Effect of immobilization stress on pipecolic acid transport in mouse brain areas and peripheral tissues

Transport activity of d-pipecolic acid and of l-pipecolic acid in mouse brain and peripheral tissues were tested, and the effect of immobilization stress was described, along with the method for preparative, enantiomeric resolution and purification of d,l-pipecolic acid using high performance liquid chromatography equipped with a chiral column. It was found that l-isomer, an endogenous substance, was more rapidly transported to brain and liver than the d-isomer, non-endogenous one, which was more rapidly eliminated into the kidney. Immobilization stress caused acceleration of transport of l-pipecolic acid into the brain region, liver and heart, but not that of d-pipecolic acid. From these results it was suggested that the elevation of pipecolic acid concentration caused by stress might be exerted through its stimulatory effect on the transport of l-pipecolic acid into the tissues.     

Accumulation and metabolism of pipecolic acid in the brain and other organs of the mouse

The long-term accumulation of pipecolic acid, as well as its disappearance following exogenous administration was studied in brain and other organs of the mouse. Mice were pulse-injected intraperitoneally or intravenously with 1Ci[³H]D,l-pipecolic acid (6.9 nmol/mouse=2.9 g/kg). The total radioactivity retained in tissues was measured in brain, liver, and kidney, as well as in plasma during the period 1 min to 24 hr. TLC separation of DNP-derivatives was performed. Three features of the pattern of retention of pipecolic acid are most salient; first the rapid accumulation in brain, second the rapid secretion of this compound in the urine, and third the long-lasting steady levels of radioactivity maintained in brain.Sixty minutes after i.v. injection, the brain/plasma ratio is approximately 0.2 and approaches unity only at 5 hr. Following intraperitoneal injection the percent recovered as pipecolic acid in brain is 78% at 30 min and 71% at 120 min, suggesting a slow metabolic activity. Liver shows a different trend than brain with a slower accumulation and a faster disappearance. Kidney shows a pattern similar to plasma with a rapid secretion of radioactivity into urine which correlates well with the exponential decrease in plasma and urine. The administration of probenecid significantly increases radioactivity due to pipecolic acid in brain, liver, and urine. Formation of -aminoadipic acid, a known metabolite of pipecolic acid, can be demonstrated in kidney 30 min after intraperitoneal injection. The present data together with results obtained previously with intracarotid injections suggest that pipecolic acid is taken up in the mouse brain from the circulation. Most of the pipecolic acid taken up is rapidly removed through the circulation and secreted in the urine; however, a small part is retained and probably metabolized by brain and kidney.     

The conversion of lysine into piperidine,cadaverine, and pipecolic acid in the brain and other organs of the mouse

The biosynthesis of piperidine, a possible neuromodulator, and its presumed precursors cadaverine and pipecolic acid, has been investigated in the mouse under in vitro conditions. Conversion of lysine into piperidine was observed only in the intestines and is probably caused by the intestinal flora. Formation of cadaverine and pipecolic acid from lysine was observed in the brain, liver, kidney, and large intestine. In addition, pipecolic acid was formed in the heart. The possible contributions of the diet and of the intestinal bacteria to the endogenous pool(s) of piperidine are discussed.     

Liver, Brain, and Heart Metallothionein Induction by Stress

To date, stress has been reported to induce metallothionein (MT) synthesis in the liver only. In the present experiment, the effects of food and water deprivation alone or of immobilization stress plus food and water deprivation on liver, brain, and heart MT have been studied in adult male rats. Liver and brain MT levels were increased by immobilization stress as soon as 6 h after the onset of stress. Eighteen hours of immobilization, which is accompanied by food and water deprivation, further increased liver and brain MT levels and significantly increased heart MT content. A specific effect of immobilization was evident in all three tissues, because the effect of food and water deprivation alone was significantly lower than that of immobilization plus starvation. Changes in MT apparently were not related to changes in cytosolic Zn.     

