Hormone selective lipase activation in the isolated rabbit heart

The synthesis and release of PGs by the isolated perfused rabbit heart upon bradykinin stimulation results from lipase stimulation which liberates arachidonic acid for PG biosynthesis. The [¹⁴C]-labelled fatty acids, arachidonate, linoleate, and oleate, when infused into the heart preparation, were efficiently incorporated into the phospholipid pool in the heart, mostly in the 2-position of phosphatidylcholine. On the other hand, [¹⁴C]-palmitate was esterified into both the 1- and the 2-position. Bradykinin released bioassayable PG when injected into the rabbit hearts regardless of which fatty acid label was incorporated into the phospholipid pool. However, only [¹⁴C]-arachidonic acid (but not [¹⁴C]-linoleate, oleate or palmitate) was liberated from the variously labelled hearts upon hormone stimulation. This selective bradykinin effect on fatty acid release suggests that hormone stimulation either activates a specific lipase that distinguishes different fatty acids in the 2-position or activates lipase which is selectively compartmented with arachidonate-containing phospholipids. Ischemia, on the other hand, appeared to non-specifically stimulate tissue lipases, resulting in a non-selective release of oleic as well as arachidonic acid. A disproportionally large release of arachidonic acid was observed accompanying a relatively small PG (10:1 arachidonate: PG ratio) production during ischemia, as compared to bradykinin (3:1 ratio), suggesting distinct mechanisms for PG biosynthesis induced by bradykinin and ischemia.This work was supported by NIH grants: SCOR-HL-17646, HE-14397, HL-20787, and Experimental Pathology training grant (WH) 5 TO1 GM00897-16. Address correspondence to Dr. Philip Needleman, Department of Pharmacology, Washington University Medical School, St. Louis, Missouri 63110.     

Selective incorporation of 14C-arachidonic acid into the phospholipids of intact tissues and subsequent metabolism to 14C-prostaglandins

A method is described for the efficient incorporation of radioactive arachidonic acid into the lipids of rabbit hearts and kidneys. Infusion of ¹⁴C-arachidonate through perfused tissues resulted in the quantitative removel of label from the media. Analysis of the lipids from tissues labeled by this procedure revealed that the majority of the ¹⁴C-arachidonate was incorporated into phospholipids. Essentially all of the radioactivity in phosphatidylcholine was found in the 2-position. Subsequent to the ¹⁴C-arachidonate infusion, stimulation of prostaglandin biosynthesis (e.g. by bradykinin) resulted in the release of radioactive prostaglandins. This suggests that the ¹⁴C-arachidonate is incorporated in a manner such that it is available for homone-stimulated prostaglandin biosynthesis. The method described allows both qualitative and quantitative analysis of arachidonate metabolism in intact tissues and offers significant advantages over other presently used methods.     

Hormonal stimulation of arachidonic release from isolated perfused organs relationship to prostaglandin biosynthesis

The lipids of isolated Krebs perfused rabbit kidneys and hearts were labeled with [¹⁴C]arachidonic acid. Subsequent hormonal stimulation (e.g. bradykinin, ATP) of the pre-labelled tissue resulted in dose-dependent release of [¹⁴C]prostaglandins; little or no release of the precursor [¹⁴]arachidonic acid was observed. When fatty acid-free bovine serum albumin was added to the perfusion medium as a trap for fatty acids substantial release of [¹⁴C]arachidonic acid was detected following hormonal stimulation. The release of [¹⁴C]arachidonic acid was dose-dependent and >;3 fold that of [¹⁴C]prostaglandin release. Indomethacin by inhibiting the cyclo-oxygenase, completely inhibited release of [¹⁴C]prostaglandins and only slightly inhibited release of [¹⁴C]arachidonic acid. These results demonstrate that in both rabbit kidney and heart much more substrate is released by hormonal stimulation than is converted to prostaglandins. This suggests that either the deacylation reaction is not tightly coupled to the prostaglandin synthetase system or that there are two deacrylation mechanisms, one which is coupled to prostaglandin synthesis while the other is non-specific. It has previously been shown that prostaglandin release due to hormones such as bradykinin is transient despite continued presence of the hormone (tachyphylaxis). By utilizing albumin to trap released fatty acid, it was found that hormone-stimulated release of arachidonic acid is also transient. This directly demonstrates that tachyphylaxis occurs at a step prior to the cyclo-oxygenase.     

