Des-aspartate-angiotensin I and angiotensin AT1 receptors in rat cardiac ventricles

The binding of 125I-[Sar1,Ile8]angiotensin II and 125I-angiotensin II to ventricular membranes of rat heart was studied. Displacement of bound 125I-[Sar1,Ile8]angiotensin II by its cold equivalents, angiotensin I, angiotensin II, angiotensin III, des-aspartate-angiotensin I, losartan, PD123319 and CGP42112B supports the presence of the AT1 and the near absence of the AT2 angiotensin receptor in adult rat ventricle. The presence of binding sites for des-aspartate-angiotensin I could account for its reported cardioprotective actions. Binding of 125I-angiotensin II but not that of 125I-[Sar1,Ile8]angiotensin II was partially displaced by GppNHp suggesting that a portion of the receptor population was in the active state with dissociated G-protein. Saturation experiments carried out in the absence and presence of 1 mM GppNHp showed similar magnitude of decrease in the number of receptors (Bmax from 26.2+/-1.3 to 15.7+/-1.1 fmol/mg protein) in [125I]-angiotensin II binding. However, the guanine nucleotide had no effect on the binding of 125I-[Sar1,Ile8]angiotensin II as has also been reported elsewhere, and may suggest that Sar1-Ile8-angiotensin II, being a partial agonist, binds to both the G-protein coupled and uncoupled states of the angiotensin receptors. The present study demonstrates that des-aspartate-angiotensin I binds to angiotensin receptors in the heart, and provides further evidence for its involvement in the pathophysiology of the organ.     

Inability of [125I]Sar1, Ile8-Angiotensin II to Move Between the Blood and Cerebrospinal Fluid Compartments

The angiotensin II competitive antagonist [125I]-Sar1, Ile8-angiotensin II was not transported from the vascular space to the cerebroventricular space in either intact or nephrectomized rats. In addition [125I]Sar1, Ile8-angiotensin II lacked the capacity to move in the opposite direction over a 20-min collection period following cerebroventricular infusion. These data suggest that angiotensins lack the capacity to move freely between the blood and cerebrospinal fluid compartments and are consistent with the notion that blood-borne and cerebroventricular angiotensins access different receptor populations.     

Antagonists of angiotensin II containing N-methyl-L-alanine and DL-nipecotic acid in position 7.

[1-sarcosine, 7-N-methyl-L-alanine, 8-isoleucine]-Angiotensin II and [1-sarcosine, 7-DL-nipecotic acid, 8-isoleucine]-angiotensin II were synthesized by the solid-phase method and purified by cation-exchange chromatography and high-pressure liquid chromatography. In the isolated rat uterus these analogs and less than 0.1% of the myotropic activity of angiotensin II and inhibited angiotensin II with pA2 values of 8.2 and 7.8, respectively. In the rat pressor assay (vagotomized ganglion blocked rat) these analogs had 0.9 and 2.8%, respectively, of the pressor activity of angiotensin II. The results show that the proline residue in position 7 of [Sar1,Ile8]-angiotensin II may be replaced by other secondary amino acids without disrupting interactions at angiotensin II receptors.     

Evidence for angiotensin II receptors in the urinary bladder of the rabbit

Dose-response (DR) curves for several angiotensin analogs were examined on isolated rabbit detrusor strips with washout and rest between each addition. The order of potency was [Val5]-angiotensin II greater than [Ile5]-angiotensin II greater than [Ile5]-angiotensin I greater than [Val4]-angiotensin III. Repeated cumulative DR to [Val5]-AII resulted in a gradual increase in potency and intrinsic activity for four DR. However, the maximum force generated occurred at lower agonist concentrations and was less than that of the single methods, suggesting tachyphylaxis. Atropine (1.0 microM) shifted the cumulative DR curve downward, suggesting some cholinergic component possibly involving a presynaptic site of action. The magnitude of field-stimulated atropine-resistant contractions was reduced by both 1.0 and 10 microM saralasin as well as 10 microM naloxone. Tissue binding with 125I-labelled angiotensin II on isolated detrusor smooth muscle membranes indicated specific binding saturation occurred at 14.3 fmol/mg with a KD of 0.72 nM in EDTA-Tris buffered saline. Thus our results show that angiotensin II (AII) receptors can be demonstrated in destrusor muscle by ligand binding experiments on cell membranes and that saralasin and naloxone partially block atropine-resistant contractions. However, it seems unlikely that AII serves as a neurotransmitter because of the delay in onset of action of exogenous AII in isolated bath experiments and the apparent inability of saralasin to totally abolish the atropine-resistant field-stimulated preparation. If AII serves a role in neurotransmission it most probably is as a neuromodulator.     

