Metabolism of thromboxane B2 in the cynomolgus monkey

[5,6,8,9,11,12,14,15-³H₈]-Thromboxane B₂ was injected into the saphenous vein of female cynomolgus monkeys, and blood samples were withdrawn from the contralateral saphenous vein. The compound was eliminated from the circulation with a half-life of about 10 min after an initial rapid disappearnace. Some more polar products appeared with time, and also small amounts of material less polar than thromboxane B₂; however, the dominating compound in all blood samples was unconverted thromboxane B₂.About 45% of the given dose of tritium was excreted into urine in 48 hrs. Several metabolites of thromboxane B₂ were found. The major urinary metabolites was identified as dinorthromboxane B₂ (about 32% of urinary radioactivity). Unconverted thromboxane B₂ was also found in considerable amounts (13% of urinary radioactivity).It is concluded that 1) dehydrogenation at C-12 is not a major pathway in the degradation of this compound, in contrast to metabolism at the corresponding C-15 alcohol group of prostaglandins; 2) after having gained access to the circulation, thromboxane B₂ is the main circulating compound; however, assay of thromboxane B₂ in plasma will be complicated or precluded by large artifactual production of the compound by platelets during sample collection.     

Identification of 11-dehydro-TXB2 as a suitable parameter for monitoring thromboxane production in the human

In order to identify suitable parameters for measurement of thromboxane production in vivo, the metabolism of TXB2 was studied in the human. [3H8]-TXB2 was given intravenously to a healthy human volunteer. Blood samples were collected for 50 min after the injection, and urine was collected for 24 hours. The urinary and blood metabolic profiles were visualized by the use of two-dimensional TLC and autoradiography. Identification of metabolites was achieved with GC/MS and in some cases by cochromatography with reference compounds in TLC and GC. In blood, unmetabolized TXB2 was the dominating compound during the first 30 min. Three less polar metabolites appeared, two of which were identified as 11-dehydro-TXB2 and 11,15-didehydro-13,14-dihydro-TXB2, respectively. The third compound was tentatively identified as 15-dehydro-13,14-dihydro-TXB2. Since 11-dehydro-TXB2 was one of the major metabolites in blood as well as urine, it was deemed suitable as target for measurement of thromboxane production in vivo. The advantages of 11-dehydro-TXB2 over its parent compound, TXB2, were demonstrated in experiments where unlabeled TXB2 was injected i.v. to a human volunteer, and the blood and urinary levels of both compounds were then followed by radioimmunoassay. Measured levels of 11-dehydro-TXB2 were found to give a more reliable picture of metabolic events than TXB2, the latter compound to a large extent reflecting technical difficulties during blood sample collection.     

Circulating and urinary thromboxane B2 metabolites in the rabbit: 11-dehydro-thromboxane B2 as parameter of thromboxane production

The metabolism of thromboxane B2 was studied in the rabbit. The aim of the study was to identify metabolites in blood and urine that might serve as parameters for monitoring thromboxane production in vivo. [5,6,8,9,11,12,14,15-3H8]-Thromboxane B2 was administered by i.v. injection to rabbits, and blood samples and urine were collected with brief intervals. The metabolic profiles were visualized by two-dimensional thin layer chromatography and autoradiography, and the structures of five major metabolites were determined using chromatographic and mass spectrometric methods. In urine the major metabolites were identified as 11-dehydro-TXB2 and 2,3,4,5-tetranor-TXB1, and other prominent products were 11-dehydro-2,3,4,5-tetranor-TXB1, 2,3-dinor-TXB1 and 2,3-dinor-TXB2. In the circulation, TXB2 was found to disappear rapidly. The first major metabolite to appear was 11-dehydro-TXB2, which also remained a prominent product in blood for the remainder of the experiment (90 min). With time, the profile of circulating products became closely similar to that in urine. TXB2 was not converted into 11-dehydro-TXB2 by blood cells or plasma. The dehydrogenase catalyzing its formation was tissue bound and was found to have a widespread occurrence: the highest conversion was found in lung, kidney, stomach and liver. The results of the present study suggest that 11-dehydro-TXB2 may be a suitable parameter for monitoring thromboxane production in vivo in the rabbit in blood as well as urinary samples, and possibly also several tissues. This was also demonstrated in comparative studies using radioimmunoassays for TXB2 and 11-dehydro-TXB2.     

