©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Structural Characterization of a Novel Neuropeptide from the Central Nervous System of the Leech Erpobdella octoculata
THE LEECH OSMOREGULATOR FACTOR (*)

(Received for publication, October 2, 1995; and in revised form, December 27, 1995)

Michel Salzet (1)(§) Phillipe Bulet (2) Wolf-Michael Weber (3) Wolfgang Clauss (3) Martine Verger-Bocquet (1) Jean Malecha (1)

From the  (1)Laboratoire de Phylogénie moléculaire des Annélides ER 87 CNRS, Groupe de Neuroendocrinologie des Hirudinées, Université des Sciences et Technologies de Lille, F-59655 Villeneuve d'Ascq Cédex, France, the (2)Institut de Biologie Moléculaire et Cellulaire, UPR 9022 CNRS, 15 rue Descartes, F-67084 Strasbourg Cédex, France, and the (3)Institut für Tierphysiologie, Justus-Liebig-Universität, Giessen, D-35392 Giessen, Germany

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

Purification of a material immunoreactive to an antiserum against the C-terminal part of the oxytocin (Pro-Leu-Gly-amide) and present in the central nervous system of the Pharyngobdellid leech Erpobdella octoculata was performed by reversed-phase high performance liquid chromatography combined with both enzyme-linked immunosorbent and dot immunobinding assays for oxytocin. The amino acid sequence of the purified peptide (Ile-Pro-Glu-Pro-Tyr-Val-Trp-Asp) was established by Edman degradation and confirmed by electrospray mass spectrometry measurement. When injected in leeches, purified or synthetic peptides exert an anti-diuretic effect, the most effective ranged between 10 pmol and 1 nmol. They provoked an uptake of water 1-2 h post-injection. Furthermore, electrophysiological experiments conducted in the leech Hirudo medicinalis revealed an inhibition of the potency of Na conductances of leech skin by this peptide. Immunocytochemical studies with an antiserum against synthetic oxytocin-like molecule provided the cytological basis for existence of a neuropeptide, since large amounts of immunoreactive neurons were detected in the central nervous systems of E. octoculata. The purified molecule is both different to peptides of the oxytocin/vasopressin family and is a novel neuropeptide in the animal kingdom. It was named the leech osmoregulator factor (LORF).

An identification of the proteins immunoreactive to an antiserum against oxytocin performed at the level of both central nervous systems extracts and in vitro central nervous system-translated RNA products indicated that in the two cases, a single protein was detected. These proteins with a molecular masses of, respectively, 34 kDa (homodimer of 17 kDa) for the central nervous systems extracts and 19 kDa for in vitro central nervous system-translated RNA products were not recognized by the antiserum against MSEL- and VLDV-neurophysin (proteins associated to oxytocin and vasopressin), confirming that LORF did not belong to the oxytocin/vasopressin family.


INTRODUCTION

In annelids, the central nervous system (CNS) (^1)of Hirudinae is known to influence water balance (Rosca et al., 1958; Czechowicz, 1968; Kulkarni and Nagabhushanam, 1978; Malecha, 1983). In the rhynchobdellid leech Theromyzon tessulatum genital maturity is concomitant with a phasis of water retention reflected by an increase in mass of the animals and correlated to a clomic accumulation of yolk proteins (Baert et al., 1991, 1992). This animal was used for a study of the control of water balance.

Angiotensin II-amide (Salzet et al., 1995), GDPFLRF-amide (Salzet et al., 1994), and lysine-conopressin (Salzet et al., 1993a) have been isolated from CNS of the Pharyngobdellid leech Erpobdella octoculata. They generated when injected in T. tessulatum a decrease in mass of the injected animals, expressing a diuretic effect. On the other hand, an injection of an antiserum directed against oxytocin (OT) provoked a loss of mass in the injected leeches (Malecha et al., 1989a), pointing to an anti-diuretic role for substance(s) immunoreactive to anti-OT.