Quantitative distribution of angiotensin II binding sites in rat brain by autoradiography

Angiotensin II binding sites were localized and quantified in individual brain nuclei from single rats by incubation of tissue sections with 1 nM 125I-[Sar1]-angiotensin II, [3H]-Ultrofilm autoradiography, computerized microdensitometry and comparison with 125I-standards. High angiotensin II binding was present in the circumventricular organs (organon vasculosum laminae terminalis, organon subfornicalis and area postrema), in selected hypothalamic nuclei (nuclei suprachiasmatis, periventricularis and paraventricularis) and in the nucleus tractus olfactorii lateralis, the nucleus preopticus medianus, the dorsal motor nucleus of the vagus and the nucleus tractus solitarii. High affinity (KA from 0.3 to 1.5 X 10(9) M-1) angiotensin II binding sites were demonstrated in the organon subfornicalis, the nucleus tractus solitarii and the area postrema after incubation of consecutive sections from single rat brains with 125I-[Sar1]-angiotensin II in concentrations from 100 pM to 5 nM. These results demonstrate and characterize brain binding sites for angiotensin II of variable high affinity binding both inside and outside the blood-brain barrier.     

Angiotensin II binding to mammalian brain membranes.

High affinity binding sites for angiotensin II in bovine and rat brain membranes have been identified and characterized using monoiodinated Ile5-angiotensin II of high specific radioactivity. Degradation of labeled and unlabeled peptide by washed brain particulate fractions was prevented by adding glucagon to the final incubation medium and including a proteolytic enzyme inhibitor (phenylmethylsulfonyl fluoride) in preincubation and incubation procedures. 125I-Angiotensin II binding can be studied using either centrifugation or filtration techniques to separate tissue-bound radioactivity. 125I-Angiotensin II binding to calf brain membranes is saturable and reversible, with a dissociation binding constant of 0.2 nM at 37 degrees. A similar binding constant is found in rat brain membranes. Analogues and fragments of angiotensin II compete for these brain binding sites with potencies which correlate with both their in vivo potencies and their binding inhibition protencies at adrenal cortex angiotensin II receptors. Angiotensin I is 1 to 2 orders of magnitude weaker than angiotensin II; the 3-8 hexapeptide and 4-8 pentapeptide are much weaker still. (desAsp1) angiotensin II (angiotensin III) is slightly more potent than angiotensin II, as are several antagonists of angiotensin II with aliphatic amino acids substituted at position 8. In calf brain 125I-angiotensin II binding is restricted almost exclusively to the cerebellum (cortex and deep nuclei). In rat brain, angiotensin II binding is highest in the thalamus-hypothalamus, midbrain, and brainstem, areas which are believed to be involved in mediating angiotensin II-induced central effects. These findings illustrate the presence of high affinity specific binding sites for angiotensin II in rat and bovine brain and suggest a physiological role for angiotensin peptides in the central nervous system.     

Cerebroventricular and Intravascular Metabolism of [125I]Angiotensins in Rat

This study compared the metabolism of [125I]angiotensin II (AII), [125I]angiotensin III (AIII), and [125I]Sar1,Ile8-AII (SI-AII) in the vascular and cerebroventricular compartments. Using HPLC methods to monitor degradation the following t1/2 values were established in the vascular compartment: AII, 12.7 +/- 1.4 s; AIII, 16.3 +/- 0.7 s; and SI-AII, 100.7 +/- 7.3 s. HPLC analysis also revealed that [125I]AII is converted in an obligatory manner to [125I]AIII during its degradation sequence. Cerebrospinal fluid contained no degradative capacity for [125I]AII but exhibited a significant capacity to degrade [125I]AIII. A technique that combined the intra-cerebroventricular injection of [125I]angiotensins followed by focused microwave fixation to stop all peptidase activity was used to determine the half-life of [125I]angiotensins in the ventricular space. Results indicated very rapid metabolism of angiotensins with the following t1/2 values: AII, 23.0 s; and AIII, 7.7 s. This extremely rapid, differential, and sequential metabolism of AII and AIII in two relevant body fluid compartments underscores the need for caution when interpreting data derived from intravascular and intracerebroventricular application of angiotensins. In addition the faster metabolism of AIII than AII in the ventricular space indicates that the actual potency of AIII at central angiotensin receptors is being underestimated.     