Identification of 11-dehydro-TXB2 as a suitable parameter for monitoring thromboxane production in the human

In order to identify suitable parameters for measurement of thromboxane production the metabolism of TXB₂ was studied in the human. [³H₈]-TXB₂ was given intravenously to a healthy human volunteer. Blood samples were collected for 50 min after the injection, and urine was collected for 24 hours. The urinary and blood metabolic profiles were visualized by the use of two-dimensional TLC and autoradiography. Identification of metabolites was achieved with GC/MS and in some cases by cochromatography with reference compounds in TLC and GC.In blood, unmetabolized TXB₂ was the dominating compound during the first 30 min. Three less polar metabolites appeared, two of which were identified as 11-dehydro-TXB₂ and 11, 15-didehydro-13, 14-dihydro-TXB₂, respectively. The third compound was tentatively identified as 15-dehydro-13, 14-dihydro-TXB₂.Since 11-dehydro-TXB₂ was one of the major metabolites in blood as well as urine, it was deemed suitable as target for measurement of thromboxane production . The advantages of 11-dehydro-TXB₂ over its parent compound, TXB₂, were demonstrated in experiments where unlabeled TXB₂ was injected i.v. to a human volunteer, and the blood and urinary levels of both compounds were then followed by radioimmunoassay. Measured levels of 11-dehydro-TXB₂ were found to give a more reliable picture of metabolic events than TXB₂, the latter compound to a large extent reflecting technical difficulties during blood sample collection.     

A solid-phase enzyme immunoassay of thromboxane B2

A solid-phase enzyme immunoassay for thromboxane B2 was developed using a conjugate of thromboxane B2 and beta-galactosidase. Anti-thromboxane B2 IgG was bound to a polystyrene tube, and the enzyme-labeled and unlabeled thromboxane B2 were allowed to react in a competitive manner with the immobilized antibody. Then, the specifically bound beta-galactosidase was assayed fluorimetrically, and the enzyme activity was correlated with the amount of unlabeled thromboxane B2. By using a calibration curve, thromboxane B2 was determined in the range of 20 fmol-14 pmol. 2,3-Dinor- and 2,3,4,5-tetranor-thromboxane B2 cross-reacted with thromboxane B2 to the extents of 18.6% and 0.4%, respectively. Most prostaglandins and their metabolites tested showed cross-reactivities of less than 1%. In application of the method to human blood and urine, an octadecylsilyl silica column was utilized for extraction and concentration of thromboxane B2. The crude extract contained a substance(s) which disturbed the enzyme immunoassay and gave an apparently high value of thromboxane B2, and the interfering substance was separated from thromboxane B2 by reverse-phase HPLC. Various amounts of authentic thromboxane B2 added to the purified material from human plasma could be determined by the enzyme immunoassay with a recovery of about 80% and the results correlated well with the values obtained by radioimmunoassay (r = 0.979). When the extract from human urine was analyzed by reverse-phase HPLC, the 2,3-dinor metabolite rather than thromboxane B2 was the predominant compound detected by the enzyme immunoassay.     

Metabolism of thromboxane B2 in the monkey.

[3H8]Thromboxane B2 was biosynthesized and infused into an unanesthetized monkey. Several urinary metabolites were isolated and their structures elucidated using gas chromatography-mass spectrometry. In addition to the major urinary metabolite, dinor-thromboxane B2, a series of metabolites resulting from dehydrogenetion of the alcohol group at C-11 were identified: 11-dehydro-thromboxane B2, 11-dehydro-15-keto-13,14-dihydro-2,3-dinor-thromboxane B2, and 11-dehydro-15-keto-13,14-dihydro-19-carboxyl-2,3,4,5-tetranor-thromboxane B2. 6-(1,3-dihydroxypropyl)-7-hydroxy-10-oxo-3-pentadecaenoic acid was also identified. Three mono-O-ethylated metabolites were formed from thromboxane B2, which in this study was infused in an ethanolic solution. A small quantity of thromboxane B2 was excreted unchanged into the urine.     

