Impaired renal production of prostaglandin E2: A newly identified lesion in human essential hypertension

To test the hypothesis that impaired renal prostaglandin production may accompany the hypertensive state, we have measured urinary PGE₂ by radio-immunoassay in 52 normotensive and 50 hypertensive subjects. PGE₂ levels were lower in females, and were not affected by Na⁺ intake or age. Patients with essential hypertension had significantly lower PGE₂, particularly those with low-renin hypertension. Forty percent of the hypertensives excreted less than 70 ng/24 hr, values never observed in normotensives except after receiving indomethacin, a well-known prostaglandin synthetase inhibitor. It appears that impaired renal prostaglandin production is commonly encountered in patients with essential hypertension, perhaps contributing to their increased renal resistance. The data further suggest a role for renal prostaglandins in the pathogenesis of low-renin hypertension.     

Urinary 6-keto PGF1α and PGE2 in two kidney-one clip hypertension in the rat

The 24 hour urinary excretion of 6-keto PGF_1α and PGE₂ was compared in 2 kidney-1 clip rats developing hypertension within 12 weeks of renal artery clipping with rats remaining normotensive over this period. Although systolic blood pressure was markedly elevated in the hypertensive (210 ± 5.1 mm Hg), in contrast with the normotensive (141 ± 1.9 mm Hg) group, urinary levels of 6-keto PGF_1α (26.1 ± 3.4 and 22.1 ± 2.7 ng/24h, respectively) and PGE₂ (52.8 ± 28 and 53.3 ± 10.8 ng/24h) were not significantly different. Treating the 2 kidney-1 clip normotensive group with indomethacin (3.0 mg/kg, by intraperitoneal injection) twice-weekly for 3 weeks reduced 6-keto PGF_1α excretion from 22.1 ± 2.7 to 8.4 ± 2.2 ng/24h (P < 0.002) and PGE₂ from 53.3 ± 10.8 to 8.7 ± 1.8 ng/24h (P < 0.002) but did not change blood pressure when compared with a similar group given buffer vehicle only. These findings do not support a role for renal prostaglandins in 2 kidney-1 clip hypertension in the rat.     

Dissociation between renal medullary PGE2-synthesis and urine PGE2-excretion. Antagonism by bumetanide of chlorazanil induced urine PGE2-excretion in rats

Normal conscious female Sprague-Dawley rats were treated with chlorazanil (3 mg/kg i.p.), and urine was collected for 3 hours. Urine prostaglandin E₂-excretion increased from 25±3 to 271±32 ng/kg/3 h. The enhancement of urine PGE₂-excretion was inhibited by pretreatment with bumetanide (75 mg/kg p.o.). In separate experiments the papillary quantity of PGE₂ was determined in freshly homogenized tissue. The basal level (14±2 ng PGE₂/papilla) was increased by chlorazanil to 51±11 ng PGE₂/papilla and 24±7 ng PGE₂/papilla at one and two hours respectively after drug administration. The capacity of chlorazanil to increase medullary PGE₂ accumulation was unaffected by bumetanide dissociated the medullary PGE₂ level from the excretion of PGE₂ in urine, when the former was elevated by chlorazanil.     

The treatment of the hepatorenal syndrome with intra-renal administration of prostaglandin E1

Three patients with the hepatorenal syndrome were treated with prostaglandin E₁ administered through a selective renal arterial catheter. Prostaglandin E₁ was given in progressively increasing doses (2 to 100 ng/kg/min) over a 60-minute period. Control plasma prostaglandin E levels were elevated in all three patients, 0.98, 0.91, and 0.83 ng/ml, respectively. At the end of the infusion, plasma prostaglandin E levels had risen to 10.4, 2.63, and 10.3 ng/ml in the three patients respectively. Plasma renin activity increased during the course of the infusion in two of the patients. The plasma aldosterone concentration did not change during the prostaglandin E₁ infusion. Intrarenal prostaglandin E₁ failed to increase urine volume or urinary sodium concentration in three patients with the hepatorenal syndrome.     

