovered that lung epithelial cells possess a distinct cytoplasmic diphenyleneiodonium-sensitive NAD(P)H:paraquat oxidoreductase. This enzyme utilizes oxygen, requires NADH or NADPH, and readily generates the reduced paraquat radical. Purification and sequence analysis identified this enzyme activity as thioredoxin reductase. Purified paraquat reductase from the cells contained thioredoxin reductase activity, and purified rat liver thioredoxin reductase or recombinant enzyme possessed paraquat reductase activity. Reactive oxygen intermediates and subsequent oxidative stress generated from this enzyme are likely to contribute to paraquat-induced lung toxicity.

Increased synaptosomal dopamine content and brain concentration of paraquat produced by selective dithiocarbamates

Exposure to pesticides may be a risk factor for Parkinson's disease based on epidemiologic data in humans, animal models and in vitro studies. Different dithiocarbamate pesticides potentiate the toxicity of both 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine and paraquat in mouse models of Parkinsonism by an unknown mechanism. This study examined the effects of commercially used dithiocarbamates on [3H]dopamine transport in striatal synaptosomal vesicles and on the concentration of [14C]paraquat in vivo in mice. Different ethylenebis-dithiocarbamates and diethyl-dithiocarbamate increased dopamine accumulation in synaptosomes, whereas dimethyl-dithiocarbamate and methyl-dithiocarbamate did not. Increased dopamine accumulation in synaptosomes was dose dependent and was related to the carbon backbone of these molecules. The dithiocarbamates that increased accumulation of dopamine did not alter the influx of dopamine, but rather delayed the efflux out of synaptosomes. These same dithiocarbamates also increased the tissue content of [14C]paraquat in vivo by a mechanism that appeared to be distinct from the dopamine transporter. There was a consistent relationship between the dithiocarbamates that increased synaptosomal accumulation of dopamine and tissue content of paraquat, with those previously demonstrated to enhance paraquat toxicity in vivo. These results suggest that selective dithiocarbamates may alter the kinetics of different endogenous and exogenous compounds to enhance their neurotoxicity.

Polyamines in the lung: polyamine uptake and polyamine-linked pathological or toxicological conditions

The natural polyamines putrescine, cadaverine, spermidine, and spermine are found in all cells. These (poly)cations exert interactions with anions, e.g., DNA and RNA. This feature represents their best-known direct physiological role in cellular functions: cell growth, division, and differentiation. The lung and, more specifically, alveolar epithelial cells appear to be endowed with a much higher polyamine uptake system than any other major organ. In the lung, the active accumulation of natural polyamines in the epithelium has been studied in various mammalian species including rat, hamster, rabbit, and human. The kinetic parameters (Michaelis-Menten constant and maximal uptake) of the uptake system are the same order of magnitude regardless of the polyamine or species studied and the in vitro system used. Also, other pulmonary cells accumulate polyamines but never to the same extent as the epithelium. Although different uptake systems exist for putrescine, spermidine, and spermine in the lung, neither the nature of the carrier protein nor the reason for its existence is known. Some pulmonary toxicological and/or pathological conditions have been related to polyamine metabolism and/or polyamine content in the lung. Polyamines possess an important intrinsic toxicity. From in vitro studies with nonpulmonary cells, it has been shown that spermidine and spermine can be metabolized to hydrogen peroxide, ammonium, and acrolein, which can all cause cellular toxicity. In hyperoxia or after ozone exposure, the increased polyamine synthesis and polyamine content of the rat lung is correlated with survival of the animals. Pulmonary hypertension induced by monocrotaline or hypoxia has also been linked to the increased polyamine metabolism and polyamine content of the lung. In a small number of studies, it has been shown that polyamines can contribute to the suppression of immunologic reactions in the lung.

Cellular disposition of transported polyamines in hypoxic rat lung and pulmonary arteries

The polyamines putrescine, spermidine (SPD), and spermine are a family of low-molecular-weight organic cations essential for cell growth and differentiation and other aspects of signal transduction. Hypoxic pulmonary vascular remodeling is accompanied by depressed lung polyamine synthesis and markedly augmented polyamine uptake. Cell types in which hypoxia induces polyamine transport in intact lung have not been delineated. Accordingly, rat lung and rat main pulmonary arterial explants were incubated with [(14)C]SPD in either normoxic (21% O(2)) or hypoxic (2% O(2)) environments for 24 h. Autoradiographic evaluation confirmed previous studies showing that, in normoxia, alveolar epithelial cells are dominant sites of polyamine uptake. In contrast, hypoxia was accompanied by prominent localization of [(14)C]SPD in conduit, muscularized, and partially muscularized pulmonary arteries, which was not evident in normoxic lung tissue. Hypoxic main pulmonary arterial explants also exhibited substantial increases in [(14)C]SPD uptake relative to control explants, and autoradiography revealed that enhanced uptake was most evident in the medial layer. Main pulmonary arterial explants denuded of endothelium failed to increase polyamine transport in hypoxia. Conversely, medium conditioned by endothelial cells cultured in hypoxic, but not in normoxic, environments enabled hypoxic transport induction in denuded arterial explants. These findings in arterial explants were recapitulated in rat cultured main pulmonary artery cells, including the enhancing effect of a soluble endothelium-derived factor(s) on hypoxic induction of [(14)C]SPD uptake in smooth muscle cells. Viewed collectively, these results show in intact lung tissue that hypoxia enhances polyamine transport in pulmonary artery smooth muscle by a mechanism requiring elaboration of an unknown factor(s) from endothelial cells.

Regulation of polyamine synthesis and transport by retinoic acid and epidermal growth factor in cultured adult rat type II pneumocytes

During injury of lung epithelial cells, the type II pneumocyte proliferates and differentiates into a type I pneumocyte to restore the epithelium. Polyamines, which constitute a family of small organic polycations, are required for this process of cell repair. Because retinoic acid (RA) and epidermal growth factor (EGF) also are involved, the purpose of this research was to determine their effect on polyamine transport and synthesis in cultured type II pneumocytes. Rat type II pneumocytes were isolated, cultured overnight, and treated with RA and/or EGF for 24 hours. Polyamine transport was determined by [(3)H]spermidine uptake, and polyamine synthesis was assessed by the activity of the initial rate-limiting enzyme ornithine decarboxylase. EGF (100 ng/mL) significantly increased spermidine transport, but RA did not. At low concentrations of spermidine (2 microM), the combined effect of RA and EGF on spermidine transport was additive. Both EGF (25 ng/mL) and RA (1 microM) increased polyamine synthesis, and cotreatment resulted in an additive effect (a fourfold increase over the control). We also found that ornithine decarboxylase activity is greatly diminished in the presence of tyrphostin B56, which is a specific inhibitor for the tyrosine kinase of the EGF receptor, suggesting that polyamine synthesis within the type II pneumocyte may depend on activation of tyrosine kinase of the EGF receptor. These results indicate that RA and EGF increase the availability of polyamines, which may be important in the lung cell repair process.