Renal arachidonic acid metabolism and cellular changes in the rabbit renal vein constricted kidney: Inflammation as a common process in renal injury models

The process of renal inflammation was examined using the partial renal vein constricted rabbit kidney (RVC) as a model. Forty eight hours of partial renal vein constriction in the rabbit was associated with an increase in prostaglandin (PG) and thromboxane (Tx) production. The perfused RVC kidney showed an enhanced time-dependent increase in PG and Tx production in response to bradykinin stimulation when compared with the unlatered contralateral (CLK) or normal kidney. At 6 hrs of perfusion bradykinin stimulation lateral (CLK) or normal kidney. At 6 hrs of perfusion bradykinin stimulation released 2950±350 ng PGE₂, 61±15 ng TxB₂ from the RVC, and 225±85 ng PGE₂ and undetectable TxB₂ from the CLK. Histological examination of the RVC cortex showed an increase in fibroblast-like cells, a modest increase in the interstitial space and an appearance of macrophages and lymphocytes not seen in the normal of CLK. Endotoxin has been reported to stimulate macrophages in culture to produce PGE₂ and TxB₂. Endotoxin (100 ng)_stimulation of the perfused RVC kidney caused an immediate, followed by a chronically increasing, release of PGs and Tx. Two hours after endotoxin injection 50 ml of effluent fromt the RVC contained 1450±107 ng PGE₂ and 15.0±4.5 ng TxB₂. Other models of renal inflammation (e.g., the hydronephrotic kidney, chronic glomerulonephritis) also show the histological appearance of macrophages. In addition, hydronephrotic kidneys undergo fibroblast proliferation and changes in arachidonic acid metabolism similar to what we observed in the RVC. This work suggests that the inflammatory process (mononuclear cell infiltration), fibroblast-like cell proliferation, and accompanying changes in arachidonate metabolism) is common among different forms of renal injury.     

Production of thromboxane A2 by the kidney in glycerol-induced acute renal failure in the rabbit

The hemodynamic alterations occuring in glycerol induced renal failure are controversial. To date no single humoral substance can fully explain the change in renal resistance observed in this hemodynamic model of acute renal failure. To assess the capacity of the rabbit kidney to produce thromboxane A₂, a potent vasoconstrictor, the following experiments were carried out. Rabbits received 14 ml/kg of 50% glycerol subcutaneously 24 hrs before the study. After 24 hrs., the kidneys were removed and perfused ex vivo in superfusion bioassay cascade. Kidneys from rabbits which developed renal failure, as assessed by elevated serum creatinines, released a substance which produced contraction of rabbit aorta (RCS) in response to bradykinin (BK) and angiotensin II. Microsomes prepared from these kidneys when incubated with [¹⁴C]-arachidonic acid produced a peak of radioactivity which comigrated with thromboxane B₂ on thin layer chromatography and was inhibited by the thromboxane synthetase inhibitor imidazole. Furthermore, an inverse linear relation was found between the BK dose required to release RCS from perfused kidney and the serum creatinine levels. A direct linear relation was found between the percent of TxB₂ produced by renal microsome preparations and the serum creatinine.These studies demonstrate an increased renal capacity of the glycerol-model of acute renal failure to produce TxA₂. The production of TxA₂ a potent vasoconstrictor should therefore be further evaluated as a potential endogenous mediator of the hemodynamic changes occurring in acute renal failure.     

Hormonal stimulation of arachidonate release from isolated perfused organs. Relationship to prostaglandin biosynthesis

The lipids of isolated Krebs perfused rabbit kidneys and hearts were labelled with [14C]arachidonic acid. Subsequent hormonal stimulation (e.g. bradykinin, ATP) of the pre-labelled tissue resulted in dose-dependent release of [14C]prostaglandins; little or no release of the precursor [14C]arachidonic acid was observed. When fatty acid-free bovine serum albumin was added to the perfusion medium as a trap for fatty acids substantial release of [14C]arachidonic acid was detected following hormonal stimulation. The release of [14C]arachidonic acid was dose-dependent and greater than 3 fold that of [14C]prostaglandin release. Indomethacin by inhibiting the cyclo-oxygenase, completely inhibited release of [14C]prostaglandins and only slightly inhibited release of [14C]arachidonic acid. These results demonstrate that in both rabbit kidney and heart much more substrate is released by hormonal stimulation than is converted to prostaglandins. This suggests that either the deacylation reaction is not tightly coupled to the prostaglandin synthetase system or that there are two deacylation mechanisms, one which is coupled to prostaglandin synthesis while the other is non-specific. It has previously been shown that prostaglandin release due to hormones such as bradykinin is transient despite continued presence of the hormone (tachyphylaxis). By utilizing albumin to trap released fatty acid, it was found that hormone-stimulated release of arachidonic acid is also transient. This directly demonstrates that tachyphylaxis occurs at a step prior to the cyclo-oxygenase.     

