trypsin inhibition by sheep haptoglobin

It was found that sheep haptoglobin causes non-competitive inhibition of trypsin. The enzyme inactivation is due to its interaction with haptoglobin. MetHb and thionine do not influence the efficiency of haptoglobin as a trypsin inhibitor. It is concluded that the haptoglobin molecule has a trypsin-binding site which differs from the sites responsible for the interaction with MetHb and thionine.     

Dual inhibition of cyclooxygenase and lipoxygenase by human haptoglobin: its polymorphism and relation to hemoglobin binding

Haptoglobin (Hp) binds hemoglobin (Hb) specifically and stoichiometrically. Since Hb stimulates prostaglandin (PG biosynthesis), we investigated if Hp effects arachidonic acid (AA) metabolism. The results showed that Hp (50-250 microg protein) inhibited the biosynthesis of PGs via cyclooxygenase (COX) and 12-HETE via lipoxygenase pathway in human platelets. Additional evidence was obtained by the loss of Hp inhibitory activity upon removal of Hp by affinity chromatography on hemoglobin sepharose and by inhibition of AA or bradykinin-induced bronchoconstriction in the guinea pig. Hb reduced the inhibitory effect of Hp in a concentration-related manner such that all its inhibitory activity was lost when completely bound by Hb. Of the three Hp phenotypes, Hp 1-1 showed maximum binding capacity to Hb indicating its greater protective role. These findings implicate Hp in the regulation of COX and lipoxygenase pathways and show Hp involvement in the body's endogenous defense system against inflammation. This indicates that mammals have dual defense system, i.e., a specific immune system and non-specific Hp defense system.     

Insulin induced fetal hypoglycaemia and fetal and maternal plasma prostaglandin concentrations in sheep in late gestation.

Fetal hypoglycaemia consequent on food withdrawal for 48 h in sheep in late pregnancy is accompanied by an increase in fetal PGE2 plasma concentrations and myometrial contractility. To assess the contribution of fetal hypoglycaemia and related cellular glucopenia in the increased production of fetal PGE2 we studied the effect of 48 h insulin infusion to the fetus. Fetal whole blood glucose was lowered from 19 +/- 2 to 9 +/- 1 mg.dl-1. This experimental regimen maintains glucose availability to those fetal cells in which insulin increases glucose uptake. Fetal umbilical venous and femoral arterial PGE2 concentrations and umbilical veno-arterial PGE2 difference were unchanged, but maternal uterine veno-arterial difference for PGFM increased during the insulin induced fetal hypoglycaemia. Myometrial activity was also unchanged. We conclude that the increased fetal PGE concentration previously reported during food withdrawal is due to a deficiency of glucose to specific insulin dependent cells within vascular beds served by the fetal cardiovascular system. In addition, the findings suggest a need for a supply of glucose of fetal origin for cells that are responsible for increased PGFM concentrations in the maternal uteroplacental circulation.     

Effects of maternal nutritional status on fetal and placental growth and on fetal urea synthesis in sheep

Fetal and placental growth, and fetal and maternal urea synthesis in late gestation, were studied in 2-year-old Corriedale ewes on a maintenance ration (M) except when subjected to moderate dietary restriction from day 50 to day 100 (RM), day 100 to day 135 (MR) or day 50 to day 135 (RR). In comparison with fetuses of ewes maintained throughout the experiment (MM), RR fetuses were smaller and RM fetuses were larger whereas MR fetuses were unaffected; all restrictions were associated with increased placental size. Fetal urea synthesis at day 133 in the well-nourished ewes (MM) was 21.5 mg N h-1 kg-1 increasing to, respectively, 25.7, 27.3 and 38.8 mg N h-1 kg-1 in groups MR, RM and RR; these values were 1.6, 3.9, 2.2 and 3.8 times the maternal rates of synthesis. On the basis of the observed urea synthesis rates, amino acid oxidation could have accounted for up to, respectively, 32, 38, 40 and 57% of fetal oxygen consumption in groups MM, MR, RM and RR. Amino acids, in addition to their role in tissue accretion, may be key energy substrates for the fetus.     