The structure of steroids and their diffusion through blood vessel walls in a counter-current system

Several substances including prostaglandin F2 alpha, progesterone and 85-krypton have been shown to be transferred from the venous side to the arterial side of the circulation in the ovarian vascular pedicle. Experiments were therefore carried out to study the transfer of three pairs of steroids (progesterone and 20 alpha-dihydroprogesterone, C-21; androstenedione and testosterone, C-19; and estrone and estradiol-17 beta, C-18) in which each member of a pair differed by one hydroxyl group. Each pair of steroids, one labeled with 3H and the other with 14C, were infused in sequence for 30 minutes into a side branch of an ovarian vein near the hilus of the ovary with a rest period of 90 minutes between infusions. An increase in radioactivity in ovarian arterial plasma compared to the radioactivity in an equal volume of aortic plasma sampled simultaneously was used as the index for a direct transfer of steroids from the ovarian vein to the adjacent ovarian artery. All six steroids showed such a transfer which began 3 to 6 minutes after the start of each infusion and decreased rapidly after the infusion was stopped. The results of this study also showed that a larger quantity of the less polar (ketonic) form of each steroid pair examined was transferred than its hydroxyl counterpart.     

Tandem mass spectrometric determination of 11-dehydrothromboxane B2, an index metabolite of thromboxane B2 in plasma and urine

11-Dehydrothromboxane B2 is one of the major enzymatic metabolites of thromboxane B2 (TXB2), a biologically inactive product of thromboxane A2. The short half-life of thromboxane A2 and ex vivo production of thromboxane B2 by platelet activation make these prostanoid metabolites inappropriate as indices of systemic thromboxane biosynthesis, whereas 11-dehydro-TXB2 has been shown to reflect the release of thromboxane A2 in the human blood circulation. Analysis of 11-dehydro-TXB2 in plasma and urine was performed by gas chromatography-mass spectrometry-mass spectrometry using the chemically synthesized tetradeuterated compound as an internal standard. The high selectivity of triple-stage quadrupole mass spectrometry (tandem mass spectrometry) considerably facilitates sample purification as compared to single quadrupole mass spectrometric determination. Plasma concentrations in five healthy male volunteers were in the range 0.8-2.5 pg/ml. Urinary excretion of 11-dehydro-TXB2 was higher than that of 2,3-dinor-TXB2: 1.2 +/- 0.36 micrograms/24 h vs 0.53 +/- 0.33 micrograms/24 h (n = 5). Thus 11-dehydro-TXB2 appears at present to be the best index metabolite of systemic TXA2 activity in plasma as well as in urine.     

Enterohepatic circulation of N-acetyl-leukotriene E4

N-Acetyl-leukotriene E4, the end product of leukotriene C4 metabolism in the mercapturic acid pathway, was rapidly eliminated from the blood circulation into the bile of rats. Part of the N-acetyl-leukotriene E4 secreted from bile into the intestine underwent enterohepatic circulation. Leukotriene absorption occurred from the small intestine and from the colon. Biliary and urinary excretion within 5.5 h amounted to 15 and 2%, respectively, of the intraduodenally administered N-acetyl- 3H leukotriene E4 in animals anesthetized with ketamine. HPLC analyses indicated that 35% of the biliary radioactivity corresponded to unchanged N-acetyl-3H leukotriene E4, while 65% in bile and 100% in urine were polar metabolites. Enterohepatic circulation extends the biological half-life of N-acetyl-leukotriene E4.     

