Use of reverse-phase high-performance liquid chromatography in structural studies of neurophysins,photolabeled derivatives,and biosynthetic precursors

The neurophysins are a class of hypothalamo-neurohypophyseal proteins that function as carriers of the neuropeptide hormones oxytocin and vasopressin. Currently, we are using reverse-phase high-performance liquid chromatography for structural characterization of the neurophysins, their chemically modified derivatives, and biosynthetic precursors. A cyanopropylsilyl (Zorbax CN) matrix has been found to be efficient and convenient for separation of major tryptic peptides of performic acid, oxidized or reduced, and alkylated neurophysins. Using this peptide mapping system we have studied the site of modification of a photoaffinitylabeled derivative of bovine neurophysin II by separation and identification of covalently modified peptides. In addition, this system has been used for mapping subfemtomole amounts of radioactively labeled biosynthetic precursors of the neurophysins. This procedure has allowed identification of neurophysin sequences within both pre-pro-neurophysins produced by in vitro translation and rat pro-neurophysins produced by in vivo pulse labeling.     

Mapping and isolation of large peptide fragments from bovine neurophysins and biosynthetic neurophysin-containing species by high-performance liquid chromatography

A peptide mapping procedure suitable for rapid analysis and peptide recovery was devised for the neurophysins. Tryptic fragments of performic acid-oxidized bovine neurophysins I and II were fractionated by reverse-phase high-performance liquid chromatography using γ-cyanopropyl-bonded columns. Elutions were achieved using a gradient from triethylammonium phosphate buffer to mixtures of this buffer with increasing proportions of acetonitrile. All tryptic fragments, except for dipeptides, were separated. Assignments of eluted peaks to particular authentic neurophysin peptides were achieved by collection of peaks and determination of their amino acid compositions. The use of this peptide mapping procedure to detect subpicomole amounts of neurophysin peptides in cell-free biosynthetic products was demonstrated.     

The effects of ligands on enzymic carboxyl-methylation of neurophysins

The methyl-acceptor activities of bovine neurophysins I and II for the enzyme protein carboxymethylase (EC 2.1.1.24) were found to be similar and as high as for other previously identified, biologically active protein substrates. Effects on the rate of methylation of these neurophysins were investigated with the posterior pituitary hormone ligands, oxytocin and vasopressin, and the hormone-related tripeptide ligand, methionyl-tyrosyl-phenylalaninamide. An increase in the rate of neurophysin II methylation was observed with both oxytocin and tripeptide. This ligand-induced response did not occur with either native neurophysin I or disulfide-scrambled neurophysin II.     

Immunocytochemical demonstration of separate vasopressin-neurophysin and oxytocin-neurophysin neurons in the human hypothalamus

Summary With the use of immunocytochemistry, it was shown that both the supraoptic and paraventricular hypothalamic nuclei in humans contain at least two different neurophysins. These two human neurophysins are immunologically related to bovine neurophysin I and neurophysin II, respectively. One human neurophysin is associated with vasopressin, the other with oxytocin. Human vasopressin-neurophysin and oxytocin-neurophysin are located separately in two different types of neurons, which correspond respectively to the vasopressinergic and oxytocinergic neurons of both the supraoptic and paraventricular nuclei. The neurophysin of the human vasopressinergic suprachiasmatic neurons appears to be closely related to or identical with neurophysin of the vasopressinergic neurons of the human magnocellular hypothalamic nuclei.This investigation was supported by a grant from the Belgian Nationaal Fonds voor Geneeskundig Wetenschappelijk Onderzoek     

Neurophysins of Mammals: evolution and biological signification]

Neurohypophysial hormone-Neurophysin complexes have been prepared from posterior pituitary glands of Artiodactyla (ox, sheep, pig), Perissodactyla (horse) and Cetacea (whale), by fractionated salt precipitation. The components have been separated by molecular sieving in 0.2 M acetic acid and neurophysins have been purified by ion-exchange chromatography on DEAE-Sephadex A-50. Two types of neurophysins, MSEL-neurophysins and VLDV-neurophysins, can be distinguished according to the amino acid residues in positions 2, 3, 6 and 7. MSEL-neurophysins of sheep, ox and pig have been characterized by the amino acid sequence. Ovine and bovine MSEL-neurophysins are nearly identical (one substitution out of 95 residues) and porcine MSEL-neurophysin is very similar (four substitutions and an apparent 3-residue C-terminal deletion). The biological function of neurophysins might be the carriage of neurohypophysial hormones but in this respect, each type of neurophysin is not clearly specific for a given hormone. On the other hand, each neurophysin might share a common precursor with a neurohypophysial hormone, the two parts remaining associated after cleavage. However, in the sheep posterior pituitary gland, the molar proportions of the two types of neurophysins, oxytocin and arginine vasopressin, are not equal, MSEL-neurophysin being more abundant than the other components. If a common precursor exists, neurophysins and neurohypophysial hormones are not merely produced by a simple cleavage mechanism.     

