The degradation of corticotropin-releasing factor by enzymes of the rat brain studied by liquid chromatography-mass spectrometry.

The corticotropin-releasing factor (CRF; 41 amino acid residues) is a major regulatory peptide in the response to stress and is distributed over many regions of the brain. We have studied the enzymatic degradation of CRF and related peptides by the CRF-degrading enzyme(s) of the rat brain (CRF-DA) by liquid-chromatographic-mass spectrometric technique and by online tandem mass spectrometric experiments. Peptide fragments of the human/rat CRF (1-41) generated by the CRF-DA of the particulate cell fraction were separated and structurally assigned. Major sites of enzymatic attack were identified at the P1 positions Ser1, Thr11 , His13, Leu15, Arg23, Arg35, and Lys36 with Leu15 as the site of primary cleavage. The CRF-DA was shown to be dominated by a metalloendopeptidase activity inhibited by O-phenanthroline and EDTA. The cytosolic fraction generated a similar degradation pattern with a pronounced cleavage at the Arg35 position.

Identification and measurement of beta-endorphin levels in the skin during induced hair growth in mice.

We describe new and effective techniques for extracting proopiomelanocortin (POMC)-derived peptides from mammaliar skin. Using this methodology (hot-acid extraction) and two independent HPLC-controlled RIA systems, we identify beta-endorphin peptide in mammalian skin and demonstrate significant hair cycle-dependent fluctuations in both the skin concentration and the in situ expression pattern of beta-endorphin (sebaceous glands) during the entire murine hair cycle. The observed anagen (growth phase) associated increase in beta-endorphin concentration and its decline during the follicle involution (catagen) or resting (telogen) phase raise the possibility of a regulatory function of this neuropeptide in cyclic changes of skin physiology.

Disposition of 3H-labelled buserelin continuously infused into rats.

The disposition of the gonadotropin-releasing hormone (GnRH) agonist buserelin was studied in male rats under conditions of long-term administration. Rats were continuously infused with about 30 pmole [3H]-buserelin/24 h subcutaneously by osmotic minipumps for 4-7 days. After killing the rats, the 3H-activity of the tissues was measured and was found to be highly concentrated (about 10-fold to plasma) only in the pituitary. The daily amounts of 3H-activity excreted in urine and faces were constant over the whole infusion period, suggesting steady state conditions. On a molar basis, of the infused dose of buserelin, 14.8% was found to be excreted into urine as intact peptide, and 16.5, 10.8 and 20.6% as the partial buserelin sequences 1-2, 1-3 and 5-9. It is concluded that the major elimination route of buserelin, constant with time, is glomerular filtration, followed by enzymatic degradation of part of the filtered peptide by kidney tubuli enzymes to the partial sequences 1-2, 1-3 and 5-9, which reflects the proteolytic breakdown of buserelin by kidney membrane peptidases in vitro. Based on the similarities in the pharmacokinetics, in vivo metabolities, and in vitro enzymatic degradabilities among the GnRH agonists that have the native GnRH sequence modified at position 6 with or without additional modification at the C-terminal, the elimination process as shown here for buserelin should also be valid for other GnRH agonists.

Liquid chromatographic-mass spectrometric studies on the enzymatic degradation of beta-endorphin by endothelial cells.

An on-line HPLC-mass spectrometric procedure with an electrospray atmospheric pressure ionization (ESI-API) ion source was developed to identify the enzymatic degradation products (peptides) generated by incubation of human beta-endorphin (h beta E) with cultured aortic endothelial cells. The samples from the complex incubation mixture were prepurified and enriched using a small reversed-phase (RP) perfusion precolumn. Flow switching was applied to transfer the peptides from this precolumn to the analytical RP column of 2 or 0.32 mm I.D. and to separate them by gradient elution. The peptides were detected by means of an on-line coupled triple quadrupole mass spectrometer (TSQ 700) with an ESI-API ion source operated in the positive ion mode. This MS system behaves as a concentration sensitive detector at flow-rates from 5 to 150 microliters/min. MS-MS experiments supported the unambiguous assignment of the peptide structures. Thus most of the peptide fractions were identified and the region 16-17-18 (-L-F-K-) of h beta E was found to be primarily attacked by the enzymes of the endothelial cells.

Pathways of degradation of buserelin by rat kidney membrane.