In E. octoculata, it is known that an OT-like material is found in large amounts in the sex segmental ganglia (sex SG), and that an extract of sex SG exerts an anti-diuretic effect when injected in leeches (Salzet et al., 1993c). Cell counts of OT-like cells in immature and mature animals indicated that the number of immunoreactive cells was higher in immature specimens. Furthermore, radioimmunoassays showed an amount of OT-like material 3-fold higher in immature than in mature leeches. A biochemical study of an extract of sex SG of mature E. octoculata demonstrated the presence of two zones immunoreactive to a-OT. On the other hand, in immature E. octoculata, an additional zone bearing 80% immunoreactivity to a-OT was detected. For this additional zone in immature animal, hypothesis of the presence of a possible fragment of the OT-like precursor was given (Salzet et al., 1993c). In supernumerary neurons of sex SG, OT-like material is colocalized with four RF-amide peptides, i.e. FMRF-amide, FM(O)RF-amide, FLRF-amide, and GDPFLRF-amide. FMRF-amide and GDPFLRF-amide as OT-like substance(s) are involved in osmoregulation (Salzet et al., 1994).

In this study, we now report the isolation and the characterization of an OT-like peptide from CNS of the Pharyngobdellid leech E. octoculata using HPLC purification procedures, automatic Edman degradation and electrospray mass spectrometry analysis, electrophysiological experiments, and immunocytochemical studies performed with an antiserum against synthetic oxytocin-like peptide. Finally, an identification of CNS proteins immunoreactive to an antiserum against OT at the level of both CNS extracts and in vitro CNS-translated products was also undertaken. This work demonstrated the existence of a novel neuropeptide involved in the process of osmoregulation. This molecule named leech osmoregulator factor (LORF) is unique in the animal kingdom.


MATERIALS AND METHODS

Animals and Dissection Procedure

Mature and immature Pharyngobdellid leech E. octoculata, collected at Harchies (Belgium) and kept in the dark at 15 °C in pond water, were used for the isolation of the OT-like peptide. After anesthesia in 0.01% chloretone, animals were pinned out, dorsal side up, in leech Ringer's solution (Muller et al., 1981) and central nervous systems (CNS) were excised, immediately frozen in liquid nitrogen, and stored at -70 °C until use.

Mature Rhynchobdellid leeches T. tessulatum were used in this study as a bioassay according to Salzet et al. (1995).

Antiserum

A polyclonal antiserum used in ELISA and dot immunobinding assay (DIA) procedures was raised in our laboratory by immunizing rabbits with synthetic oxytocin (Interchim) coupled to thyroglobulin with glutaraldehyde. It was characterized by Salzet et al. (1993b). Briefly, it did not cross-react with arginine-vasopressin and lysine-vasopressin but presented 40% cross-reactivity with isotocin in ELISA. As regards the molecule of oxytocin (OT), it was only directed against its C-terminal fragment (Pro-Leu-Gly-amide, PLGa): 80.7% cross-reactivity with PLGa, 30% with the dipeptide Pro-Leu and 20% with the dipeptide Pro-Ile in competitive ELISA, and 78.8% cross-reactivity with PLGa in radioimmunoassay. It did not recognize the N-terminal fragment (tocinoic acid) of OT: 0.06% cross-reactivity with tocinoic acid in competitive ELISA and in radioimmunoassay.

Immunoassays

DIA and ELISAs based on the protocols of Salzet et al. (1992, 1993a) were used to follow the OT-like activity during the purification procedures. Quantification of the OT-like peptide in CNS extracts was done in direct ELISA. As control, preadsorption of a-OT was carried out using homologous peptide at a concentration of 100 µg/ml undiluted a-OT.

Purification of the OT-like Peptide

A four-step procedure was used for this purification.

Step I: Sep-Pak Prepurification

4000 CNS were needed. Batches of 400 CNS were homogenized at 4 °C in 400 µl of 1 M acetic acid and sonicated (30 s) twice. Homogenates were centrifuged at 12,000 rpm for 30 min at 4 °C. After reextraction of the pellet, the two supernatants were combined and loaded onto Sep-Pak C(18) cartridges (500 µl of extract/cartridge) for solid phase extraction. After washing the cartridges with 5 ml of 1 M acetic acid, elution was performed with 5 ml of 50% acetonitrile in acidified (0.1% trifluoroacetic acid, Pierce) water. The volume of the eluted fractions was reduced 20-fold in a vacuum centrifuge (Savant) to remove organic solvent and trifluoroacetic acid. The total amount of OT-like material was quantified using ELISA.