Putrescine uptake by alveolar epithelial cell monolayers exhibiting differing transepithelial electrical resistances

Rat alveolar type II cells were isolated following elastase digestion and cultured on polycarbonate filters at various densities and in different media. Two days after seeding, the cells formed a monolayer on the filters which consisted predominantly of type II cells, these then de-differentiated to a alveolar type I-like cell monolayer by day 6. The seeding density and media utilized affected the transepithelial electrical resistance (TEER) generated by the monolayer. Only certain culture conditions allowed the production of a monolayer that mimics, putatively, the in vivo alveolar epithelium (TEER greater than 1000 omega cm2). Vmax and K(m) values for the uptake of putrescine by monolayers exhibiting low and high TEERs on day 6 were determined. The capacity of the putrescine uptake mechanisms was greater in cell monolayers exhibiting a high TEER than those exhibiting a low TEER, suggesting that the TEER does not only measure the "tightness" of the monolayer but contains an element representative of the viability of the cell monolayer. The selection of appropriate TEERs for cell culture investigations is discussed.

Putrescine accumulation in human pulmonary tumours

Type II pneumocytes and Clara cells, both epithelial cells that possess an active uptake system for polyamines, have been identified as possible precursor cells of at least some types of lung tumours. In this study we have investigated whether human pulmonary tumours exhibit putrescine uptake. Lung slices from both tumoral tissue and non-tumoral tissue, obtained from patients undergoing surgery for lung cancer, were incubated with radiolabelled putrescine at both 37 degrees C and 4 degrees C. The accumulation of putrescine was evaluated by its apparent kinetic parameters, in the presence or absence of cystamine, and by autoradiography. The investigated tumoral tissue (six squamous carcinomas and five adenocarcinomas) did not show accumulation of putrescine above that attributable to simple diffusion, except for one adenocarcinoma. In this specimen autoradiography showed that the accumulation was not specifically associated with any particular cell type, but that practically every cell accumulated putrescine. We conclude that human pulmonary tumours do not accumulate polyamines in a manner similar to normal pulmonary epithelial cells.

Putrescine and paraquat uptake in human lung slices and isolated type II pneumocytes

Paraquat is accumulated into the lungs of various species by an active uptake system which also appears to mediate the uptake of endogenous polyamines, such as putrescine. The accumulation of putrescine in the human lung has been previously shown to be mainly located in the type II cells. In the present study, we have studied the mutually competitive inhibition of putrescine and paraquat in human lung slices and the inhibition of putrescine by paraquat or cystamine in isolated human type II pneumocytes. Peripheral lung tissue taken from patients undergoing pneumectomy or lobectomy was used. The initial steps of the cell isolation procedure differed from the literature in that the tissue was first sliced in 0.7 mm thick slices, which were washed in phosphate buffered saline without calcium and magnesium (PBS-), followed by incubations with trypsin. The type II cells were purified and isolated by differential adherence on plastic followed by Percoll gradient centrifugation. Uptake was determined 48 hr after cell isolation. The accumulation of radiolabelled putrescine showed saturation kinetics, with the following apparent kinetic parameters: Km 6.7 and 6.2-7.6 microM and Vmax 2.7 and 3.0-3.4 mumol/g prot/hr for slices and isolated cells, respectively. In the presence of paraquat, putrescine uptake was reduced, in both systems, in a manner compatible with competitive inhibition, with calculated inhibition constants (Ki) of 549-614 and 659-895 microM paraquat for slices and isolated cells, respectively. The accumulation of putrescine in isolated human pneumocytes was strongly reduced in the presence of cystamine, with calculated Ki of 3.7 microM cystamine. These data indicate that putrescine, paraquat and cystamine accumulate in the human lung by the same uptake system, but that the affinities for the three substrates differ. The presence of an uptake system for putrescine in cultured human pulmonary type II is probably useful as a functional viability test.

Kinetics and cellular localisation of putrescine uptake in human lung tissue

BACKGROUND

The polyamines (putrescine, spermidine, and spermine) are involved in cellular growth, proliferation, and differentiation. In the lungs of various species, polyamines are accumulated by an active uptake system which also mediates the uptake of cystamine and paraquat. In the rat lung putrescine uptake has been shown to be cell-specific, occurring predominantly in the alveolar epithelium. The aim of this study was to characterise the uptake of putrescine in human lung.

METHODS

Lung tissue was obtained from 31 patients undergoing surgery for lung cancer. Slices (0.7 mm thick) from non-tumour containing lung parenchyma were incubated for 15-60 minutes in Krebs-Ringer phosphate buffer with various concentrations of putrescine (2.5 to 80 mumol/l) containing 0.1 microCi [1,4-14C]-putrescine. Uptake was assessed from tissue radioactivity. For autoradiographic imaging, slices were incubated for 30 minutes with 2.5 mumol/l putrescine containing 2.5 mCi [1,4n-3H]-putrescine.

RESULTS

The accumulation of [14C]-putrescine into slices was time-dependent and energy-dependent, and obeyed saturation kinetics, with mean calculated values for Vmax (maximal rate of uptake) of 414 nmol/g/hour and for Km (medium concentration at which the rate of uptake is half Vmax) of 7.2 mumol/l, with a large interindividual variation. Competitive inhibition was observed on incubation with cystamine, which appears to have a high affinity for the uptake system since its calculated Ki (concentration of inhibitor at which the Km is doubled) was 3.2 mumol/l. Ultrastructural autoradiography showed labelling over both type I and type II cells of the alveolar epithelium, but not over the endothelium or any cells of the interstitium. Alveolar macrophages were also devoid of label.

CONCLUSIONS

These results show that the human lung possesses an active uptake system for putrescine, and probably also cystamine, which is located in both cell types of the alveolar epithelium. These findings may be used to develop tests for the assessment of the alveolar epithelium.

Change of polyamine level in various tissues of male rats intoxicated with paraquat

The effects of paraquat (PQ) on the contents of putrescine (PUT), spermidine (SPD) and spermine (SPM) in the various tissues and organs were examined by means of high-performance liquid chromatography in rats intoxicated with the toxin by three intraperitoneal infusions of PQ for 6 days on every other day. The contents of PUT, SPD and SPM in the large intestine per mg of wet weight showed statistically significant decreases of 39 (P < 0.01), 73 (P < 0.01) and 27% (P < 0.05), respectively. In the liver, however, they showed statistically significant increases of 214 (P < 0.01), 39 (P < 0.05) and 78% (P < 0.01).