Changes in drug-metabolizing activities in the livers of suckling rats as a result of treatment of the lactating mothers with phenobarbitone and chlorpromazine

1. The activities in rat tissues of 3-oxo acid CoA-transferase (the first enzyme involved in acetoacetate utilization) were found to be highest in kidney and heart. In submaxillary and adrenal glands the activities were about one-quarter of those in kidney and heart. In brain it was about one-tenth and was less in lung, spleen, skeletal muscle and epididymal fat. No activity was detectable in liver. 2. The activities of acetoacetyl-CoA thiolase were found roughly to parallel those of the transferase except for liver and adrenal glands. The high activity in the latter two tissues may be explained by additional roles of thiolase, namely, the production of acetyl-CoA from fatty acids. 3. The activities of the two enzymes in tissues of mouse, gerbil, golden hamster, guinea pig and sheep were similar to those of rat tissues. The notable exception was the low activity of the transferase and thiolase in sheep heart and brain. 4. The activities of the transferase in rat tissues did not change appreciably in starvation, alloxan-diabetes or on fat-feeding, where the rates of ketone-body utilization are increased. Thiolase activity increased in kidney and heart on fat-feeding. 5. The activity of 3-hydroxybutyrate dehydrogenase did not change in rat brain during starvation. 6. The factors controlling the rate of ketone-body utilization are discussed. It is concluded that the activities of the relevant enzymes in the adult rat do not control the variations in the rate of ketone-body utilization that occur in starvation or alloxan-diabetes. The controlling factor in these situations is the concentration of the ketone bodies in plasma and tissues.     

Brain uptake of pipecolic acid,amino acids,and amines following intracarotid injection in the mouse

The uptake of pipecolic acid by the mouse brain was compared to that of several amino acids and amines, following an injection of a double-labeled mixture into the carotid artery. In general, BUI (brain uptake index) values were lower in the mouse than those previously reported in the rat. The only exception was proline. Lysine, a precursor of pipecolic acid biosynthesis in brain, showed a higher BUI than pipecolic acid. The BUI ofD,l-[³H]pipecolic acid was found to be 3.39 (at 0.114 mM). This was saturable between a concentration of 0.114 and 3.44 mM. Kinetic analysis suggests the presence of two kinds of transport systems. Substances structurally related to pipecolic acid, such as nipecotic acid, isonipecotic acid,l-proline, and piperidine show a significant inhibitory effect. Among the amino acids tested, only GABA showed an inhibitory effect. Data are reported which, when considered with other findings (5), present evidence that pipecolic acid is (1) synthesized both in vitro and in vivo in the mouse brain, (2) actively transported in vivo into the brain, and (3) taken up in vitro by synaptosomal preparations.     

Simultaneous analysis of pipecolic acid with proline in the brain by selected ion-monitoring technique

A method for the simultaneous analysis of pipecolic acid and proline in the brain is developed. The qualification and quantification of pipecolic acid and proline are accomplished with gas chromatography/mass spectrometry including a selected ion-monitoring technique by using deuterium-labeled proline as an internal standard, after the amino and carboxylic groups of these cyclic amino acids are derivatized with boron trifluoride methanol complex and heptafluorobutyric anhydride. The lower limit of quantification for the method is picomole levels and the concentration of pipecolic acid and proline in rat whole brain is determined to be 1.05 and 71.50 nmol/g of tissue, respectively.     

Immobilization stress in rat tissues: alterations in protein oxidation, lipid peroxidation and antioxidant defense system

We determined the effects of immobilization stress on antioxidant status, protein oxidation and lipid peroxidation in brain, liver, kidney, heart and stomach of rats. Sixteen male Wistar rats (3 months old) were divided into controls (C) and immobilization stress group (IS). IS rats were immobilized for 180 min/day for 15 days. Plasma corticosterone levels were increased in IS group. Copper,zinc-superoxide dismutase activities were increased in brain, liver and kidney, but decreased in the heart and stomach after immobilization. Catalase activities were increased in brain, kidney and heart, and decreased in liver and stomach. Selenium-dependent glutathione peroxidase activities were decreased in brain and kidney, but increased in heart and stomach. Reduced glutathione levels were decreased, while protein carbonyl, conjugated dienes and thiobarbituric acid-reactive substances levels were increased in all tissues. Our results showed that the response of antioxidant defense system to stress differs for each tissue, and protein oxidation and lipid peroxidation is induced by immobilization stress in peripheral tissues.     

