Abstract
The tornaria larva of hemichordates occupies a central position in phylogenetic discussions on the relationships between Echinodermata, Hemichordata, and Chordata. Dipleurula-type larvae (tornaria and echinoderm larvae) are considered to be primary in the life cycle and thus provide a model for the ancestral animal common to all three taxa (the theory of W. Garstang). If the similarities between tornaria and the larvae in Echinodermata result from homology, their nervous systems should be basically similar as well. The present study utilizes anti-serotonin and FMRFamide antisera together with laser scanning microscopy, and transmission electron microscopy, to describe in detail the nervous system of the tornaria of Balanoglossus proterogonius. Serotonin immunoreactive neurons were found in the apical and esophageal ganglia, and in the stomach epithelium. FMRFamide immunoreactive neurons, probably sensory in nature, were detected in the apical ganglion and in the equatorial region of the stomach epithelium. At the ultrastructural level, the apical organ consists of a columnar epithelium of monociliated cells and includes a pair of symmetrical eyespots. The apical ganglion is located at its base and has a well-developed neuropil. Different types of neurons are described in the apical organ, esophagus, and stomach. Comparison with larvae in Echinodermata shows several significant differences in the way the larval nervous system is organized. This calls into question the homology between tornariae and echinoderm larvae. The possibility of convergence between the two larval types is discussed.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Arendt D, Nübler-Jung K (1994) Inversion of dorsoventral axis? Nature 371:26
Arendt D, Technau U, Wittbrodt J (2001) Evolution of the bilaterian larval foregut. Nature 409:81–85
Azmitia EC (2001) Modern views on an ancient chemical: serotonin effects on cell proliferation, maturation and apoptosis. Brain Res Bull 56:413–424
Bartolomaeus T (2001) Ultrastructure and formation of the body cavity lining in Phoronis muelleri (Phoronida, Lophophorata). Zoomorphology 120:135–148
Beer AJ, Moss C, Thorndyke M (2001) Development of serotonin-like and SALMFamide-like immunoreactivity in the nervous system of the sea urchin Psammechinus miliaris. Biol Bull 200:268–280
Bisgrove BW, Burke RD (1986) Development of serotonergic neurones in embryos of the sea urchin, Strongylocentrotus purpuratus. Dev Growth Differ 28:569–574
Bisgrove BW, Burke RD (1987) Development of the nervous system of the pluteus of Strongylocentrotus droebachiensis. Cell Tissue Res 248:335–343
Brandenburger JL, Woollacott RM, Eakin RM (1973) Fine structure of eyespots in tornarian larvae (Phylum: Hemichordata). Z Zellforsch 142:89–102
Bromham LD, Degnan BM (1999) Hemichordates and deuterostome evolution: robust molecular phylogenetic support for a hemichordate + echinoderm clade. Evol Dev 1:166–171
Brusca RC, Brusca GJ (1990) Invertebrates. Sinauer, Sunderland, MA
Bullock TH, Horridge GA (1965) Structure and function in the nervous systems of invertebrates, vol 1. Freeman, San Francisco, pp 1–798
Burke RD (1978) The structure of the nervous system of the pluteus larva of Strongylocentrotus purpuratus. Cell Tissue Res 191:233–247
Burke RD (1983a) Development of the larval nervous system of the sand dollar, Dendraster excentricus. Cell Tissue Res 229:145–154
Burke RD (1983b) The structure of the larval nervous system of Pisaster ochraceus (Echinodermata: Asteroidea). J Morphol 178:23–35
Burke RD, Brand DG, Bisgrove BW (1986) Structure of the nervous system of the auricularia larva of Parastichopus californicus. Biol Bull 173:450–460
Byrne M, Cisternas P (2002) Development and distribution of the peptidergic system in larval and adult Patiriella: comparison of sea star bilateral and radial nervous system. J Comp Neurol 451:101–114
Byrne M, Cisternas P, Koop D (2001) Evolution of larval form in the sea star genus Patiriella: conservation and change in the larval nervous system. Dev Growth Differ 43:459–468