Uterine vein prostaglandin levels in late pregnant dogs

We studied the uterine venous plasma concentrations of prostaglandins E₂, F_2α, 15 keto 13,14 dihydro E₂ and 15 keto 13,14 dihydro F_2α in late pregnant dogs in order to evaluate the rates of production and metabolism of prostaglandin E₂ and F_2α in pregnancy $\text{in vivo}$. We used a very specific and sensitive gas chromatography-mass spectrometry assay to measure these prostaglandins. The uterine venous concentrations of prostaglandin E₂ and 15 keto 13,14 dihydro E₂ were 1.35±.27 ng/ml and 1.89±.37 ng/ml, respectively; however, we could not find any prostaglandin F_2α and very little of its plasma metabolite in uterine venous plasma. Since uterine microsomes can generate prostaglandin F_2α and E₂ from endoperoxides, prostaglandin F_2α production $\text{in vivo}$ must be regulated through an enzymatic step after endoperoxide formation. Prostaglandin E₂ is produced by pregnant canine uterus in quantities high enough to have a biological effect in late pregnancy; however, prostaglandin F_2α does not appear to play a role at this stage of pregnancy.     

hCG-induced prostaglandin E2 and F2 alpha release in adult rat testis: role in Leydig cell desensitization to hCG.

Testicular levels of prostaglandin E₂ and F_2α were measured in decapsulated adult rat testis following hCG stimulation. Basal levels were, respectively, 342 ± 74 and 502 ± 89 pg/testis. Following hCG administration these basal values are not significantly modified up to 2 hours. From 2 to 24 hours the concentrations are clearly increased above the basal level: at 12 hrs they are 1925 ± 165 for E₂ and 3200 ± 190 for F_2α. Levels are back to normal at 48 hrs and remain so until 144 hrs. An identical pattern of prostaglandin release is observed in vitro in Leydig cell preparations isolated at different times following in vivo hCG injection. This suggests that prostaglandins are secreted by Leydig cells. In hypophysectomized animals the release of both prostaglandins E₂ and F_2α is similar to controls indicating that prostaglandin secretion is not directly linked to testosterone production. alternatively testosterone injections (10 mg) does not modify prostaglandin levels. Binding sites for prostaglandins E₁, E₂ and F_2α are present on the Leydig cells and consequently Leydig cell function may be modulated by endogenous or exogenous prostaglandins. Their level is slightly increased at 24 hrs following hCG stimulation. Since the acute changes in prostaglandin E₂ and F_2α secretion occur during the period of “desensitization” and of acute “down regulation” of the LH-hCG receptor in the Leydig cells it is suggested that prostaglandins are involved in both phenomena.     

Induction of renin release by exogenous prostaglandins in hyporeninemic hypoaldosteronism

A deficiency in renal prostaglandin synthesis has been proposed as the cause of the syndrome of hyporeninemic hypoaldosteronism. To determine if renin release could be stimulated by pharmacologic infusions of PGA₁, we infused PGA₁ 0.075 to 0.60 μg/kg/min to nine patients with the syndrome. Total renal PGE production as measured by urinary PGE excretion was normal (650 ± 169 vs 400 ± 55 ng/24hr in normal subjects). Renin (PRA) was markedly depressed in all patients despite stimulation with upright posture and furosemide (1.0 ± 0.4 vs 9.3 ± 0.7 ng/ml/hr, p<0.001). But in two patients PGA₁ induced an increase in renin similar to that of normal subjects. PRA increased to a lesser degree in two other patients and plasma aldosterone slightly increased. Five showed no response. Infusions of nitroprusside in doses and duration that mimicked the hypotensive effects of PGA₁ failed to increase PRA or aldosterone. The data suggest that total renal PGE production is normal in patients with the syndrome of hyporeninemic hypoaldosteronism. Although orthostasis, furosemide and nitroprusside do not increase renin, prostaglandin A₁ infusion appears to be a potent stimulus to renin release in some of the patients.     

Mass fragmentographic determination of prostaglandin F2α in human and rabbit urine

Analysis of prostaglandin F_2α (PGF_2α) in urine is a useful indicator of renal prostaglandin synthesis. A mass fragmentographic method for PGF_2α analysis in human urine was developed using [3,3,4,4-²H₄]PGF_2α as an internal standard and carrier. PGF_2α was extracted from urine (20 ml) with chloroform, purified by preparative thin-layer chromatography and converted to the methyl ester trimethylsilyl ether before analysis by gas chromatograph—mass spectrometry. The specificity of the urine analysis was demonstrated by retention time and the use of two pairs of fragments m/e 494/498 and 513/517 with the same results. The coefficient of variation for duplicate analysis averaged 12.6%, n = 17. Urine from recumbent women contained 4.9 ± 2.6 (S.D.) ng/ml or 4.1 ± 1.0 ng PGF_2α per mg creatinine (n = 10) with little diurnal variation. Male urine contained 5.0 ± 2.7 (S.D.) ng/ml or 3.7 ± 2.1 ng/mg creatinine (n = 10). Similar concentrations were found in boys and in girls. These observations indicate that urinary PGF_2α originates from the kidneys with little contribution from the male accessory sexual glands. This method can also be applied to analysis of PGF_2α in rabbit urine.     

