the larval apical organ in the holothuroid chiridota gigas (apodida): inferences on evolution of the...

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The Larval Apical Organ in the Holothuroid Chiridota gigas (Apodida): Inferences on Evolution of the Ambulacrarian Larval Nervous System Author(s): Maria Byrne, Mary A. Sewell, Paulina Selvakumaraswamy and Thomas A. A. Prowse Source: Biological Bulletin, Vol. 211, No. 2 (Oct., 2006), pp. 95-100 Published by: Marine Biological Laboratory Stable URL: http://www.jstor.org/stable/4134584 . Accessed: 28/06/2014 08:25 Your use of the JSTOR archive indicates your acceptance of the Terms & Conditions of Use, available at . http://www.jstor.org/page/info/about/policies/terms.jsp . JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact [email protected]. . Marine Biological Laboratory is collaborating with JSTOR to digitize, preserve and extend access to Biological Bulletin. http://www.jstor.org This content downloaded from 91.213.220.103 on Sat, 28 Jun 2014 08:25:33 AM All use subject to JSTOR Terms and Conditions

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Page 1: The Larval Apical Organ in the Holothuroid Chiridota gigas (Apodida): Inferences on Evolution of the Ambulacrarian Larval Nervous System

The Larval Apical Organ in the Holothuroid Chiridota gigas (Apodida): Inferences on Evolutionof the Ambulacrarian Larval Nervous SystemAuthor(s): Maria Byrne, Mary A. Sewell, Paulina Selvakumaraswamy and Thomas A. A. ProwseSource: Biological Bulletin, Vol. 211, No. 2 (Oct., 2006), pp. 95-100Published by: Marine Biological LaboratoryStable URL: http://www.jstor.org/stable/4134584 .

Accessed: 28/06/2014 08:25

Your use of the JSTOR archive indicates your acceptance of the Terms & Conditions of Use, available at .http://www.jstor.org/page/info/about/policies/terms.jsp

.JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range ofcontent in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new formsof scholarship. For more information about JSTOR, please contact [email protected].

.

Marine Biological Laboratory is collaborating with JSTOR to digitize, preserve and extend access toBiological Bulletin.

http://www.jstor.org

This content downloaded from 91.213.220.103 on Sat, 28 Jun 2014 08:25:33 AMAll use subject to JSTOR Terms and Conditions

Page 2: The Larval Apical Organ in the Holothuroid Chiridota gigas (Apodida): Inferences on Evolution of the Ambulacrarian Larval Nervous System

Reference: Biol. Bull. 211: 95-100 (October 2006) ? 2006 Marine Biological Laboratory

The Larval Apical Organ in the Holothuroid Chiridota gigas (Apodida): Inferences on Evolution of the

Ambulacrarian Larval Nervous System

MARIA BYRNE1'" MARY A. SEWELL2, PAULINA SELVAKUMARASWAMY', AND THOMAS A. A. PROWSE1

'Department of Anatomy and Histology, F13, University of Sydney, NSW 2006, Australia; and 2School of Biological Sciences, University of Auckland, New Zealand

Within the deuterostomes, the similarity of the dipleu- rula-type larvae of echinoderms (auricularia, bipinnaria) and hemichordates (tornaria) is striking. Here we describe the serotonergic system of the auricularia larvae of the apodid sea cucumber Chiridota gigas to broaden the com- parison of the dipleurula-type larval nervous system in the Holothuroidea. This larva has a simple serotonergic ner- vous system largely composed of the apical organ. The apical organ is a concentration of cells and fibers along, and spanning between, the portions of the ciliary band that traverse the larval apex. Bipolar and multipolar cells give rise to fibers that connect the bands. In contrast to other echinoderm larvae, this larva does not develop serotonergic cells around the mouth. The similar topology and structure of the apical organ of the auricularia and the tornaria suggests that the serotonergic apical organ of the Ambu- lacraria (Echinodermata + Hemichordata) may have orig- inated as a group of nerve cell bodies and fibers that developed in association with ciliary band sectors at the larval apex.