Cameron CB, Garey JR, Swalla BJ (2000) Evolution of the chordate body plan: new insight from the phylogenetic analyses of deuterostome phyla. Proc Natl Acad Sci U S A 97:4469–4474
Castresana J, Feldmaier-Fuchs G, Yokobori S, Satoh N, Paabo S (1998) The mitochondrial genome of the hemichordate Balanoglossus carnosus and the evolution of deuterostome mitochondria. Genetics 150:1115–1123
Chee F, Byrne M (1997) Visualization of the developing serotonergic nervous system in the larvae of the sea star, Patiriella regularis using confocal microscopy and computer generated 3-D reconstructions. Invert Reprod Dev 31:151–158
Chee F, Byrne M (1999a) Serotonin-like immunoreactivity in the brachiolaria larvae of Patiriella regularis. Invert Reprod Dev 36:111–115
Chee F, Byrne M (1999b) Development of the larval serotonergic nervous system in the sea star Patiriella regularis as revealed by confocal imaging. Biol Bull 197:123–131
Chen CP, Tseng CH, Chen BY (1995) The development of the catecholaminergic nervous system in starfish and sea-cucumber larvae. Zool Stud 34:248–256
Chia F-S, Burke RD, Koss R, Mladenov PV, Rumrill SS (1986) Fine structure of the doliolaria larva of the feather star Florometra seratissima (Echinodermata: Crinoidea), with special emphasis on the nervous system. J Morphol 189:99–120
Child CM (1921) The origin and development of the nervous system. University of Chicago Press, Chicago
Crowther RJ, Whittaker JR (1992) Structure of the caudal neural tube in an ascidian larva: vestiges of its possible evolutionary origin from a ciliated band. J Neurophysiol 23:280–292
Dautov SS, Nezlin LP (1992) Nervous system of the tornaria larva (Hemichordata: Enteropneusta). A histochemical and ultrastructural study. Biol Bull 183:463–475
Dillon LS (1965) The hydrocoel and the ancestry of the chordates. Evolution 19:436–446
Garstang W (1894) Preliminary note on a new theory of the phylogeny of the Chordata. Zool Anz 27:122–125
Garstang W (1928) The morphology of the Tunicata and its bearing on the phylogeny of the Chordata. J Microsc Sci 72:51–187
Garstang W (1939) Spolia bermudiana. II. The ciliary feeding mechanism of tornaria. Q J Microsc Sci 81:347–366
Gilmour TH (1982) Feeding in tornaria larva and the development of gill slits in enteropneust hemichordates. Can J Zool 60:3010–3020
Halanych KM (1995) The phylogenetic position of the pterobranch hemichordates based on 18S rDNA sequence data. Mol Phylogenetics Evol 4:72–76
Hanström B (1928) Vergleichende Anatomie des Nervensystems der wirbellosen Tiere unter Berücksichtigung seiner Funktion. Springer, Berlin Heidelberg New York
Hart MW, Miller RL, Madin LP (1994) Form and feeding mechanism of a living Planctosphaera pelagica (phylum Hemichordata). Mar Biol 120:521–533
Hay-Schmidt A (1990) Distribution of catecholamine-containing, serotonin-like and neuropeptide FMRFamide-like immunoreactive cells and processes of the nervous system of the actinotroch larva of Phoronis muelleri (Phoronida). Cell Tissue Res 259:105–118
Hay-Schmidt A (1992) Ultrastructure and immunocytochemistry of the nervous system of the larvae of Lingula anatina and Glottidia sp. (Brachiopoda). Zoomorphology 112:189–205
Hay-Schmidt A (1995) The larval nervous system of Polygordius lacteus Schneider, 1868 (Polygordiidae, Polychaeta): immunocytochemical data. Acta Zool (Stockh) 76:121–140
Hay-Schmidt A (2000) The evolution of the serotonergic nervous system. Proc R Soc Lond B 267:1071–1079
Hessling R, Purschke G (2000) Immunohistochemical (cLSM) and ultrastructural analysis of the central nervous system and sense organs in Aeolosoma hemprichi (Annelida, Aeolosomatidae). Zoomorphology 120:65–78
Hessling R, Westheide W (2002) Are Echiura derived from a segmented ancestor? Immunohistochemical analysis of the nervous system in developmental stages of Bonellia viridis. J Morphol 252:100–113
Ivanova-Kazas OM (1995) Evolutional embryology (in Russian). Nauka, St. Petersburg
Ivanova-Kazas OM, Ivanov AV (1987) The trochaea theory and phylogenetic significance of ciliated larvae. Sov J Mar Biol 13:67–80
Jägersten G (1972) Evolution of the Metazoan life cycle. Academic, London