Urinary prostaglandin E2 excretion in renal allotransplantation in man

The urinary prostaglandin E₂ excretion was measured daily for 28 days in 15 patients (10 men and 5 women) after renal allotransplantation. Patients with acute oliguric renal failure immediately after the transplantation showed high urinary PGE₂ concentrations, but no or minimal increase in the total excretion rates. The median PGE₂ excretion was 211 μg/24 h after establishment of stable renal function, but with great individual variations. Rejection crises were characterized by a two-fold increase in PGE₂ excretion, with a subsequent fall induced by the steroid treatment. The PGE₂ excretion correlated better with urinary sodium excretion than diuresis.The pathophysiological role of the renal prostaglandin ssynthesis remains incompletely defined. The prostaglandin E₂ (PGE₂) appears to act as a modulator of the renal salt and water excretion (1,2) and prostaglandins are important mediators of the immunresponses (3,4). The eraly renal allograft rejection is an event characterized by salt and water retention together with decreasing renal function (5). Antibodies against renal tissue as well as cytotoxic leukocytes (“killer cells”) are active in the process (6,7) and many hormonal systems are involved, among them renin and vasopressin (8). Both hormones are known to stimulate the synthesis of prostaglandin in the kidneys and interact with its effect (9,10,11). The present material was therefore designed to study the urinary excretion of PGE₂ in the kidney allografts before and during rejection crises.     

The lack of an effect of furosemide on uterine prostaglandin metabolism

We determined the effect of 2 mg/kg intravenous furosemide on the production and metabolism of prostaglandin E₂ in the utero-placental unit of pregnant dogs. Uterine venous prostaglandins E₂ and 15-keto-13,14-dihydro E₂ were measured by gas chromatography-mass spectrometry. Even though the dose of furosemide was adequate to effect a good diuresis, neither the production nor the metabolism of prostaglandin E₂ by the uterus was altered by that dose of the drug. Using radioactive microspheres to measure hemodynamic parameters, we observed no change in uterine vascular resistance while renal vascular resistance decreased. Although the renal concentration of furosemide may be higher than the uteroplacental concentration, there is so far no evidence that usual doses of furosemide enhance the production or inhibit the metabolism of prostaglandin E₂.     

Prostaglandin metabolism during circulatory shock

The rates of metabolic degradation and the patterns of metabolite formation of tritium-labeled prostaglandins E₂ and F_2α were assessed in vitro in tissues obtained from normal rabbits and from rabbits subjected to hemorrhagic or endotoxic shock. Normal rabbit tissues metabolized prostaglandin E₂ at the following rates: renal cortex 479 ± 34, liver 389 ± 95, and lung 881 ± 93 pmol of PGE₂ metabolized/mg soluble protein per min at 37°C (mean ± S.E.). Prostaglandin F_2α metabolism proceeded in normal animal tissues at rates of 477 ± 39, 324 ± 95, and 633 ± 69 pmol of PGF_2α metabolized/mg soluble protein per min for renal cortex, liver and lung, respectively. There were no significant differences between these rates of PGE₂ and PGF_2α metabolism when compared to rates in tissues obtained from animals subjected to either hemorrhagic or endotoxic shock. In addition, no significant differences were observed between the rate of PGE₂ metabolism and that of PGF_2α metabolism for any tissue. However, the lung was able to metabolize PGE₂ and PGF_2α significantly more rapidly than the liver, and to degrade PGE₂ at a significantly greater rate than the renal cortex. Although slightly different patterns of metabolite production were observed between lung and kidney homogenates, only the liver metabolized prostaglandins almost exclusively to more polar metabolites. While hemorrhagic or endotoxic shock induced slight changes in the patterns of PGE₂ metabolite formation in all three tissues studied, PGF_2α metabolite formation patterns were not significantly altered by circulatory shock. Thus, prostaglandin metabolism is not significantly impaired during the first 2 h of hemorrhagic or endotoxic shock in rabbit tissues. Therefore, impairment of prostaglandin metabolism is not the major factor responsible for the early increase in circulating prostaglandin concentrations in these forms of shock.     

