Your search keyword '"Manni L"' showing total 16 results

1. The colonial tunicate Botryllus schlosseri: A key species for evolutionary developmental studies.

Author

Manni L

Subjects

Animals, Biological Evolution, Reproduction, Urochordata genetics

Published

2023

2. Giovanna Zaniolo: An inspiring scientist, teacher, mentor, and colleague. Active: 1967-2012.

Author

Manni L and Anselmi C

Published

2023

3. Amphioxus neuroglia: Molecular characterization and evidence for early compartmentalization of the developing nerve cord.

Author

Bozzo M, Lacalli TC, Obino V, Caicci F, Marcenaro E, Bachetti T, Manni L, Pestarino M, Schubert M, and Candiani S

Subjects

Animals, Biological Evolution, Neurogenesis physiology, Neuroglia, Vertebrates, Lancelets genetics

Abstract

Glial cells play important roles in the development and homeostasis of metazoan nervous systems. However, while their involvement in the development and function in the central nervous system (CNS) of vertebrates is increasingly well understood, much less is known about invertebrate glia and the evolutionary history of glial cells more generally. An investigation into amphioxus glia is therefore timely, as this organism is the best living proxy for the last common ancestor of all chordates, and hence provides a window into the role of glial cell development and function at the transition of invertebrates and vertebrates. We report here our findings on amphioxus glia as characterized by molecular probes correlated with anatomical data at the transmission electron microscopy (TEM) level. The results show that amphioxus glial lineages express genes typical of vertebrate astroglia and radial glia, and that they segregate early in development, forming what appears to be a spatially separate cell proliferation zone positioned laterally, between the dorsal and ventral zones of neural cell proliferation. Our study provides strong evidence for the presence of vertebrate-type glial cells in amphioxus, while highlighting the role played by segregated progenitor cell pools in CNS development. There are implications also for our understanding of glial cells in a broader evolutionary context, and insights into patterns of precursor cell deployment in the chordate nerve cord., (© 2021 Wiley Periodicals LLC.)

Published

2021

4. Developmental signature, synaptic connectivity and neurotransmission are conserved between vertebrate hair cells and tunicate coronal cells.

Author

Rigon F, Gasparini F, Shimeld SM, Candiani S, and Manni L

Subjects

Acetylcholinesterase metabolism, Animals, Basic Helix-Loop-Helix Transcription Factors genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Embryo, Nonmammalian, Gene Expression Regulation, Developmental physiology, Hair Cells, Auditory ultrastructure, Mechanoreceptors, Microscopy, Electron, Transmission, RNA, Messenger metabolism, Receptors, Notch genetics, Receptors, Notch metabolism, Signal Transduction physiology, Synapses ultrastructure, Synaptic Transmission genetics, Vertebrates, Vesicular Glutamate Transport Proteins metabolism, Vesicular Glutamate Transport Proteins ultrastructure, gamma-Aminobutyric Acid metabolism, Biological Evolution, Hair Cells, Auditory cytology, Synapses physiology, Synaptic Transmission physiology, Urochordata cytology

Abstract

In tunicates, the coronal organ represents a sentinel checking particle entrance into the pharynx. The organ differentiates from an anterior embryonic area considered a proto-placode. For their embryonic origin, morphological features and function, coronal sensory cells have been hypothesized to be homologues to vertebrate hair cells. However, vertebrate hair cells derive from a posterior placode. This contradicts one of the principle historical criteria for homology, similarity of position, which could be taken as evidence against coronal cells/hair cells homology. In the tunicates Ciona intestinalis and C. robusta, we found that the coronal organ expresses genes (Atoh, Notch, Delta-like, Hairy-b, and Musashi) characterizing vertebrate neural and hair cell development. Moreover, coronal cells exhibit a complex synaptic connectivity pattern, and express neurotransmitters (Glu, ACh, GABA, 5-HT, and catecholamines), or enzymes for their synthetic machinery, involved in hair cell activity. Lastly, coronal cells express the Trpa gene, which encodes an ion channel expressed in hair cells. These data lead us to hypothesize a model in which competence to make secondary mechanoreceptors was initially broadly distributed through placode territories, but has become confined to different placodes during the evolution of the vertebrate and tunicate lineages., (© 2017 Wiley Periodicals, Inc.)