Indomethacin but not aspirin inhibits basal and stimulated lipolysis in rabbit kidney

The concurrent effect of indomethacin or aspirin on prostaglandins (PGs) biosynthesis and on cellular fatty acid efflux were compared. Studies with rabbit kidney medulla slices and with isolated perfused rabbit kidney showed a marked difference between the two non-steroidal anti-inflammatory drugs, with regard to their effects on fatty acid efflux from kidney tissue. While aspirin effect was limited to inhibition of PGs biosynthesis, indomethacin also reduced the release of free fatty acids. In medullary slices, indomethacin inhibited the Ca²⁺ stimulation of phospholipase A₂ activity and the resulting release of arachidonic and linoleic fatty acids. In the isolated perfused rabbit kidney, indomethacin inhibited the basal efflux of all fatty acids as well as the angiotensin II — induced selective release of arachidonate. Indomethacin also blunted the angiotensin II — induced temporal changes in the efflux of all other fatty acids. Neither indomethacin nor aspirin affected significantly the uptake and incorporation of exogenous (¹⁴C)-arachidonic acid into kidney total lipid fraction.Our tentative conclusion is that indomethacin inhibits basal as well as Ca²⁺ or hormone stimulated activity of kidney lipolytic enzymes. This action of indomethacin reduces the pool size of free arachidonate available for conversion to oxygenated products (both prostaglandin and non-prostaglandin types). The non-steroidal anti-inflammatory drugs can therefore be divided into two groups: a) $\text{aspirin-type compounds}$ which inhibit PGs formation only by interacting with the prostaglandin endoperoxide synthetase and b) $\text{indomethacin-type compounds}$ which inhibit PG generation by both reduction in the amount of available arachidonate and direct interaction with the enzyme.     

The effect of progesterone on the release of arachidonic acid from human endometrial cells stimulated by histamine

Progesterone at concentrations of 10⁻⁷M and 10⁻⁸M inhibits release of [³H]-arachidonic acid from stimulated, perfused, endometrial cells. The effect is independent of the mechanism of stimulation. Cortisol (10⁻⁵M but not 10⁻⁷M) has a similar effect in this system but estradiol (10⁻⁷M) is without effect. There was a positive correlation (p<0.05) between the magnitude of inhibition by progesterone and the day of cycle. The inhibitory action of progesterone on the release of arachidonic acid was greater in endometrial cells than in decidual cells and was apparent after fifteen minutes. The activities of commercial and endometrial cell-free preparations of phospholipase A₂ and phospholipase C were unaffected by the presence of progesterone. We conclude that progesterone modulates release of [³H]-arachidonic acid from endometrial cells by a rapid, indirect action on phospholipase activity.     

Prostaglandin generation in rabbit kidney. Hormone-activated selective lipolysis coupled to prostaglandin biosynthesis.

The endogenous release of prostaglandins and free fatty acids from the isolated perfused rabbit kidney in the absence or presence of stimulation by bradykinin or angiotensin-II was investigated. Basal (nonstimulated) release of prostaglandin-precursor arachidonic acid was 15-20-fold higher than that of prostaglandin E2 indicating a low conversion of released arachidonate to prostaglandins. Addition of bovine serum albumin to the perfusion medium caused a substantial (50-250%) increase in the release of all fatty acids except myristic and arachidonic acids, and no significant change in prostaglandin E2 generation. In contrast, administration of bradykinin (0.5 microgram) or angiotensin-II (1 microgram) caused a 10-15-fold increase in prostaglandin E2 release, and with albumin present, also a 2-3-fold selective increase in arachidonic acid release. Thus, unlike what was observed under basal conditions, arachidonic acid released following hormone stimulation is efficiently converted to prostaglandin E2. We conclude that administration of bradykinin or angiotensin-II into the perfused kidney activates a lipase which selectively releases arachidonic acid, probably from a unique lipid entity. This lipase reaction is tightly coupled to a prostaglandin generating system so that the released arachidonate is first made available to the prostaglandin cyclooxygenase, resulting in its substantial conversion to prostaglandins.     