Effects of diet and of alloxan-diabetes on the activity of branched-chain 2-oxo acid dehydrogenase complex and of activator protein in rat tissues.

The total activities (sum of active and inactive forms) of branched-chain 2-oxo acid dehydrogenase complex in tissues of normal rats fed on a standard diet were (unit/g wet wt.): liver, 0.82; kidney, 0.77; heart, 0.57; hindlimb skeletal muscles, 0.034. Total activity was decreased in liver by 9%- or 0%-casein diets and by 48 h starvation, but not by alloxan-diabetes. Total activities were unchanged in kidney and heart. The amount of active form of the complex (in unit/g wet wt. and as % of total) in tissues of normal rats fed on standard diet was: liver, 0.45, 55%; kidney, 0.55, 71%; heart, 0.03, 5%; skeletal muscle less than 0.007, less than 20% (below lower limit of assay). The concentration of the active form of the complex was decreased in liver and kidney, but not in heart, by low-protein diets, 48 h starvation and alloxan-diabetes. In heart muscle alloxan-diabetes increased the concentration of active complex. The concentration of activator protein (which activates phosphorylated complex without dephosphorylation) in liver and kidney was decreased by 70-90% by low-protein diets and 48 h starvation. Alloxan-diabetes decreased activator protein in liver, but not in kidney. Evidence is given that in tissues of rats fed on a normal diet approx. 70% of whole-body active branched chain complex is in the liver and that the major change in activity occasioned by low-protein diets is also in the liver.     

Effect of starvation and exercise on actual and total activity of the branched-chain 2-oxo acid dehydrogenase complex in rat tissues.

Starvation does not change the actual activity per g of tissue of the branched-chain 2-oxo acid dehydrogenase in skeletal muscles, but affects the total activity to a different extent, depending on the muscle type. The activity state (proportion of the enzyme present in the active state) does not change in diaphragm and decreases in quadriceps muscle. Liver and kidney show an increase of both activities, without a change of the activity state. In heart and brain no changes were observed. Related to organ wet weights, the actual activity present in the whole-body muscle mass decreases on starvation, whereas the activities present in liver and kidney do not change, or increase slightly. Exercise (treadmill-running) of untrained rats for 15 and 60 min causes a small increase of the actual activity and the activity state of the branched-chain 2-oxo acid dehydrogenase complex in heart and skeletal muscle. Exercise for 1 h, furthermore, increased the actual and the total activity in liver and kidney, without a change of the activity state. In brain no changes were observed. The actual activity per g of tissue in skeletal muscle was less than 2% of that in liver and kidney, both before and after exercise and starvation. Our data indicate that the degradation of branched-chain 2-oxo acids predominantly occurs in liver and to a smaller extent in kidney and skeletal muscle in fed, starved and exercised rats.     

Effects of surgical stress on the response of hepatic carnitine metabolism to 48 h starvation in the rat

Rats subjected to laparotomy and handling of the liver were starved for 48 h, starting either immediately after surgery or 48 h later. Surgery enhanced the rise in plasma non-esterified fatty acid concentrations after starvation without affecting the responses of blood or liver ketone bodies. Thus in surgically stressed rats, blood and liver ketone body concentrations were inappropriately low for the blood fatty acid concentrations. In the control rats, starvation increased hepatic carnitine concentrations, mainly through increases in short-chain acylcarnitine. Surgical stress decreased or abolished these increases. This may possibly contribute to the blunted ketonaemic response observed after surgery.     