Characterization of two different peptides from the venom of the scorpion Buthus sindicus

Two disulfide-rich, low-molecular mass peptides (approximately 3 kDa and approximately 4 kDa) have been isolated from Buthus sindicus venom using ion-exchange and reverse-phase HPLC. Peptide I has 35 residues with 8 half-cystine residues and is clearly related to four-disulfide core proteins of the neurophysin type and to toxins of other scorpion species (55-63% residue identity). Peptide II, present in low yield, has 28 residues with 6 half-cystine residues and a structure largely dissimilar from that of peptide I and other characterized toxins, although probably still a member of the disulfide core peptide type. Consequently, scorpion venom contains, in addition to toxins characterized before, toxin-like compounds with distant relationships.     

Preparation of Porcine Neurophysin Proteins by High Performance Liquid Chromatography

Abstract: The crude neurophysin containing extract from posterior lobes of porcine pituitaries was roughly purified by gel chromatography. 15 mg of the lyophilized neurophysin complex were completely separated by HPLC yielding in neurophysin I₁ (3.6 mg), I₂ (4.0 mg), II (4.6 mg) and III (1.9 mg). All of the neurophysins were homogenous by PAGE and SDS-electrophoresis, isoelectrofocussing, amino-acid composition and N- and C-terminal amino acid analysis. In conclusion, HPLC is a reliable and quick method for the preparation of pure neurophysins.     

Complete amino acid sequence of goose VLDV-neurophysin. Traces of a putative gene conversion between promesotocin and provasotocin genes

Goose VLDV-neurophysin (mesotocin-associated neurophysin) has been purified from posterior pituitary glands through molecular sieving on Sephadex G-75 and high-pressure reverse-phase liquid chromatography on Nucleosil C-18 columns. Despite apparent molecular mass of unreduced VLDV-neurophysin measured by polyacrylamide gel electrophoresis with sodium dodecylsulfate appeared near 17 kDa, this value fell to 11 kDa after reduction with mercaptoethanol, suggesting the existence of a homodimer. Complete amino acid sequence (93 residues) of goose VLDV-neurophysin has been determined. N- and C-terminal sequences of the protein have been established by Edman degradation (microsequencing) and use of carboxypeptidase Y, respectively. Peptides derived from oxidized or carboxamidomethylated neurophysin by trypsin or staphylococcal proteinase hydrolyses have been isolated by high-pressure liquid chromatography and microsequenced, allowing determination of the complete sequence. Comparison within the vertebrate VLDV-neurophysin lineage, namely goose VLDV-neurophysin to mammalian VLDV-neurophysins and to deduced toad VLDV-neurophysin, reveals a residue insertion between positions 66 and 67 in the nonmammalian VLDV-neurophysins. When goose MSEL-neurophysin (vasotocin-associated neurophysin) and goose VLDV-neurophysin are compared to their bovine counterparts, identical substitutions are found in positions 17 (Asn in both goose neurophysins instead of Gly in both ox neurophysins), 18 (Arg instead of Lys), 35 (Tyr instead of Phe), and 41 (Thr instead of Ala). Identity of the sequences 10-74 in both ox neurophysins has been explained by partial gene conversion between oxytocin and vasopressin genes, and identical substitutions in both goose neurophysins might reveal a similar gene conversion between mesotocin and vasopressin genes in birds.     

Highly purified neurophysin proteins: Method of isolation based on their acidic properties