The discovery of a rapidly metabolized polymeric tetraphosphate derivative of adenosine in perfused rat heart.

The predicted presence in perfused rat hearts of a rapidly metabolized but hitherto unrecognized form of adenosine phosphate has been confirmed by specific radioactive labelling. The properties of the purified compound suggest that it is a heteropolymer of a small organic acid, phosphate and purine nucleoside in the proportions 1:4:1.     

Metabolic phenotyping of the diseased rat heart using 13C-substrates and ex vivo perfusion in the working mode

The objective of the present study was to compare energy substrate fluxes through metabolic pathways leading to mitochondrial citrate synthesis and release in normal and diseased rat hearts using ¹³C-substrates and mass isotopomer analysis by gas chromatography-mass spectrometry (GCMS). This study was prompted by our previous finding of a modulated citrate release by perfused rat hearts and by the possibility that a dysregulated myocardial citrate release represents a specific chronic alteration of energy metabolism in cardiac patients. The 15-week-old spontaneously hypertensive rat (SHR) was chosen as our animal model of disease and the Wistar-Kyoto (WKY) rat as its matched control. Ex vivo work-performing hearts were perfused with a semi-recirculating buffer containing physiological concentrations of unlabeled (glucose) and ¹³C-labeled ([U-¹³C₃](lactate + pyruvate) and/or [1-¹³C]oleate) substrates. In parallel to the continuous monitoring of indices of the heart's functional and physiological status, the following metabolic parameters were documented: (i) citrate release rates and citric acid cycle intermediate tissue levels, (ii) the contribution of fatty acids as well as pyruvate decarboxylation and carboxylation to citrate synthesis, and (iii) lactate and pyruvate uptake and efflux rates. Working hearts from both rat species showed a similar percent contribution of carbohydrates for citrate synthesis through decarboxylation (70%) and carboxylation (10%). SHR hearts showed the following metabolic alterations: a higher citrate release rate, which was associated with a parallel increase in its tissue level, a lower contribution of oleate -oxidation to citrate synthesis, and an accelerated efflux rate of unlabeled lactate from glycolysis. These metabolic changes were not explained by differences in myocardial oxygen consumption, cardiac performance or efficiency, nor correlated with indices of tissue necrosis or ischemia. This study demonstrates how the alliance between ex vivo semi-recirculating working perfused rat hearts with ¹³C-substrates and mass isotopomer analysis by GCMS, can provide an unprecedented insight into the metabolic phenotype of normal and diseased rat hearts. The clinical relevance of metabolic alterations herein documented in the SHR heart is suggested by its resemblance to those reported in cardiac patients. Taken altogether, our results raise the possibility that the increased citrate release of diseased hearts results from an imbalance between citrate synthesis and utilization rates, which becomes more apparent under conditions of substrate abundance.     

Prostaglandin F2α produced by rabbit renal slices is not a metabolite of prostaglandin E2

Slices of rabbit renal medulla and rabbit renal papilla were incubated with a mixture of [1-¹⁴C]-arachidonic acid and [5,6,8,9,11,12,14,15-³H]-arachidonic acid. In both tissues, comparison of the isotope ratios of the radioactive products with the isotope ratio of the added arachidonic indicated that: (a) there was no discernable isotope effect in the biosynthesis of prostaglandin E₂; (b) prostaglandin F₂α was formed by reduction of prostaglandin H₂ and not by reduction of prostaglandin E₂; and (c) most of the radioactive product arose from arachidonic acid that had been incorporated into the tissue and not from the direct action of cyclooxygenase on arachidonic acid in the medium.     

