Potent antagonistic action of synthetic analogues of APGWGNamide,an antagonist of molluscan neuropeptide APGWamide

Fifty-five kinds of analogues of APGWGNamide (Ala-Pro-Gly-Trp-Gly-Asn-NH2), which is an antagonist of molluscan neuropeptide APGWamide, were synthesized and their antagonistic activities were examined on two molluscan smooth muscles. Among all the analogues tested, on spontaneous contraction of the crop of the land snail, Euhadra congenita, APGWG(L-biphenylalanine, Bip)amide showed the most potent antagonistic activity and its potency was 50-100 times higher than that of APGWGNamide. Likewise, on phasic contraction of the anterior byssus retractor muscle (ABRM) of the sea mussel, Mytilus edulis, the effect of APGWG(D-homophenylalanine, dHfe) was the most potent and showed 5-10 times stronger activity than that of APGWGNamide. In the tolerance test to known exo- and endopeptidases or the crop tissue homogenate, APGWGNamide was not only easily degraded by a proline-specific endopeptidase but also by the homogenate. Two kinds of potent antagonists were thus developed: APGWG(Bip)amide and APGWG(dHfe)amide, which will be useful tools for investigation of the function of APGWamide in the snail and the mussel, respectively.     

Neurotransmitters and neuromodulators controlling the anterior byssus retractor muscle of Mytilus edulis.

1. The anterior byssus retractor muscle (ABRM) of Mytilus edulis is innervated by at least two kinds of nerves, excitatory and relaxing nerves. The principal neurotransmitters released from these nerves have been shown to be acetylcholine and serotonin, respectively. 2. Some other monoamines, such as dopamine and octopamine, and various peptides, such as FMRFamide-related peptides, Mytilus inhibitory peptides, SCP-related peptides and a catch-relaxing peptide, may also be involved in the regulation of the muscle as neurotransmitters or neuromodulators. 3. The ABRM seems to be typical of invertebrate muscles controlled by multiple neurotransmitters and neuromodulators.     

A variety of Mytilus inhibitory peptides in the ABRM of Mytilus edulis: isolation and characterization.

1. Five species of Mytilus inhibitory peptides, MIP1-5, were isolated from acetone extracts of the anterior byssus retractor muscle (ABRM) of Mytilus edulis. MIP1 and MIP2 were shown to be S2-MIP and A2-MIP, respectively, first isolated from the pedal ganglia of the animal. 2. All the five peptides had a common C-terminal structure of -Pro-Xaa-Phe-Val-NH2, which was shown to be important for their biological activity. 3. The five MIPs showed similar inhibitory effects on contractions of the ABRM but did not affect catch tension and its relaxation. 4. In addition to the MIPs, catch-relaxing peptide (CARP) was also found in the ABRM.     

Pharmacology of FMRFamide in Mytilus catch muscle

In the anterior byssus retractor muscle (ABRM) of Mytilus, low concentrations of FMRFamide (10(-8)-10(-7) M) relax ACh-induced catch-tension, whereas high concentrations (greater than 10(-7) M) cause contraction. To study the structure-activity relations of these actions, a number of peptide analogs of FMRFamide were screened for their biological activities on the ABRM. The structure-activity relations for contraction were different from those for relaxation. Among the peptides tested, FMR-[D-Phe]-amide and gamma 1-MSH substantially antagonized FMRFamide contractions; but only gamma 1-MSH was even slightly antagonistic to FMRFamide-induced relaxation. Relaxations produced by 10(-7) M FMRFamide, or by 10(-5) M FMRFamide-relating relaxing peptides, were markedly depressed by treating the muscle first with 10(-5) M FMRFamide or with 10(-5) M FMRFamide-related contractile peptides. However, contractile agents that are structurally unrelated to FMRFamide, such as 3 X 10(-5) M SCPB and 2 X 10(-2) M caffeine, showed little or no such after-effect on the relaxation. Relaxations in response to submaximal serotonin, dopamine and repetitive electrical pulses of stimulation were not affected by a pretreatment with 10(-5) M FMRFamide. These results suggest that the ABRM of Mytilus has at least two pharmacologically distinct classes of receptors which are capable of being activated by FMRFamide.     