PGI2 production and angiotensin converting enzyme activity in cultured porcine pulmonary artery endothelial cells treated with paraquat

The herbicide paraquat (PQ) is known to cause acute pulmonary edema at toxic dose and to induce morphologic changes in alveolar epithelial cells, even in the early phase of toxicity. However, whether the pulmonary vascular endothelial cells are specifically vulnerable to PQ is still controversial. To investigate the direct toxic and metabolic effects of PQ on pulmonary vascular endothelial cells, cultured porcine pulmonary artery endothelial cells (PPAEC) were evaluated. A dose of 10(-4) M of PQ inhibited the growth of endothelial cells. The thrombin- and bradykinin-stimulated production of prostacyclin (PGI2) by PPAEC was significantly enhanced, and the angiotensin converting enzyme (ACE) activity of cell lysate of PPAEC was significantly suppressed after incubation for 24 h with 10(-4) M PQ. No further enhancement of PGI2 production in response to thrombin after 48 h of incubation was demonstrated. These alterations in arachidonic acid metabolism and ACE activity did not result from the cytotoxicity of PQ, because the release of lactate dehydrogenase (LDH) into the culture medium increased only after 72 h incubation with PQ. Incubation for more than 48 h induced an obvious toxis effect on PPAEC.

A novel pharmacological approach for paraquat poisoning in rat and A549 cell line using ambroxol, a lung surfactant synthesis inducer

Paraquat (PQ) is a widely used herbicide that causes acute adult respiratory distress syndrome (ARDS) and chronic lung damage (diffuse fibrosis). One of the earliest biochemical effects induced by PQ is damage to type II pneumocytes with consequent depletion of surfactant. With the aim of counteracting the toxic effects of PQ, a series of investigations were performed into the possible protective effect of the drug ambroxol, which induces the synthesis of surfactant in lung alveolar type II cells. The number of survivors and survival time of rats treated ip with 35 mg PQ/kg was significantly increased by 3 days of ambroxol pretreatment and by ambroxol treatment 30 min or 2 hr after PQ. Total phospholipid content in lung and bronchoalveolar lavage fluid (BALF) was significantly reduced 30 hr after treatment with PQ alone. The association of ambroxol with PQ significantly antagonized this reduction. In BALF the ratio between palmitic acid and stearic acid concentrations was significantly lower in animals treated with PQ alone but was returned to normal by the association with ambroxol. The cell line A549, exposed in vitro to PQ concentrations from 0.5 x 10(-4) to 2 x 10(-3) M, showed a significant dose-dependent loss of viability. Cells pretreated with ambroxol (10 mg/ml) were more resistant to PQ and their viability started to decrease significantly only from a PQ concentration of 0.8 x 10(-3) M. Membrane microviscosity was measured on the same cells. Cells treated with PQ alone showed a reduction of membrane microviscosity, which was significantly counteracted by ambroxol pretreatment. The curves of modification of membrane microviscosity of cells treated with PQ and with ambroxol plus PQ paralleled those of cell viability, indicating that the stimulation of surfactant synthesis in vitro may be a prerequisite for counteracting some of the early effects of PQ.

The accumulation of pentamidine into rat lung slices and its interaction with putrescine

The aromatic diamidine, pentamidine, accumulated into rat lung slices by an uptake system that obeyed saturation kinetics, with an average Km value of 554 microM and a Vmax value of 4077 nmol/g lung wet wt/30 min, respectively. This system was not inhibited by metabolic inhibitors but was greatly diminished by lowering the temperature from 37 degrees to 4 degrees. Both compounds, pentamidine and putrescine, inhibited the uptake of the other and the inhibition of pentamidine accumulation by putrescine was demonstrated to be non-competitive. Uptake of putrescine was inhibited by increasing concentrations of pentamidine. As putrescine accumulates in epithelial type 1 and type 2 cells and in Clara cells, it is likely that pentamidine is also accumulated in these cell types but does not utilize the pulmonary uptake system for polyamine transport. Within the time period studied, toxic effects of the drug were not observed.

Protection of rats against the effects of alpha-naphthylthiourea (ANTU) by elevation of non-protein sulphydryl levels

We have investigated the influence of the elevation of pulmonary glutathione (GSH) levels on the toxicity of the rodenticide alpha-naphthylthiourea (ANTU) to rat lung. Administration of phorone (diisopropylidene acetone; 200 mg/kg i.p.) caused an initial depletion of both pulmonary and hepatic GSH followed after 48 hr by a marked elevation in both tissues, due most probably to a compensatory rebound synthesis. In control rats, ANTU produced a dose-dependent lethality, hydrothorax and loss of ability of lung tissue to accumulate adenosine and spermidine (markers of endothelial and epithelial cell function, respectively). These effects were prevented or markedly ameliorated when ANTU was given 48 hr after pretreatment with phorone. The mechanism of the protection by phorone pretreatment against ANTU-induced pulmonary toxicity is unclear. It may be due, in part, to elevated GSH levels in pulmonary endothelial cells and, in addition, to increased detoxification of ANTU in the liver, resulting in a decreased availability to the lung.

Molecular features necessary for the uptake of diamines and related compounds by the polyamine receptor of rat lung slices

The influence of 17 putrescine analogues on the uptake of putrescine and/or paraquat by rat lung slices has been determined. Most of these compounds are competitive inhibitors of putrescine and/or paraquat uptake, but three show no inhibiting activity. Apparent Ki values of the putrescine derivatives increase, and thus the inhibitory effects decrease, with increasing N-methylation. Comparison of N-methyl-1,4-diaminobutane (Ki = 8 microM) with N,N'-bis-methyl-1,4-diaminobutane (Ki = 25.5 microM) shows that a single primary amino group is desirable for high inhibiting activity. Dimethylation at one amino function does not greatly decrease inhibitory potential (thus N,N-dimethyl-1,4-diaminobutane has Ki = 11.5 microM). Increasing the size of N-alkyl substituents in putrescine derivatives, decreased their inhibitory action on the uptake of putrescine. Investigation of the effect of conformationally-restricted analogues of putrescine shows that both (E) and (Z) isomers of 1,4-diaminobut-2-ene are poor inhibitors of putrescine uptake. Analogues of putrescine with bulky substituents on the butyl chain, i.e. the meso- and rac-isomers of 1,1-dichloro-2,3-diaminomethylcyclopropane, do not inhibit putrescine uptake. Inhibiting putrescine derivatives which contain aziridine groups are competitive inhibitors of putrescine and paraquat uptake. Surprisingly, N-(4-aminobutyl)aziridine is the most effective inhibitor of putrescine uptake studied, and is a better inhibitor of paraquat uptake than the endogenous polyamine, putrescine. N-(4-Aminobutyl)aziridine binds reversibly to the polyamine transporter and its inhibitory effects do not appear to be due to any cytotoxic activity of the aziridine. The parameter A (mM)-1 defined as 1000/Ki (where Ki units are microM) was taken as a measure of the affinity of a compound for the polyamine receptor in this paper.