Jollie M (1973) The origin of the chordates. Acta Zool (Stockh) 54:81–100
Kempf SC, Chun GV, Hadfield MG (1992) An immunocytochemical search for potential neurotransmitter in larvae of Phestilla sibogae (Gastropoda, Opistobranchia). Comp Biochem Physiol 101C:299–305
Kempf SC, Page LR, Pires A (1997) Development of serotonin-like immunoreactivity in the embryos and larvae of nudibranch mollusks with emphasis on the structure and possible function of the apical sensory organ. J Comp Neurol 386:507–528
Komatsu M, Chia FS, Koss R (1991) Sensory neurons of the bipinnaria larva of the sea star, Luidia senegalensis. Invert Reprod Dev 19:203–211
Kuhlenbeck H (1967) The central nervous system of vertebrates, vol 2. Invertebrates and origin of vertebrates. Karger, Basel
Lacalli TC (1993) Ciliary bands in echinoderm larvae: evidence for structural homologies and common plan. Acta Zool (Stockh) 74:127–133
Lacalli TC (1994) Apical organs, epithelial domains, and the origin of the chordate central nervous system. Am Zool 34:533–541
Lacalli TC (1996) Mesodermal pattern and pattern repeats in the starfish bipinnaria larva, and related patterns in other deuterostome larvae and chordates. Philos Trans R Soc Lond B 351:1737–1758
Lacalli TC, Gilmour THJ (2001) Locomotory and feeding effectors of the tornaria larva of Balanoglossus biminiensis. Acta Zool (Stockh) 82:117–126
Lacalli TC, Holland LZ (1998) The developing dorsal ganglion of the salp Thalia democratica, and the nature of the ancestral chordate brain. Philos Trans R Soc Lond B 353:1943–1967
Lacalli TC, Kelly SJ (2002) Anterior neural centres in echinoderm bipinnaria and auricularia larvae: cell types and organization. Acta Zool (Stockh) 83:99–110
Lacalli TC, West JC (1993) A distinctive cell type common to diverse deuterostome larvae: comparative data from echinoderms, hemichordates and amphioxus. Acta Zool (Stockh) 74:1–8
Lacalli TC, Gilmour TH, West JE (1990) Ciliary band innervation in the bipinnaria larva of Pisaster ochraceus. Philos Trans R Soc Lond B 330:371–390
Løvtrup S (1977) The phylogeny of vertebrata. Wiley, London
Morikawa K, Tsuneki K, Ito K (2001) Expression patterns of HNK-1 carbohydrate and serotonin in sea urchin, amphioxus, and lamprey, with reference to the possible evolutionary origin of the neural crest. Zoology 104:81–90
Moss C, Burke RD, Thorndyke MC (1994) Immunocytochemical localisation of the neuropeptides S1 and serotonin in larvae of the starfish Pisaster ochraceus and Asterias rubens. J Mar Biol Assoc U K 74:61–71
Müller J (1850) Über die Larven und die Metamorphose der Echinodermen. Abhandl Akad Wiss Berlin 1948:75–109
Muneoka Y, Morishita F, Furukawa Y, Matsushima O, Kobayashi M, Ohtani M, Takahashi T, Iwakoshi E, Fujisawa Y, Minakata H (2000) Comparative aspects of invertebrate neuropeptides. Acta Biol Hung 51:111–132
Nakajima Y (1986) Development of the nervous system of sea urchin embryos: formation of the ciliary bands and the appearance of two types of ectoneural cells in the pluteus. Dev Growth Differ 28:531–542
Nakajima Y (1987) Localization of catecholaminergic nerves in larval echinoderms. Zool Sci 4:293–299
Nakajima Y (1988) Serotonergic nerve cells of starfish larvae. In: Burke RP, Mladenov PV, Lambert P, Parsley RL (eds) Echinoderm biology. Balkema, Rotterdam, pp 235–239
Nezlin L (2000) Tornaria of hemichordates and other dipleurula-type larvae: a comparison. J Zool Syst Evol Res 38:149–156
Nezlin LP, Yushin VV (1994) The digestive tract of the echinopluteus of Echinocardium cordatum (Echinodermata, Echinoida): its ultrastructure and innervation. Can J Zool 72:2090–2099
Nielsen C (1987) Structure and function of metazoan ciliary bands and their phylogenetic significance. Acta Zool (Stockh) 68:205–262
Nielsen C (1999) Origin of the chordate central nervous system: and the origin of the chordates. Dev Genes Evol 209:198–205
Nielsen C (2001) Animal evolution: interrelationships of the living phyla, 2nd edn. Oxford University Press, Oxford