Step II: High Pressure Gel Permeation Chromatography (HPGPC)

The 50% elution fraction was taken up to 300 µl with deionized water and applied on a HPGPC column (Ultraspherogel, 7.5 times 300 mm, SEC 2000; Beckman) associated to a precolumn (Ultraspherogel, 7.5 times 40 mm; Beckman) and equilibrated with 30% acetonitrile. Elution was performed with 30% acetonitrile at a flow rate of 1 ml/min. The column effluent was monitored by absorbance at 226 nm, and the presence of OT-like material was detected in DIA and quantified using ELISA. Before being applied onto a C(18) HPLC column, biological activity on osmoregulation of the immunoreactive fractions was tested by injection in vivo to T. tessulatum.

Step III: Reversed-phase HPLC

The T. tessulatum active and immunoreactive fractions obtained after HPGPC were applied onto a C(18)-peptide protein column (250 times 4.6 mm; Vydac) associated to a RP(18) precolumn (Merck), equilibrated with acidified water (0.1% trifluoroacetic acid). Elution was performed with a discontinuous linear gradient of acetonitrile in acidified water from 0 to 45% in 30 min and from 45 to 80% in 10 min at a flow rate of 1 ml/min. The column effluent was monitored by absorbance at 226 nm and the presence of OT-like material was detected in DIA and quantified by ELISA.

The fractions containing the immunological material were further applied to the same column with a shallower gradient of acetonitrile in acidified water from 0 to 15% in 10 min and from 15 to 45% in 40 min at a flow rate of 1 ml/min. After a 20-fold concentration by freeze drying, fraction aliquots of 0.5 µl were tested using DIA.

Step IV: Final Purification

The OT-like material was finally purified to homogeneity on an ODS C(18) reversed-phase column (Ultrasphere, 250 mm times 2 mm, Beckman). The column was developed with a linear gradient of acetonitrile in acidified water from 0 to 60% in 60 min at a flow rate of 300 µl/min. The column effluent was monitored by absorbance at 226 nm and the immunoreactive material detected as above.

All HPLC purifications were performed with a Beckman Gold HPLC system equipped with a photodiode array detector Beckman 168.

Amino Acid Sequence Analysis

Automated Edman degradation of the purified peptide and detection of phenyl-thiohydantoin amino acids derivatives were performed on a pulse-liquid automatic sequenator (Applied Biosystems, model 473A).

Electrospray Mass Spectrometry

The purified peptide was dissolved in water/methanol (50/50, v/v) containing 1% acetic acid and analyzed on a VG Biotech BioQ mass spectrometer (Manchester, United Kingdom) and treated according to Salzet et al.(1995).

Biological Assay

The bioassay was conducted on T. tessulatum, rhynchobdellid leeches bred in the laboratory (Malecha, 1989b). Leeches at stage 3B, stage which corresponds to an important water retention phasis according to Malecha et al. (1989a), were distributed in lots of 20 animals having an identical mean body mass before being injected subepidermally (10 µl of solution/leech).

Experiment 1

Leeches received an aqueous solution of each immunoreactive fraction to a-OT eluted from the HPGPC column. Controls received deionized water.

Experiments 2 and 3

Leeches received an aqueous solution of either synthetic peptide (1 pmol; Neosystem) corresponding to the isolated LORF from E. octoculata or purified peptide (1 pmol), or either synthetic LORF at four different doses (1-100 fmol, 1-100 pmol, and 1 nmol). Controls received deionized water.

All injected animals were kept at room temperature. To estimate the effect of an injection, leeches blotted on tissue paper were weighed to the nearest 0.1 mg at various time intervals following the injection (1, 2, 4, and 6 h). The change in body mass of the animals between the beginning of the experiment and the time of weighing was registered. Responses were expressed as percentages of mass variation (means ± S.D.). The efficiency of the product was determined by its capacity to elicit a variation of mass significantly different from that registered in controls.

Statistical analysis of data was done according to Salzet et al. (1993a). The confidence limit of the relative mean variation of mass was obtained according to Cochran(1977).

Electrophysiological Experiments: Ussing Chamber Experiments

The methods and materials were similar to those used and described in detail in a previous study (Weber et al., 1995).

Immunocytochemistry

A polyclonal antiserum raised against synthetic LORF used in immunocytochemistry was generated in a rabbit using synthetic LORF coupled to human serum albumin via glutaraldehyde. Parts of E. octoculata taken at the level of the nerve cord and brain were fixed overnight at 4 °C in Bouin-Hollande fixative (+10% HgCl(2) saturated solution), they were then embedded in paraffin and serially sectioned at 7 µm. After removal of paraffin with toluene, the sections were successively treated with the primary antibody (a-LORF) diluted 1:200 and with goat anti-rabbit IgG conjugated to horseradish peroxidase as described elsewhere (Verger-Bocquet et al., 1992).