Further identification of bioactive peptides in the anterior byssus retractor muscle of Mytilus: Two contractile and three inhibitory peptides

1. Two contractile and three inhibitory peptides were newly isolated from the anterior byssus retractor muscles (ABRMs) of the bivalve mollusc Mytilus edulis by using the muscle as the bioassay system.2. The structures of the two contractile peptides were GPFGTHIKamide (GPFG-8) and GPFGLNKHGamide (GPFG-9). The contractile response of the ABRM to the first-time application of GPFG-8 or GPFG-9 was of considerable size. The threshold concentrations of the peptides were around 10⁻⁹M. However, the contractile response to the second-time application was far smaller than that to the first-time application in both cases. Namely, the muscle showed tachyphylaxis to the peptides.3. Two of the three inhibitory peptides were members of the Mytilus-inhibitory-peptide (MIP) family. Their structures were RAPLFIamide (MIP₆) and RSPMFVamide (MIP₇). The peptides, as well as the other MIPs previously identified, showed a potent inhibitory effect on phasic contraction of the ABRM in response to repetitive electrical stimulation. The remaining one was an MIP-related peptide (MIP-RP) having the sequence of MRYFVamide. The MIP-RP was less potent than the two MIPs in inhibiting the contraction of the ABRM.     

Changes of nucleotide contents and of energy charge induced by contraction, catch and relaxation in smooth molluscan muscle fibres. An analysis using reversed-phase ion-pair high-performance liquid chromatography

1. The content of 14 different nucleotides, including cAMP, in isolated muscle fibres of the anterior byssus retractor muscle of Mytilus edulis was analysed. The nucleotide levels were determined after the muscle fibres performed phasic, tonic, or tetanic contractions and after serotonin-induced relaxation of tonic contraction. 2. Isolated resting muscle fibres revealed a lower energy charge than freshly-dissected ones. 3. During active force development adenosine energy charge decreased to stay at the same low level during catch, tetanus and serotonin-induced relaxation of catch respectively. 4. The energy charges of the guanosine, uridine and cytidine systems did not show changes parallel to the adenosine system. 5. The levels of cyclic AMP were only changed under the influence of serotonin.     

ACh and 5-HT induced changes in the concentration of cytosolic inositol trisphosphate (InsP3) and inositol bisphosphate (InsP2) in the ABRM of Mytilus edulis L.

1. For determination of the phosphoinositides and inositol phosphates present in anterior byssus retractor muscle (ABRM) of Mytilus edulis fiber bundles of this muscle were incubated with [3H]-inositol. Close-to-equilibrium labelling was achieved after 14-17 hr of incubation. 2. The phosphoinositides formed during incubation were identified as phosphatidylinositolphosphates by thin layer chromatography and as glycerophosphoryl esters by anion-exchange chromatography after deacylation. Besides PtdIns, PtdInsP and PtdInsP2 two labelled products are formed, which could not be identified. 3. Inositol phosphates were separated by anion-exchange chromatography. InsP, InsP2 and InsP3 are present, while InsP4 seemed to be absent. 4. Incubation of pre-labelled fibers with ACh induces the accumulation of InsP3 and InsP2 immediately. While 5-Ht accomplishes the accumulation after a lag time of 25 sec. The concentration of cytosolic InsP does not change.     

Carbachol and KCl-induced changes in intracellular free calcium concentration in isolated, fura-2 loaded smooth-muscle cells from the anterior byssus retractor muscle of Mytilus edulis

Intracellular free calcium concentration [( Ca2+]1) was measured in suspensions of fura-2 loaded smooth-muscle cells isolated from the anterior byssus retractor muscle of Mytilus edulis. Successive application of 5mM carbachol (CCh) and 100mM KCl to the cells transiently elevated [Ca2+]1 from the resting value of 124 +/- 4.5nM (mean +/- S.E., n = 14) to 295 +/- 15.3 and 383 +/- 20.5 nM, respectively. The response to CCh was concentration-dependent with an ED50 of 10(-5) M. Under the microscope, 67 +/- 3.0 and 83 +/- 1.3 % of fura-2 loaded cells contracted on the addition of 5mM CCh and 100mM KCl, respectively. In Ca2+ -free sea water, the CCh induced change in [Ca2+]1 was partially suppressed whereas that induced by KCl was completely abolished, suggesting an agonist-evoked release of stored Ca2+.     