Published

2018

5. Sexual and asexual reproduction in the colonial ascidian Botryllus schlosseri.

Author

Gasparini F, Manni L, Cima F, Zaniolo G, Burighel P, Caicci F, Franchi N, Schiavon F, Rigon F, Campagna D, and Ballarin L

Subjects

Animals, Biological Evolution, Female, Germ Cells cytology, Male, Reproduction, Reproduction, Asexual, Urochordata physiology

Abstract

The colonial tunicate Botryllus schlosseri is a widespread filter-feeding ascidian that lives in shallow waters and is easily reared in aquaria. Its peculiar blastogenetic cycle, characterized by the presence of three blastogenetic generations (filtering adults, buds, and budlets) and by recurrent generation changes, has resulted in over 60 years of studies aimed at understanding how sexual and asexual reproduction are coordinated and regulated in the colony. The possibility of using different methodological approaches, from classical genetics to cell transplantation, contributed to the development of this species as a valuable model organism for the study of a variety of biological processes. Here, we review the main studies detailing rearing, staging methods, reproduction and colony growth of this species, emphasizing the asymmetry in sexual and asexual reproduction potential, sexual reproduction in the field and the laboratory, and self- and cross-fertilization. These data, opportunely matched with recent tanscriptomic and genomic outcomes, can give a valuable help to the elucidation of some important steps in chordate evolution., (© 2014 Wiley Periodicals, Inc.)

Published

2015

6. The oral sensory structures of Thaliacea (Tunicata) and consideration of the evolution of hair cells in Chordata.

Author

Caicci F, Gasparini F, Rigon F, Zaniolo G, Burighel P, and Manni L

Subjects

Afferent Pathways physiology, Animals, Axons ultrastructure, Cilia ultrastructure, Hair Cells, Auditory ultrastructure, Mechanoreceptors ultrastructure, Microscopy, Electron, Mouth physiology, Biological Evolution, Chordata anatomy & histology, Hair Cells, Auditory physiology, Mechanoreceptors physiology, Urochordata anatomy & histology

Abstract

We analyzed the mouth of three species, representative of the three orders of the class Thaliacea (Tunicata)--Pyrosoma atlanticum (Pyrosomatida), Doliolum nationalis (Doliolida), and Thalia democratica (Salpida)--to verify the presence of mechanoreceptors, particularly hair cells. In vertebrates, hair cells are well-known mechanoreceptors of the inner ear and lateral line, typically exhibiting an apical hair bundle composed of a cilium and stereovilli but lacking an axon. For a long time, hair cells were thought to be exclusive to vertebrates. However, evidence of a mechanosensory organ (the coronal organ) employing hair cells in the mouth of tunicates, considered the sister group of vertebrates, suggests that tunicate and vertebrate hair cells may share a common origin. This study on thaliaceans, a tunicate group not yet investigated, shows that both P. atlanticum and D. nationalis possess a coronal organ, in addition to sensory structures containing peripheral neurons (i.e., cupular organs and triads of sensory cells). In contrast, in T. democratica, we did not recognize any oral multicellular sensory organ. We hypothesize that in T. democratica, hair cells were secondarily lost, concomitantly with the loss of branchial fissures, the acquisition of a feeding mechanism based on muscle activity, and a mechanosensory apparatus based on excitable epithelia. Our data are consistent with the hypothesis that hair cells were present in the common ancestor of tunicates and vertebrates, from which hair cells progressively evolved., (Copyright © 2013 Wiley Periodicals, Inc., A Wiley Company.)

Published

2013

7. Expression of a Musashi-like gene in sexual and asexual development of the colonial chordate Botryllus schlosseri and phylogenetic analysis of the protein group.