The specificity of the antiserum (a-LORF) was tested on consecutive sections mounted on different slides by preadsorbing this antiserum overnight at 4 °C with the homologous antigen at a concentration of 500 µg/ml pure antiserum.

OT-like Protein Identification

Protein Purifications

CNS in batches of 400 were homogenized at 4 °C in 400 µl of Tris-buffered saline (50 mM Tris-HCl, pH 7.4, 150 mM NaCl) supplemented with 2% EDTA and 1 mM phenylmethylsulfonyl fluoride and sonicated (30 s) twice. Each homogenate was centrifuged at 12,000 rpm for 30 min at 4 °C. The pellet was reextracted a second time, and the two supernatants were combined and subjected to a HPGPC on a SEC2000 (Ultraspherogel, 7.5 mm times 300 mm, Beckman) column and eluted with 30% acetonitrile at a flow rate of 300 µl/min. The effluent was monitored at 215 nm. Eluted fractions were concentrated 5-fold by freeze-drying and tested by ELISA. Positive fractions were then subjected to electrophoresis and Western blot analysis.

In Vitro Translated Products of Central Nervous System RNA Extracts

CNS in batches of 400 were subjected to a total RNA extraction by the guanidium isothiocyanate method (Sambrook et al., 1989). 20 µl of a solution of total RNA (30 µg) were then subjected to a translation in a mixture containing 30 µl of rabbit reticulocyte lysate (Amersham Corp.) for 1 h at 30 °C. Translation was stopped on ice. The translated products were subjected to a HPGPC as described above, and the immunoreactive fractions to a-OT were then subjected to a Western blot analysis.

Western Blot Analysis

SDS-polyacrylamide gels were prepared according to Laemmli (1970) except that the separating gel consisted of a 10-25% polyacrylamide gradient slab gel. The sample buffer contained beta-mercaptoethanol or not. After electrophoresis, proteins were transferred to a polyvinylidene difluoride membrane (Immobilon P; Millipore) and reacted with a-OT as described previously (Salzet et al., 1995). Control of specificity was realized by preadsorbing a-OT overnight at 4 °C with synthetic homologous peptide (100 µg of OT (Sigma)/ml of undiluted antiserum).


RESULTS

OT-like Peptide Isolation

4000 CNS of E. octoculata were subjected to a peptide extraction in 1 M acetic acid at pH 2. ELISA revealed the presence in the crude extract of CNS of a quantity of OT-like material estimated at 8 ± 1.2 pmol/CNS. The crude extract was prepurified using Sep-Pak C(18) cartridges. The fraction eluted by 50% acetonitrile in water acidified by 0.1% trifluoroacetic acid was reduced 20-fold by freeze-drying and applied to a HPGPC. DIA results indicated that the OT-like substances eluted from the column in three zones with molecular mass less than 1 kDa for Z1, 1-4.5 kDa for Z2, and 5-10 kDa for Z3 (Fig. 1). Results obtained after using a-OT preadsorbed by synthetic OT established the specificity of the immunodetection. Quantification by ELISA at this step of purification indicated 0.6 ± 0.12 pmol of OT-like material/CNS for Z1, 2.05 ± 0.65 pmol of OT-like material/CNS for Z2, and 4.35 ± 1.12 pmol of OT-like material/CNS for Z3. Before separated in reversed-phase HPLC, peptides contained in Z1, Z2, and Z3 were injected in vivo to T. tessulatum (Fig. 2). Only fraction Z2, which has an anti-diuretic potential (Fig. 2), was applied to a C(18) reversed-phase HPLC column. A heterologous immunoreactive peak to a-OT (Fig. 3) eluted at a retention time of 25.1 min (corresponding to 37.6% acetonitrile). The immunoreactive peak containing the OT-like material was analyzed on the same column with a more resolutive gradient. A peak immunoreactive to a-OT, with a retention time of 27 min (corresponding to 32% acetonitrile), was resolved. At this step of purification, quantification by ELISA indicated an amount of 1.5 ± 0.75 pmol of OT-like material/CNS (recovery 33% of the starting material). This peak was then purified to homogeneity on an ODS C(18) reversed-phase column and gave a peptide at a retention time of 29.52 min (Fig. 4). Quantification by ELISA at this step of purification indicated 1.05 ± 0.25 pmol of OT-like material/CNS (final recovery of 20%). The retention time of this peptide did not correspond to the ones found in this system for OT (native, 24.4 min; reduced, 21.3 min; oxidized, 24.7 min), OT fragments (tocinoic acid, 20.5 min; PLGa, 15.6 min), and peptides of the OT/VP family (arginine-vasopressin, 24.1 min; arginine-vasotocin, 23.7 min; lysine-vasopressin, 23.1 min; lysine-conopressin, 29 min; isotocin, 23.5 min).