Tonic contraction and the control of relaxation in a chemically skinned molluscan smooth muscle

The same functional states that characterize the living anterior byssus retractor muscle (ABRM) from Mytilus edulis can be initiated in the saponin-treated (chemically skinned) muscle preparation under controlled biochemical conditions. A tonic contraction was induced if the concentration of free Ca2+ was above approximately 10(7) M in the presence of Mg2+ and ATP. Maximum tension development was achieved at a Ca2+ concentration of approximately 10(4) M. Within these Ca2+ concentrations tension was always associated with the presence of 'active state," as indicated by a high recovery of tension after a quick release in muscle length. Tonic tension, and the associated active state was maintained for hours during these conditions irrespective of variations in both ionic strength and pH. Reduction of the Ca2+ concentration to below threshold for tension initiation during a tonic contraction immediately switched off the active state and relaxation of the muscle preparation resulted. However, the rate of relaxation was extremely low, leaving a substantial fraction of tension in the absence of active state. Both 5-hydroxytryptamine (5-HT) and cAMP accelerated this slow relaxation in the absence of Ca2+. Thus, this state was considered equivalent to the 'catch state" in the living ABRM. In the presence of Ca2+ concentrations above 10(7) M, cAMP did not affect either the maximum tension developed or the Ca2+ sensitivity of the chemically skinned muscle preparation.     

A variety of Mytilus inhibitory peptides in the abrm of Mytilus edulis: Isolation and characterization

1. Five species of Mytilus inhibitory peptides, MIP_1–5, were isolated from acetone extracts of the anterior byssus retractor muscle (ABRM) of Mytilus edulis. MIP₁ and MIP₂ were shown to be S²-MIP and A²-MIP, respectively, first isolated from the pedal ganglia of the animal.2. All the five peptides had a common C-terminal structure of -Pro-Xaa-Phe-Val-NH₂, which was shown to be important for their biological activity.3. The five MIPs showed similar inhibitory effects on contractions of the ABRM but did not affect catch tension and its relaxation.4. In addition to the MIPs, catch-relaxing peptide (CARP) was also found in the ABRM.     

Sudden increase in speed of an actin filament moving on myosin cross-bridges of "mismatched" polarity observed when its leading end begins to interact with cross-bridges of "matched" polarity.

Under in vitro movement assay conditions, actin filaments move about 10 times faster toward, than away from, the center of large bipolar thick filaments of molluscan smooth muscle. Using thick filaments isolated from the anterior byssus retractor muscle of Mytilus edulis, the two speed modes of movement were studied in detail. Some thick filaments crossed over each other on the surface of the assay chamber, allowing actin filaments that moved into the crossover region to transfer to other thick filaments. When an actin filament that had been moving in the low speed mode crossed over to another thick filament and the speed changed to fast, the entire actin filament started to move in the high speed mode at the moment of transfer of its leading end, leaving the trailing part still in contact with the original thick filament. This indicates that myosin cross-bridges interacting in the slow mode do not impose a significant load on the cross-bridges interacting in the fast mode. Assuming the theoretical model of Tawada and Sekimoto [Biophys. J. 59, 343-356 (1991)], we suggest that the magnitude of force developed, as well as the speed of unloaded movement, differs greatly, depending on the orientation of the myosin cross-bridges.     

31P-nuclear-magnetic-resonance study of muscles from Mytilus edulis

Phosphorus-31 nuclear magnetic resonance (NMR) spectra were recorded from freshly excised and resting anterior byssus retractor muscles of the mussel Mytilus edulis. The absolute concentrations of phosphometabolites measured by NMR compare well with the values obtained by a biochemical method. Quantitative measurements were achieved in several minutes by applying to the observed NMR signals a correction taking the saturation effects into account. The time evolution of the phosphometabolite concentrations reveals that the hydrolysis of phosphoarginine is a first-order reaction producing inorganic phosphate, whilst the adenosine triphosphate level remains constant for more than 10 h. The phosphoarginine hydrolysis rate varies as a function of the season and reaches a maximum during the reproduction period of the mussel. This increase in phosphoarginine consumption could be bound up with the higher excitability of the muscles during spring. The activation energy of the phosphoarginine hydrolysis reaction also depends on the season and the difference between the value determined in winter and that measured in spring is explained by a modification of the mode of action or of the proportions of the enzymes involved in the muscular metabolism.     

Elastic properties of isolated thick filaments measured by nanofabricated cantilevers.