The pathways of in vitro degradation of the gonadotropin-releasing hormone (GnRH) analog buserelin [pGlu-His-Trp-Ser-Tyr-D-Ser(tBu)-Leu-Arg- ProNHEt, B1-9] by the rat kidney membrane fraction was investigated using high-performance liquid chromatography for the separation of the peptide products and electrospray mass spectrometry for their identification. The N-terminal peptides B1-4, B1-3, B1-2, C-terminal peptides B3-9, B4-9, B5-9, B6-9, middle sequence B3-4 and the amino acids Trp, Ser and Tyr were found to be formed. However, due to extreme differences in the stability of the peptides toward the battery of membrane enzymes (B1-2, B6-9 >> B1-3, B5-9 >> B1-9 >> B1-4 > B4-9 > B3-9, B3-4), the final products of buserelin degradation were B1-2, B1-3, B5-9, and B6-9 and the amino acids Ser and, corresponding to the formation of B1-2 and B6-9, Trp and Tyr, respectively. The sequences B3-9, B4-9 and B3-4 were clearly detectable only when the inhibitors of aminopeptidases amastatin and bestatin were included in the incubations.(ABSTRACT TRUNCATED AT 250 WORDS)

The enzymatic degradation of bradykinin in semen of various species.

The degradation of bradykinin in semen and on washed sperm cells of various species (human, pig, cattle, sheep) is mainly controlled by two peptidases, the angiotensin-converting enzyme (ACE/kininase II; E.C. 3.4.15.1) and neutral metalloendopeptidase (NEP; E.C. 3.4.24.11). In addition, minor activities of kininase I (carboxypeptidase N/CPN; E.C. 3.4.17.3) were measured exclusively in human samples. Samples of the investigated species varied considerably in their ratios of the activities of bradykinin degrading peptidases. This should be considered in any approach aimed at maintaining the promoting effect of bradykinin on sperm motility by use of enzyme inhibitors.

Liquid chromatographic-mass spectrometric studies on the enzymatic degradation of gonadotropin-releasing hormone.

Gonadotropin-releasing hormone (GnRH) derivatives are used in cancer therapy, but relatively little is known about their metabolic fate in the organism. This paper describes the application of high-performance liquid chromatography combined with electrospray mass spectrometry to identify the degradation products resulting from the incubation of two GnRH analogues, D-Phe6-GnRH and DSer(OtBu)6-desGly10-GnRH-ethylamide (buserelin) with rat kidney membranes. Reversed-phase columns were applied with gradient elution using a flow-rate of ca. 2 microliters/min to the mass spectrometer. Post- and precolumn stream splitting were employed to adjust the flow-rates for columns of 2 and 0.32 mm I.D. The pattern of peptide degradation products obtained with this method indicates that a defined proteolytic membrane enzyme system is responsible for these catabolic processes.

Disposition of the 3H-labeled gonadotropin-releasing hormone analog buserelin in rats.

The short-time disposition of 3H-labeled D-Ser(TBU)6-desGly10-GnRH-ethylamide ([3H]buserelin) was studied in rats after bolus intravenous and subcutaneous injections and killing the rats after 1 and 3 hr, respectively. When estimated as the percentage of the injected dose, 3H-activity within the whole blood rapidly declined from 25.5% at 2 min to 4.7% at 60 min after intravenous injection and remained nearly constant at 3.4% from 30 to 180 min after subcutaneous injection. More than 94% of the blood activity was confined to plasma. 3H-Activity was highly concentrated in the pituitary, as seen from the concentration ratio of activity tissue/plasma (ti/pl), being 12.6 and 8.0 at 60 and 180 min, respectively. A transient accumulation of activity was observed in kidney (ti/pl 9.5 and 2.2 at 60 and 180 min, respectively). All the other tissues studied (liver, spleen, adrenal, testis, epididymis, muscle, lung, fat, skin, heart, thyroid, stomach, and intestine) showed ratios ti/pl below 2.0, mostly below 1.0. The tissues within the blood-brain barrier cortex/thalamus and hypothalamus had the lowest ti/pl (0.08 at 60 min). Within 24 hr after intravenous injection of [3H]buserelin into rats, 58% of the administered 3H-dose was recovered in urine, 21.6% of the urinary radioactivity being identified as intact buserelin. Only 3.6% of the 3H-dose were found in the feces. It is concluded that buserelin is concentrated specifically only in its target organ pituitary, whereas kidney accumulates the peptide transiently due to glomerular filtration and presence of the peptide in the primary urine, part of the peptide being degraded to smaller peptides in the kidney tubuli before being excreted into urine.(ABSTRACT TRUNCATED AT 250 WORDS)

Degradation of bradykinin in semen of ram and boar.