Figure 1: HPGPC elution profile of a C(18) Sep-Pak prepurified extract of 1000 central nervous systems of E. octoculata. After solid phase extraction on Sep-Pak C(18) cartridges, the fraction eluted by 50% acetonitrile in acidified water (0.1% trifluoroacetic acid), containing the oxytocin-like material, was loaded onto a HPGPC (Ultraspherogel, 7.5 times 300 mm, SEC200, Beckman) column. Elution was performed with 30% acetonitrile at a elution rate of 1 ml/min. The oxytocin-like material was detected on aliquots of each fraction by the oxytocin-DIA. Bars indicate the immunoreactive material, and arrowheads, the eluted positions of molecular mass markers (a, hirudin; b, adrenocorticotropic hormone; c, angiotensin II; d, tryptophan).




Figure 2: Effect on the body mass of stage 3B T. tessulatum of the injection (10 µl/leech) of 1 pmol of purified oxytocin-like material from the immunoreactive zones (Z1, Z2 or Z3) detected after HPGPC separation. Controls received deionized water. The loss of mass was determined at different times (1, 2, 4, and 6 h) after injection. Results are expressed as means ± S.D. Data are from 20 injected animals, at each time point (experiment was performed 4 times). Groups with an asterisk differ significantly from controls (alpha = 0.05).




Figure 3: Reversed-phase HPLC separation of oxytocin-like material from the HPGPC column. The active and immunoreactive fraction eluted from HPGPC column was loaded onto a C(18)-peptide-protein column (250 mm times 4.6 mm; Vydac). Elution was performed with a discontinuous linear gradient of 0-45% acetonitrile in acidified water (0.1% trifluoroacetic acid) for 30 min, followed by a gradient of 45-80% acetonitrile in acidified water (0.1% trifluoroacetic acid) for 10 min at a flow rate of 1 ml/min. The oxytocin-like material was detected on aliquots of each fraction by DIA. The bar indicates the immunoreactive material.




Figure 4: Final purification of the oxytocin-like peptide. After three successive reversed-phase HPLC steps, the oxytocin-like peptide was purified to homogeneity on a C(18)reversed-phase column (250 mm times 2 mm; Beckman). Elution was performed with a linear gradient of 0-60% acetonitrile in acidified water (0.1% trifluoroacetic acid) for 60 min at a flow rate of 0.3 ml/min. The asterisk indicates the peak containing the purified oxytocin-like peptide, which was subjected to an automated Edman degradation.



OT-like Peptide Characterization

After the final purification step, a fraction aliquot of the immunoreactive purified material was submitted to Edman degradation. The sequence, established on 43.33 pmol of purified OT-like peptide with a sequencing yield of 91.5%, was Ile-Pro-Glu-Pro-Tyr-Val-Trp-Asp (Table 1). Measurement of the molecular mass of the OT-like peptide by electrospray mass spectrometry gave an m/z of 1018.29 ± 0.68 Da, which was in good agreement with monoisotopic molecular mass (1018.6 Da) calculated from the amino acid sequence determined by Edman degradation. The primary structure (IPEPYVWD) of the E. octoculata OT-like peptide has no sequence similarity with peptides of the OT/VP family.



Biological Activity of the Leech OT-like Peptide

In Vivo Experiments

Comparative analyses of repercussion on the leech mass variation after injection of OT-like peptides were performed ( Fig. 5and Fig. 6). Injection of either synthetic or purified OT-like peptide at a same concentration of 1 pmol shown a very close response (Fig. 5). The two peptides exert, compared to controls, an anti-diuretic effect when injected to T. tessulatum (Fig. 5). Moreover, dose-response experiments with synthetic LORF indicated compared to controls, and in contrast to the lowest doses assayed (1-100 fmol), that the highest doses assayed (1-100 pmol and 1 nmol) were found to be effective in injected leeches. The optimal doses were 100 pmol and 1 nmol, which provoked an increase in mass in injected leeches 1, 2, and 4 h post-injection, reflecting an uptake of water (Fig. 6).