Radioimmunoassay of 11-dehydrothromboxane B2 in human plasma and urine

Because of the discrepancy between the capacity of platelets to synthesize thromboxane B2 ex vivo and the actual synthetic rate in vivo, measurement of thromboxane B2 in plasma is highly influenced by sampling-related artifacts. We have developed and validated a radioimmunoassay for a major enzymatic derivative of thromboxane B2 with an extended plasma half-life, i.e., 11-dehydrothromboxane B2. The binding of the tracer is displaced by as low as 1 pg/ml of the homologous ligand, with a high degree of specificity for the open ring structure as well as for the omega side-chain. This method can detect changes in the plasma concentration and urinary excretion of 11-dehydrothromboxane B2 associated with stimulated short-term increases of thromboxane B2 secretion in the human circulation.     

Safety profile of Coartem®: the evidence base

Background

Dihydroartemisinin (DHA), a powerful anti-malarial drug, has been used as monotherapy and artemisinin-based combination therapy (ACT) for more than decades. So far, however, the tissue distribution and metabolic profile of DHA data are not available from animal and humans.

Methods

Pharmacokinetics, tissue distribution, mass balance, and elimination of [¹⁴C] DHA have been studieded in rats following a single intravenous administration. Protein binding was performed with rat and human plasma. Drug concentrations were obtained up to 192 hr from measurements of total radioactivity and drug concentration to determine the contribution by the parent and metabolites to the total dose of drug injected from whole blood, plasma, urine and faecal samples.

Results

Drug was widely distributed after 1 hr and rapidly declined at 24 hr in all tissues except spleen until 96 hrs. Only 0.81% of the total radioactivity was detected in rat brain tissue. DHA revealed a high binding capacity with both rat and human plasma proteins (76–82%). The concentration of total radioactivity in the plasma fraction was less than 25% of that in blood total. Metabolism of DHA was observed with high excretion via bile into intestines and approximately 89–95% dose of all conjugations were accounted for in blood, urine and faeces. However, the majority of elimination of [¹⁴C] DHA was through urinary excretion (52% dose). The mean terminal half-lives of plasma and blood radioactivity (75.57–122.13 h) were significantly prolonged compared with that of unchanged DHA (1.03 h).

Conclusion

In rat brain, the total concentration of [¹⁴C] was 2-fold higher than that in plasma, indicating the radioactivity could easily penetrate the brain-blood barrier. Total radioactivity distributed in RBC was about three- to four-fold higher than that in plasma, suggesting that the powerful anti-malarial potency of DHA in the treatment of blood stage malaria may relate to the high RBC binding. Biliary excretion and multiple concentration peaks of DHA have been demonstrated with high urinary excretion due to a most likely drug re-absorption in the intestines (enterohepatic circulation). The long lasting metabolites of DHA (> 192 hr) in the rats may be also related to the enterohepatic circulation.     

Enterohepatic circulation of N-acetyl-leukotriene E4

N-Acetyl-leukotriene E₄, the end product of leukotriene C₄ metabolism in the mercapturic acid pathway, was rapidly eliminated from the blood circulation into the bile of rats. Part of the N-acethyl-leukotriene E₄ secreted from bile into the intestine undewent enterohepatic circulation. Leukotriene absorption occurred from the small intestine and from the colon. Biliary and urinary excretion within 5.5 h amounted to 15 and 2%, respectively, of the intraduodenally administered N-acetyl- H leukotriene E₄ in animals anesthetized with ketamine. HPLC analyses indicated that 35% of the biliary radioactivity corresponded to unchanged N-acetyl- H leukotriene E₄, while 65% in bile and 100% in urine were polar metabolites. Enterohepatic circulation extends the biological half-life of N-acetyl-leukotriene E₄.     