The pattern of bradykinin (BK; Arg1-Pro2-Pro3-Gly4-Phe5-Ser6-Pro7-Phe8-Arg9)-inact iva ting peptidases in semen of boar and ram was investigated. The degradation of BK in semen was completely abolished by the metalloprotease inhibitors EDTA and o-phenanthroline. Inhibitors of angiotensin-converting enzyme (ACE; EC 3.4.15.1) and phosphoramidon, an inhibitor of neutral metalloendopeptidase (NEP; EC 3.4.24.11), were only partially effective in preventing BK degradation in semen. An additive effect was seen with simultaneous inhibition of both enzymes, resulting in complete abolition of BK degradation. HPLC analysis demonstrated that exogenous BK in semen is cleaved at Gly4-Phe5, Phe5-Ser6 and Pro7-Phe8. These results indicate that NEP and ACE are the main peptidases responsible for rapid BK inactivation in semen. The involvement of other peptidases known to be responsible for BK cleavage in other tissues and body fluids, namely carboxypeptidase N (EC 3.4.12.7), post proline cleaving enzyme (EC 3.4.21.26) and aminopeptidase P (EC 3.4.11.9) was excluded. NEP and ACE were shown to be localized mainly in seminal plasma and to a lesser extent on sperm cells.

Spontaneous chemical degradation of substance P in the solid phase and in solution.

The instability of the undecapeptide substance P (SP), a neuropeptide implicated in several physiological processes, was occasionally observed when the peptide was stored in the solid state or in solution. The aim of the present study was to identify the decomposition products of SP stored as lyophilized peptide or in aqueous neutral solution. The main pathway of the decomposition of SP acetate consists of the subsequent release of N-terminal dipeptides via their diketopiperazines, cyclo(Arg-Pro) and cyclo(Lys-Pro). In contrast to the decomposition of the acetate of SP, the hydrochloride and trifluoroacetate salts were found to be considerably more stable. Under the studied conditions the release of N-terminal dipeptides dominates over other possible routes of spontaneous modifications, such as S-oxidation and deamidation.

Gonadotropin-releasing hormone (GnRH) analogs: relationship between their structure, proteolytic inactivation and pharmacokinetics in rats.

There are two types of superactive agonists of gonadotropin-releasing hormone (GnRHa-I: (D-amino acid)6-GnRH and GnRHa-II: (D-amino acid)6-(desGly)10-GnRH- ethylamide) the high hormonal activity of which is understood to be due to their higher receptor affinity and their higher proteolytic stability as compared with the native GnRH sequence. Using the soluble fractions of various rat tissues in studies on the inactivation of GnRH peptides, we confirmed the higher proteolytic resistance of GnRHa-II, but not of D-Phe6-GnRH (GnRHa-I) and of another analog, D-Trp3-D-Phe6-GnRH, as compared with GnRH. The exact behaviour of the peptides during degradation was found to be dependent on the peptide concentrations used, showing the importance of using conditions as near to the physiological ones a possible. Towards the membrane fractions, however, the order of degradability was found to be GnRH much greater than D-Phe6-GnRH much greater than D-Trp3-D-Phe6-GnRH. The pharmacokinetic consequences of the different proteolytic degradabilities of the GnRH peptides, observed in rats, were a moderate increase in the biological half-life of D-Phe6-GnRH by 2.5-fold, as compared with GnRH, and a small increase in half-life of D-Trp3-D-Phe6-GnRH by 1.4-fold when compared with D-Phe6-GnRH. Whereas no intact GnRH was recovered in rat urine, small amounts of D-Phe6-GnRH (about 1% of dose) and high amounts of D-Trp3-D-Phe6-GnRH (25.5%) were excreted into urine. Combining the biochemical and pharmacokinetic data, it is concluded that proteolytic stability of GnRH analogs in pharmacological terms means stability towards membrane enzymes (pharmacologically-related stability) and that designing analogs with further increased proteolytic stability will be of only limited consequences with respect to their biological half-lives, the glomerular filtration rate of the kidney becoming the determining factor in the peptide clearance.