Prostaglandin biosynthesis and catabolism in the developing fetal sheep lung

The prostaglandin biosynthetic and catabolic capacity of homogenates of lungs fetal sheep of various gestational ages was measured. Prostaglandin biosynthesis was assayed by the deuterium-isotope dilution technique making us e of mas fragmentography whereas prostaglandin catabolism was measured by the radioisotope-dilution method described previously (Pace-Asciak, C.R. and Rangaraj, G. (1976) J. Biol. Chem. 251, 3381–3385).Homogenates of lung sform fetuses of all ages tested (40 days to term) formed both prostaglandins E₂ and F_2α; although prostaglandin F_2α was formed to a greater extent than prostaglandin E₂ by the 40 day lung, prostaglandin E₂ increased with increasing age until at term the ratio of both prostaglandins approached unity. Total prostaglandin biosynthesis (E₂ + F_2α) rose gradually with age (approx. 3 fold increase between 40 days and term). Prostaglandin F_2α catabolism occurred mainly by the prostaglandin 15-hydroxy dehydrogenase pathway; this activity was detectable even at 40 days and remained unchanged up to 80 days. Prostaglandin catabolic activity rose sharply at 90 days (approx. 3 fold) with a maximum around 110 days (approx. 4 fold) decreasing back to 40 day levels by term (143 days).The increasing prostaglandin catabolic activity around 90–100 days in this species is discussed in relation to the hemodynamic changes in the lungs starting around this age and the appearance of surfactant. Prostaglandin catabolism might play an important role in the developing organ controlling steady state concentrations of prostaglandins during certain periods of organogenesis.     

Effects of hyperthermia on fetal and maternal plasma prostaglandin concentrations and uterine activity in sheep

The exposure of pregnant sheep to high ambient temperatures (43 degrees C) for 8 hours, sufficient to significantly elevate maternal and fetal body temperature +2.0 degrees C (p less than 0.001) and +1.9 degrees C (p less than 0.001) respectively, resulted in significant increases in PGE2 plasma concentrations in both the maternal and fetal circulations. Plasma PGF2 alpha concentrations were significantly raised in the fetal circulation but not the maternal during hyperthermia. The increase in prostaglandin concentrations were correlated with the magnitude of the increase in maternal and fetal body temperature. Uterine activity also increased during hyperthermia, probably as a result of the increase in prostaglandin concentrations. We propose that increased synthesis and release of prostaglandins from the uterus and/or placenta is an adaptive response to hyperthermia, and may protect the fetus from the consequences of heat stress.     

Prostaglandin synthesis in human placenta and fetal membranes

The conversion of exogenous arachidonic acid into prostaglandins was studied in human placenta and fetal membrane microsomes. Only one prostaglandin was formed, prostaglandin E₂ (PGE₂), in fetal membrane microsomes. In placental microsomes PGE₂ was further transformed into 15 keto-PGE₂. Cofactor requirements and some characteristics of the system were studied. 1 to 3% conversion of arachidonic acid into prostaglandins was observed in placental microsomes and 5 to 8% conversion in fetal membrane microsomes.     

Prostaglandin synthesis by rheumatoid synovium and its stimulation by colchicine

The synthesis of prostaglandins by rheumatoid synovial tissue in organ culture was studied utilizing radioimmunoassay, with antisera to PGB₁, PGF_1α and PGF_2α. It was established that PGE₂ and PGF_2α were the major prostaglandins formed by analyses of culture media with the two antisera to PGF, before and after alkali treatment. Indomethacin at 5 μg/ml suppressed prostaglandin synthesis, usually to <1% of control cultures. Colchicine, 0.1 μg/ml resulted in marked stimulation of prostaglandin synthesis, in some cases over 10 fold. It is suggested, because of the colchicine effect, that the state of the microtubules may regulate the rate of prostaglandin biosynthesis. It is possible that prostaglandin E₂ produced by rheumatoid synovia may contribute to the pathogenesis of the inflammatory reaction and lead to destruction of juxta-articular bone in rheumatoid arthritis.     

Prostaglandin biosynthesis and catabolism in the developing fetal sheep lung.

The prostaglandin biosynthetic and catabolic capacity of homogenates of lungs from fetal sheep of various gestational ages was measured. Prostaglandin biosynthesis was assayed by the deuterium-isotope dilution technique making use of mass fragmentography whereas prostaglandin catabolism was measured by the radioisotope-dilution method described previous (Pace-Asciak, C.R. and Rangaraj, G. (1976) J. Biol. Chem. 251, 3381-3385). Homogenates of lungs from fetuses of all ages tested (40 days to term) formed both prostaglandins E2 and F2alpha; although prostaglandin F2alpha was formed to a greater extent than prostaglandin E2 by the 40 days lung, prostaglandin E2 increased with increasing age until at term the ratio of both prostaglandins approached unity. Total prostaglandin biosynthesis (E2 + F2alpha) rose gradually with age (approx. 3 fold increase between 40 days and term). Prostaglandin F2alpha catabolism occurred mainly by the prostaglandin 15-hydroxy dehydrogenase pathway; this activity was detectable even at 40 days and remained unchanged up to 80 days. Prostaglandin catabolic activity rose sharply at 90 days (approx. 3 fold) with a maximum around 110 days (approx. 4 fold) decreasing back to 40 day levels by term (143 days). The increasing prostaglandin catabolic activity around 90-100 days in this species is discussed in relation to the hemodynamic changes in the lungs starting around this age and the appearance of surfactant. Prostaglandin catabolism might play an important role in the developing organ controlling steady state concentrations of prostaglandins during certain periods of organogenesis.     