The long-standing hypothesis, based on synapomorphic features of development and morphology (1), on the close phylogenetic relationships between echinoderms and hemi- chordates is strongly supported by molecular phylogeny (2, 3). It thus appears that a dipleurula-type larva with single ciliary band topology, as seen in the holothuroid auricularia and the hemichordate tornaria, is a basal feature of the Ambulacraria. In consideration of this link, we investigated the serotonergic nervous system of the auricularia larvae of

the apodid holothuroid Chiridota gigas and compared it with that described for other dipleurula-type larvae (4-11). This is the first modern developmental study of the plank- totrophic larva of the order Apodida (12). Previous studies on the auricularia serotonergic system involved the larvae of Parastichopus californicus and Stichopus japonicus, mem- bers of the order Aspidochirotida (4, 7, 11).

The nervous system of the auricularia, bipinnaria, and tornaria develops in association with the ciliary bands (4- 11). Serotonin immunoreactivity is conspicuous in the an- terior region of these larvae, with an accumulation of cells and fibers at the larval apex forming the apical organ. Anterior serotonergic structures in these larvae have at- tracted interest because of their potential role as sensory structures (13, 14). In C. gigas, the dominance of the sero- tonergic system at the larval apex was particularly interest- ing from both a functional and a phylogenetic perspective.

The auricularia of C. gigas has a single ciliary band that loops around the larval body, with the dorsal and ventral portions converging at the apex on the larval midline (Fig. 1A-G; 2A; 3A). In early larvae (20 day) the ciliary band sections at the larval apex have a short region where they are aligned in parallel, and this carries over to the dorsal side (Fig. IB, C). In older larvae (40-80 day) the ciliary band sections meet at the apex (Fig. 1D-G), although they may retain a short parallel alignment on the dorsal side. A thin fiber crosses between the bands (Fig. lD, E, G), and this forms part of the apical organ.

Serotonergic cells first appeared at the larval apex in association with the two anterior ciliary band sections (Fig. 2A-F). Fibers from these cells connected to form a thin nerve along the ciliary band epithelium (Fig. 2B, D, F). Where the ciliary band sections converge at the larval apex,

Received 11 January 2006, accepted 12 July 2006. * To whom correspondence should be addressed. E-mail: mbyrne@

anatomy.usyd.edu.au

95

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96 M. BYRNE ET AL.

Figure 1 Auricularia of Chiridota gigas (A-C, 20-day-old; D, E, 44-day-old; F, G, 49-day-old). (A-C) Ventral (A) and dorsal (B, C) views: The ciliary band (CB) traverses the right and left sides of the oral hood (OH) and in this region two sectors of the band are parallel for a short distance (arrow). (D, E) The ciliary band (CB) sectors converge at the larval apex and a thin fiber connects them (arrow). (F, G) The ciliary band (CB) sectors at the apex are in close proximity (arrow). E, esophagus; M, mouth; Me, mesentery; S, stomach; Sk, skeleton. Scales: A, B, D, E, G = 200 ~pm; C = 100

/m; F = 500 gm. Chiridota gigas, obtained from Clovelly, Sydney,

spawned spontaneously. The larvae reared at 18-210C were fed Chaetoceros calcitrans: 10,000 cells/ml on day 3 and 15,000 cells/ml every 1-3 d starting on day 22. Every 3-4 d, 75% of the filtered seawater (1.0 tkm) in the cultures was changed.