Effects of des-aspartate-angiotensin I on angiotensin II-induced incorporation of phenylalanine and thymidine in cultured rat cardiomyocytes and aortic smooth muscle cells

Des-aspartate-angiotensin I, a pharmacologically active nine-amino acid angiotensin peptide, and losartan, an AT(1) angiotensin receptor antagonist, but not angiotensin-(1-7), another active angiotensin peptide, completely attenuated the angiotensin II-induced incorporation of [3H]phenylalanine in cultured rat cardiomyocytes. The attenuation by des-aspartate-angiotensin I but not that of losartan was inhibited by indomethacin. The data support an earlier suggestion that the nonapeptide attenuates cardiac hypertrophy in rats via an indomethacin-sensitive angiotensin AT(1) receptor subtype. In rat aortic smooth muscle cells, both des-aspartate-angiotensin I and angiotensin-(1-7) had no effect on the angiotensin II-induced [3H]phenylalanine incorporation. However, the two peptides significantly attenuated the angiotensin II-induced [3H]thymidine incorporation in the smooth muscle cells. The attenuation by angiotensin-(1-7) but not by des-aspartate-angiotensin I was inhibited by (D-Ala(7))-angiotensin-(1-7), a specific angiotensin-(1-7) antagonist. Des-aspartate-angiotensin I also attenuated FCS-stimulated [3H]thymidine incorporation. This attenuation was inhibited by the peptide angiotensin receptor antagonist, (Sar(1), Ile(8))-angiotensin II, but not by losartan. These data indicate that des-aspartate-angiotensin I and angiotensin-(1-7) do not participate in the process of protein synthesis in vascular smooth muscle cells and that the nonapeptide and heptapeptide act on different non-AT(1) receptors to mediate their anti-hyperplasic action. Although the exact mechanisms of action remain to be elucidated, the findings indicate that des-aspartate-angiotensin I acts as an agonist on angiotensin AT(1) and non-AT(1) receptor subtypes and induces responses that oppose the actions of angiotensin II.     

Simultaneous identification of estrogen and progesterone receptors by HPLC using a double isotope assay.

Polymorphism of estrogen (ER) and progestin receptors (PR) was analyzed simultaneously using high performance hydrophobic interaction chromatography (HPHIC). HPHIC was used previously to characterize four ER isoforms [Hyder et al., J. Chromat. 397 (1987) 251] based on retention times on Synchropak propyl (100 x 6 mm) HPLC columns (Synchrom, Inc.). ER and PR were prepared from human breast cancer. ER was labeled with 3 nM of either [3H]estradiol-17 beta ([3H]E) or [125I]iodoestradiol-17 beta ([125I]E) while PR was associated with 5 nM of either [3H]R5020 ([3H]R) or [125I]iodovinylnortestosterone ([125I]V). ER was resolved by HPHIC into isoforms MI (Rt = 11 min), I(Rt = 16 min), and II (Rt = 24 min). Isoforms I and II each accounted for ca 45% of specific binding. PR separated into isoforms MI (Rt = 14 min) and I (Rt = 21 min, 80% of specific binding) when eluted with the same gradient used for ER chromatography. Upon inclusion of 10 mM molybdate ER resolved into isoforms MI and MII (Rt = 16 min) and PR into isoforms MI and I (here however isoform MI represented 80-95% of specific binding). Elution patterns were preserved with different batches of stationary phase suggesting the integrity of the isoform distribution. HPLC profiles of ER isoforms labeled with earlier [125I]E or [3H]E were identical as were PR isoform profiles labeled with either [3H]R or [125I]V. Pairs of 125I- and 3H-labeled ligands were used in either combination to monitor ER and PR profiles simultaneously. Isoforms analyzed in 50 biopsies gave reproducible retention times, however the ratio between I and II for ER and MI and I for PR varied. This method allows rapid, simultaneous monitoring of the chromatographic behavior of ER and PR isoforms or other associating proteins or nucleotides. One may now better elucidate their interrelationship as it relates to the hormone-response mechanism.     

Specific, high-affinity binding sites for angiotensin II on Mycoplasma hyorhinis.