Prostaglandin synthesis in human placenta and fetal membranes.

The conversion of exogenous arachidonic acid into prostaglandins was studied in human placenta and fetal membrane microsomes. Only one prostaglandin was formed, prostaglandin E2 (PGE2), in fetal membrane microsomes. In placental microsomes PGE2 was further transformed into 15 keto-PGE2. Cofactor requirements and some characteristics of the system were studied. 1 to 3% conversion of arachidonic acid into prostaglandins was observed in placental microsomes and 5 to 8% conversion in fetal membrane microsomes.     

Steady-state maternal and fetal plasma concentrations of glyceryl trinitrate (GTN) in the preterm sheep

The administration of glyceryl trinitrate (GTN; nitroglycerin) is increasing during preterm pregnancies, yet its disposition and, importantly, the extent of fetal exposure remain to be elucidated. When used as a tocolytic (pharmacological agent that stops uterine contractions), it is administered transdermally (24-48 h). Here, we quantified the maternal and fetal steady-state plasma concentrations of maternal intravenous GTN in preterm sheep and continuously monitored maternal and fetal vascular parameters to observe possible dose-dependent vascular effects. Preterm (120 days gestation) pregnant sheep (n = 6) were instrumented with maternal femoral arterial (MA) and venous (MV) and fetal femoral arterial (FA) and umbilical venous (UV) polyethylene blood-sampling catheters. During maternal GTN infusion (3.0 micro g.kg-1.min-1, 60-min duration) the steady-state GTN concentrations ([GTN]) were as follows: MA, 98.6 +/- 9.0 nM; UV, 17.4 +/- 7.6 nM; and FA, <5 nM. There were no changes in maternal and fetal mean arterial pressure and heart rate or in uterine activity. Overall, the steady-state [GTN] was established by 5 min, and the UV/MA ratio of [GTN] was 0.18. The FA [GTN] (<5 nM) indicates that the fetus cleared essentially all GTN in the UV, and the maternal and fetal heart rate and mean arterial pressure appear to be independent of maternal GTN infusion.     

Nutritional control of respiratory and other muscular activities in relation to plasma prostaglandin E in the fetal sheep

The effects of nutrient availability on fetal plasma prostaglandin E (PGE) concentrations, on fetal breathing movements and electromyographic (EMG) activities of fetal nuchal and forelimb muscles were investigated in pregnant ewes by varying dietary intake and by manipulation of fetal plasma glucose concentration. The incidence of fetal breathing movements (06.00-10.00 h) decreased with increasing gestational age while fetal arterial concentrations of plasma PGE increased significantly over the same period of gestation. Maternal fasting for 48 h reduced the incidence of fetal breathing movements and the amount of nuchal EMG activity (06.00-10.00 h) in animals older than 130 days but had no effect earlier in gestation. No changes in forelimb EMG activity were observed during fasting at any gestational age. Plasma PGE levels increased significantly during fasts begun both before and after 130 days of gestation. When data from fed and fasted states were combined for all fetuses, irrespective of gestational age, there was a significant inverse correlation between fetal breathing movements incidence and plasma PGE concentration in utero. This relationship was even more pronounced when the fetuses were considered individually. Insulin infusions induced hypoglycaemia, an increase in fetal plasma PGE concentration and a significant reduction in the incidence of fetal breathing movements at all ages. Glucose infusions of fetal breathing movements only after 130 days and had no effect on plasma PGE levels in utero at any gestational age. Neither insulin nor glucose infusions altered the EMG activities of the nuchal and forelimb muscles. The results show that glucose availability is an important factor in determining the incidence of fetal breathing movements in utero and indicate that nutritionally induced changes in fetal breathing movements are mediated in part by PGE. They also suggest that PGE is a physiological regulator of fetal breathing movements in the sheep during late gestation.     