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APODID LARVAL NERVOUS SYSTEM 97

Figure 2 A 20-day-old auricularia. (A) Dorsal view. The apical organ (AO) develops in association with anterior sectors of the ciliary band (CB). (B) Cells and fibers innervate the dorsal and ventral portions of the

ciliary band (arrows). Arrowhead, isolated cells. (C, D) Side view showing the connecting fibers (CF) between the dorsal and ventral ciliary band (CB) regions. (E, F) Ventral view. The apical organ (AO) has fibers (arrows) and cells that extend posteriorly along the ciliary band nerve. (G) Detail of serotonergic cells and processes (arrowheads). HP, hydropore; M, mouth: S, stomach. Scales: A, C, E = 100

/_m; B, D, F = 50 ptm; G = 25

/pm. Relaxed larvae (7% MgCl, for 10 rmin) were processed by routine methods (6). The 1:4000 dilution of

anti-serotonin in phosphate-buffered saline provided the best resolution of the serotonergic system.

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98 M. BYRNE ET AL.

Figure 3 A 49-day-old auricularia. (A) Ventral view showing the apical organ (AO) and the thin fiber (F) along the ciliary band. (B) Dorsal view: the right and left sections of the ciliary band align in parallel. Arrows, isolated cells; F, thin fiber. (C) Apical organ cells (arrows) and fibers along the ciliary band. (D, E) Connecting fibers (CF) span between the band regions. Arrows, cell bodies. (F) Fibers, stacked 1-3 deep (arrows) along the lateral region of the ciliary band nerve. (G) At the apex the nerve is 3-5 fibers wide. The cell body and proximal portion of the cell process are strongly immunoreactive (arrow). S, stomach. Scales: A, B = 200 tm; C = 100

/Lm; D-G = 25 pm.

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APODID LARVAL NERVOUS SYSTEM 99

fibers spanned between them (Fig. 2A-F). The cells of the ciliary band nerve and the fibers that span between the bands at the larval apex compose the apical organ of C. gigas (Fig. 2A-G). In 20-day-old larvae, there were 6-22 serotonergic cells (X = 13; SE = 3.2, n = 10) in the apical organ; these were mostly bipolar, with a few multipolar cells present (Fig. 2G). The cells (X = 5.9 gm diam, SE = 0.5 gm; n = 22 cells from 6 larvae) had a strongly immu- noreactive cytoplasm and gave rise to fibers that extended posteriorly along the ciliary band nerve (Fig. 2E, F). Lone immunoreactive cells and fibers present in the oral hood connected with the ciliary band plexus (Fig. 2A, B). One to two serotonergic cells were present in the esophagus.

In older auricularia (49-day-old) an immunoreactive fiber dotted by a few cell bodies developed in the mid and posterior regions of the larva. The nervous system was more complex, with the addition of more cells and fibers (Fig. 3A, B). These larvae had 23-32 serotonergic cells (X = 28; SE = 2.2, n = 6) in the apical organ. Fibers connecting the two ciliary band regions crossed directly or at an angle between the bands (Fig. 3C-E). The cells that formed the connections between the bands were mostly tripolar. They had a mean diameter of 4.8 gm (SE = 0.4 gm, n = 10 cells from 2 larvae) and were similar to the nerve cells in the apical organ of the auricularia of P. californicus and S. japonicus (4, 7, 15). No immunoreactive cells were seen between the bands. The ciliary band nerve had up to 5 fibers across its width at the larval apex and 2-3 fibers in the lateral region (Fig. 3F, G). Immunoreactive cytoplasm ex- tended from the soma into the proximal portion of the fibers (Fig. 3F, G). Elsewhere around the larval body a thin fiber was present in the ciliary band nerve and appeared to be continuous (Fig. 3A, B).

Throughout the development of C. gigas, serotonin im- munoreactivity was largely restricted to the apical and an- terolateral ciliary band regions and had a right-left bilateral symmetry. The serotonergic system of the auricularia is morphologically simpler than in the other dipleurula-type echinoderm larva, the asteroid bipinnaria. Bipinnariae have a complex serotonergic system of processes and neuropil and have lateral and oral ganglia and postoral immunoreac- tivity (5, 6, 8). As in the auricularia, the anterior ciliary band sectors of the bipinnaria are joined by processes that span between them (6). The asteroid apical organ also has prom- inent lateral ganglia (5, 6, 8) that are suggested to have arisen through a split of the single apical organ (13).