Mycoplasmataceae are known to express various proteins that are similar to those present in mammals. We report a strain of Mycoplasma hyorhinis isolated from opossum kidney cells with specific, high-affinity binding sites for human angiotensin II (Kd = 5.1 +/- 1.9 nM). In contrast, two strains of M. hominis revealed no specific binding. These binding sites resembled mammalian angiotensin II receptors by their high affinity and by their sensitivity to dithiothreitol. However, they are different from mammalian angiotensin II receptors in that they bind angiotensin I with high affinity (Kd = 1.6 +/- 0.29 nM) but not angiotensin III (Kd approximately 330,000 nM). [125I]-angiotensin II binding was not inhibited by angiotensin receptor subtype antagonists DuP 753 and CGP 42112A but it was sensitive to bacitracin and aprotinin. Positions Asp1, Ile5, His6 and Pro7 were essential for binding to M. hyorhinis as deletion of these residues led to a more than 10,000-fold decrease in affinity.     

Angiotensin II receptors in the human placenta are type AT1

Membrane angiotensin II receptors were measured in human placenta by means of 125I [Sar1 Ile8] All (angiotensin II antagonist) and characterized by using 2 other antagonists of angiotensin II: Dup 753 and CGP 42112A. These are specific and selective ligands which enable identification of AT1 and AT2 receptor subtypes respectively. The [Sar1 Ile8] All affinity is similar (Kd approximately 1 nmol.l-1) in the 3 different placental structures examined. However, the Bmax of villous tissues is approximately 9 times higher than that observed in chorionic plate but remains near that found in basal plate. In the central area of the placenta, mean values of 125I [Sar1 Ile8] All binding observed at a single concentration of 0.15 nmol.l-1 are 242 +/- 31 fmol/mg proteins in basal plate, 300 +/- 35 in villous tissues and 36 +/- 8 in chorionic plate. The umbilical vein and arteries respectively have 8.8 +/- 4.8 and 4.0 +/- 1.7 fmol/mg protein. The subtype analysis shows that only AT1 receptor is present in placental tissues. The Bmax values as well as those obtained by the relative measurement performed at a fixed 125I [Sar1 Ile8] All concentration of 0.15 nmol.l-1 indicate that the highest concentrations of angiotensin II receptors are found in placental villous tissues.     

Analysis of renal and hippocampal type I and type II receptors by fast protein liquid chromatography

Type I and Type II adrenal steroid receptors from rat renal and hippocampal cytosols were studied by the technique of Fast Protein Liquid Chromatography. Type I receptors were labelled with [3H]aldosterone plus excess RU26988, and Type II receptors with [3H]dexamethasone. On a Mono Q anion exchange column the molybdate-stabilized renal and hippocampal Type I receptors both eluted as single symmetrical peaks at 0.27 M NaCl, with a recovery of approximately 90% and 60-fold purification (renal) and 10-15-fold (hippocampal). Molybdate-stabilized Type II binding sites from both hippocampal and renal cytosols co-eluted with the Type I sites. On Superose gel filtration renal Type I receptor-steroid complexes consistently eluted two fractions later than hippocampal Type I complexes, suggesting that the renal complexes are smaller; Type II receptor-steroid complexes from both cytosols co-eluted, consistently one fraction behind hippocampal Type I sites. Sequential gel filtration and anion exchange chromatography achieved a 1000-fold purification of renal Type I binding sites, with an overall recovery of 10%.     

Purification and characterization of a human kidney neutral endopeptidase that hydrolyzes succinyl trialanine-4-nitroanilide and biologically active peptides

An enzyme hydrolyzing succinyl trialanine-4-nitroanilide was extracted from human kidney homogenate and purified by means of gel filtration on Sepharose CL-4B, anion-exchange chromatography on DEAE-Sepharose CL-6B and affinity chromatography on carbobenzoxy-L-Ala-L-Ala-D-Ala-polylysine-agarose. The purified enzyme consists of a single peptide, and its molecular weight was estimated to be about 125 000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified enzyme cleaved the substrate at the bond between succinyl dialanine and alanine-4-nitroanilide and showed a Km value of 2.1 mM at the optimal pH of 8.0. The activity was increased by Ca2+ and Mg2+, but was inhibited by phosphoramidon and ethylenediaminetetraacetic acid. The enzyme cleaved the oxydized insulin B chain, angiotensinogen tetradecapeptide, angiotensin I, angiotensin II, angiotensin III, [Sar1,Ala8]-angiotensin II, bradykinin, des-Pro2-bradykinin, Leu5-enkephalin, Met 5-enkephalin, [D-Ala2,Met5]-enkephalinamide and [D-Ala2-Met5]-enkephalin, but did not cleave [D-Ala2,D-Leu5]-enkephalin. The bonds on the amino side of the hydrophobic amino acids of the peptides were cleaved by the enzyme.     

