Peptidergic innervation of the vasoconstrictor muscle of the abdominal aorta in Aplysia kurodai

doi:10.1242/jeb.01273

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):

Home Help Feedback Subscriptions Archive Search Table of Contents

First published online November 19, 2004
Journal of Experimental Biology 207, 4439-4450 (2004)
Published by The Company of Biologists 2004
doi: 10.1242/jeb.01273

This Article

Summary

Full Text

Full Text (PDF)

Alert me when this article is cited

Alert me if a correction is posted

Services

Email this article to a friend

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via Google Scholar

Google Scholar

Articles by Sasaki, K.

Articles by Furukawa, Y.

Search for Related Content

PubMed

PubMed Citation

Articles by Sasaki, K.

Articles by Furukawa, Y.

Peptidergic innervation of the vasoconstrictor muscle of the abdominal aorta in Aplysia kurodai

Kosei Sasaki, Fumihiro Morishita and Yasuo Furukawa^*

Department of Biological Science, Graduate School of Science, Hiroshima University, Kagamiyama 1-3-1, Higashi-Hiroshima 739-8526, Japan

View larger version (76K):

[in a new window]

Fig. 1. Innervation pattern of the vasoconstrictor muscle viewed by immunohistochemistry. (Ai) AMRP-immunoreactivity in the vicinity of the abdominal ganglion and three major arteries. The preparation is placed ventral side up except for the abdominal ganglion (the ganglion is rotated 180° to see the dorsal surface). The abdominal aorta is mainly innervated by the branches of the pericardial and spermathecal nerves (see Aii). Scale bar is 2 mm. Inset shows a higher magnification of a part of the abdominal aorta including the vasoconstrictor muscle. Note the extensive ramification of the immunopositive fibers. Scale bar in the inset is 1 mm. (Aii) Diagram of the preparation shown in Ai. AA, anterior aorta; AbA, abdominal aorta; AbG, abdominal ganglion; GA, gastroesophageal artery; Pn, pericardial nerve; Spn, spermathecal nerve; Vm, a region containing the vasoconstrictor muscle. (B) Immunopositive fibers and varicosities in the vasoconstrictor muscle. Scale bars in all figures are 100 µm. (Bi) AMRP-immunoreactivity. (Bii) Enterin-immunoreactivity. (Biii) NdWFamide-immunoreactivity.

View larger version (31K):

[in a new window]

Fig. 2. ENpa and GSPRFFamide depress the contraction of the vasoconstrictor muscle evoked by the stimulation of the pericardial nerve. (A) Effects of 10^–7 mol l^–1 ENpa (Ai) and 10^–7 mol l^–1 GSPRFFamide (Aii) on the contraction evoked by a train of the electrical pulse (1 ms, 1.6 V, 10 Hz) for 1 s. The stimulus train was applied every 20 s. Peptides were applied for 2 min as indicated by bars. Ai and Aii are from the same preparation. (B) Concentration–response relationships of the effects of ENpa and GSPRFFamide. Amplitude of the most depressed contraction after the peptide application is normalized to that of the control contraction and the mean ± S.E. was plotted against the concentration of the peptides (N=3 $~$ 6). (C) Time-dependent effects of the peptide actions. Amplitude of the muscle contraction was normalized to the control contraction just before the peptide application and plotted against the time (N=3). 10^–5 mol l^–1 of ENpa or GSPRFFamide was applied for 2 min as indicated.

View larger version (24K):

[in a new window]

Fig. 3. NdWFamide enhances the nerve-evoked contractions of the vasoconstrictor muscle. (A) and (B) are from the different preparations. The contraction of the muscle was evoked by the nerve stimuli as described in Fig. 2. Duration of each stimulus train in A and B were 1 s and 0.4 s, respectively. Note a tonic contraction was also induced by NdWFamide at higher concentrations.

View larger version (32K):

[in a new window]

Fig. 12. Actions of the peptides on the vasoconstriction of the abdominal aorta. The vasoconstricion was monitored by an internal pressure change of the perfusion line as described in Materials and methods. Typical examples of the peptide actions (i) and the concentration–response relationships (ii) are shown. (A) Action of ENpa (N=4). (B) Action of GSPRFFamide (N=3). (C) Action of NdWFamide (N=3). The pressure change was evoked by stimulation of the pericardial nerve using the stimulus train (1 ms, 1.6 V, 10 Hz) for 0.9 s (A,B) or 0.5 s (C).

View larger version (22K):

[in a new window]

Fig. 4. Action of ENpa, GSPRFFamide or NdWFamide on the ACh-induced contraction of the vasoconstrictor muscle. (A) Blockade of the nerve-evoked contraction by 10^–3 mol l^–1 hexamethonium. Each contraction was evoked by the stimulus train (1 ms, 1.6 V, 10 Hz) for 0.5 s every 20 s. (B) Effect of ENpa (Bi), GSPRFFamide (Bii) or NdWFamide (Biii) on the ACh-induced contraction. The contraction was evoked by perfusion of 10^–6 mol l^–1 ACh for 40 s as indicated by bars. Peptide was applied between arrows.