Diamine uptake by rat lung type II cells in vitro

Lung epithelial type II cells are responsible for synthesising and secreting pulmonary surfactant which reduces surface tension and prevents lung collapse. Type II cells replace type I cells and can proliferate in response to alveolar injury. An important aspect of this proliferation may be the ability of type II cells to accumulate amines actively, particularly the endogenous diamine putrescine. Putrescine is accumulated into isolated alveolar type II cells by an energy-dependent process. The uptake obeys saturation kinetics for which an apparent Km of 14.7 microM and Vmax of 130 pmol/micrograms DNA/hr was derived. The inhibitory effects of structurally similar amines on putrescine accumulation are described. As the herbicide paraquat has been suggested to share the same uptake system as putrescine from lung slice studies, this phenomenon was investigated in type II cell cultures. The results demonstrated that paraquat is a partially competitive inhibitor of putrescine accumulation in the cells. The Ki for the inhibition of putrescine uptake by paraquat in type II cells was calculated to be 69 microM, a value which closely matches the Km for paraquat (70 microM) predicted from lung slice studies. In molecular terms, the partial nature of the competition indicates that paraquat and putrescine do not occupy identical sites. Saturation of its site by paraquat reduced the affinity of putrescine 3.6-fold, but did not abolish it.

Mechanism of protection of alveolar type II cells against paraquat-induced cytotoxicity by deferoxamine

Paraquat toxicity has been associated with the generation of free radicals in alveolar epithelial cells in which paraquat specifically accumulates via a polyamine uptake system. In the present study we investigated whether deferoxamine (DF), an iron chelator that has antioxidant capacity and that also has a polyamine-like structure, could protect alveolar type II cells (ATTC) against injury by paraquat. Radiolabeled [3H]adenine ATTC were incubated in a medium containing 75 microM paraquat in the absence or presence of DF (500 microM). After 3 hr of incubation paraquat-mediated cytotoxicity of ATTC, as measured by [3H]adenine release, was significantly (P less than 0.005) decreased by addition of DF (26.6 +/- 2.6% vs 7.4 +/- 1.7%). Accumulation of radiolabeled [14C]paraquat at a concentration of 75 microM was also decreased (70%) by 500 microM DF from 94.8 +/- 2.1 to 28.9 +/- 6.7 nmoles paraquat/2.5 x 10(5) ATTC. This effect of DF was dose dependent and comparable with the protective effect of equimolar concentrations of putrescine. However, per cent uptake of paraquat at a concentration of 500 microM was not significantly inhibited by DF (1 mM), whereas paraquat-induced injury was still markedly reduced (36.2 +/- 2.5% vs 2.6 +/- 4.2%). This indicated that the protective effect of DF could not be explained by its competition with paraquat on uptake alone. In the same series of experiments using another iron chelator, pyridoxal benzoyl hydrazone (PBH), which has antioxidant properties similar to DF but does not show its polyamine-like structure, ATTC lysis was also prevented although paraquat uptake was not reduced. These in vitro data indicate that the mechanism of protection by DF against paraquat toxicity in lung epithelial type II cells is two-fold: inhibition of paraquat uptake through its compliance with the structural requirements necessary for transport, and inhibition of paraquat-induced iron-catalysed free radical generation.

The identification and characterization of an uptake system for taurine into rat lung slices

The objective of this study was to determine whether taurine was accumulated by rat lung slices and if so, to establish the role of this uptake as a source of pulmonary taurine. We have shown that taurine is accumulated into rat lung by an active uptake process that was both ATP and Na(+)-dependent and obeyed saturation kinetics, exhibiting an apparent Km of 186 microM and Vmax of 970 nmol/g wet wt/hr. Substrate specificity of the system was high and only compounds possessing anionic and cationic groups separated by two methylene groups were able to competitively inhibit taurine uptake. Subsequent to its uptake, taurine was not significantly metabolized, and since the apparent Km for the uptake process is similar to the known plasma concentration of taurine, it can be inferred that this system will contribute to pulmonary taurine uptake in vivo. Taurine has been suggested to possess antioxidant and antiinflammatory properties, and we suggest that this uptake system may contribute to the defence of pulmonary tissue against oxidative stress.

Potentiation of the cell specific toxicity of paraquat by 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU). Implications for the heterogeneous distribution of glutathione (GSH) in rat lung

In order to study oxidative stress in the lung, we have developed a rat lung slice model with compromised oxidative defences. Lung slices with markedly inhibited glutathione reductase activity (approximately 80% inhibition) were prepared by incubating slices, with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) (100 microM) in an amino acid-rich medium for 45 min at 37 degrees. These lung slices had similar levels of GSH and ATP and polyamine uptake (a marker of alveolar epithelial type I and II cell function) to control rat lung slices. We have utilized these BCNU pretreated slices to study the effects of the herbicide, paraquat, in comparison to those of 2,3-dimethoxy-1,4-naphthoquinone, a potent redox cycler. Paraquat (10-100 microM) caused only minimal changes in the levels of GSH or ATP in control or compromised slices. In contrast, 2,3-dimethoxy-1,4-naphthoquinone caused a decrease in GSH in control slices but a markedly enhanced decrease in both GSH and ATP in compromised slices. Both compounds had only limited effects on putrescine and spermidine uptake in control slices. However, they caused a marked inhibition in compromised slices. Paraquat had little effect on 5-hydroxytryptamine uptake (a marker of endothelial cell function) in either control or compromised slices whereas the quinone inhibited uptake in the compromised slices. Thus, the lack of effect of paraquat on GSH and ATP does not support the involvement of oxidative stress in its toxicity. In contrast, using polyamine uptake, as a functional marker of alveolar epithelial cell damage, suggests a role for redox cycling. As paraquat is known to be accumulated primarily in alveolar type I and II cells (a small fraction of the lung cell population), our data suggest that only a small proportion of pulmonary GSH and ATP is present in alveolar epithelial type I and II cells but that much larger amounts may be present in endothelial cells. These studies highlight the problem of gross tissue measurements in heterogeneous tissues such as the lung.

Characterisation of putrescine uptake by cultured adult mouse hepatocytes

Uptake of polyamines by cultured cells has been shown to be influenced by growth rate and/or differentiation. In this study, we have investigated whether the fully differentiated, non-proliferating adult mouse hepatocyte is capable of accumulating extracellular putrescine. When hepatocytes were cultured from 4 to 48 h, uptake of putrescine was found to increase substantially with time spent in culture. The Vmax for putrescine uptake increased 22-fold during this period with no change in apparent Km. Treatment of the cells with cycloheximide or actinomycin D at concentrations that did not affect cell viability inhibited the induction of putrescine uptake. Endogenous putrescine levels increased from 19.7 nmol/mg DNA after 4 h in culture to over 500 nmol/mg DNA after 48 h in culture. This increase was accompanied by a loss of over 90% of ornithine decarboxylase activity. Spermidine levels did not change over this time period, whereas spermine levels decreased by 35%. Difluoromethylornithine prevented the observed increase in intracellular putrescine but did not affect putrescine uptake. The increase in putrescine transport was not inhibited by culturing the hepatocytes in a high concentration of putrescine, spermidine or spermine. Moreover, the induction process was not stimulated by foetal calf serum but was selectively inhibited by the differentiating agents dimethylsulfoxide and retinoic acid. The results from those studies show that cultured mouse hepatocytes express a putrescine transport system that is poorly regulated by extracellular polyamines. The expression of the transporter requires the synthesis of mRNA and protein, and appears to be related to a time-dependent change in hepatocyte phenotype.