Localization of exaggerated prostaglandin synthesis associated with renal damage

Regional localization of the exaggerated prostaglandin E₂ (PGE₂) synthesis caused by hydronephrosis was studied in unilateral ureteral ligated rabbits. The renal distribution of PGE₂ production was compared in the hydronephrotic and contralateral kidneys. Basal and bradykinin-stimulated PGE₂ synthesis were increased in cortical and medullary slices of the hydronephrotic kidneys. Contralateral (control) cortical slices produced very low levels of PGE₂ and were insensitive to stimulation by bradykinin (BK). The hydronephrotic cortex produced 10 times more PGE₂ than the contralateral cortex and responded to BK stimulation with increased PGE₂ synthesis. Cortical slices from the hydronephrotic kidney exhibited a time-dependent increase in PGE₂ release, presumably as a result of new protein synthesis. The division of the hydronephrotic cortex into outer and inner regions revealed that the inner cortex produced more PGE₂ than the outer cortex. A similar division of the hydronephrotic medulla showed that the inner medulla produced slightly greater amounts of PGE₂ than the outer medulla. The present study demonstrates that hydronephrosis causes increases in prostaglandin synthesis throughout the kidney. We suggest from these results and other studies that a possible explanation for this finding is the involvement of the collecting duct system in this response. The gradient of PGE₂ production detected in the cortex may have a very significant role in the control of renal hemodynamics and could provide an explanation for the large decrease in blood flow to the inner cortex caused by indomethacin treatment.     

Metabolism of [14C] arachidonic acid in the isolated rabbit spleen

Infusion of [¹⁴C] arachidonic acid (AA) into the isolated, Tyrode perfused rabbit spleen resulted in the release of a substance into the venous effluent with the musculotropic activity and chromatographic properties of prostaglandin (PG)E₂. Smaller amounts of radioactive materials with the chromatographic properties of PGF_2α, 6-keto-PGF_1α, and PGD₂ were also released. The radiolabeled material released in largest amounts from the spleen was identified as PGE₂ on the basis of: 1) Co-chromatography with PGE₂ in three solvent systems, 2) Conversion of the radioactive material and of authentic [³H] PGE₂ to similar products by treatment with sodium borohydride and with potassium hydroxide, and 3) Stability of the musculotropic activity in Tyrode solution at 37°C. Release of the major and minor radioactive products was inhibited by pretreatment of the spleen with either indomethacin or 5,8,11,14-eicosatetraynoic acid.     

Effect of various prostaglandins on the release of arachidonic acid from cultured fibroblasts

Effect of various prostaglandins on the release of arachidonic acid from [¹⁴C]arachidonic acid labeled fibroblasts was studied. Prostaglandin(PG) F_2α was found to enhance the release of radioactive arachidonic acid from the cells. The stimulatory effect was dose dependent, and was greater than that of bradykinin. The active compounds can be ranked in potency for the release of arachidonic acid from the pre-labeled cells per cent of control: PGF_2α(200.1%)>PGF_1α (141.8%)>PGD₂ (137.1%)>thromboxane B₂ (113.7%)>PGE₂ (109.4%). On the other hand, PGI₂ showed a strong inhibitory effect on the arachidonic acid release from the pre-labeled cells (the value was only 69% of the control), while 6-ketoPGF_1α, an end metabolite of PGI₂, had no effect.     

Bradykinin effects on phospholipid metabolism and its relation to arachidonic acid turnovers in neuroblastoma × glioma hybrid cells (NG 108-15)

In neuroblastoma × glioma hybrid cells (NG 108-15) labelled with [³²P]-trisodium phosphate, [³H]-inositol and [¹⁴C]-arachidonic acid, bradykinin stimulated the hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP₂) while it had no effect on the release of [¹⁴C]-arachidonic acid (AA). The effect on PIP, was time- and dose-dependent with a maximal effect on [³H]-inositol- and [³²P]-labelled cells after 10–30 s of stimulation with 10⁻⁶ M bradykinin. However, the hydrolysis of [¹⁴C]-AA labelled PIP₂ was delayed compared to the effect on [³H]- and [¹⁴C]-PIP₂ and was not detectable until after 60 s of stimulation. Bradykinin stimulation resulted in an increased formation of [³H]-inositol phosphates (IP) and [³²P]- and [¹⁴P]- and [¹⁴C]-phosphatidic acid (PA) but the time course for PA formation did not allow the time-course for PIP₂ hydrolysis. A reduced labelling of [²³P]- and [¹⁴C]-phosphatidylcholine was also found in stimulated cells suggesting that PA may derive from other sources than PIP₂. In conclusion, our results indicate that bradykinin activates phospholipase C, but not phospholipase A₂, in NG 108-15 cells.     