Prostaglandin F2α induced luteolysis,hypothermia, and abortions in beagle bitches

Luteal phase plasma progesterone was radioimmunoassayed in samples collected before, during, and after a 72 hr treatment period during which Beagle bitches received repeated i.m. injections of prostaglandin F₂α (n=17) or saline (n=3). PGF₂α (20 ug/kg every 8 hr or 30 ug/kg every 12 hr) was administered to 7 pregnant and 8 nonpregnant bitches during the mid or late luteal phase of the cycle (Day 25–58) and to 2 nonpregnant bitches during the early luteal phase (Days 5 and 20). Progesterone was depressed from pretreatment levels (3 – 40 ng/ml) in each of the 15 bitches given PGF₂α after Day 25 of the cycle. Mean progesterone (ng/ml plasma) at ?24, 0, 12, 24, 36, 48, 60, 72 and 96 hr from the initial PGF₂α injection were 16.6, 15.6, 9.3, 5.1, 2.1, 1.5, 1.4, 1.1 and 1.1 (±0.9, n=15). Thereafter, progesterone was nondetectable in the 8 nonpregnant bitches and in 4 pregnant bitches that aborted. Abortions occurred when progesterone was depressed to 0.6 – 1.4 ng/ml, 56–80 hr after starting PGF₂α treatment on Days 33–53 of the cycle. Three pregnant bitches did not abort when progesterone was depressed to a mean low value of 2.1 ng/ml during PGF₂α treatments begun on Day 31 – 40 of pregnancy. Progesterone in these bitches recovered to 5 – 10 ng/ml and was maintained until the normal prepartum decline. Since PGF₂α can induce complete luteolysis it may be of use as an abortifacient in the bitch.A transient fall in rectal temperature occurred in each of 12 luteal phase bitches injected with PGF₂α (20 ug/kg, i.m.). The hypothermia was detectable within 15 min, maximal at 45 – 60 min, and averaged 1.39° C. No temperature changes were noted in eight ovariectomized bitches similarly treated. In six luteal phase bitches, plasma progesterone fell 20–45% within the 15 min required to observe a consistent decline in rectal temperature following PGF₂α administration. The transient hypothermia following PGF₂α appears to be secondary to the luteolytic effect and dependent on a fall in progesterone.     

The lack of an effect of furosemide on uterine prostaglandin metabolism in vivo

We determined the effect of 2 mg/kg intravenous furosemide on the production and metabolism of prostaglandin E₂ in the utero-placental unit of pregnant dogs. Uterine venous prostaglandins E₂ and 15-keto-13,14-dihydro E₂ were measured by gas chromatography-mass spectrometry. Even though the dose of furosemide was adequate to effect a good diuresis, neither the production nor the metabolism of prostaglandin E₂ by the uterus was altered by that dose of the drug. Using radioactive microspheres to measure hemodynamic parameters, we observed no change in uterine vascular resistance while renal vascular resistance decreased. Although the renal concentration of furosemide may be higher than the uteroplacental concentration, there is so far no evidence $\text{in vivo}$ that usual doses of furosemide enhance the production or inhibit the metabolism of prostaglandin E₂.     

Altered Kidney CYP2C and Cyclooxygenase‐2 Levels Are Associated with Obesity‐Related Albuminuria

Objective: To determine cytochrome P450 (CYP450) and cyclooxygenase (COX) expression and metabolite regulation and renal damage in the early stages of obesity‐related hypertension and diabetes. Research Methods and Procedures: Obese and lean Zucker rats at 10 to 12 weeks of age were studied. Blood pressure was measured in the conscious state using radiotelemetry. Blood glucose levels and body weight were measured periodically. Protein expression of CYP450 and COX enzymes in the kidney cortex, renal microvessels, and glomeruli was studied. The levels of CYP450 and COX metabolites in urine were measured, and urinary albumin excretion, an indicator of kidney damage, was measured. Results: Body weight and blood glucose averaged 432 ± 20 grams and 105 ± 5 mg/dl, respectively, in obese Zucker rats as compared with 320 ± 8 grams and 91 ± 5 mg/dl, respectively, in age‐matched 10‐ to 12‐week‐old lean Zucker rats. Renal microvascular CYP4A and COX‐2 protein levels were increased 2.3‐ and 17.0‐fold, respectively, in obese Zucker rats. The protein expression of CYP2C11 and CYP2C23 was decreased 2.0‐fold in renal microvessels isolated from obese Zucker rats when compared with lean Zucker rats. The urinary excretion rate of thromboxane B₂ was increased significantly in obese Zucker as compared with lean Zucker rats (22.0 ± 1.8 vs. 13.4 ± 1.0 ng/d). Urinary albumin excretion, an index of kidney damage, was increased in the obese Zucker rat at this early age. Discussion: These results suggest that increased CYP4A and COX‐2 protein levels and decreased CYP2C11 and CYP2C23 protein levels occur in association with microalbuminuria during the onset of obesity‐related hypertension and type 2 diabetes.     