Localization of spermidine uptake in rabbit lung slices

The lungs have a high polyamine transport capability, and the type II pneumocyte has recently been identified as a major site of putrescine uptake and localization (N. A. Saunders, P. J. Rigby, K. F. Ilett, and R. F. Minchin. Lab. Invest. 59: 380-386, 1988). However, recent evidence suggests that multiple polyamine transport systems exist. In the present study, localization of spermidine uptake in rabbit lung was investigated. Although [14C]spermidine was rapidly accumulated by lung slices, it was not significantly metabolized, and no efflux of the accumulated polyamine was apparent. Autoradiographs prepared after [3H]spermidine transport revealed a localization of uptake activity to cells identified by electron microscopy as type II pneumocytes. Spermidine uptake occurred in all type II cells examined and thus appeared to be a characteristic function of this cell type. In contrast, spermidine uptake was virtually absent in the major airways and blood vessels, whereas moderate uptake was associated with pulmonary alveolar macrophages and alveolar tissue. Subsequent purification and culture of type II pneumocytes showed these cells to have significant polyamine uptake activity. In addition, spermidine uptake activity was positively correlated with the proportion of type II cells present at the various stages of their purification. In other studies, cultured pulmonary alveolar macrophages possessed similar uptake activity to that of cultured type II cells. Combined, these data suggest that both type II cells and pulmonary alveolar macrophages may represent major sites of spermidine uptake in vivo. We also suggest that the transport of polyamines by type II cells may reflect a critical role for polyamines in a characteristic function of this cell type.

Pulmonary alveolar macrophages express a polyamine transport system

Polyamine transport is an important mechanism by which cells regulate their intracellular polyamine content. It is well established that the lung has a high capacity for polyamine transport, and recently the polyamine putrescine has been shown to be selectively accumulated into the type II pneumocyte of rabbit lung slices (Saunders et al.: Lab. Invest., 95:380-386, 1988). In addition, it has been suggested that there may be more than one polyamine transport system in lung tissue (Byers et al.: Am. J. Physiol., 252:C663-C669, 1987). In the present study, we have examined whether there are differences in the distribution of putrescine and spermidine uptake activities in isolated rabbit lung cells. We report that pulmonary alveolar macrophages have a greater rate of uptake of both putrescine and spermidine than the total lung cell population. Kinetic analysis of the polyamine uptake system present in macrophages showed putrescine uptake consisted of a saturable (Km = 2.1 microM) and nonsaturable component whilst spermidine uptake consisted of both a high- and a low-capacity saturable component (Km = 0.16 microM and 1.97 microM, respectively). The rate of polyamine transport was similar to those reported for many proliferative or tumor cell-lines and appears to be greater than any other major lung cell type. Inhibition studies of the transport of polyamines into pulmonary alveolar macrophages suggested that the uptake of both putrescine and spermidine was mediated by the same system, which could not be described by simple Michaelis-Menten kinetics. The transport appears to be reversible due to significant efflux. This is the first study to describe the presence of multiple polyamine transport systems in pulmonary alveolar macrophages.

Effects of paraquat on canine bronchoalveolar lavage fluid

Bronchoalveolar lavage (BAL) recovers the epithelial lung fluid of the lower respiratory tract. In this study, we have used BAL to detect early pulmonary injury in beagle dogs following an intravenous infusion of 10 mg paraquat dichloride/kg bodyweight. Bronchoalveolar lavage was performed twice in 11 dogs, 60 hr before and 34 hr after an intravenous infusion of paraquat dichloride (n = 8) or saline (n = 3). The dogs were studied in three groups: (1) paraquat only (n = 4); (2) paraquat plus hemoperfusion (n = 4); and (3) hemoperfusion only (n = 3). Because hemoperfusion, a treatment used for paraquat poisoning, could have effects on BAL independent of paraquat, we evaluated the effects on BAL fluid of this procedure performed separately from and together with administration of paraquat. We examined cytology, proteins, enzymes, and glutathione in the BAL fluid and expressed all results per milliliter of aspirated lavage fluid. Hemoperfusion did not alter the BAL fluid. In contrast, in dogs studied 34 hr after administration of paraquat, total cell counts, alveolar macrophage and neutrophil counts, and concentrations of total protein, albumin, ACE, LDH, and ALP were increased. Bronchoalveolar lavage in the dog provides an excellent tool with which to detect early paraquat-induced pulmonary injury. The same technique could be useful for sequential monitoring of other types of pulmonary disease and injury.

Competition for polyamine uptake into rat lung slices by WR2721 and analogues

The objective of these studies was to determine whether a series of structurally related radioprotective agents could act as substrates for the recently identified polyamine system in the lung. We have shown that WR2721 (S-2(3-aminopropylamino)ethyl phosphorothioate), S-2(4-aminobutylamino)ethyl phosphorothioate (S-ABEP or WR2822) and S-2(7-aminoheptylamino)ethyl phosphorothioate (S-AHEP) competitively inhibit the uptake of putrescine into rat lung slices. The ability of the radioprotectors to act as substrates for the polyamine uptake system was expressed as the Ki for each compound. The Ki values for WR2721, S-ABEP and S-AHEP in the absence of dithiothreitol were 48, 57 and 7 mumol dm-3 compared to 155, 88 and 15 mumol dm-3 in the presence of dithiothreitol, indicating that the disulphide form may have a higher affinity for the transport system. By analogy with other substrates for the polyamine uptake system we have concluded that it should be possible to target radioprotectors to the alveolar epithelial type I and II cells and the Clara cells in the lung, as they prossess this uptake system, and thus protect these cells from oxidative stress.

The accumulation of cystamine and its metabolism to taurine in rat lung slices

The objective of these studies was to determine the accumulation and fate of the disulphide, cystamine by rat lung slices. Cystamine was accumulated by two active uptake systems that obeyed saturation kinetics, with apparent Km values of 12 and 503 microM, and maximal rates of 530 and 5900 nmol/g wet weight/hr respectively. The high affinity system was competitively inhibited by the diamine, putrescine and the herbicide paraquat, which are themselves accumulated. Thus, this pulmonary uptake process appears to be identical for all three compounds. In contrast, the low affinity process was not inhibited by putrescine, and this process results from the diffusion of cystamine into the cell and its subsequent metabolism. Upon accumulation, cystamine was metabolised, predominantly to the sulphonic acid, taurine, with 10-20% of the intracellular label covalently binding to protein. Conversion to taurine was unaffected by amine oxidase inhibitors, but was decreased after GSH depletion, suggesting that pulmonary cystamine metabolism is glutathione-dependent, and is not mediated by diamine oxidase. Both cystamine and taurine have been implicated as antioxidants, and we suggest that cystamine is actively accumulated by the lung as part of the process to protect pulmonary tissue against oxidative stress.