Increased renal tubular synthesis of prostaglandins in the rabbit kidney in response to ureteral obstruction

The hydronephrotic rabbit kidney exhibits elevated basal prostaglandin synthesis and supersensitivity to peptide stimulation of vascular prostaglandin and thromboxane formation. In this study the distribution of the prostaglandin-forming cyclooxygenase in hydronephrotic and contralateral rabbit kidneys following one and four day ureteral obstructions was compared using immunohistofluorescence. No alterations were detected in the distribution or intensity of cyclooxygenase-positive fluorescence in the renal vasculature in response to ureteral obstructions. However, two significant differences were noted between hydronephrotic and contralateral kidneys in the staining of renal tubules: (a) the intensity of fluorescent staining in cortical and medullary collecting tubules of the hydronephrotic kidney was increased and (b) cyclooxygenase antigenicity appeared in the thin limbs of Henle's loop in the hydronephrotic organ. Although alterations in prostaglandin formation by the renal vasculature have been documented previously, our results indicate that ureteral obstruction also causes increased prostaglandin synthesis by renal tubules.     

Metabolism of [C] arachidonic acid in the isolated rabbit spleen

Infusion of [¹⁴C] arachidonic acid (AA) into the isolated, Tyrode perfused rabbit spleen resulted in the release of a substance into the venous effluent with the musculotropic activity and chromatographic properties of prostaglandin (PG)E₂. Smaller amounts of radioactive materials with the chromatographic properties of PGF_2α, 6-keto-PGF_1α, and PGD₂ were also released. The radiolabeled material released in largest amounts from the spleen was identified as PGE₂ on the basis of: 1) Co-chromatography with PGE₂ in three solvent systems, 2) Conversion of the radioactive material and of authentic [³H] PGE₂ to similar products by treatment with sodium borohydride and with potassium hydroxide, and 3) Stability of the musculotropic activity in Tyrode solution at 37°C. Release of the major and minor radioactive products was inhibited by pretreatment of the spleen with either indomethacin or 5,8,11,14-eicosatetraynoic acid.     

Increased renal tubular synthesis of prostaglandins in the rabbit kidney in response to ureteral obstruction.

The hydronephrotic rabbit kidney exhibits elevated basal prostaglandin synthesis and supersensitivity to peptide stimulation of vascular prostaglandin and thromboxane formation. In this study the distribution of the prostaglandin-forming cyclooxygenase in hydronephrotic and contralateral rabbit kidneys following one and four day ureteral obstructions was compared using immunohistofluorescence. No alterasions were detected in the distribution or intensity of cyclooxygenase-positive fluorescence in the renal vasculature in response to ureteral obstructions. However, two significant differences were noted between hydronephrotic and contralateral kidneys in the staining of renal tubules: (a) the intensity of fluorescent staining in cortical and medullary collecting tubules of the hydronephrotic kidney was increased and (b) cyclooxygenase antigenicity appeared in the thin limbs of Henle's loop in the hydronephrotic organ. Although alterations in prostaglandin formation by the renal vasculature have been documented previously, our results indicate that ureteral obstruction also causes increased prostaglandin synthesis by renal tubules.     

Pharmacological modification of thromboxane and prostaglandin release in cardiac anaphylaxis

Isolated perfused sensitized guinea pig hearts release relatively larhe amounts of radioimmunologically measurable thromboxane B₂ (TXB₂) as well as smaller amounts of prostaglandins (PGs) after antigenic challenge. Using thin layer chromatography the major PG released was shown to co-chromatograph with PGD₂, while smaller amounts of immunoreactive PGF_2α were found. The TX-synthetase inhibitor imidazole (100 μg/ml) significantly decreased TXB₂ release and simultaneously increased PG release during cardiac anaphylaxis. On the other hand, the β-sympathomimetic drug isoproterenol decreased both TXB₂ and PG release from the anaphylactic hearts. While isoproterenol significantly diminished anaphylactic coronary flow reduction, imidazole was without effect in this respect. PGD₂ (0.5 μ/min and 5.0 μg/min) infused intraaortally into non-sensitized guinea pig hearts reduced coronary flow dose-dependently. These results are compatible with the view that release of TX and PGs might contribute to coronary flow reduction in cardiac anaphylaxis.