Author

Gasparini F, Shimeld SM, Ruffoni E, Burighel P, and Manni L

Subjects

Animals, Bayes Theorem, Embryonic Development genetics, Gene Expression Regulation, Developmental physiology, In Situ Hybridization methods, Life Cycle Stages physiology, Phylogeny, RNA-Binding Proteins biosynthesis, Urochordata anatomy & histology, Urochordata embryology, Gene Expression Regulation physiology, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Synteny physiology, Urochordata genetics, Urochordata growth & development

Abstract

Tunicates are the unique chordates to possess species reproducing sexually and asexually. Among them, the colonial ascidian Botryllus schlosseri is a reference model for the study of similarities and differences in these two developmental pathways. We here illustrate the characterization and expression pattern during both pathways of a transcript for a gene orthologous to Dazap1. Dazap1 genes encode for RNA-binding proteins and fall into the Musashi-like (Msi-like) group. Our phylogenetic analysis shows that these are related to other RNA-binding proteins (Tardbp and several heterogeneous nuclear ribonucleoproteins types) that share the same modular domain structure of conserved tandem RNA Recognition Motifs (RRMs). We also classify the whole group as derived from a single ancient duplication of the RRM. Our results also show that Dazap1 is expressed with discrete spatiotemporal pattern during embryogenesis and blastogenesis of B. schlosseri. It is never expressed in wholly differentiated tissues, but it is located in all bud tissues and in different spatiotemporally defined territories of embryos and larva. These expression patterns could indicate different roles in the two processes, but an intriguing relationship appears if aspects of cell division dynamics are taken into account, suggesting that it is related to the proliferative phases in all tissues, and raising a similarity with known Dazap1 orthologs in other metazoans., (© 2011 Wiley Periodicals, Inc.)

Published

2011

8. Relationships among hemocytes, tunic cells, germ cells, and accessory cells in the colonial ascidian Botryllus schlosseri.

Author

Ballarin L, Del Favero M, and Manni L

Subjects

Animals, Antibodies, Monoclonal, Cell Differentiation immunology, Electrophoresis, Polyacrylamide Gel, Germ Cells immunology, Hemocytes immunology, Immunoblotting, Immunohistochemistry, Urochordata immunology, Cell Differentiation physiology, Germ Cells physiology, Hemocytes physiology, Urochordata physiology

Abstract

Monoclonal antibodies were raised against hemocytes of the colonial ascidian Botryllus schlosseri as possible tools to study hemocyte differentiation. In this species, blood cells are involved in various biological functions, such as immunosurveillance, encapsulation of foreign bodies, metal accumulation, and allorecognition. The latter process drives the fusion or rejection of contacting colonies, according to whether they do or do not share at least one allele at the fusibility/histocompatibility (Fu/HC) locus. Hemocytes take part in the rejection reaction, which suggests that they express molecules, coded by the Fu/HC locus, on their surface. A homozygous colony at the Fu/HC locus was used to produce the antibodies, which were screened by immunocytochemistry on hemocyte monolayers, immunohistochemistry on colony paraffin sections, and immunoblotting on colony homogenates. Here, we report on one of the obtained antibodies (1D8), which recognized a surface epitope on hemocytes of the donor colony and other colonies, apparently in a manner specific to the Fu/HC genotype. It also labeled a single 80-kDa band in colony homogenates. In addition, it specifically recognized tunic cells, germ cells, and their accessory cells. These results strengthen the assumption of a close relationship among these types of cells and blood cells, and suggest a close relationship among the above cells, probably deriving from undifferentiated blood cells., (Copyright © 2011 Wiley-Liss, Inc., A Wiley Company.)

Published

2011

9. Differentiation of papillae and rostral sensory neurons in the larva of the ascidian Botryllus schlosseri (Tunicata).

Author

Caicci F, Zaniolo G, Burighel P, Degasperi V, Gasparini F, and Manni L

Subjects

Afferent Pathways cytology, Afferent Pathways growth & development, Afferent Pathways metabolism, Animals, Apocrine Glands cytology, Apocrine Glands growth & development, Apocrine Glands metabolism, Axons metabolism, Axons ultrastructure, Brain cytology, Brain growth & development, Brain metabolism, Chemoreceptor Cells cytology, Chemoreceptor Cells metabolism, Dendrites metabolism, Dendrites ultrastructure, Ectoderm cytology, Ectoderm embryology, Ectoderm metabolism, Embryonic Development physiology, Epidermis growth & development, Immunohistochemistry, Larva growth & development, Larva metabolism, Mechanoreceptors cytology, Mechanoreceptors metabolism, Metamorphosis, Biological physiology, Microscopy, Electron, Nerve Net cytology, Nerve Net growth & development, Nerve Net metabolism, Urochordata growth & development, Cell Differentiation physiology, Epidermal Cells, Larva cytology, Sensory Receptor Cells cytology, Urochordata cytology