Figure 5: Effect of the injection (10 µl/leech) of synthetic (1 pmol) or of purified (1 pmol) LORF on the body mass of the leech T. tessulatum at stage 3B. Controls received deionized water. The loss of mass was determined at different times (2, 4, 6, and 8 h) after injection. Results are expressed as means ± S.D. Data are from 40 injected animals at each time point (experiment was performed four times). Groups with an asterisk differ significantly from controls (alpha = 0.05).




Figure 6: Effect of the injection of synthetic LORF (10 µl/leech) at different concentrations (1-100 fmol, 1-100 pmol, and 1 nmol) on the body mass of the leech T. tessulatum at stage 3B. Controls received deionized water. The loss of mass was determined at different times (1, 2, and 4 h) after injection. Results are expressed as means ± S.D. Data are from 40 injected animals at each time point (experiment was performed four times). Groups with an asterisk differ significantly from controls (alpha = 0.05).



Electrophysiological Experiments

Pieces of the dorsal integument of the medicinal leech Hirudo medicinalis could be maintained in modified Ussing chambers under stable conditions for several hours. After an equilibration period of about 30 min, the electrical parameters reached a stable phase for at least 4-5 h. With a transepithelial resistance of about 1 k, leech skin belongs to the class of tight epithelia. After the equilibration period all preparations were routinely tested for amiloride inhibition. When amiloride (100 µM) was added to the apical side of the short-circuited skin, I began to drop instantaneously because amiloride-sensitive Na channels are the main pathway for ionic transport across leech skin (Weber et al., 1993). The short circuit current showed a further decrease when after amiloride application (100 µM) sodium was removed from the apical solution. Readdition of sodium resulted in a strong overshoot in short circuit due to activation of silent Na channels under Na-free conditions and their immediate down-regulation by increasing Na concentrations (Fig. 7).


Figure 7: Transepithelial Nacurrents measurement from the skin of leech Hirudo medicinalis. The tissue was clamped to zero with a low-noise voltage clamp. Transepithelial resistance was calculated from superimposed 10 mM-pulsed of 500 ms duration according to Ohm's law. Amiloride or oxytocin-like peptide was applied to the serosal solution.



Shortly after serosal application of oxytocin-like peptide (5 µM), I decreased by 18.15 ± 0.94% (n = 3). 28.19 ± 2.74% of the amiloride-sensitive portion of the short circuit was inhibited by oxytocin-like peptide, and 34.8 ± 9.5% of the whole Na-mediated currents were blocked.

Immunocytochemical Study

Large amounts of neurons immunoreactive to an antiserum against a-LORF were detected at the level of the segmental ganglia of the nerve cord (Fig. 8b). Preadsorption of a-LORF with the homologous antigen abolished the staining capacity of the antiserum, reflecting the specificity of the immunodetection (Fig. 8, a and c). Among the LORF neurons, several are also immunoreactive to a-OT (data not shown), confirming the previous results obtained at the level of the supernumerary neurons of sex segmental ganglia (Salzet et al., 1993c).


Figure 8: Frontal section through segmental ganglia of the nerve cord of E. octoculata, treated with anti-LORF preadsorbed (a and c) or not (b) with the homologous antigen (indirect immunoperoxidase). Preadsorption of the antiserum with LORF abolished the immunostaining. Bars = 50 µm.



Identification of Proteins Immunoreactive to a-OT

Identification in CNS Extracts

Extracts of CNS with Tris-buffered saline were fractionated on HPGPC. The collected fractions were assayed with a-OT (Fig. 9). Two specific immunoreactive zones (Za and Zb), corresponding to proteins with a molecular mass ranging from 20 to 45 kDa for Za and to peptides with a molecular mass less than 10 kDa for Zb, were observed. Peptides contained in Zb corresponded to immunoreactive material present in Z1, Z2, and Z3, previously detected in the acidic extraction method. Proteins contained in Za were further subjected to Western blot analysis with a-OT. After SDS-PAGE in reducing conditions, a single immunoreactive band was detected at 17 kDa (Fig. 9A). In contrast, in non-reducing conditions, an immunoreactive band at 34 kDa was detected (Fig. 9B), indicating that the OT-like protein extract from CNS is an homodimer protein with a molecular mass of 17 kDa.


