Oral administration of deuterium-labelled polyamines to sucking rat pups:luminal uptake, metabolic fate and effects on gastrointestinal maturation

Non-physiological amounts of oral polyamines have been reported to induce precocious gut maturation in rat pups. The aim of the present study was to investigate organ distribution and metabolic fate of orally administered stable-isotopically labelled polyamines in rat pups. Pups received tetradeuterium-labelled putrescine (Pu-d4; 3 mumol), spermidine (Sd-d4; 5 mumol), spermine (Sp-d4; 3 mumol), or physiological saline twice daily on postnatal days 7-10 or 12-15. They were killed on days 10 and 15. We determined activities of ileal lactase (EC 3.2.1.23), maltase (EC 3.2.1.20), sucrase (EC 3.2.1.48) and diamine oxidase (EC 1.4.3.6) and established villus and crypt lengths. Polyamines and their labelling percentages in organs were determined by GC and mass fragmentography. Treatments did not affect growth rate, but caused lower weights of liver, kidneys and heart. Maltase activity increased, lactase decreased, whereas sucrase and diamine oxidase did not change. Villus and crypt lengths increased. Organ polyamine pools were labelled to different extents. Irrespective of the orally administered polyamine, all organs contained Pu-d4, SD-d4 and Sp-d4. Administered Pu-d4 and Sd-d4 were recovered mainly as Sd-d4, whereas Sp-d4 was recovered as Sp-d4 and Sd-d4. Total polyamines in a caecum, colon and erythrocytes increased, but increases were only to a minor extent with regard to labelled polyamines. Our data confirm precocious gut maturation by exogenous polyamines. Putrescine appears to be limiting factor. The exogenous polyamines were distributed among all investigated organs. They are not only used for the synthesis of higher polyamines, but also retroconverted to their precursors. Changes in erythrocyte polyamine contents suggest precocious stimulation of erythropoiesis

The diagnosis of 21-hydroxylase deficiency in a prematurely born infant on the basis of the urinary steroid-excretion pattern

The urine of a 6-day-old prematurely born female infant (birth weight 1060 g) suspected of having a 21-OH deficiency showed no steroid abnormalities on capillary GLC analysis. Using GC-MS tetrahydrocortisone (THE) and also 3α, 17α-dihydroxy-5β-pregnane-20-one (17-OH-Polone) were absent, but two androstanetriolone peaks were observed. In the urine collected on day 9 THE was absent, but a large amount of 3α, 11β-dihydroxy-5α-androstane-17-one (11-HA) was found by GC-MS to be contaminated by a small amount of 17-OH-Polone. The next urine specimen collected on the 22nd day while the child received cortisol therapeutically showed the characteristic steroid profile for the diagnosis 21-OH deficiency, large peaks of 17-OH-Polone, pregnanetriol (P3) and 11-keto-pregnanetriol (11-keto-P3). Over the next few weeks two other compounds were found to have been excreted in relatively large amounts, 3ξ, 16ξ, 17ξ, 20ξ-pregnanetetrol (16-OH-P3) and surprisingly also a 21-hydroxylated compound, namely 3β, 20α, 21-trihydroxy-5-pregnene. These same two compounds were also found in the urine of another infant with suspected 21-OH deficiency. The urinary steroid excretion patterns characteristic for 21-OH deficiency are dependent on the maturity and age of .the infant. In the prematurely born infant androstanetriolones appear in the urine before 17-OH-Polone. The occurrence of these different steroid excretion patterns is tentatively explained

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

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