Abstract

During the metamorphosis of tunicate ascidians, the swimming larva uses its three anterior papillae to detect the substrate for settlement, reabsorbs its chordate-like tail, and becomes a sessile oozooid. In view of the crucial role played by the anterior structures and their nerve relations, we applied electron microscopy and immunocytochemistry to study the larva of the colonial ascidian Botryllus schlosseri, following differentiation of the anterior epidermis during late embryogenesis, the larval stage, and the onset of metamorphosis. Rudiments of the papillae appear in the early tail-bud stage as ectodermic protrusions, the apexes of which differentiate into central and peripheral bipolar neurons. Axons fasciculate into two nerves direct to the brain. Distally, the long, rod-like dendritic terminations extend during the larval stage, becoming exposed to sea water. After the larva selects and adheres to the substrate, these neurons retract and regress. Adjacent to the papillae, other scattered neurons insinuate dendrites into the tunic and form the net of rostral trunk epidermal neurons (RTENs) which fasciculate together with the papillary neurons. Our data indicate that the papillae are simple and coniform, the papillary neurons are mechanoreceptors, and the RTENs are chemoreceptors. The interpapillary epidermal area, by means of an apocrine secretion, provides sticky material for temporary adhesion of the larva to the substrate., (2009 Wiley-Liss, Inc.)

Published

2010

10. Coronal organ of ascidians and the evolutionary significance of secondary sensory cells in chordates.

Author

Manni L, Mackie GO, Caicci F, Zaniolo G, and Burighel P

Subjects

Animals, Microscopy, Electron, Scanning, Microscopy, Electron, Transmission, Biological Evolution, Chordata, Mechanoreceptors ultrastructure, Neurons, Afferent ultrastructure, Urochordata ultrastructure

Abstract

A new mechanoreceptor organ, the coronal organ, in the oral siphon of some ascidians belonging to the order Pleurogona has recently been described. In contrast to the known mechanoreceptor organs of ascidian atrium that consist of sensory neurons sending their own axons to the cerebral ganglion, coronal sensory cells are secondary mechanoreceptors, i.e., axonless cells forming afferent and efferent synapses with neurites of neurons located in the ganglion. Moreover, coronal cells exhibit an apical apparatus composed of a cilium accompanied or flanked by rod-like microvilli (stereovilli). Because of the resemblance of these cells to vertebrate hair cells, their ectodermal origin and location in a linear array bordering the bases of the oral tentacles and velum, the coronal organ has been proposed as a homologue to the vertebrate acousticolateralis system. Here we describe the morphology of the coronal organs of six ascidians belonging to the suborders Phlebobranchia and Aplousobranchia (order Enterogona). The sensory cells are ciliated, lack typical stereovilli, and at their bases form synapses with neurites. In two species, the sensory cells are accompanied by large cells involved in synthesis and secretion of protein. We hypothesize that the coronal organ with its secondary sensory cells represents a plesiomorphic feature of ascidians. We compare the coronal organ with other chordate sensory organs formed of secondary sensory cells, i.e., the ventral lip receptors of appendicularians, the oral secondary sensory cells of cephalochordates, and the acousticolateralis system of vertebrates, and we discuss their homologies at different levels of organization.