LYSINE METABOLISM IN THE RAT BRAIN: THE PIPECOLIC ACID-FORMING PATHWAY

Employing both the intraventricular and intraperitoneal injection techniques, ¹⁴C-l -lysine at non-overloading concentrations was found to be metabolized to l -¹⁴C-pipecolic acid at significantly high levels in the rat. Labeled pipecolic acid in the brain and liver was only found at rather low levels 24 h after intraperitoneal administration of ¹⁴C-l -lysine regardless of non-labeled lysine metabolite overload. A marked enhancement of pipecolic acid labeling was only found in the brain when ¹⁴C-l -lysine was intraventricularly administered to animals under various lysine metabolite overloads. While overloading doses of non-labeled saccharopine or α-aminoadipate did not significantly alter the labeling patterns of pipecolic acid in the brain, liver or urine when ¹⁴C-l -lysine was intraperitoneally administered, pipecolate overloading markedly reduced labeled pipecolic acid levels in the brain, liver and urine. These results indicate: pipecolic acid formation is subject to product inhibition, and saccharopine is not in the pathway of pipecolic acid synthesis from l -lysine. The labeling pattern of lysine metabolites was not significantly affected by the overloading injection of pipecolic acid when ¹⁴C-l -lysine was intraventricularly administered suggesting a blood-brain barrier for pipecolate. Besides ¹⁴C-pipecolic acid, labeled α-aminoadipic acid was also found at significant levels mostly in the brain. Labeled saccharopine was not detected in any tissues or urine samples analyzed. The ¹⁴C-l -lysine metabolic pattern of the newborn rats did not seem to be any different from the adult rats, i.e. labeled pipecolic acid was also detected in substantial quantities in the brain, liver and urine 5 h after injection. ¹⁴C-d -Lysine was mainly metabolized to l -¹⁴C-pipecolic acid through either route of administration. These experimental evidences indicate that the pipecolic acid-forming pathway is a significant route for lysine metabolism in the rat, and that the rat brain probably utilizes this pathway mainly for lysine metabolism. The present study also discusses the potential neurological significance of the pipecolic acid pathway in relation to the major lysine metabolic pathway (the saccharopine pathway).     

Effect of age and dietary protein level on tissue mineral levels in female rats

Mineral (phosphorus, sulfur, potassium, calcium, magnesium, iron, zinc, copper, and manganese) concentrations were measured in plasma, and several tissues from female Wistar rats (young: 3-wk-old; mature: 6-mo-old) were fed on a dietary regimen designed to study the combined or singular effects of age and dietary protein on mineral status. Three diets, respectively, contained 5, 15, and 20% of bovine milk casein. Nephrocalcinosis chemically diagnosed by increased calcium and phosphorus in kidney was prevented in rats fed a 5% protein diet. Renal calcium and phosphorus were more accumulated in young rats than mature rats. A 5% protein diet decreased hemoglobin and blood iron. The hepatic and splenic iron was increased by a 5% protein diet in mature rats but was not altered in young rats. Mature rats had higher iron in brain, lung, heart, liver, spleen, kidney, muscle, and tibia than young rats. A 5% protein diet decreased zinc in plasma and liver. Zinc in tibia was increased with dietary protein level in young rats but was not changed in mature rats. A 5% protein diet decreased copper concentration in plasma of young rats but not in mature rats. Mature rats had higher copper in plasma, blood, brain, lung, heart, liver, spleen, and kidney than young rats. With age, manganese concentration was increased in brain but decreased in lung, heart, liver, kidney, and muscle. These results suggest that the response to dietary protein regarding mineral status varies with age.     

The effects of starvation and force-feeding on the metabolism of the Northern pike, Esox lucius L.