4-Bromophenacyl bromide inhibits prostaglandin D2 synthesis from arachidonic acid rather than phospholipase A2 activity in liver macrophages

4-Bromophenacyl bromide at a concentration of 50 microM does not inhibit phospholipase A2 activity in liver macrophages. Rather, this compound increases the amount of radioactivity released from [3H]arachidonate-prelabeled Kupffer cells and leads to the formation of small amounts of thromboxane, prostaglandin D2 and prostaglandin E2. Also the zymosan-induced formation of thromboxane and prostaglandin E2 from endogenous sources which is thought to involve phospholipase A2 remains unaffected in the presence of this compound. The generation of superoxide and the formation of prostaglandin D2 from arachidonate and after stimulation of the cells with zymosan, however, are blocked by 4-bromophenacyl bromide. Furthermore, this compound suppresses the incorporation of externally added arachidonate into membrane lipids of the cells. 4-Bromophenacyl bromide seems, therefore, not to be a useful tool to demonstrate the involvement of phospholipase A2 in complex biological systems.     

An increase in the ratio of thromboxane A2 to prostacyclin in association with increased blood pressure in patients on cyclosporine A

The aim of this study was to determine the effect of two years of treatment with cyclosporine A on blood pressure and the rates of secretion into the circulation of the vasoconstrictor thromboxane A2 and the vasodilator prostacyclin. Seven patient suffering from multiple sclerosis took part. Their blood pressures and urinary concentrations of 2,3-dinor-thromboxane A2 (a major urinary metabolite of thromboxane A2) and of 2,3-dinor-6-keto-prostaglandin F1 alpha (the major urinary metabolite of prostacyclin) were determined at the end of two years of treatment with cyclosporine A, and once again three months after cessation of this treatment. No other drugs were given during or after cyclosporine A. Mean arterial blood pressure was 113 +/- 5 mmHg (mean +/- SEM) during the cyclosporine A treatment, but fell to 94 +/- 4 mmHg after the three-month's wash-out period. Urinary excretion of the thromboxane metabolite decreased slightly from 674 +/- 150 pg.mg-1 creatinine during cyclosporine A therapy to 503 +/- 90 pg.mg-1-creatinine after the end of therapy. At the same time the prostacyclin metabolite increased significantly from 82 +/- 17 pg.mg-1 creatinine to 113 +/- 23 pg.mg-1 creatinine (P less than 0.05). The ratio of 2,3-dinor-thromboxane B2 to 2,3-dinor-6-keto-prostaglandin F1 alpha (taken as a measure of vasoconstrictor prostanoid activity) fell significantly from 8.4 +/- 0.8 4.7 +/- 0.6 (P less than 0.005). The shift in prostanoid production observed during cyclosporine A treatment could be one causal factor for the hypertensive and thromboembolic events associated with the use of this drug.     

Metabolites of estradiol in serum, bile, intestine and feces of the domestic cat (Felis catus )

We wished to develop an efficient, noninvasive method for monitoring ovarian function in domestic and nondomestic Felidae. We hypothesized that the method could be based on measurement of one of the major excreted estrogen metabolites. To identify and characterize the major excreted metabolites, a bolus of (14)C-estradiol was administered into the femoral vein of adult female cats. We measured the amounts of total radioactivity per unit time contained in unconjugated and conjugated estradiol metabolites, in conjugated metabolites that were hydrolyzable, and in those not hydrolyzable by beta Glucuronidase / aryl sulfatase (the enzyme). Radionuclide levels were determined in voided feces and urine, in jugular vein plasma, bile, contents of the duodenum, and in the small intestine. Metabolites of (14)C-estradiol were voided preferentially in feces and in equal amounts either as unconjugated estradiol or as conjugates not hydrolyzable by the enzyme. In plasma, conjugated estrogens comprised an increasing proportion of the total radioactivity during the first 40 min after administration. Plasma pools of samples from 0.5 to 30 min and 40 to 360 min contained a monoconjugate and a diconjugate, respectively; both were hydrolyzable by the enzyme. Bile and intestinal samples were collected at 360 min after administration. In the bile, 99% of the total radioactivity was in conjugated compounds, only 20% of which were not hydrolysable by the enzyme. The proportion of unconjugated metabolites increased to 18% in the duodenum and to 45% in the small intestine. The major conjugates contained in voided feces not hydrolyzable by the enzyme were estradiol sulfate (m/z = 351.6836), distributed as the 3-sulfate (20%) and 17-sulfate (80%); of the latter, 70% were 17alpha- and 30% 17beta-estradiol sulfates. These data document the fate of estradiol in the circulation of the cat, they demonstrate that a large portion of the voided estradiol metabolites are not hydrolyzable by the enzyme, and account for those conjugates previously termed nonhydrolyzable.     