Published

2006

11. Stomodeal and neurohypophysial placodes in Ciona intestinalis: insights into the origin of the pituitary gland.

Author

Manni L, Agnoletto A, Zaniolo G, and Burighel P

Subjects

Animals, Biological Evolution, Body Patterning physiology, Ciona intestinalis ultrastructure, Larva growth & development, Larva ultrastructure, Pituitary Gland ultrastructure, Pituitary Gland, Posterior growth & development, Ciona intestinalis growth & development, Pituitary Gland growth & development

Abstract

The ascidian larva has a central nervous system which shares basic characteristics with craniates, such as tripartite organisation and many developmental genes. One difference, at metamorphosis, is that this chordate-like nervous system regresses and the adult's neural complex, composed of the cerebral ganglion and associated neural gland, forms. It is known that neural complex differentiation involves two ectodermal structures, the neurohypophysial duct, derived from the embryonic neural tube, and the stomodeum, i.e. the rudiment of the oral siphon; nevertheless, their precise role remains to be clarified. We have shown that in Ciona intestinalis, the neural complex primordium is the neurohypophysial duct, which in the early larva is a short tube, blind anteriorly, with its lumen in continuity with that of the central nervous system, i.e. the sensory vesicle. The tube grows forwards and fuses with the posterior wall of the stomodeum, a dorsal ectodermal invagination of the larva. The duct then loses posterior communication with the sensory vesicle and begins to grow on the roof of the vesicle itself. The neurohypophysial duct differentiates into the neural gland rudiment; its dorsal wall begins to proliferate neuroblasts, which migrate and converge to build up the cerebral ganglion. The most anterior part of the neural gland organizes into the ciliated duct and funnel, whereas the most posterior part elongates and gives rise to the dorsal strand. The hypothesis that the neurohypophysial duct/stomodeum complex possesses cell populations homologous to the craniate olfactory and adenohypophysial placodes and hypothalamus is discussed., (Copyright 2005 Wiley-Liss, Inc.)

Published

2005

12. Neurogenic and non-neurogenic placodes in ascidians.

Author

Manni L, Lane NJ, Joly JS, Gasparini F, Tiozzo S, Caicci F, Zaniolo G, and Burighel P

Subjects

Animals, Cell Differentiation physiology, Ectoderm ultrastructure, Embryo, Nonmammalian embryology, Embryo, Nonmammalian ultrastructure, Italy, Microscopy, Electron, Morphogenesis, Phylogeny, Urochordata anatomy & histology, Ectoderm cytology, Ectoderm physiology, Nervous System embryology, Urochordata embryology

Abstract

The late differentiation of the ectodermal layer is analysed in the ascidians Ciona intestinalis and Botryllus schlosseri, by means of light and electron microscopy, in order to verify the possible presence of placodal structures. Cranial placodes, ectodermal regions giving rise to nonepidermal cell types, are classically found exclusively in vertebrates; however, data are accumulating to demonstrate that the nonvertebrate chordates possess both the genetic machinery involved in placode differentiation, and ectodermal structures that are possible homologues of vertebrate placodes. Here, the term "placode" is used in a broad sense and defines thickenings of the ectodermal layer that can exhibit an interruption of the basal lamina where cells delaminate, and so are able to acquire a nonepidermal fate. A number of neurogenic placodes, ones capable of producing neurons, have been recognised; their derivatives have been analysed and their possible homologies with vertebrate placodes are discussed. In particular, the stomodeal placode may be considered a multiple placode, being composed of different sorts of placodes: part of it, which differentiates hair cells, is discussed as homologous to the octavo-lateralis placodes, while the remaining portion, giving rise to the ciliated duct of the neural gland, is considered homologous to the adenohypophyseal placode. The neurohypophyseal placode may include the homologues of the hypothalamus and vertebrate olfactory placode; the rostral placode, producing the sensorial papillae, may possibly be homologous to the placodes of the adhesive gland of vertebrates.