The effects of starvation and force-feeding on certain tissue and blood constituents were studied in the Northern pike, Esox lucius L. Starvation resulted in a reduction of liver and muscle glycogen and liver lipid. Blood glucose concentration and haematocrit were reduced, total plasma cholesterol levels were increased, while the levels of plasma free fatty acids (FFA), amio acid nitrogen and protein remained unaltered. No significant changes were observed in either muscle protein, muscle water or the response to amino acid loading during the starvation period.
The force-feeding of pike starved for 3 months resulted in liver lipid and muscle glycogen being increased to levels higher than those observed in freshly-captured fish. Liver glycogen, however, increased to values only slightly higher than those of starved animals. Furthermore, while force-feeding had little effect on plasma FFA or protein concentrations, blood glucose, plasma cholesterol and haematocrit returned to the levels found in freshlycaptured fish and those of amino acid nitrogen were higher.
The results indicate that pike are well adapted for periods of prolonged starvation and that hepatic and extra-hepatic lipid and glycogen stores serve for metabolic needs during food shortage, while body protein is conserved. The endocrine basis for these changes in the tissue and blood constituents is discussed.     

The significance of hyperpipecolatemia in Zellweger syndrome.

The plasma pipecolic acid concentration in two newborn infants with Zellweger syndrome at ages 4 and 10 days were 7.8 and 7.7 microM. Reported concentrations from this laboratory for normal newborn infants averaged 12 microM +/- 5.6 (SD). Both patients had the facies and severe hypotonia characteristic of the disease. Autopsy examination at age 6 days in one of these patients revealed the developmental microscopic abnormalities in brain, liver, and kidney that are associated with Zellweger syndrome. In three additional patients ages 3 1/2 weeks, 2 months, and 2 months, the pipecolic acid concentrations were 15, 17, and 25 microM. The concentrations increased to distinctly pathological levels on subsequent assays at a later age. It is concluded that the hyperpipecolatemia in Zellweger syndrome occurs postpartum and that the plasma concentrations may not be diagnostic early in life. The major manifestations of the disease, already evident at birth, cannot be attributed to pipecolatemia. Currently available data do not exclude the possibility of pipecolic acid accumulation in the brain where it has been reported to be a major metabolite of lysine. Hyperpipecolatemia of considerable degree is also consistently found in familial hyperlysinemia where it appears to be benign.     

Ketone-body metabolism after partial hepatectomy in the rat.

Fed or 24 h-starved rats were subjected to two-thirds partial hepatectomy or sham-operation and subsequently starved for 4, 14 or 24 h. Despite high plasma fatty acid concentrations, the partially hepatectomized rats failed to respond to post-operative starvation with increased blood and liver ketone-body concentrations or to maintain the high ketone-body concentrations associated with pre-operative starvation. Hypoglycaemia and hyperlactaemia were observed within 30 min of functional hepatectomy, but not partial hepatectomy, of 24 h-starved rats, and, even after a further 24 h starvation of partially hepatectomized rats, blood glucose concentrations were only slightly decreased. The results are discussed with reference to fat oxidation and gluconeogenesis in the liver remaining after partial hepatectomy.     

Tissue manganese levels and liver pyruvate carboxylase activity in magnesium-deficient rats

To investigate the manganese status in magnesium deficiency, 40 male Wistar rats, 3 wk old, were divided into two groups and fed a magnesium deficient diet or a normal synthetic diet for 2 wk. Dietary magnesium depletion decreased magnesium levels in brain, spinal cord, lung, spleen, kidney, testis, bone, blood, and plasma, while it elevated the magnesium level in liver. In magnesium-depleted rats, calcium concentration was increased in lung, liver, spleen, kidney, and testis, while it was decreased in tibia. In magnesium-depleted rats, manganese concentration was decreased in plasma and all tissues except adrenal glands and blood. Dietary magnesium depletion diminished pyruvate carboxylase (EC 6.4.1.1) activity in the crude mitochondrial fraction of liver. Positive correlation was found between the liver manganese concentration and the pyruvate carboxylase activity. In the magnesium-depleted rats, glucose was decreased while plasma lipids (triglycerides, phospholipids, and total cholesterol) were increased. These results suggest that dietary magnesium deficiency changes manganese metabolism in rats.     