The isolation of highly purified bovine neurophysins I and II from freshly frozen posterior pituitaries is reported. The method can also be used for the isolation of neurophysins from other species, and acetone-desiccated preparations may serve as starting material as well. Crude posterior pituitary extract was obtained as described by Hollenberg and Hope (1967, Biochem. J., 104, 122–127). Basic and neutral proteins were then separated from the acidic neurophysins by cation-exchange chromatography on Cellex-CM (carboxymethyl). Neurophysin I was separated from neurophysin II by anion-exchange chromatography on DEAE-(diethylaminoethyl)-Sephadex with a continuous sodium chloride gradient (0 to 0.4 m). Highly purified bovine neurophysin I was also secured with a stepwise sodium chloride gradient (0.22 m starting gradient followed by a steep gradient from 0.22 to 0.4 m). The current method yields neurophysin proteins in a higher overall yield than previous procedures, as determined by single radial immunodiffusion and concentration-dependent absorption after disc electrophoresis. The method also gives neurophysins of greater purity than standard procedures currently in use. The proteins are characterized by a single, sharp precipitation band on immunodiffusion and immunoelectrophoretic analysis against antiporcine neurophysin antibody, by single bands on analytical gel disc electrophoresis at a running pH of either 8.8, 5.9, or 4.0. Isoelectric focusing on polyacrylamide gel gave an apparent pI value of 4.31 ± 0.07 for neurophysin I and a value of 4.79 ± 0.11 for neurophysin II. Radioimmunoassay revealed barely detectable levels of adrenocorticotropin-like material in neurophysin I (12 pg/100 μg of neurophysin) and no detectable levels in neurophysin II. Both proteins were devoid of avian vasodepressor activity in the conscious chicken, melanotropic activity in vitro in frog skin, and did not effect electrolyte excretion in hydropenic rats.     

Identification of rat neurophysins: Complete amino acid sequences of MSEL- and VLDV-neurophysins

Two rat neurophysins have been purified by salt precipitation, molecular sieving and ion-exchange chromatography. The proteins, performic-acid oxidized or reduced-alkylated, have been split either by trypsin or by staphylococcal proteinase and fragments have been separated by peptide mapping. Amino acid sequences of tryptic peptides have been determined either directly or after cleaving the large fragments by subtilisin, chymotrypsin, elastase or staphylococcal proteinase and characterizing the subfragments. Tryptic peptides have been ordered through the fragments given by staphylococcal proteinase. The N-terminal sequences of both proteins have also been established by automated degradation.The two usual types of mammalian neurophysins have been identified. One neurophysin belongs to the MSEL-neurophysin family and shows 11 substitutions and a 2-residue C-terminal truncation when compared with bovine MSEL-neurophysin. The other belongs to the VLDV-neurophysin family and shows 8 substitutions when compared with bovine VLDV-neurophysin. There are 23 differences between the MSEL- and VLDV-neurophysins of the rat.     

Presence of immunoreactive neurophysins of a higher molecular weight in addition to the 10.000 form in the ovine pineal gland

Using an aqueous extraction followed by ultrafiltration through Amicon Diaflo membranes, two ovine pineal fractions were obtained, which contain immunoreactive neurophysin. The presence of neurophysin was monitored by radioimmunoassay, employing an antiserum raised against pituitary bovine neurophysin and selected because it reacts with neurophysins of many other mammals. From 50 g of wet ovine pineal glands 552 micrograms of immunoreactive neurophysins were obtained. About 5% of these immunoreactive neurophysins are eluted from three different Sephadex columns with an elution volume corresponding to Mr above 10,000 between bovine serum albumin and pituitary neurophysin. The remaining 95% of ovine immunoreactive pineal neurophysin (Mr 10,000) shares immunological and physico-chemical properties with highly purified bovine pituitary neurophysin used as a reference. From the results of gel filtration and affinity chromatography on LVP-Sepharose it was concluded that ovine pineal gland may contain a neurophysin precursor molecule in addition to the neurophysin Mr 10,000.     

HPLC Analysis of Neurophysin Proteins from Neurosecretory Granules

Abstract: Neurosecretory granules were obtained from neurolobes of porcine pituitary glands. From the granules, highly purified neurophysins were prepared by HPLC. According to polyacrylamide gel electrophoresis, isoelectric focusing, N- and C-terminal amino acid residue determination, and amino acid composition, the neurophysins I₁ I₂, and II were identical to the neurophysins obtained from whole posterior lobes. Since degradation could not have occurred, we conclude that neurophysin I₁ and I₂ originated in the neurosecretory granules.     