The effect of age and smoking on vascular prostaglandin production in men and women

6-Keto-PGF1 alpha, PGF2 alpha and PGE2 production by homogenates of aorta was unaffected by age, sex or smoking habits. Homogenates of saphenous vein from women aged 51-60 years produced greater and smaller amounts of 6-keto- PGF1 alpha and PGF2 alpha, respectively, than from women aged 41-50 and 61-70 years. In the 41-50 and 61-70 age groups, the amounts of 6-keto-PGF1 alpha and PGF2 alpha produced by homogenates of saphenous vein were smaller and greater, respectively, in women than in men. Cigarette smoking had no effect on PG production by homogenates of female saphenous vein. 6-Keto-PGF1 alpha production by homogenates of male saphenous vein was 20% lower in smokers and ex-smokers than in non-smokers, although this reduction was statistically significant only for ex-smokers. The amounts of PGE2 and PGF2 alpha produced by homogenates of male saphenous vein were smaller in smokers and ex-smokers, respectively, than in non-smokers. In spite of these changes in PG production by homogenates of saphenous vein, the basal outputs of PGs, particularly of 6-keto-PGF1 alpha, from the saphenous vein were little affected by age, sex or smoking habits.     

Smoking alters thromboxane metabolism in man

Chronic smoking is a major risk factor of atherosclerosis and coronary heart disease. The measurement of three major thromboxane A2 metabolites, 11-dehydrothromboxane B2, 2,3-dinorthromboxane B2 and thromboxane B2, in the urines of 13 apparently healthy smokers (average 39 years, range 27-56 years) showed significantly elevated excretion rates for all thromboxane A2 metabolites as compared to 10 apparently healthy age-matched non-smokers (average 37 years, range 26-56 years). Importantly, characteristic alterations in the thromboxane A2 metabolite pattern were found in the urines of smokers. The contribution of 2,3-dinorthromboxane B2 to total measured excretion of thromboxane A2 metabolites was 59.2% in smokers (404.0 +/- 53.0 pg/mg creatinine) versus 19.4% in non-smokers (85.2 +/- 8.3 pg/mg creatinine), that of 11-dehydrothromboxane B2 35.7% in smokers (673.2 +/- 88.9 pg/mg creatinine) as compared to 75.5% in non-smokers (332.6 +/- 30.9 pg/mg creatinine). The contribution of thromboxane B2 (57.5 +/- 7.7 pg/mg creatinine in smokers versus 21.9 +/- 1.5 pg/mg creatinine in non-smokers) was similar at 5.1%. The excretion of cotinine, the major urinary metabolite of nicotine that correlates well with the reported daily cigarette consumption (r = 0.97, P less than 0.0001), showed a good correlation to thromboxane A2 metabolite excretion (2,3-dinorthromboxane B2: r = 0.92, P less than 0.0001; 11-dehydrothromboxane B2; r = 0.87, P less than 0.0001).     

Comparative effects of endothelin (ET-1) and U46619 on human saphenous vein and gastroepiploic artery,sources of human autologous grafts

The effects of endothelin (ET-1) on smooth muscle contractile activity were investigated and compared in human saphenous vein and gastroepiploic artery, vessels frequently used in revascularization procedures. ET-1 contracted saphenous vein and gastroepiploic artery in a concentration-dependent manner. The peptide produced a greater maximal effect in the vein than in the artery and, in both preparations, ET-1 was less efficacious than U46619, an agent which mimics the actions of thromboxane A₂ at the thromboxane A₂/prostaglandin HZ receptor. The contractile response to ET-1 declined spontaneously at a more rapid rate in the artery than in the vein. The present data indicate that ET-1 has significant contractile activity in both vessels which are used for coronary arterial bypass surgery and suggest that although, a weaker vasoconstrictor than U46619, the peptide could induce vasospasm in both graft vessels.     