Spermidine uptake by type II pulmonary epithelial cells in primary culture

The transport pathway for the polyamine spermidine (SPD) was characterized in primary isolates of type II pulmonary epithelial cells from rat lungs. [14C]spermidine was accumulated by type II cells via a temperature-, sodium-, and concentration-dependent saturable pathway, with an apparent Km of 0.48 microM and a maximum velocity (V max) of 0.32 pmol.microgram DNA-1.min-1. SPD uptake was inhibited by gramicidin and by reduced extracellular sodium but was unaffected by alpha-aminoisobutyric acid (AIB), which entered the cells by a similar saturable pathway. Uptake of SPD also was inhibited by the exogenous polyamines putrescine (PUTR) and spermine (SPM), as well as by the methylglyoxal bis(guanylhydrazone) (MGBG) and by paraquat (PQ). The order of potency of these inhibitors was SPM greater than PUTR = MGBG much greater than PQ. The absence of serum reduced the Vmax of the system slightly but had no effect on the apparent Km. In contrast, after 3 days in primary cell culture, the kinetics of SPD transport were altered by decreases in both the Km and Vmax of the uptake process. These observations indicate that type II pulmonary epithelial cells exhibit a pathway of polyamine uptake with general characteristics similar to those observed previously in intact lung tissue and other cell types.

Pulmonary indoleamine 2,3-dioxygenase activity and its significance in the response of rats, mice, and rabbits to oxidative stress

The physiological significance of the enzyme indoleamine 2,3,-dioxygenase (IDO) (EC 1.13.11.17), which consumes superoxide anion (O2-), is not known. Since this enzyme is found in high concentrations in lung tissue, we examined the possibility that IDO may protect against chemically induced oxidative stress in the lung. The induction of IDO by bacterial lipopolysaccharide (LPS) was found to be 20-fold in the mouse and 4-fold in the rat, but did not confer protection against paraquat-induced pulmonary toxicity. Moreover, paraquat, when dosed to rats or mice, did not induce pulmonary IDO activity. An elevation in the intracellular O2- concentration was sought by incubating lung slices with 5 mM diethyldithiocarbamate (DDTC) (to inhibit SOD), paraquat (10(-4) M), or methylene blue (10(-4) M) or under an atmosphere of 100% oxygen. These attempts did not enhance the IDO activity in lung slices prepared from control or LPS-treated rats and mice. There was also no evidence that the uptake of an IDO substrate, tryptophan, was limiting for IDO activity in rat and mouse lung slices. We have concluded in the case of rats and mice that the pulmonary IDO activity, even following induction, is too low for O2- to be the rate-limiting factor. For this reason IDO cannot act as a protective enzyme by scavenging O2- in the lung of these species. However, in the rabbit, a species comparatively resistant to paraquat- and oxygen-induced lung damage, pulmonary IDO activity is 170 times that of rats or mice. IDO activity in rabbit lung slices was increased 4-fold by incubation with 5 mM DDTC and 10-fold by incubation with methylene blue (10(-4) M). However, paraquat (10(-4) M and oxygen (100% atmosphere) were able to enhance IDO activity (5-fold) only when SOD had previously been inhibited. We have concluded that in the rabbit lung IDO is able to scavenge O2- and therefore has the potential to act as a protective enzyme in this species.

Passive sequestration of putrescine, spermidine and spermine by rat lungs

The pulmonary uptake and accumulation of the three polyamines putrescine, spermidine and spermine by isolated ventilated and perfused rat lungs was investigated using 0.1, 1 or 5 mM concentrations of these compounds. The lung uptake of putrescine for all concentrations was greater than that of spermidine and spermine, but all three showed concentration-dependent linear uptake. A significant uptake of all three polyamines was also observed when incubated separately with rat lung slices for 60 min. Harmaline (0.4 mM), ouabain (0.2 mM) and perfusate with decreased Na+ (50 mEq/l) did not affect the uptake of any of the three polyamines by isolated perfused rat lungs or rat lung slice incubations. HPLC analysis of the whole lung or slices and media after perfusion or incubation studies, respectively, with polyamines did not reveal the presence of any metabolites. Likewise, the analysis of the lung homogenate incubated at 37 degrees C for 60 min with polyamines did not show any metabolites, confirming the absence of detectable pulmonary metabolism. These findings indicate a significant accumulation of polyamines in the rat lungs, accumulation predominantly occurring via simple diffusion, at variance with the reported active polyamine uptake process in the lung.

The accumulation and localisation of putrescine, spermidine, spermine and paraquat in the rat lung. In vitro and in vivo studies

Putrescine was accumulated into the isolated perfused rat lung by a temperature dependent process. The uptake obeyed saturation kinetics for which an apparent Km of 14 microM and Vmax of 48 nmol/g wet wt/hr was derived. After rats were dosed subcutaneously with [14C]putrescine, it was accumulated in the lung to concentrations greater than that in the plasma with the highest amount found between 3 and 12 hr. From 3 hr after dosing until 24 hr, there was a progressive increase in 14C label incorporated into spermidine, indicating that putrescine was converted to spermidine. Using autoradiographic techniques in lung slices the [3H]oligoamines were found in the alveolar epithelial type II. Clara and very probably the alveolar type I cells. With [3H]paraquat, the presence was detected only in the alveolar type II cells. Likewise, in the isolated perfused rat lung or following s.c. dosing of rats with [3H]putrescine the radiolabel was located only in the alveolar type II cell. We have suggested that the most likely explanation for the differences in localisation of label between in vitro and in vivo studies resulted from the use of [3H] label of different specific activity. Consequently we have concluded that the cell types with the ability of accumulate paraquat and oligoamines were the alveolar epithelial type I and type II cells and Clara cells.

Isolation, biochemical characterization, and culture of lung type II cells of the rat

A method is described for the isolation of rat lung epithelial Type II cells using trypsin digestion of tissue to release cells for subsequent separation by Percoll gradient centrifugation. Both the concentration of trypsin and the age (body weight) of the rat affect the yield from primary digestion and the final number of Type II cells obtained. A lung weighing 1 g from a 200 g rat yields approximately 30 X 10(6) washed Type II cells (approximately 25% of the total estimated lung population). These cells have a plating efficiency of 40-50% after 48 h of culture. The cells have a high alkaline to acid phosphatase ratio (usually greater than 4.0) compared with that of alveolar macrophages (0.1) and accumulate putrescine by an active transport mechanism with an apparent KM between 8 and 14 microM. Together with studies of [3H]thymidine uptake into DNA, which is maximal between 48 and 72 h of culture, these quantitative measurements form a good basis for investigating the interactions between a number of chemical agents and Type II cells in vitro.