Effect of furosemide on urinary excretion of prostaglandin E in normal volunteers and pateints with essential hypertension

Urinary excretion of prostaglandin E was measured radioimmunologically in 19 healthy persons ( 15 men and 4 women ) and in 16 patients ( 10 men and 6 women ) with essential hypertension before and after the administration of furosemide. The excretion rates were increased from 26.3±3.0 to 64.5±11.3 ng/hr in the former and from 11.9±2.7 to 26.9±85 ng/hr in the latter. There was a significant difference between them, healthy subjects showing a greater increase than patients with essential hypertension.There was an obvious sexual difference in urinary excretion of prostaglandin. In men, greater increase in the excretion rates was found than in the women. Greater increases were also obtained in healthy men than in hypertensive men and in healthy women than in hypertensive women. The present results suggest that furosemide enhances urinary excretion of prostaglandin E by mechanisms which entails either an increase in prostaglandin synthesis or a decrease in renal metabolism.     

Hypoxemia increases renin secretion rate in anesthetized newborn lambs

The response of renin secretion rate (RSR) to acute systemic hypoxemia (mean arterial p0₂ 34±8 torr) was studied in mechanically ventilated, anesthetized newborn lambs 5–10 days of age (n=6). Ventilation of these lambs with room air (normoxemia) was followed by administration of low oxygen inhaled gas mixture (f_i0₂ 0.11) which was associated with no change in arterial pC0₂, pH, mean arterial pressure (MAP), renal blood flow (RBF, measured by electromagnetic flow probe), and calculated renal vascular resistance (RVR). Arterial plasma renin activity (PRA_A 4.28±1.73 to 6.46±3.00 ng AI/ml · hr), renal vein plasma renin activity (PRA_RV, 6.26±3.79 to 11.44±7.11 ng AI/ml · hr) and renin secretion rate (RSR, 19.86±21.70 to 51.32±48.54 units/min · KgBW) increased significantly (p<0.05) in response to hypoxemia. Restoration of normoxemia (arterial p0₂ 100±18 torr) was associated with significant decline in MAP (to 65±14 mmHg) and RBF (to 9.0±2.1 ml/min · KgBW) and further increases in PRA_A (to 8.98±3.40 ng AI/ml · hr), PRA_RV (to 19.04±10.62 ng AI/ml · hr) and RSR (to 88.6±77.6 units/min · KgBW). PRA_A correlated strongly with PRA_RV (r=0.84) and RSR (r=0.60) in these lambs. These results suggest that PRA_A, PRA_RV and RSR increase in response to hypoxemia in anesthetized lambs by a mechanism other than renal arterial baroreceptor stimulation, although this mechanism may be active during recovery from hypoxemia. Furthermore, PRA_A closely approximates RSR in newborn lambs under these conditions.     

Role of prostaglandis in the control of renin secretion in the dog (II)

Infusion of prostaglandin E₁ (PGE₁) into the renal artery of anesthetized dogs (1.03 μg/min) caused increases in urine flow rate (V), renal plasma flow (RPF) and renin secretion rate without any change in mean arterial blood pressure (MABP), whereas infusion of prostaglandin F₂α (PGF_2α), (1.03 μg/min) caused no consistent change in V, RPF, or renin secretion rate. Infusion of prostaglandin E₂ (PGE₂) (1.03 μg/min) into the renal artery of “non-filtering” kidneys caused renin secretion rate to rise from 567.7 ± 152.0 U/min(M ± SEM) during control periods to 1373.6 ± 358.5 U/min after 60 minutes of infusion of PGE₂ (P < 0.01), without significant change in MABP (P > 0.1). The data suggest that PGE₁ and PGE₂ play a role in the control of renin secretion. The data further suggest that PGE may control renin secretion through a direct effect on renin-secreting granular cells.     