Nielsen C, Riisgård HU (1998) Tentacle structure and filter-feeding in Crisia eburnea and other cyclostomatous bryozoans, with a review of upstream-collecting mechanisms. Mar Ecol Prog Se 168:163–186
Page LR, Parries SC (2000) Comparative study of the apical ganglion in planktotrophic caenogastropod larvae: ultrastructure and immunoreactivity to serotonin. J Comp Neurol 418:383–401
Peterson KJ, Cameron RA, Tagawa K, Satoh N, Davidson EH (1999) A comparative molecular approach to mesodermal pattern in basal deuterostomes: the expression pattern of Brachyury in the enteropneust hemichordate Ptychodera flava. Development 126:85–95
Plate L (1922) Allgemeine Zoologie und Abstammungslehre, vol I. Fisher, Jena
Ryberg E (1974) The localization of biogenic amines in the echinopluteus. Acta Zool (Stockh) 55:179–189
Sakharov DA (1991) Integrative function of serotonin common to distantly related invertebrate animals. In: Gustafsson M, Reuter M (eds) The early brain. Akademi, Abo, pp 73–88
Salvini-Plawen L (1980) Was ist eine Trochophora? Eine Analyse der Larventypen mariner Protostomier. Zool Jahrb Anat 103:389–423
Salvini-Plawen L (1998) The urochordate larva and archichordate organization: chordate origin and anagenesis revisited. J Zool Syst Evol Res 36:129–145
Strathmann RR (1989) Existence and functions of a gel filled primary body cavity in development of echinoderms and hemichordates. Biol Bull 176:25–31
Strathmann R, Bonar D (1976) Ciliary feeding of tornaria larvae of Ptychodera flava (Hemichordata, Enteropneusta). Mar Biol 34:317–324
Tagawa K, Humphreys T, Satoh N (1998) Novel pattern of Brachyury gene expression in hemichordate embryos. Mech Dev 75:139–143
Tagawa K, Satoh N, Humphreys T (2001) Molecular studies of hemichordate development: a key to understanding the evolution of bilaterial animals and chordates. Evol Dev 3:443–454
Thorndyke MC, Crawford BD, Burke RD (1992) Localisation of a SALMFamide neuropeptide in the larval nervous system of the sand dollar, Dendraster excentricus. Acta Zool (Stockh) 73:207–212
Turbeville JM, Schulz JR, Raff RA (1994) Deuterostome phylogeny and the sister group of the chordates: evidence from molecules and morphology. Mol Biol Evol 11:648–655
Voronezhskaya EE, Tyurin SA, Nezlin LP (2002) Neuronal development in larval chiton Ischnochiton hakodadensis (Mollusca: Polyplacophora). J Comp Neurol 444:25–38
Voronezhskaya EE, Tsitrin EB, Nezlin LP (2003) Neuronal development in the larval polychaete Phyllodoce maculata (Phyllodocidae). J Comp Neurol 455:299–309
Wada H, Satoh N (1994) Details of the evolutionary history from invertebrates to vertebrates, as deducted from the sequences of 18S rDNA. Proc Natl Acad Sci U S A 91:1801–1804
Wada H, Satoh N (2001) Patterning the protochordate neural tube. Curr Opin Neurobiol 11:16–21
Whitington PM (1995) Conservation versus change in early axonogenesis in arthropod embryos: a comparison between myriapods, crustaceans and insects. In: Breidbach O, Kutsch W (eds) The nervous systems of invertebrates: an evolutionary and comparative approach, vol 72. Birkhaüser, Basel, pp 181–219
Wiedersheim R (1893) Der Bau des Menschen als Zeugniss für seine Vergangenheit, 2nd edn. Mohr, Leipzig
Willmer P (1990) Invertebrate relationships. Patterns in animal evolution. Cambridge University Press, Cambridge
Acknowledgements
The authors would like to thank Dr. S. Dautov (Institute of Marine Biology, Vladivostok) for providing us with tornaria larvae, Dr. E. Voronezhskaya (Institute of Developmental Biology, Moscow) for help with immunostaining procedures and fruitful discussions, and M. Claeys (University of Ghent) and D. Fomin (Institute of Marine Biology) for technical assistance with electron microscopy. This study was funded in part by the Support for Science Schools grant N 1219.2003.4 for V.V.Y.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Nezlin, L.P., Yushin, V.V. Structure of the nervous system in the tornaria larva of Balanoglossus proterogonius (Hemichordata: Enteropneusta) and its phylogenetic implications. Zoomorphology 123, 1–13 (2004). https://doi.org/10.1007/s00435-003-0086-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00435-003-0086-z