Figure 9: HPGPC elution profile of a protein extract of 400 central nervous systems from E. octoculata. Elution rate: 0.3 ml/min. Arrows indicate eluted positions of standards in identical conditions of column and elution (a, trypsin inhibitor (20 kDa); b, alpha-lactalbumin (14.4 kDa); c, hirudin (7 kDa); d, oxytocin (1 kDa)). Zones immunoreactive to a-OT are denoted by a bar (Za and Zb). Inset, photographs represent Western blot analyses with a-OT of proteins contained in Za after SDS-PAGE in nonreducing (A) and reducing (B) conditions. Small arrows indicate position of proteins immunoreactive to a-OT; arrowheads on left of the immunoblot indicate molecular mass standards.



Identification in CNS RNA-translated Products

After extraction of total RNA and transcription in rabbit reticulocyte lysate, translated proteins were treated in the same way as the proteins extracts from CNS. After HPGPC, a single immunoreactive zone (Zc) corresponding to proteins with molecular masses of 10-25 kDa was detected (Fig. 10). The proteins contained in Zc were further subjected to a Western blot analysis with a-OT in reducing conditions. A protein with a molecular mass of 19 kDa was detected (Fig. 10), slightly larger than the one detected in reducing conditions (17 kDa) in CNS extracts (Fig. 9B).


Figure 10: HPGPC elution profile of translated total RNA extracted from 400 central nervous systems from E. octoculata. Elution rate: 0.3 ml/min. Arrows indicate eluted positions of standards in identical conditions of column and elution (a, trypsin inhibitor (20 kDa); b, alpha-lactalbumin (14.4 kDa); c, hirudin (7 kDa); d, oxytocin (1 kDa)). Zone immunoreactive to a-OT is denoted by a bar (Zc). Inset, photograph represents a Western blot analysis with a-OT of proteins contained in Zc after SDS-PAGE in reducing conditions. Small arrows indicate position of proteins immunoreactive to a-OT. Arrowheads on left of the immunoblot indicate molecular mass standards.




DISCUSSION

After reversed-phase HPLC purification, the sequence of an OT-like peptide (IPEPYVWD) was established by a combination of automated Edman degradation and electrospray mass spectrometry measurement. Our data revealed that the 8-residue peptide present in the CNS of the leech E. octoculata is a novel neuropeptide, structurally different from peptides of the OT/VP family. This result constitutes the first report of such a peptide in the animal kingdom.

The isolation of this peptide with an antiserum against OT could be explained by the antiserum used. It was directed against the C-terminal part of OT (PLG-amide) and more precisely against dipeptides PL (30%) or PI (20%). PI is present in the purified OT-like peptide (IPEPYVWD) at the level of the N-terminal sequence. Similar results were also obtained in the mollusk Lymnaea stagnalis with an anti-lysine-vasopressin antiserum. The lysine-vasopressin antiserum directed against the sequence PKG-amide recognized the SKPFLRF-amide, peptide of the RF-amide family (De With et al., 1993). Although these results led us to think that the peptide isolated from E. octoculata CNS is not really an OT-like peptide, three lines of evidence established our results.

The use of another a-OT characterized by Tramu et al. (1983), which recognized both the N-terminal and the C-terminal parts of OT, gave identical results (data not shown). Moreover, from preliminary experiments conducted on the biological activity of the purified peptide from E. octoculata, it appears that this purified peptide is involved in the control of the hydric balance. Injection of 10 pmol, 100 pmol, or 1 nmol of synthetic OT-like peptide provoked an uptake of water in injected T. tessulatum. Furthermore, electrophysiological experiments conducted in H. medicinalis establish the inhibition of potency sodium conductance of leech skin by the OT-like peptide. Leech skin has proven to be a valuable model for the study of ion transport in invertebrate tight epithelia (Weber et al., 1993, 1995). It is known that Na transport in leech skin can be modulated by the second messenger cAMP via an increase in the number of Na channels. However, in leech skin oxytocin-like peptide failed to activate the cAMP second messenger system, as could be seen by a decreasing effect on transepithelial short circuit current. Oxytocin-like peptide inhibited the currents through amiloride-sensitive or amiloride-insensitive Na conductances. At present, it remains unclear by which mechanism oxytocin-like peptide enroles its inhibiting potency on Na conductances of leech skin. Two mechanisms seem to be possible: 1) a direct action of the peptide on the channel protein from the outside of the cell, or 2) coupling of oxytocin-like peptide to a membrane bound receptor and subsequent signal transduction to the inside of the cell, followed by a regulation of Na channels from within the cell. Finally, immunocytochemical studies performed with an antiserum raised against synthetic oxytocin-like peptide indicated a high specific immunostaining of neurons in segmental ganglia of the nerve cord. For all these reasons, the purified oxytocin-like peptide was named the leech osmoregulator factor (LORF).