Published

2004

13. Novel, secondary sensory cell organ in ascidians: in search of the ancestor of the vertebrate lateral line.

Author

Burighel P, Lane NJ, Fabio G, Stefano T, Zaniolo G, Carnevali MD, and Manni L

Subjects

Acetylcholine metabolism, Acetylcholinesterase metabolism, Afferent Pathways metabolism, Afferent Pathways ultrastructure, Animals, Axons metabolism, Axons ultrastructure, Biological Evolution, Carbocyanines, Cilia physiology, Cilia ultrastructure, Dendrites metabolism, Dendrites ultrastructure, Efferent Pathways metabolism, Efferent Pathways ultrastructure, Ganglia, Invertebrate metabolism, Ganglia, Invertebrate ultrastructure, Hair Cells, Auditory metabolism, Mechanoreceptors metabolism, Microscopy, Electron, Microscopy, Electron, Scanning, Neurons, Afferent metabolism, Peripheral Nervous System metabolism, Synapses metabolism, Synapses ultrastructure, Hair Cells, Auditory ultrastructure, Mechanoreceptors ultrastructure, Neurons, Afferent ultrastructure, Peripheral Nervous System ultrastructure, Urochordata physiology, Urochordata ultrastructure

Abstract

A new mechanoreceptor organ, the "coronal organ," located in the oral siphon, is described by light and electron microscopy in the colonial ascidians Botryllus schlosseri and Botrylloides violaceus. It is composed of a line of sensory cells (hair cells), accompanied by supporting cells, that runs continuously along the margin of the velum and tentacles of the siphon. These hair cells resemble those of the vertebrate lateral line or, in general, the acoustico-lateralis system, because they bear a single cilium, located centrally or eccentrically to a hair bundle of numerous stereovilli. In contrast to other sensory cells of ascidians, the coronal hair cells are secondary sensory cells, since they lack axonal processes directed towards the cerebral ganglion. Moreover, at their base they form synapses with nerve fibers, most of which exhibit acetylcholinesterase activity. The absence of axonal extensions was confirmed by experiments with lipophilic dyes. Different kinds of synapses were recognized: usually, each hair cell forms a few afferent synapses with dendrites of neurons located in the ganglion; efferent synapses, both axo-somatic (between an axon coming from the ganglion and the hair cell) and axo-dendritic (between an axon coming from the ganglion and an afferent fiber) were occasionally found. The presence of secondary sensory cells in ascidians is discussed in relation to the evolution of sensory cells and placodes in vertebrates. It is proposed that the coronal organ in urochordates is homologous to the vertebrate acoustico-lateralis system., (Copyright 2003 Wiley-Liss, Inc.)

Published

2003

14. Development of the motor nervous system in ascidians.

Author

Zaniolo G, Lane NJ, Burighel P, and Manni L

Subjects

Animals, Axons physiology, Axons ultrastructure, Branchial Region growth & development, Branchial Region physiology, Branchial Region ultrastructure, Central Nervous System growth & development, Central Nervous System physiology, Central Nervous System ultrastructure, Digestive System growth & development, Digestive System ultrastructure, Fluorescent Antibody Technique, Ganglia, Invertebrate growth & development, Ganglia, Invertebrate physiology, Ganglia, Invertebrate ultrastructure, Heart growth & development, Heart innervation, Heart physiology, Microscopy, Electron, Motor Neurons physiology, Peripheral Nervous System physiology, Urochordata physiology, Cell Differentiation physiology, Motor Neurons ultrastructure, Neuronal Plasticity physiology, Peripheral Nervous System growth & development, Peripheral Nervous System ultrastructure, Urochordata growth & development, Urochordata ultrastructure

Abstract

The motor nervous system of adult ascidians consists of neurons forming the cerebral ganglion from which axons run out directly to the effectors, i.e., muscular and ciliary cells. In this study, we analyzed the development of the motor fibers, correlating this with organ differentiation during asexual reproduction in Botryllus schlosseri. We used a staining method for acetylcholinesterase, whose reaction product is visible with both light and electron microscopy and which labels entire nerves, including their thin terminals, making them identifiable between tissues. While the cerebral ganglion is forming, the axons elongate and follow stereotypical pathways to reach the smooth muscle cells of the body, the striated muscle of the heart, and the ciliated cells of the branchial stigmata and the gut. A strict temporal relation links the development of the local neural network with its target organ, which is approached by nerves before the effector cells are fully differentiated. This process occurs for oral and cloacal siphons, branchial basket, gut, and heart. Axons grow through the extracellular matrix and arrive at their targets from different directions. In some cases, the blood sinuses constitute the favorite roads for growing axons, which seem to be guided by a mechanism involving contact guidance or stereotropism. The pattern of innervation undergoes dynamic rearrangements and a marked process of elimination of axons, when the last stages of blastogenesis occur. The final pattern of motor innervation seems to be regulated by axon withdrawal, rather than apoptosis of motor neurons., (Copyright 2002 Wiley-Liss, Inc.)