View larger version (13K):

[in a new window]

Fig. 5. Comparison of the effects of the peptides on the nerve-evoked and the ACh-induced contractions. (A) 10^–7 mol l^–1 ENpa, (B) 10^–7 mol l^–1 GSPRFFamide, (C) 10^–8 mol l^–1 NdWFamide. Upper, middle and lower lines of the box plots show 75th percentile, median and 25th percentile, respectively. Upper and lower bars show the largest and smallest values. Numbers of preparations are shown in parentheses. Statistical significance was assessed either by Mann-Witney U-test (A,C) or Student's t-test (B).

View larger version (25K):

[in a new window]

Fig. 6. Single vasoconstrictor muscle fiber is innervated by several excitatory axons. (A) Relationships between stimulus intensities and EJPs. The pericardial nerve was stimulated by a 1 ms pulse of various intensities as indicated. Four records are superimposed. Fast vertical deflections are stimulus artifacts. Note that the increase in stimulus intensity not only changes the peak amplitude of EJP, but also the shape of EJP. (B) Effect of 10^–3 mol l^–1 hexamethonium on EJPs evoked by the stimulus train (1 ms, 1.6 V, 10 Hz) for 0.5 s.

View larger version (24K):

[in a new window]

Fig. 7. ENpa decreases the amplitude of EJPs. (A) Effects of 10^–7 mol l^–1 ENpa. EJPs were evoked by the stimulus train (1 ms, 1.6 V, 10 Hz) for 0.3 s every 20 s. Note ENpa also hyperpolarized the resting potential of the muscle fiber. (B) Comparison of EJPs before (a) and after (b) ENpa application. (C) Inhibitory action of ENpa on EJPs. Histogram shows mean ± S.E. of the maximum amplitude of summated EJPs before and after ENpa application (N=15). Statistical significance was assessed by Student's t-test.

View larger version (24K):

[in a new window]

Fig. 8. GSPRFFamide decreases the amplitude of EJPs. (A) Effects of 10^–7 mol l^–1 GSPRFFamide. EJPs were evoked by the stimulus train (1 ms, 1.6 V, 10 Hz) for 0.5 s every 20 s. (B) Comparison of EJPs before (a) and after (b) GSPRFFamide application. (C) Inhibitory action of GSPRFFamide on EJPs. Histogram shows mean ± S.E. of the maximum amplitude of summated EJPs before and after GSPRFFamide application (N=14). Statistical significance was assessed by Student's t-test.

View larger version (24K):

[in a new window]

Fig. 9. NdWFamide increases the amplitude of EJP. (A) Effects of 10^–8 mol l^–1 NdWFamide on EJP. Each EJP was evoked by a single nerve stimulation (1 ms, 1.6 V). (B) Comparison of EJPs before (a) and after (b) NdWFamide application. (C) Excitatory action of NdWFamide on EJPs. Histogram shows mean ± S.E. of the maximum amplitude of summated EJPs before and after NdWFamide application (N=9). Statistical significance was assessed by Student's t-test.

View larger version (21K):

[in a new window]

Fig. 10. 4-AP depresses the inhibitory actions of ENpa and GSPRFFamide on the nerve-evoked contraction. (A) Action of 10^–7 mol l^–1 ENpa on the contraction in the absence (Ai) or presence (Aii) of 10^–3 mol l^–1 4-AP. The contraction was evoked by the stimulus train (1 ms, 1.6 V, 10 Hz) for 0.4 s. (B) Inhibitory actions of 10^–7 mol l^–1 ENpa (Bi, N=5) and 10^–7 mol l^–1 GSPRFFamide (Bii, N=4) in the absence [(–)4-AP] or the presence [(+)4-AP] of 10^–3 mol l^–1 4-AP. Statistical significance was assessed by Student's t-test.

View larger version (19K):

[in a new window]

Fig. 11. 4-AP abolishes the inhibitory action of ENpa on the ACh-induced contraction. (A) Action of 10^–7 mol l^–1 ENpa on the contraction in the absence (Ai) or presence (Aii) of 10^–3 mol l^–1 4-AP. 3 x10^–6 mol l^–1 ACh was applied for 20 s at arrows. (B) Inhibitory action of ENpa in the absence [(–)4-AP] or the presence [(+)4-AP] of 10^–3 mol l^–1 4-AP (N=4). Statistical significance was assessed by Student's t-test.

View larger version (25K):

[in a new window]

Fig. 13. A model of the peptide actions on the excitatory transmission in the vasoconstrictor muscle. AMRP acts mainly on the presynaptic receptors to inhibit the excitatory transmitter release. Part of this inhibition is assumed to be due to the activation of the 4-AP sensitive K⁺ channels. Because 4-AP does not completely block the inhibitory action, other route to inhibit the transmitter release seems to exist. Enterin activates both pre and postsynaptic receptors. Activation of the postsynaptic receptors induces the opening of the 4-AP sensitive K⁺ channels, and inhibits the contraction. Because 4-AP does not completely inhibit the action of enterin, the presynaptic inhibitory receptors are also assumed. NdWFamide also activates both pre and postsynaptic receptors. Activation of the postsynaptic receptors evokes the muscle contraction, and that of the presynaptic receptors enhances the transmitter release.