Mechanism of increased renal prostaglandin E2 in uranyl nitrate-induced acute renal failure

We have previously demonstrated that decreased cortical prostaglandin metabolism can contribute significantly to an increase in renal tissue levels and activity of prostaglandin E₂ in bilateral ureteral obstruction, a model of acute renal failure. In the present study, we have further investigated whether alterations in prostaglandin metabolism can occur in a nephrotoxic model of acute renal failure. Prostaglandin synthesis, prostaglandin E₂ metabolism (measured as both prostaglandin E₂-9-ketoreductase and prostaglandin E₂-15-hydroxydehydrogenase activity), and tissue concentration of prostaglandin E₂ were determined in rabbit kidneys following an intravenous administration of uranyl nitrate (5 mg/kg). No changes in the rates of cortical microsomal prostaglandin E₂ and prostaglandin F_2α synthesis were noted at the end of 1 and 3 days, while medullary synthesis of prostaglandin E₂ fell by 47% after 1 day and 43% after 3 days. Cortical cytosolic prostaglandin E₂-9-ketoreductase activity was found to be decreased by 36% and 76% after 1 and 3 days respectively. No significant changes were noted in cortical cytosolic prostaglandin E₂-15-hydroxydehydrogenase activity after 3 days. Cortical tissue levels of prostaglandin E₂ increased by 500% at the end of 3 days. These data demonstrate that in nephrotoxic acute renal failure, decreased prostaglandin metabolism (i.e., prostaglandin E₂-9-ketoreductase activity) can result in increased tissue levels of prostaglandin E₂ in the absence of increased prostaglandin synthesis and suggest that alterations in prostaglandin metabolism may be an important regulator of prostaglandin activity in acute renal failure.     

Characterization of biological properties of synthetic and biological leukotriene B3

The effect of micropuncture of the renal papilla through an intact ureter on urinary concetrating ability of rats was examined. Micropuncture of the renal papilla caused a fall in urine osmolality in the punctured kidney from 1718 ± 106 to 1035 ± 79 mosmol/kg·H₂O. In order to investigate the role of renal prostaglandins in this process, PGE₂ excretion was measured and found to increase from 63.4 ± 14.0 to 205.5 ± 57.1 pg/min. Urine osmolality and PGE₂ excretion from the contralateral kidney were not significantly altered. In animals given meclofenamate (2 mg/kg·hr), renal PGE₂ excretion was reduced to 22.3 ± 5.1 pg/min prior to micropuncture and it remained low at 8.9 ± 1.8pg/min after papillary micropuncture. Meclofenamate also blocked the fall in urine osmolality caused by micropuncture of the renal papilla, with urine osmolality averaging 1940 ± 122 before and 1782 ± 96 mosmol/kg·H₂O after the micropuncture. These results indicated that papillary micropuncture through an intact ureter increased renal PGE₂ excretion and that a rise in renal production of PGE₂ or some other prostanoid is associated with a fall in urine concentrating ability.     

Urinary steroid and gonadotropin excretion across the reproductive cycle in female Wied's black tufted-ear marmosets (Callithrix kuhli)

Details of the endocrinology of reproduction in the genus Callithrix are known only for the common marmoset, C. jacchus. This paper presents the patterns of urinary pregnandiol-3-glucuronide (PdG), urinary estrone conjugates (E₁C), and gonadotropin excretion throughout the reproductive cycle of Wied's black tufted-ear marmoset (C. kuhli) as determined via steroid conjugate enzyme immunoassays (EIA) and gonadotropin radioimmunoassays (RIA). Postpartum ovulation occurred at 13.6 ± 1.2 days after parturition (n = 12) and was characterized by low PdG and E₁C concentrations accompanied by a spike in luteinizing hormone (LH)/chorionic gonadotropin (CG) concentration. After conception, PdG concentrations increased dramatically until they dropped to periovulatory concentrations in the third trimester of pregnancy. Mean PdG concentrations in the first and second trimesters (33.7 ± 8.4 and 39.0 ± 10.9 μg/mg creatinine, respectively) were three times that of third trimester concentrations (11.7 ± 1.4 μg/mg Cr; n = 8). Urinary concentrations of E₁C rose more gradually during pregnancy and remained higher prepartum than urinary concentrations of PdG. Urinary gonadotropin concentrations also increased after conception (first trimester concentrations = 24.5 ± 4.5 ng/mg Cr) and continued to increase in the second trimester (51.4 ± 7.6 ng/mg Cr), until they finally decreased in the third trimester (mean = 7.9 ± 1.4 ng/mg Cr; n = 8). The interbirth interval was 156.3 ± 2.9 days (n = 6), with a gestation of 143.1 ± 1.6 days (n = 8). Nonconceptive cycle length was 24.9 ± 0.6 days (n = 4). The results of this study suggest strong similarities in reproductive parameters in the genus Callithrix. © 1996 Wiley-Liss, Inc.