Published

2002

15. Mechanism of neurogenesis during the embryonic development of a tunicate.

Author

Manni L, Lane NJ, Sorrentino M, Zaniolo G, and Burighel P

Subjects

Animals, Cell Differentiation physiology, Embryonic Development, Ganglia, Invertebrate embryology, Larva growth & development, Nervous System embryology, Urochordata embryology

Abstract

Ascidian and vertebrate nervous systems share basic characteristics, such as their origin from a neural plate, a tripartite regionalization of the brain, and the expression of similar genes during development. In ascidians, the larval chordate-like nervous system regresses during metamorphosis, and the adult's neural complex, composed of the cerebral ganglion and the associated neural gland is formed. Classically, the homology of the neural gland with the vertebrate hypophysis has long been debated. We show that in the colonial ascidian Botryllus schlosseri, the primordium of the neural complex consists of the ectodermal neurohypophysial duct, which forms from the left side of the anterior end of the embryonal neural tube. The duct contacts and fuses with the ciliated duct rudiment, a pharyngeal dorsal evagination whose cells exhibit ectodermic markers being covered by a tunic. The neurohypophysial duct then differentiates into the neural gland rudiment whereas its ventral wall begins to proliferate pioneer nerve cells which migrate and converge to make up the cerebral ganglion. The most posterior part of the neural gland differentiates into the dorsal organ, homologous to the dorsal strand. Neurogenetic mechanisms in embryogenesis and vegetative reproduction of B. schlosseri are compared, and the possible homology of the neurohypophysial duct with the olfactory/adenohypophysial/hypothalamic placodes of vertebrates is discussed. In particular, the evidence that neurohypophysial duct cells are able to delaminate and migrate as neuronal cells suggests that the common ancestor of all chordates possessed the precursor of vertebrate neural crest/placode cells., (Copyright 1999 Wiley-Liss, Inc.)

Published

1999

16. Neurogenic role of the neural gland in the development of the ascidian, Botryllus schlosseri (Tunicata, Urochordata).

Author

Burighel P, Lane NJ, Zaniolo G, and Manni L

Subjects

Animals, Cell Differentiation physiology, Embryonic Development, Ganglia, Invertebrate embryology, Ganglia, Invertebrate growth & development, Larva, Pituitary Gland embryology, Pituitary Gland growth & development, Urochordata embryology, Urochordata growth & development

Abstract

In adult ascidians, the neural complex consists of a cerebral ganglion (the brain) and the associated neural gland. We have studied the development of the neural complex during the vegetative reproduction of the colonial ascidian Botryllus schlosseri, the buds of which arise from the atrial mantle of the parental zooid. Each bud develops into a new organism within which a neural complex becomes differentiated. We found that the presumptive (pioneer) nerve cells that ultimately form the cerebral ganglion of the adult arise as migratory cells from a primordial cluster of rudimentary gland cells. Hence, the neural gland appears to be neurogenic in that it serves as the cellular source of components that differentiate into conventional nerve cells. In the adult, these cells take on the form of a typical invertebrate ganglion with an outer cortex of nerve cell bodies and an internal medulla. This medulla consists of a neuropile of neuronal processes making classical synaptic contacts. The adult neural gland differentiates into a structure with a ciliated duct that opens into the branchial chamber, the body of the gland, and the dorsal organ, which is quite distinct from the dorsal strand of other ascidians. The rudimentary neural gland cells, therefore, differentiate into one of two distinct pathways: the first, glandular, is possibly involved in the evaluation of environmental signals, and the other, nervous, leads to brain formation. This compares with the vertebrate situation in which the olfactory-pituitary placodes are thought to originate from a common cellular source. Thus, these data support the earlier contention of a homology between the tunicate neural gland and the vertebrate adenohypophysis.

Published

1998