Ca2+-dependent cysteine proteinase, calpains I and II are not phosphorylated in vivo

To clarify phosphorylation of calpains I and II in vivo, we purified both calpains concurrently from the [32P] metabolic-labeled human chronic myelogenous leukemia cell line K-562. By Ultragel AcA34 column chromatography, enzymatic activity of calpain I was separated from [32P] radioactivity. Whereas calpain II activity was closely associated with [32P] radioactivity on Ultragel AcA34 and Blue Sepharose CL-6B column chromatographies. By the above purification procedures, calpain I was purified 1300-fold from the crude extract and calpain II was 920-fold from the original sample, respectively. Autoradiographies of purified calpains I and II from [32P] labeled K-562 cells revealed that both calpains were not specifically phosphorylated in vivo. The autophosphorylation in vitro on calpains and modulation of their proteolytic activities reported recently thus may not occur within cells.     

Analysis of angiotensins I,II, III,and iodinated derivatives by high-performance liquid chromatography

Angiotensins I, II, and III were separated by reversed-phase high-performance liquid chromatography on an octadecylsilyl column. The peptides were isocratically eluted with 50 mm NaH₂PO₄-25% ($\text{v}\text{v}$) acetonitrile, pH 6.0. The retention times were 3.3, 6.0, and 9.6 min for angiotensin II, III, and I, respectively. ¹²⁵I-Angiotensins II, III, and I eluted with retention times of 5.4, 16.8, and 19.9 min, respectively, under the same chromatographic conditions used for the unlabeled angiotensins. The effect of iodination of the tyrosine residue on the retention time was also demonstrated by chromatographic comparison of tyrosine and diiodotyrosine. Saralasin (Sar¹, Ala⁸-angiotensin II), a partial agonist of angiotensin II, and des-Asp¹, Ile⁸-angiotensin II, an inhibitor of angiotensin III, eluted with retention times of 2.5 and 3.9 min, respectively.     

Intrarenal localization of angiotensin II specific binding in rat fetuses

Specific binding sites for angiotensin II were localized in the developing rat kidney (18th day of pregnancy and immediately before birth) by autoradiography using [125I]-ileu-5-angiotensin II either perfused in vivo through the fetal aorta or added in vitro to frozen sections in an incubation mixture. Specific binding was localized in the walls of the afferent and efferent arterioles, in the intraglomerular cells and in the peritubular arterioles of the subcapsular cortical zone. The immunohistochemical analysis, carried out on receptors saturated with unlabelled angiotensin II perfused through the mother's aorta, confirmed the autoradiographical localization. Antisera against ileu-5-angiotensin II were used in the indirect immunofluorescence technique and in the PAP method. Immunolocalization of angiotensin II was also found in the proximal tubule and in the thick ascending limb of Henle's loop.     

The hepatic angiotensin II receptor. II. Effect of guanine nucleotides and interaction with cyclic AMP production

Guanine nucleotides were observed to modify the binding of 125I-angiotensin II to rat hepatic plasma membrane receptors. GTP and its nonhydrolyzable analogues greatly increased the dissociation rate of bound 125I-angiotensin II and altered hormone binding to the receptor under equilibrium conditions. In the absence of GTP, 125I-angiotensin II labeled both high affinity sites (Kd1 = 0.46 nM, N1 = 650 fmol/mg) and low affinity sites (Kd2 = 4.1 nM, N2 = 1740 fmol/mg). In the presence of guanine nucleotides, the affinities of the two sites were unchanged, but the number of high affinity sites decreased markedly to 52 fmol/mg. In analogous experiments using the angiotensin II antagonist, 125I-sarcosine1,Ala8-angiotensin II (125I-saralasin), guanine nucleotides minimally affected the interaction of 125I-saralasin with its receptor, increasing the dissociation rate 1.9-fold and the Kd 1.4-fold. The guanine nucleotide inhibition of agonist binding required a cation such as Na+ or Mg2+, with a maximal effect occurring at about 1 mM Mg2+. In liver plasma membranes prepared in EDTA, angiotensin II inhibited basal and glucagon-stimulated adenylate cyclase activities by 30% and 10%, respectively. Angiotensin II also caused a 40% inhibition of glucagon-stimulated cyclic AMP accumulation in intact hepatocytes, with a half-maximal effect occurring at 1 nM. The inhibition by angiotensin II of adenylate cyclase in membranes and of cAMP levels in intact cells could be reversed by the antagonist sarcosine1,Ile8-angiotensin II. Vasopressin caused a smaller 26% inhibition of glucagon-stimulated cyclic AMP accumulation. The ability of angiotensin II to inhibit cyclic AMP synthesis may provide an explanation for the observed effects of guanine nucleotides on 125I-angiotensin II binding to plasma membranes.     