The localization of 1,25-dihydroxycholecalciferol in bone cell nuclei of rachitic chicks

1. A simple technique has been developed to obtain subcellular fractions of chick bone. The method yielded 60-70% of total DNA in the nuclear debris fraction and 80-90% of total (14)C recovered in bone after a dose of radioactive vitamin D. 2. After a dose of [4-(14)C,1,2-(3)H(2)]cholecalciferol (0.5mug) was given to vitamin D-deficient chicks, the time-course of total (14)C radioactivity in the epiphysis, metaphysis and diaphysis of proximal tibiae was measured. The maximum concentrations were reached at 6h, corresponding to a similar peak of radioactivity in blood, decreasing until 24h and indicating the dependence on the circulating (14)C and on the blood supply of the three bone components. 3. The (14)C radioactivity of cholecalciferol and 25-hydroxycholecalciferol (expressed per mg of DNA) followed the pattern of incorporation of total (14)C radioactivity in all three bone components. The more polar metabolite fraction reached a peak of radioactivity at 6-9h and maintained its concentration over the 24h period studied in all anatomical bone components. 4. After a dose of [4-(14)C,1-(3)H]cholecalciferol (0.5mug) was given to vitamin D-deficient chicks, the subcellular distribution was studied. At 24h after dosing, the nuclear fraction contained 27% and the supernatant fraction had 67% of total (14)C recovered in the bone filtrate. When the (14)C in the residual bone fragments was included, the nuclear fraction contained up to 35% of the total radioactivity in the bone. 5. The subcellular distribution pattern of individual vitamin D metabolites indicated that the purified nuclear fraction concentrated the polar metabolite, which lost (3)H at C-1, so that 77% of the radioactivity could be accounted for by 1,25-dihydroxycholecalciferol. The supernatant fraction contained smaller amounts of 1,25-dihydroxycholecalciferol (9%), with 66% of 25-hydroxycholecalciferol forming the major metabolite, corresponding to its concentration found in blood at 24h. 6. The preferential accumulation of 1,25-dihydroxycholecalciferol in the nuclear fraction and the overall pattern of other metabolites, found previously in intestinal tissue, suggests a similar mechanism of action in bone to that postulated for the intestinal cell in calcium translocation.     

Amino acids in ram testicular fluid and semen and their metabolism by spermatozoa

1. The testis of the ram secretes considerable amounts of amino acids (200μmoles/day) into the fluid collected from the efferent ducts. The principal amino acid in this testicular fluid is glutamate, which is present in concentrations about eight times those in testicular lymph or in blood from the internal spermatic vein. 2. The concentration of glutamate in seminal plasma from the tail of the epididymis is about ten times that in testicular fluid, and, though glutamate is the major amino acid in ejaculated seminal plasma, its concentration is less than in epididymal plasma. 3. After the intravenous infusion of [U-¹⁴C]glucose, labelled glutamate was found in the testicular fluid. Radioactivity was also detected in alanine, glycine, serine plus glutamine and aspartate. Alanine had the highest specific activity, about 50% of the specific activity of blood glucose. 4. When [U-¹⁴C]glutamate was infused, the specific activity of glutamate in testicular fluid was only about 2% that in the blood plasma. 5. Testicular and ejaculated ram spermatozoa oxidized both [U-¹⁴C]glutamate and [U-¹⁴C]leucine to a small extent, but neither substrate altered the respiration from endogenous levels. 6. No radioactivity was detected in testicular spermatozoal protein after incubation with [U-¹⁴C]glutamate or [U-¹⁴C]leucine. Small amounts of radioactivity were detected in protein from ejaculated ram spermatozoa after incubation with [U-¹⁴C]glutamate. 7. The carbon of [U-¹⁴C]glucose was incorporated into amino acids by testicular spermatozoa; most of the radioactivity occurred in glutamate.