The LORF sequence (IPEPYVWD) is included within the N-terminal part of a respiratory pigment, the myohemerythrin (protein of 14 kDa) of the sipunculid Themiste zostericola (Klippenstein et al., 1976): GWDIPEPYVWDESFRV . . . It also presents 77% sequence homology with a fragment of the N-terminal part of a yolk protein (14 kDa), the ovohemerythrin of the leech T. tessulatum: YDIPEPFRWDESF . . . (Baert et al., 1992). Several hypotheses can be advanced for these data. 1) LORF is a novel neuropeptide; 2) it is a contaminant from hemerythrin present in blood and clomic fluid. However, several findings argue in favor of the first hypothesis, i.e. LORF is a novel neuropeptide. First, immunocytochemical studies performed with an antiserum against synthetic LORF revealed neurons immunoreactive to a-LORF in the nerve cord. Moreover, some of these neurons reached projections in direction to neurohemal area, indicating a neurohormonal role (Hagadorn, 1958; Orchard and Webb, 1980) of LORF. Moreover, most of supernumerary neurons of the sex segmental ganglia that were immunoreactive to a-OT (Salzet et al., 1993c) are also immunoreactive to a-LORF. Second, a-LORF and a-OT did not recognize the ovohemerythrin in Western blot or in ELISA and a-ovohemerythrin, the LORF. Third, LORF is active on osmoregulation of leeches. Our experiments, conducted at the protein level with CNS extracts or RNA-translated products, indicated that the OT-like precursor is a homodimer protein of 17 kDa in CNS extract and a protein of 19 kDa in translated RNA. These proteins were not recognized with a-(MSEL and VLDV)-neurophysin, associated proteins in the case of OT or VP (Acher et al., 1985), confirming that LORF is not a peptide of this family. No recognition of these proteins by a-RF-amide was found, although these molecules are colocalized with LORF in supernumerary neurons of sex SG (Salzet et al., 1993c). Fourth, molecular mass of ovohemerythrin (14. 4 kDa) is different to OT-like proteins.

According to its localization in sex segmental ganglia of the nerve cord, it could be postulated that this peptide could also act on reproduction. Selective ablations of either sex segmental ganglia or cerebroïde ganglia of T. tessulatum at stage 3A, stage just before water retention phasis, indicated that only the lack of cerebroïde ganglia blocks the water phasis retention and oogenesis. LORF could exert different biological activities in function of its localization in T. tessulatum CNS. However, further experimental testing are needed to conclude.

The whole of our results establish that LORF is a novel neuropeptide, never previously isolated in the animal kingdom. Further experimental testing with a-LORF would be performed either in other phyla of invertebrates or in vertebrates, in order to investigate the presence of this neuropeptide in course of evolution.


FOOTNOTES

*
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed. Tel.: 33-2043-4054; Fax: 33-2043-4054.

(^1)
The abbreviations used are: CNS, central nervous system; HPLC, high pressure liquid chromatography; DIA, dot immunobinding assay; ELISA, enzyme-linked immunosorbent assay; HPGPC, high performance gel permeation chromatography; PLGa, Pro-Leu-glycinamide; OT, oxytocin; a-OT, anti-oxytocin; LORF, leech osmoregulator factor; VP, vasopressin; PAGE, polyacrylamide gel electrophoresis; SG, segmental ganglia.


ACKNOWLEDGEMENTS

We are indebted to Dr. A. Van Dorsselaer, (Laboratoire de Spectrométrie de Masse bioorganique, UA 31 CNRS, Strasbourg, France), for the mass spectrometry determination. We appreciate the technical assistance of A. Desmons and N. Thesse.


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