Using newly developed nanofabricated cantilever force transducers, we have measured the mechanical properties of isolated thick filaments from the anterior byssus retractor muscle of the blue mussel Mytilus edulis and the telson levator muscle of the horseshoe crab Limulus polyphemus. The single thick filament specimen was suspended between the tip of a flexible cantilever and the tip of a stiff reference beam. Axial stress was placed on the filament, which bent the flexible cantilever. Cantilever tips were microscopically imaged onto a photodiode array to extract tip positions, which could be converted into force by using the cantilever stiffness value. Length changes up to 23% initial length (Mytilus) and 66% initial length (Limulus) were fully reversible and took place within the physiological force range. When stretch exceeded two to three times initial length (Mytilus) or five to six times initial length (Limulus), at forces approximately 18 nN and approximately 7 nN, respectively, the filaments broke. Appreciable and reversible strain within the physiological force range implies that thick-filament length changes could play a significant physiological role, at least in invertebrate muscles.     

HS-142-1, a novel antagonist for natriuretic peptides,has no effect on the third member of membrane bound guanylate cyclases (GC-C) in T84 cells

HS-142-1, a novel non-peptide antagonist for natriuretic peptide, exerts antagonistic actions almost equally on two similar guanylate cyclase-linked natriuretic peptide receptors (GC-A and GC-B), but has little or no effect on the binding of natriuretic peptides to a membrane protein, the so-called “clearance receptor”, which binds all natriuretic peptides. The third mammalian form of membrane bound guanylate cyclases (GC-C) was identified not as a natriuretic peptide receptor, but as a receptor for heat-stable enterotoxins (STa). In this study, we examined effects of HS-142-1 on GC-C (STaR) in T84 cells and showed that HS-142-1 exerts neither agonistic nor antagonistic activity for GC-C, indicating that HS-142-1 is not a common antagonist for a family of membrane bound guanylate cyclase receptors, but a specific antagonist for the guanylate cyclase-linked natriuretic peptide receptors.     

Stepwise length changes in single invertebrate thick filaments

Previous experiments on thick filaments of the anterior byssus retractor muscle of Mytilus and the telson-levator muscle of Limulus polyphemus have shown large, reversible length changes up to 23% and 66% of initial length, respectively, within the physiological tension range. Using nanofabricated cantilevers and newly developed high-resolution detection methods, we investigated the dynamics of isolated Mytilus anterior byssus retractor muscle thick filaments. Single thick filaments were suspended between the tips of two microbeams oriented perpendicular to the filament axis: a deflectable cantilever and a stationary beam. Axial stress was applied by translating the base of the deflectable nanolever away from the stationary beam, which bent the nanolever. Tips of flexible nanolevers and stationary beam were imaged onto a photodiode array to track their positions. Filament shortening and lengthening traces, obtained immediately after the motor had imposed stress on the filament, showed steps and pauses. Step sizes were 2.7 nm and integer multiples thereof. Steps of this same size paradigm have been seen both during contraction of single sarcomeres and during active interaction between single isolated actin and myosin filaments, raising the question whether all of these phenomena might be related.     

Stretch induced tension rise in a molluscan smooth muscle skinned by freeze drying

Summary The anterior byssus retractor muscle (ABRM) ofMytilus edulis was skinned by freeze drying. Tension transients in response to quick length steps were recorded during isometric contraction induced in ATP salt solution containing 2×10^–6 M Ca²⁺. These transients consisted of four phases similar to those described by Huxley (1974) in skeletal muscle. Under certain conditions (stretch amplitude not larger than 0.6% L_O), and in particular in the presence of cyclic AMP, we observed a delayed tension rise following a quick stretch (stretch activation) which appears to be similar to the stretch activation of insect flight muscle (Jewell and Rüegg 1966).     

An X-Ray Diffraction Study of Contracting Molluscan Smooth Muscle

The living anterior byssus retractor muscle of Mytilus (ABRM), a smooth, “catch” muscle, has been studied by X-ray diffraction while relaxed and while tonically contracted. X-ray reflections were observed from the actin and paramyosin filaments and from the α-helical substructure of the paramyosin filaments. No differences in spacings or relative intensities were observed when the relaxed and contracting muscle patterns were compared. This result is consistent with a sliding filament mechanism involving an interaction between actin and paramyosin filaments.     