Metabolic response to short periods of starvation in hypo- and hyper-thyroid male rats.

1) Thyroidectomized rats were fed with a low iodine diet, injected daily with 0, 0.1, 1.8 or 25 microgram of L-thyroxine/100 g body wt., and compared with intact controls. 2) Plasma protein-bound iodine was decreased in the rats given the 0 and 0.1 microgram doses, unchanged in those given the 1.8 microgram doses, unchanged in those given the 1.8 microgram dose increased in those given the 25 microgram one. 3) The liver content of DNA-P, phospholipid-P, proteins and fatty acids was decreased in the rats that did not receive thyroxine, practically recuperated in those receiving 0.1 microgram and normal in those given 1.8 or 25 microgram of thyroxine. 4) 3 h of starvation produced a reduction in the liver content of total fatty acids that disappeared after 24 h. 5) When fed, liver glycogen concentration was low in the rats given 25 microgram of thyroxine. 6) With starvation, the fall in liver glycogen and blood glucose, and the rise in liver acetyl-CoA and citrate and blood glycerol concentrations were faster in the thyroidectomized rats that did not receive thyroxine than in the other groups. 7) The rise in plasma free fatty acid and blood ketone bodies concentrations were similar in all the groups, the greater level of the first parameter being observed after 6 h of starvation in the rats given 25 microgram of thyroxine and in the second one after 24 h in the rats given either 0.1, 1.8 or 25 microgram of thyroxine. 8) The rapid decrease in the availability of carbohydrate stores with starvation in the thyroidectomized rats could be responsible for their fast call for lipid utilization. The slower response to fasting in the hyperthyroid animals is probably a consequence of their reduced amount of endogenous substrates to be mobilized.     

Possible significance of changes in the energy metabolism for the release of liver lactate dehydrogenase and for the uptake and incorporation of [14C]-orotic acid into liver ribonucleic acid after partial hepatectomy

The mouse liver revealed no increased incorporation of [14C]-orotic acid into either the total acid-soluble fraction, the uridine triphosphate or the RNA at 6 and 24 h after partial hepatectomy. In regenerating mouse and rat liver, the concentration of adenosine triphosphate was decreased 15-20% at 6 h, but was in the same range as that of the controls at 24 h. The adenosine monophosphate concentration of mouse liver increased 4-fold and 2-fold at these times after partial hepatectomy, respectively. The results indicate no direct relationship between the energy metabolism and the uptake and incorporation of orotic acid into RNA of regenerating liver. The activity of mouse plasma lactate dehydrogenase 5 (LDH 5) was increased 12-fold at 6 h and 5-fold at 24 h after partial hepatectomy. In rat, the LDH 5 activity was increased 2-fold at 6 h but was not different from that of the controls at 24 h. An increased leakage of LDH 5, possibly related to the decreased energy content of the liver, was thus revealed by the partially hepatectomized mice.     

Effects of brief starvation on brain protease activity

Changes in the activity of proteases (cathepsin D and calpains) caused by 48-h food withdrawal were studied in the brain, liver, kidney, spleen, and heart of 3-, 12-, and 24-month-old Fischer rats. Cathepsin D activity was similar in brain, liver, and heart of control animals; in kidney it was 5-fold higher and in spleen about 10-fold higher. With age, activity increased in all organs tested except spleen. Brief starvation caused no change of cathepsin D activity in brain, but caused an increase in liver and a decrease in spleen. Neutral proteolytic activity in control was highest in the pons-medulla-cerebellum fraction of brain, and activity in liver and heart was below that in brain. Activity increased with age in brain and decreased in other organs. Brief starvation in young animals caused an increase in activity in brain, and a decrease in liver and spleen. Isolated calpain II activity was high in control brain. It increased with age in the cerebrum. Brief starvation resulted in a decrease in the brain. The results indicate that the protease content of the brain is altered with age and in malnutrition, with changes not being the same for all proteases, and changes in brain being different from those in other organs.Special issue dedicated to Dr. Louis Sokoloff.