Multiple pathways for uptake of paraquat, methylglyoxal bis(guanylhydrazone), and polyamines

The uptake of polyamines, methylglyoxal bis(guanylhydrazone) (MGBG), and paraquat [N,N-dimethyl-4,4'-bipyridylium] into control Chinese hamster ovary (CHO) cells and a mutant CHO cell line selected for resistance to the toxicity of MGBG was examined. In contrast to control CHO cells, the mutant cells had no detectable uptake of MGBG or any of the polyamines. There was no difference between the two cell lines in the uptake of alpha-aminoisobutyric acid (AIB), which indicates that there was no general change in membrane transport processes. The mutant cells were also found to be resistant to the toxicity of paraquat and to have a reduced capability to take up the herbicide. This finding confirms that the uptake of paraquat is necessary for the toxicity of this compound and that the paraquat is taken up by a transport system that also transports MGBG. Competition experiments showed that an excess of unlabeled paraquat inhibited uptake of MGBG and, to a lesser extent, uptake of putrescine and spermidine, but no inhibitory action on spermine uptake could be detected. Studies with type II cells isolated from rat lung also demonstrated uptake of paraquat and spermidine, but paraquat was only a weak inhibitor of spermidine uptake in this system. These results suggest that there may be multiple systems for the uptake of MGBG and polyamines and that paraquat is taken up by at least one but not by all of these systems.

Specific polyclonal and monoclonal antibody prevents paraquat accumulation into rat lung slices

Sheep polyclonal and mouse monoclonal antibodies have been produced that bind to the bipyridyl herbicide, paraquat. The binding capacities and affinities of the various antibody solutions (serum, ascites, purified tissue culture supernatant) to paraquat were determined using a radioimmunoassay. All antibody solutions bound paraquat with high affinity (Ka = 10(9)-10(10) l/mol). The sheep polyclonal antisera, the mouse ascites fluid, and the purified culture supernatant had mean binding capacities of 8, 1 and 22 micrograms paraquat/ml respectively. All the antibody preparations were able to prevent the in vitro accumulation of paraquat into rat lung tissue. The amount of antibody to achieve this was dependent upon the binding capacity of the antibody solution, i.e. when the binding capacity of the antibody was equal to the amount of paraquat present in the incubation medium a total blockade of uptake was achieved. When antibody was added to lung tissue that had been accumulating paraquat for 1 hr, the inhibition of uptake was immediate and was complete for at least 2 hr. Both the radioimmunoassay and lung slice experiments indicate that an equivalent of 1 mg of IgG is required to bind 2.5 micrograms of paraquat ion. Preincubation of lung tissue with antibody did not affect the subsequent accumulation of paraquat, nor did it result in a detectable degree of intracellular neutralisation of paraquat as measured by paraquat's ability to stimulate the pentose phosphate pathway. The rate of efflux of paraquat from lung slices prepared from rats dosed intravenously with paraquat was not increased by the presence of antibody in the incubation medium. In conclusion, neutralising antibodies to paraquat have been produced. They bind to paraquat in solution with high affinity and render the paraquat unavailable for its in vitro accumulation into lung cells.

Uptake, efflux and metabolism of the polyamine putrescine in rabbit lung slices

The herbicide paraquat is a selective pulmonary toxin in many mammals, including man, and its pulmonary toxicity has been attributed to selective uptake by a polyamine transport system in lung. In the present study, we investigated the characteristics of this transport process in rabbit lung slices. [14C]Putrescine was accumulated by both saturable and non-saturable processes and the accumulated putrescine was non-effluxable over 60 min. The saturable component was inhibited by spermine and paraquat. Moreover, uptake studies in Na+-deficient medium indicated that the lack of Na+ may selectively enhance uptake via the non-saturable process. The two components also differed in the metabolic fate of accumulated substrate. At 0.6 microM putrescine, where the saturable process predominated, 98% of the 14C in the perchloric acid-soluble fraction of tissue homogenates was present as putrescine, whilst 3% of the accumulated substrate was found in the acid-insoluble fraction. With 500 microM putrescine, where the non-saturable process predominated, 82% of the 14C in the acid-soluble fraction was present as putrescine and 15% of accumulated putrescine was found in the acid-insoluble fraction. The acid-insoluble 14C was localised mainly in the 700 g and 4500 g pellets obtained after homogenising the tissue. We conclude that there are two components to putrescine uptake in rabbit lung slices, both of an apparently irreversible nature. We suggest that the components represent compartmentalisation of putrescine in selective pulmonary cell-types or separate subcellular organelles. The observed metabolism and covalent binding of putrescine appeared to be associated with the non-saturable component only.

Evidence for the reversible binding of paraquat to deoxyribonucleic acid

Evidence for the reversible binding of paraquat to calf thymus DNA has been obtained using equilibrium dialysis and thermal melting point determinations. The data indicated the presence of at least two populations of binding site with affinity constants of 6.2 X 10(4) and 7.1 X 10(3) M-1, respectively. The binding capacities of DNA for paraquat were 66 and 480 nmol/mumol DNA nucleotide, respectively, and were equivalent to one ligand bound per 2 DNA phosphate groups. Putrescine inhibited paraquat binding to the low affinity sites without altering binding to the high affinity sites. Scatchard plots of paraquat binding characteristics indicated the presence of positive cooperativity between the compound and DNA. Thermal melting curves of DNA in the presence of paraquat and the endogenous amines putrescine, spermidine and spermine, provided evidence that paraquat cross-linked to DNA with a similar affinity as spermidine. The thermal melting point data also suggested the presence of positive cooperativity between ligand and macromolecule that possibly resulted from a conformation change in the structure of the DNA molecule. Paraquat competitively inhibited the binding of ethidium bromide to DNA and this effect was reversed by Na+. From the data, it is suggested that paraquat binds primarily to the negatively charged phosphates on the DNA backbone but is displaced into the interbase region occupied by the intercalator ethidium bromide. DNA binding of paraquat may, in part, account for its weak mutagenic activity.

Uptake of exogenous spermidine by rat lungs perfused in situ

Uptake of the polyamine spermidine (SPD) from the pulmonary circulation was characterized by using ventilated rat lungs perfused in situ with Krebs-Henseleit-bicarbonate buffer containing 4.5% bovine serum albumin, 5.6 mM glucose, and 20 amino acids at plasma levels. [14C]SPD was accumulated by the lungs in a time- and concentration-dependent manner. The pathway of SPD uptake exhibited saturation kinetics with an apparent Km in the range of 1 microM and a Vmax of 450-540 pmol/g lung min. SPD uptake was inhibited by the naturally occurring polyamines putrescine and spermine (SPM) and by the inhibitor of polyamine synthesis, methyglyoxal bis(guanylhydrazone) (MGBG). Inhibition of SPD uptake by SPM followed competitive kinetics; although MGBG was also a competitive inhibitor of SPD uptake, MGBG was less effective than SPM. These observations indicate that SPD is taken up from the pulmonary circulation by a carrier-mediated pathway that is inhibited by other natural polyamines and by MGBG and exhibits substrate affinity in the range of plasma SPD concentrations.