Contributions of the interdomain loop, amino terminus, and subunit interface to the ligand-facilitated dimerization of neurophysin: crystal structures and mutation studies of bovine neurophysin-I

Current evidence indicates that the ligand-facilitated dimerization of neurophysin is mediated in part by dimerization-induced changes at the hormone binding site of the unliganded state that increase ligand affinity. To elucidate other contributory factors, we investigated the potential role of neurophysin's short interdomain loop (residues 55-59), particularly the effects of loop residue mutation and of deleting amino-terminal residues 1-6, which interact with the loop and adjacent residues 53-54. The neurophysin studied was bovine neurophysin-I, necessitating determination of the crystal structures of des 1-6 bovine neurophysin-I in unliganded and liganded dimeric states, as well as the structure of its liganded Q58V mutant, in which peptide was bound with unexpectedly increased affinity. Increases in dimerization constant associated with selected loop residue mutations and with deletion of residues 1-6, together with structural data, provided evidence that dimerization of unliganded neurophysin-I is constrained by hydrogen bonding of the side chains of Gln58, Ser56, and Gln55 and by amino terminus interactions, loss or alteration of these hydrogen bonds, and probable loss of amino terminus interactions, contributing to the increased dimerization of the liganded state. An additional intersubunit hydrogen bond from residue 81, present only in the liganded state, was demonstrated as the largest single effect of ligand binding directly on the subunit interface. Comparison of bovine neurophysins I and II indicates broadly similar mechanisms for both, with the exception in neurophysin II of the absence of Gln55 side chain hydrogen bonds in the unliganded state and a more firmly established loss of amino terminus interactions in the liganded state. Evidence is presented that loop status modulates dimerization via long-range effects on neurophysin conformation involving neighboring Phe22 as a key intermediary.     

Isolation of spectrin subunits by reverse-phase high-performance liquid chromatography.

We present a one-step uncomplicated method of separation of spectrin subunits. The method is based on reverse-phase HPLC employing an analytical C4 column. Reverse-phase HPLC combines the steps of dissociation and separation of spectrin subunits. The method can be applied to different spectrin isoforms. It can be used for analytical purposes, as well as for small-scale (<0.4 mg) isolation of spectrin subunits.     

High-performance liquid chromatography and studies of neurophysin—neurohypophysial hormone pathways

High-performance liquid chromatography (HPLC) is being used extensively to characterize active polypeptides, precursor processing mechanisms, and cooperative peptide—protein noncovalent complexes in neuroendocrine pathways for neurohypophysial peptide hormones, oxytocin and vasopressin, and the hormone-associated proteins, neurophysins. Reversed-phase and ion-exchange HPLC polypeptide mapping have been used to detect the hormones, associated proteins, and other molecular forms containing these. This mapping but also ultimately to identify anatomical sites which contain the neurophysin/ hormone molecular pathways and to define the relatedness of polypeptide forms contained in different pathways. Reversed-phase HPLC also has provided a means to study proteolytic precursor processing, both to isolate synthetic and semisynthetic polypeptides and intermediates produced by these reactions. Finally, bioaffinity HPLC is being evaluated as a separatory and analytical tool. The latter includes its use to characterize the noncovalent peptide—protein and protein—protein interactions which occur among the molecular forms of the neurophysin/hormone pathways. These experiments typify the impact of HPLC for both analytical and preparative separations in studies of biologically active peptides and proteins.     

Neurophysin heterogeneity. Difference between newly formed and aged neurosecretory granules

Neurosecretory granules from bovine neurohypophyses were isolated on iso-osmotic gradients. The content of the granules was analyzed by analytical and two-dimensional gel electrophoreses. The distributions in the gels of vasopressin precursor and neurophysins were detected by radioimmunoassays. Analytical gel electrophoresis of the content of a crude granule preparation showed the presence of different populations of neurophysin molecules. Further analysis demonstrated that vasopressin-neurophysin and oxytocin-neurophysin can be subdivided into molecules with different pI values. Whereas newly formed granules showed two main spots of neurophysin with pI of 5.0 and 5.6, aged granules contain in addition to these different populations of neurophysin-like material, some of which had a basic pI. Vasopressin precursor activity was detected in spots containing proteins with acidic pI and Mr approximately 18,000 and also in proteins of Mr = 8,000-10,000 migrating in the basic region of the gel. The results suggest that in the neural lobe there is an aging process which gives rise to several subpopulations of neurophysins. The different forms of vasopressin-associated bovine neurophysin and oxytocin-associated bovine neurophysin are only found in the granules which are not required for release.     

Mass spectrometric characterization of Limulus polyphemus hemocyanin.

Electrospray ionization-mass spectrometry of ion-exchange and reverse-phase purified hemocyanin from Limulus polyphemus revealed six predominant isoforms with molecular weights ranging from 71,730 to 72,695 Da. The heaviest of these agreed closely with the molecular weight calculated for the previously determined Edman sequence with substitution of isoleucine for valine at position 9 and inclusion of three internal disulfide bonds and one copper atom. Proposed structures for the other isoforms were made on the basis of the molecular weight measurements. Reverse-phase chromatography can be used in addition to the traditional ion-exchange step to produce hemocyanin preparations of greater purity that might be valuable for further detailed investigations of the physicochemical properties of these important proteins. The results reflect yet again the value of mass spectrometry for recognizing molecular microheterogeneity in biological macromolecules and for following protein purification.     