The location and cellular organization of the echinoid apical organ differs from that seen in dipleurula-type larvae, and this is likely due to evolution of the echinopluteus. In echinoplutei, the apical organ is a single structure posi- tioned on the oral hood and is made up of two ganglionic groups of cells joined by a thick nerve commissure (8, 16). The cell bodies of the echinoid apical organ do not reside

within the ciliary nerve, but processes from the apical organ connect with the ciliary band nerve of the arms.

Apical serotonin immunoreactivity in C. gigas larvae parallels the location of catecholaminergic cells in the au- ricularia of Actinopyga miliaris and P. californicus, which also form a nerve connecting the apical ciliary band sections (4, 17). In contrast to the serotonergic system, the cat- echolaminergic system traces the entire ciliary band and is conspicuous in the oral region (5, 17). Clearly we have identified only a subset of neurons that compose the apical organ of C. gigas. Use of other neuronal markers (5, 8, 11, 18) may reveal greater complexity of the holothuroid larval nervous system and apical organ.

Serotonergic immunoreactivity was conspicuously absent in the oral region of C. gigas larvae, and this is also the case for aspidochirotid auriculariae and the tornaria (4, 9-11). The presence of serotonergic adoral ganglia along the pos- terior rim of the mouth of asteroid, ophiuroid, and echinoid larvae is likely to be a convergent feature, given our current understanding of echinoderm class interrelationships (3). This structure is suggested to have a gustatory function in feeding (5, 6, 16, 19). It seems likely that the auricularia of C. gigas have the ability to discriminate food particles, as do other echinoderm feeding larvae (20). This ability may involve nonserotonergic cells such as the catecholaminergic cells seen in the adoral region of P. californicus and A. miliaris (4, 17). The shared absence of serotonergic adoral ganglia in the auricularia and tornaria suggests that the ancestral dipleurula larva also lacked this structure and may have employed other neurochemicals to modulate feeding behavior. We have a very poor understanding of what larval nervous systems do, and it would be useful to apply current detailed knowledge of their cellular organization to func- tional studies.

The larval form and topology of the single ciliary band of auricularia with parallel ciliary band segments traversing the right and left portions of the oral hood (Fig. lA, B) is most similar to that seen in the tornaria (9, 10). Asteroid bipinnaria differ from these larvae in having two ciliary bands that follow a dorsoventral path. The serotonergic system of the auricularia is largely restricted to the anterior region where the apical organ develops (Fig. 2A, B; 3A, B). In the tornaria, the serotonergic system is restricted to the apical organ and does not give rise to posteriorly directed fibers (9, 10).

Comparison of the auricularia and tornaria indicates that the ancestral-type apical organ may have originated as an accumulation of nerve cells and processes at the larval apex that differentiated in association with two ciliary band sec- tors. In its anterior location, the ancestral apical organ may have had a sensory role in feeding and settlement.

For some time, interest in the echinoderm and hemichor- date larval nervous system and the apical organ has focused on the proposed evolutionary link between the dipleurula

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100 M. BYRNE ET AL

larva and the chordate nervous system (21), a hypothesis that now has little support (see discussion in 22). Insights into similarities between the echinoderm and hemieh4rdate nervous systems and that of the chordates appear best gen- erated by investigation of the developing juvenile nervous system (23-25). Comparison of echinoderm and hemichor- date larval nervous systems remain, however, of great in- terest with respect to larval evolution (26).

Acknowledgments

The research was supported by the Australian Research Council (MB) and a University of Auckland Research and Study Leave Grant (MAS). M. Orchard, R. Morgan, and the Electron Microscope Unit (University of Sydney) provided technical assistance. Thanks to the Whiteley Center, Uni- versity of Washington, for support during manuscript prep- aration, and to the reviewers.

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