Effects on maternal and fetal steroid concentrations of induction of parturition in the sheep by inhibition of 3 beta-hydroxysteroid dehydrogenase

Changes in circulating steroid hormones, the incidence of myometrial contractions, and the onset of labour were all monitored after administration of the 3 beta-hydroxysteroid dehydrogenase inhibitor, epostane, to chronically catheterized ewes and fetuses near term. In all animals the drug induced delivery 33-36 h after injection or infusion into the ewe with the birth of live healthy lambs which showed normal subsequent development. Epostane induced immediate, permanent falls in both maternal and fetal plasma progesterone concentrations, accompanied by increased PGF metabolite concentrations in the uterine vein beginning 15 min after treatment. Of the other hormonal changes observed, the most striking was the pronounced drop in both maternal and fetal plasma cortisol. In the fetus this fall was followed by increasing concentrations of circulating ACTH which eventually restored the cortisol levels. By 12-24 h after epostane a substantial overshoot had occurred and at 27-30 h the fetal plasma cortisol concentrations were as high as those seen during normal parturition at term. No significant changes in maternal plasma oestradiol-17 beta could be detected after epostane treatment or during labour. The incidence of slow myometrial contractions increased significantly during the second 3-h period after epostane, although their duration did not change. Contraction patterns typical of first stage labour were seen from 20 to 24 h. These results show that epostane may be used as a safe, predictable inducing agent in sheep if given 6-10 days before term; the lambs showed no signs of prematurity despite their lowered plasma cortisol concentrations which persisted for some hours before labour was induced.     

Prostaglandin synthesis by rheumatoid synovium and its stimulation by colchicine.

The synthesis of prostaglandins by rheumatoid synovial tissue in organ culture was studied utilizing radioimmunoassay, with antisera to PGB1, PGF1alpha and PGF2alpha. It was established that PGE2 and PGF2alpha were the major prostaglandins formed by analyses of culture media with the two antisera to PGF, before and after alkali treatment. Indomethacin at 5 mug/ml suppressed prostaglandin synthesis, usually to less than 1% of control cultures. Colchicine, 0.1 mug/ml resulted in marked stimulation of prostaglandin synthesis, in some cases over 10 fold. It is suggested, because of the colchicine effect, that the state of the microtubules may regulate the rate of prostaglandin biosynthesis. It is possible that prostaglandin E2 produced by rheumatoid synovia may contribute to the pathogenesis of the inflammatory reaction and lead to destruction of juxta-articular bone in rheumatoid arthritis.     

Estrogen synthesis in fetal sheep brain: effect of maternal treatment with an aromatase inhibitor

The aim of the present study was to determine whether the fetal lamb brain has the capacity to aromatize androgens to estrogens during the critical period for sexual differentiation. We also determined whether administration of the aromatase-inhibitor 1,4,6-androstatriene-3,17-dione (ATD) could cross the placenta and inhibit aromatase activity (AA) in fetal brain. Eight pregnant ewes were utilized. On Day 50 of pregnancy, four ewes were given ATD-filled Silastic implants, and the other four ewes received sham surgeries. The fetuses were surgically delivered 2 wk later (Day 64 of gestation). High levels of AA (0.8-1.4 pmol/h/mg protein) were present in the hypothalamus and amygdala. Lower levels (0.02-0.1 pmol/h/mg protein) were measured in brain stem regions, cortex, and olfactory bulbs. The Michaelis-Menten dissociation constant (K(m)) for aromatase in the fetal sheep brain was 3-4 nM. No significant sex differences in AA were observed in brain. Treatment with ATD produced significant inhibition of AA in most brain areas but did not significantly alter serum profiles of the major sex steroids in maternal and fetal serum. Concentrations of testosterone in serum from the umbilical artery and vein were significantly greater in male than in female fetuses. No other sex differences in serum steroids were observed. These data demonstrate that high levels of AA are found in the fetal sheep hypothalamus and amygdala during the critical period for sexual differentiation. They also demonstrate that AA can be inhibited in the fetal lamb brain by treating the mother with ATD, without harming fetal development.     

The inhibition and reactivation of human maternal and fetal plasma cholinesterase following exposure to the organophosphate, dichlorvos.

Spontaneous and chemically-induced reactivation of organophosphate-inhibited cholinesterase were studied using as an enzyme source plasma obtained from non-pregnant females, pregnant females at term and their respective neonates, sampled immediately following delivery. Aliquots of plasma were incubated with dichlorvos (10^?6M) for 5 min at 37°C resulting in a 96 percent inhibition of cholinesterase activity in all three groups at which time either pralidoxime chloride (10^?3M) or an equivalent volume of saline was added to the reaction flask and the restoration of cholinesterase activity was monitored over the next 120 min. Pralidoxime-mediated cholinesterase reactivation in ‘non-pregnancy’ plasma was significantly greater than that observed in either ‘maternal’ or ‘fetal’ plasma, however, no significant difference was noted in reactivation rates for these latter two groups. Significant differences were also observed in the rates of spontaneous reactivation, however, after correcting for this, there were still significant differences in the rates of pralidoxime-mediated reactivation (non-pregnant > pregnant ≥ fetal).