THE DISTRIBUTION OF NEUROPHYSINS AND POSTERIOR PITUITARY HORMONES IN THE PORCINE NEUROHYPOPHYSEAL SYSTEM

Specific, homologous porcine neurophysin I and II radioimmunoassays were established together with specific oxytocin and vasopressin radioimmunoassays. The levels of each of these proteins and peptides were measured in acid extracts of individual paraventricular nuclei, supraoptic nuclei, neurohypophyseal stalks and posterior pituitary lobes of 12 pigs in order to quantitate the neurophysin-hormone relationships in the porcine neurohypophyseal system. Neurophysin III was found to be immunologically identical to neurophysin I. Neurophysin measurements by radioimmunoassay were quantitatively validated by scanning densitometry of polyacrylamide gels stained with 0.5% amido schwarz. In the hypothalamic nuclei vasopressin was in 3–4 M excess of oxytocin but in the neurohypophyseal stalk and posterior pituitary lobe the hormones were equimolar suggesting that the rate of formation of vasopressin differs from that of oxytocin. Neurophysin I immunoreactivity was present in a 3:1 molar ratio with neurophysin II throughout the porcine neurohypophyseal system. In posterior pituitary lobes total neurophysins were equimolar to total hormone concentrations. The specific activity (pmol/mg extracted protein) of oxytocin increased 1800 times, vasopressin 560 times and neurophysins about 360 times from the paraventricular nucleus to the posterior pituitary lobe. In the hypothalamic nuclei relationships between immunoreactive neurophysin I and vasopressin, and between neurophysin II and oxytocin were highly significant. In the posterior pituitary lobe each immunoreactive neurophysin level correlated with both hormone levels. Quantification of densitometric scans of stained polyacrylamide gels from neurophypophyseal extracts and immunoreactivity patterns of neurophysins in eluates of sliced, duplicate gels indicated that neurophysin III decreased distally within the neurohypophyseal tract while neurophysin I increased. The results demonstrated that vasopressin was associated with porcine neurophysin I. However, oxytocin may be associated with both immunoreactive neurophysin I and neurophysin II in the porcine neurohypophyseal system if a 1:1 molar ratio of neurophysin to hormone is to be maintained. Neurophysin III contributed to the stoichiometry of this relationship.     

Bovine neurophysin lipid complex. Their isolation, characterization and reaggregation

A lipid-containing neurophysin fraction was isolated and purified from bovine posterior pituitary glands by acid extraction and affinity chromatography on a heparin-Sepharose 4B column. This lipid-rich fraction was found to be composed of noncovalent aggregates of neurophysin proteins and phospholipids such as phosphatidyl choline, phosphatidyl ethanolamine, phosphatidyl serine and sphingomyelin. The lipid-containing neuophysin was delipidated by treatment with choloform-methanol. The resultant apoproteins were characterized as bovine neuroions were developed for the reaggregation of purified bovine neurophysin-I and -II with lipids extracted from bovine posterior pituitary and hypothalamus and with synthetic lecithin. The resultant neurophysin lipid complexes have been shown to band upon isopycnic centrifugation at densities different from those of the respective purified bovine neurophysins.     

Concomitant secretion of big endothelin and its C-terminal fragment from human and bovine endothelial cells

A specific radioimmunoassay (RIA) for the carboxyl-terminal fragment (CTF) of big porcine endothelin (pET), an intermediate form of pET, was established to characterize big ET-like and its CTF-like immunoreactivity (LI) secreted from cultured bovine and human endothelial cells (EC). The antibody used crossreacted equally with big pET(1-39) and its CTF(22-39), but not with pET(1-21). Serial dilution curves of the culture media from bovine and human EC were parallel to that of standard CTF. Reverse-phase HPLC coupled with RIAs for big ET and ET of the culture media from bovine and human EC revealed essentially the same elution profiles: two major CTF-LI components, one corresponding to big pET(1-39) and the other to its CTF(22-39), in addition to one major ET-LI component corresponding to pET(1-21). The amounts of CTF-LI were almost equal to that of ET-LI on a molar basis. These data suggest that big ET is processed by a putative ET converting enzyme to yield its CTF and the mature ET(1-21) in EC.