Angiotensin receptors in resting smooth muscle are the low affinity sites observed in binding studies

Angiotensin receptors in rat uterine smooth muscle have been investigated by [125I]angiotensin II binding studies in membrane preparations. Scatchard analysis of binding data has demonstrated the presence of low and high affinity angiotensin binding sites with KLD = 3.0 X 10(-8) and KHD = 5.0 X 10(-10)M respectively. These values are identical to our previously reported values for the EC50 and dissociation constant, respectively, obtained from bioassays on intact uterine tissues. The antagonist [Sar1, Ile8]angiotensin II also demonstrates a binding affinity in uterine membranes (pKD = 8.7) which is not significantly different from its apparent binding affinity (pA2 = 8.6) in responding tissues. Taken in conjunction with our previously published bioassay data the present binding studies suggest that the resting state of the angiotensin receptor in smooth muscle is a low affinity state, and that interaction with ANG II induces a portion of the receptors into a high affinity "excited" state. The antagonist [Sar1, Ile8]angiotensin II apparently binds with higher affinity than angiotensin II to the low affinity (resting) state of the receptor.     

Enzymatic formation of angiotensins II and III in the hindlimb circulation of dogs

Experiments were performed in 14 anesthetized dogs to (1) to determine if the reductions in hindlimb blood flow produced by [des-Asp1] angiotensin I were due to its local enzymatic (kininase II) conversion to angiotensin III and (2) to quantitate the extent of conversion of angiotensin I to angiotensin II and of [des-Asp1] angiotensin I to angiotensin III in the hindlimb circulation. Graded doses of these peptides were administered as bolus injections directly into the left external iliac artery while measuring flow in this artery electromagnetically. Dose-response relationships were determined before and during the inhibition of kininase II activity with captopril or antagonism of angiotensin receptor sites with [Ile7] angiotensin III. Captopril inhibited the vasoconstrictor responses to angiotensin I and [des-Asp1] angiotensin I, but did not affect the responses to angiotensins II or III, or norepinephrine. [Ile7] angiotensin III inhibited the vasoconstrictor responses to all four angiotensin peptides but did not alter the responses to norepinephrine. These findings indicate that the hindlimb vasoconstrictor responses to [des-Asp1] angiotensin I were due to the local formation of angiotensin III. The extent of conversion of [des-Asp1] angiotensin I to angiotensin III that occurred in one transit through the hindlimb arterial circulation was estimated to be 36.7%, which was not different from the estimated 36.4% conversion of angiotensin I to angiotensin II. We conclude that angiotensin I and [des-Asp1] angiotensin I are converted to their respective vasoactive forms (angiotensins II and III) to a similar extent in the hindlimb circulation via the action of kininase II.     

Characterization by high performance liquid chromatography of angiotensin peptides in the plasma and cerebrospinal fluid of the dog

A high performance liquid chromatography (HPLC) method is described for the separation of angiotensin (Ang) peptides and their subsequent quantification by radioimmunoassay in plasma and cerebrospinal fluid (CSF). The use of the ion-pair solvent heptafluorobutyric acid in gradient HPLC achieves baseline resolution of Ang I, Ang II, and the C-terminal fragments des-[Asp1]-Ang I, des-[Asp1]-Ang II, des-[Asp1,Arg2]-Ang II and des-[Asp1,Arg2,Val3]-Ang II in approximately 25 min. Recovery of synthetic Ang standards after phenylsilica extraction and HPLC separation was greater than 70% for each peptide in both plasma and CSF. Ang I and Ang II were shown to be the major immunoreactive Ang components in plasma, and Ang II, des-[Asp1,Arg2]-Ang II and des-[Asp1,Arg2,Val3]-Ang II in CSF.