Mechanism of paraquat toxicity in lung and its relevance to treatment

The symptoms of paraquat poisoning depend largely on the amount of compound consumed, although in many cases the most characteristic feature of poisoning is lung damage, causing severe anoxia which leads to death. Studies in experimental animals have demonstrated that paraquat produces an acute damaging phase in the lung, followed by a reparative phase dominated by an extensive fibrosis. The latter is a major contributor to the lung lesion that causes anoxia. The specific toxicity in the lung can be explained in part by the selective accumulation of paraquat into this organ in comparison with other tissues. The accumulation is energy-dependent and probably specific to certain lung cells. It is now known that paraquat is accumulated into the lung by a recently described diamine transport process located in the alveolar epithelial cells and the Clara cells of the airways. When accumulated, paraquat undergoes a NADPH-dependent one-electron reduction to for its free radical which almost instantly reacts with molecular oxygen to reform the cation and concomitantly produce superoxide anion. This species of oxygen radical can contribute to the formation of more toxic species of radical which may directly damage vital cellular constituents. Paraquat has been shown to stimulate rapidly the pentose phosphate pathway and inhibit the synthesis of fatty acids in the lung in a dose-dependent manner. In addition there is a rapid increase in the pulmonary levels of mixed disulphides and the eventual reduction of NADPH levels in the lung. These results are consistent with the suggestion that paraquat causes a rapid and pronounced oxidation of NADPH which initiates compensatory biochemical responses in the lung.(ABSTRACT TRUNCATED AT 250 WORDS)

Increased pulmonary uptake of exogenous polyamines after unilateral pneumonectomy

Alterations in pulmonary uptake of the naturally occurring polyamine spermidine and of an exogenous polyamine substrate analogue, methylglyoxal bis(guanylhydrazone) (MGBG), were investigated during the early phase of compensatory lung growth after partial pneumonectomy (PNX) in rats. In lungs perfused in situ 3 days after left PNX, when a small (14%) but significant (P less than 0.01) increase in right lung mass could be detected, uptake of [14C]spermidine and of [14C]MGBG from the pulmonary circulation was increased. MGBG uptake exhibited saturation kinetics (1-50 microM MGBG), both in lungs of control animals apparent Km, 11.3 microM; Vmax, 479 pmol X g-1 X min-1) and on the 1st and 3rd post-PNX days. In both PNX groups, the apparent Km of the uptake pathway was decreased somewhat (8.5 microM), while Vmax increased progressively to 584 and 678 pmol X g-1 X min-1 at days 1 and 3, respectively. The effects of PNX on MGBG uptake were detected as early as 3 h after lung resection and were no longer evident when compensatory lung growth was completed 14 days after surgery. In rats adrenalectomized 5 days before left PNX, an accelerated onset and increased rate of lung restoration were associated with a doubling of the effect of PNX alone on MGBG uptake.

Paraquat toxicity

Paraquat (1,1'-dimethyl-4,4'-bipyridylium dichloride) is marketed as a contact herbicide. Although it has proved safe in use there have been a number of cases of poisoning after the intentional swallowing of the commercial product. The most characteristic feature of poisoning is lung damage, which causes severe anoxia and may lead to death. The specific toxicity to the lung can be explained in part by the accumulation of paraquat into the alveolar type I and type II epithelial cells by a process that has been shown to accumulate endogenous diamines and polyamines. When accumulated, paraquat undergoes an NADPH-dependent, one-electron reduction to form its free radical, which then reacts avidly with molecular oxygen to reform the cation and produce superoxide anion, which in turn will dismutate to form H2O2. This may lead to the formation of more reactive (and hence toxic) radicals which have the potential to cause lipid peroxidation and lead to cell death. Biochemical changes provoked by paraquat in the lung suggest that it causes a rapid, pronounced and prolonged oxidation of NADPH that initiates compensatory biochemical processes in the lung. NADPH may be further depleted as it is consumed in an attempt to detoxify H2O2 or lipid hydroperoxides. Thus it is possible that with toxic levels of paraquat in the cell, compensatory biochemical processes are insufficient to maintain levels of NADPH consistent either with cell survival or with the ability to detoxify H2O2 or prevent lipid peroxidation.

Polyamine uptake by bovine adrenocortical cells

Bovine adrenocortical cells of fasciculo-reticulata origin in primary culture actively accumulate polyamines from the extracellular medium in an energy-dependent process. At low extracellular concentration (e.g., 1 microM putrescine), the transport system resulted in a several-hundred-fold concentration of polyamine in the cellular compartment within 1-2 h of incubation. Putrescine uptake appeared to be the sum of a sodium-dependent, saturable process, with an apparent Km of about 10 microM and of a non-saturable, sodium-independent component. By contrast, spermine was taken up by the cells mostly in a sodium-independent manner. Cross-competition experiments suggested that both polyamines were at least partly transported by the same system. Using specific corresponding probes, it was shown that the polyamine uptake was independent of the amino acid transport systems of the A, L and N types known in a number of cell systems. Adrenocortical cell polyamine content is known to be modulated by adrenocorticotropin through induction of ornithine decarboxylase activity. The existence of a specific uptake system in these cells opens the possibility of a more rapid pathway for the regulation of cellular polyamine levels. It remains to be examined whether this polyamine transport system is under hormonal control, and whether this can support the suggestion that polyamines may represent a form of intracellular messengers in the mechanism of hormone action.

Pulmonary accumulation of methylglyoxal-bis(guanylhydrazone) by the oligoamine uptake system

The accumulation of methylglyoxal-bis(guanylhydrazone) (MGBG) into rat lung slices and its relationship to the accumulation of oligoamines has been investigated. MGBG was accumulated by rat lung slices by a process which obeyed saturation kinetics (Km 6.6 microM; Vmax 75.3 nmoles/g wet wt lung/hr). The uptake process appeared to be identical to those described for the accumulation of oligoamines and paraquat, being both KCN-(1 mM) and temperature-sensitive but insensitive to ouabain (100 microM). Pulmonary MGBG accumulation was found to be sodium-independent, either being enhanced or unaffected by sodium chloride-deficient media, so distinguishing the process from that described for the monoamine, 5-hydroxytryptamine. The ability and nature of various rat tissue slices to accumulate MGBG generally followed that of the oligoamines. Slices of lung, brain cortex and seminal vesicles accumulated MGBG by a KCN-sensitive and temperature-dependent process. These observations, together with the ability of MGBG to inhibit pulmonary oligoamine accumulation, indicate that it is the uptake system for the oligoamines which is mainly responsible for the in vitro accumulation of MGBG.