The relaxation induced by indole and nonindole 5-HT agonists in the molluscan smooth muscle

1. The abilities of two indole agonists and some nonindole agonists to induce relaxation of catch contraction and the influence of the agonists on cyclic AMP (cAMP) levels in the anterior byssus retractor muscle (ABRM) of Mytilus were investigated. 2. 5-MeOT (5-methoxytryptamine) and 5-MeODMT (5-methoxy-N,N-dimethyltryptamine) dose-dependently relaxed the contraction. 3. TFMPP (m-trifluoromethylphenyl piperazine), PAPP (p-amino-phenyl TFMPP) and mCPP (1-(3-chlorophenyl)piperazine dose-dependently relaxed the contraction, but 2MPP (1-(2-methylphenyl) piperazine and quipazine did not. 4. 5-MeOT (10(-6)M), 5-MeODMT (10(-6)M), TFMPP (10(-4)M), 2MPP (10(-4)M), quipazine (10(-4)M) and 8-OH-DPAT (3 x 10(-5) M) significantly reduced the cAMP levels, but PAPP (3 x 10(-4)M) and mCPP (10(-4)M) did not have any effect on cAMP levels. 5. These findings indicate that the pharmacological properties of 5-HT1-like receptors in the ABRM are similar to those of 5-HT1A receptors in mammalian tissues, and that the changes in cAMP levels induced by the agonists used are unlikely to be directly linked to the relaxation induced by them.     

The molluscan neurosecretory peptide FMRFamide: comparative pharmacology and relationship to the enkephalins

The molluscan neuropeptide FMRFamide (Phe-Met-Arg-Phe-NH2) has diverse actions on excitable tissues of molluscs, including hearts, noncardiac muscles, complex organs, and neurons. The intracellular transducing mechanisms are also diverse and are not readily correlated with particular responses. FMRFamide increases cyclic AMP levels concomitant with both cardioexcitation and inhibition, but not with muscle contraction. In the same tissues, the effects of 5-hydroxytryptamine are dissimilar and are always accompanied by a cyclic AMP increase. FMRFamide and acetylcholine cause similar tonic contractions of the Busycon radula protractor muscle and identical catch contractures of the mytilid anterior byssus retractor muscle, but the ionic basis of excitation and the sources of activator calcium for contraction are not the same for the two agonists. A comparative study of structure-activity relations showed that FMRFamide receptors are heterogeneous. Helix aspersa ganglia contain no FMRFamide, but a close analog occurs and has been tentatively identified. Evidence supporting a proposed homology between FMRFamide-like and opioid peptides is summarized. The effects of the amphiactive heptapeptide Tyr-Gly-Gly-Phe-Met-Arg-Phe-NH2 on the venus clam rectum support this hypothesis.     

The relation between excitation-contraction coupling and fine structure of a molluscan muscle,the radular retractor of the whelk,Buccinum undatum

The Buccinum radula is of the rachiglossate type with two outer rows of fierce hook-like attack teeth and a medial row of straight sharp-pointed shredding teeth. Individual cells of the radular retractor muscle are 10–12 m in diameter and separated at the closest by gaps of only 40 nm, providing areas of potential electrical contact. The cell membranes are heavily invested with long finger-like invaginations, associated with sarcoplasmic reticular cisternae, and surface caveolae; the latter are associated with the numerous dense body membrane attachment plaques found in this muscle. The radular retractor muscle possesses a significant sarcoplasmic reticulum of peripheral cisternae and deeper vesicles associated with mitochondria. The surface caveolae may result from myofilament force exerted via attachment plaques at the cell membrane, while deeper invaginations may constitute a rudimentary transverse tubular system to relay surface depolarization to associated sarcoplasmic reticular cisternae inducing calcium release to effect excitation-contraction coupling. The radular retractor muscle possesses the usual thick paramyosin and thin actin myofilaments, the latter associated with dense bodies and attachment plaques presumably to transduce force to the cell membrane. The mitochondria are unusually large and packed into dense central clusters surrounded by large deposits of glycogen granules. The nerve endings on the radular retractor muscle fibres show four different types of transmitter vesicle, presumably related to the four kinds of agonist action in this muscle, cholinergic, serotonergic, peptidergic and purinergic. All nerve endings have mixed vesicle populations, clear evidence of co-transmission. In this muscle we see a modification of usual smooth muscle structure to effect fast sustained contractions, an ultrastructural configuration functionally designed for the muscle's central role in the feeding cycle.Abbreviations ABRM anterior byssus retractor muscle - EC coupling excitation-contraction coupling - RP radular protractor muscle - RR radular retractor muscle - SR sarcoplasmic reticulum - T-system transverse tubular system