Comparative ultrastructure of the pharynx simplex in turbellaria

Summary The simple pharynges in thirteen species of Turbellaria in the orders Macrostomida, Haplopharyngida, Catenulida, and Acoela have been studied by electron microscopy. After consideration of the functional aspects of the pharynx simplex, the relationship of the pharynx simplex ultrastructure to the phylogeny of the above mentioned groups is analyzed.The Haplopharyngida and Macrostomida are united as a group by the following characters: a pharynx transition zone of 1–5 circles of insunk cells with modified ciliary rootlets or no cilia, pharynx sensory cells without stereocilia collars and with a variable number of cilia, a prominent nerve ring with more than 30 axons circling the pharynx at the level of the beginning of the pharynx proper distal to the gland ring, 2 or more gland cell types in the pharynx, with at least two layers of muscle present and the longitudinal muscles derived from regular and special body wall circular muscles and a prominent post-oral nerve commissure. This specific arrangement can be distinguished from the other pharynx simplex types and is called the pharynx simplex coronatus.The catenulid pharynx simplex is characterized by the lack of a prominent nerve ring, no prominent post-oral commissure, a transition zone with epidermal type ciliary rootlets, recessed monociliated sensory cells, and one or no type of pharynx gland cell. The Acoela are specialized because of the epidermal type rootlets in the pharynx proper. They also lack a transition zone and a prominent nerve ring and have monociliated sensory cells different from the catenulid type.Ultrastructural characters of the pharynx simplex support the view that the Haplopharyngida-Macrostomida are monophyletic. The more primitive catenulid pharynx probably arose from a common ancestral pool with the Haplopharyngida and Macrostomida, although it does not appear possible presently to establish a clear monophyletic line for these forms. The various pharynx types within the Acoela appear to indicate independent origins with no clear link to the basic pharynx simplex type in the three other orders.Abbreviations Used in Figures a nerve axon - ar accessory rootlet - bb basal body - bn brain-nerve ring commissure - c caudal rootlet - ce centriole - ci cilium - cm circular muscle - cp ciliary pit - cu cuticle - cw cell web - d dictyosome - dp proximal pharynx proper cell - e epidermis - er rough endoplasmic reticulum - f fibrous rod - g gastrodermis - gc gastrodermal gland cell - he heterochromatin - i intercellular matrix - lc lateral nerve cord - lm longitudinal muscle - m mitochondria - mo mouth - mt microtubules - mv microvilli - n nucleus - nr nerve ring - ns neurosecretory granules - p pharynx proper - ph pharynx - po post-oral commissure - r rostral rootlet - rm radial muscle - s sphincter - sc sensory cell - sj septate junction - sr sensory rootlet - t transition zone - u ultrarhabdite - v vertical rootlet - va food vacuole - za zonula adhaerens - 1 type I gland cell - 2 type II gland cell - 3 type III gland cell - 4 type IV gland cell - 5 type V gland cell - 6 type VI gland cell - 7 type VII gland cell     

Inflamed adult pharynx tissues and swimming larva of Ciona intestinalis share CiTNFα-producing cells

In situ hybridisation and immunohistochemistry analyses have shown that the Ciona intestinalis tumour necrosis factor alpha gene (CiTNFα), which has been previously cloned and sequenced, is expressed either during the inflammatory pharynx response to lipopolysaccharide (LPS) or during the swimming larval phase of development. Granulocytes with large granules and compartment/morula cells are CiTNFα-producing cells in both inflamed pharynx and larvae. Pharynx vessel endothelium also takes part in the inflammatory response. Haemocyte nodules in the vessel lumen or associated with the endothelium suggest the involvement of CiTNFα in recruiting lymphocyte-like cells and promoting the differentiation of inflammatory haemocytes. Specific antibodies against a CiTNFα peptide have identified a 43-kDa cell-bound form of the protein. Observations of pharynx histological sections (at 4 and 8 h post-LPS inoculation) from naive and medium-inoculated ascidians have confirmed the CiTNFα-positive tissue response. Larval histological sections and whole-mount preparations have revealed that CiTNFα is expressed by trunk mesenchyme, preoral lobe and tunic cells, indicating CiTNFα-expressing cell immigration events and an ontogenetic role.     

Intercalary muscle cell renewal in planarian pharynx

 Planarian cell renewal is achieved as a result of proliferation and differentiation of totipotent undifferentiated cells called neoblasts. The absence of mitosis within the planarian pharynx raises the question as to how cell renewal and growth occur within this organ. Two explanations have been advanced: one proposes that new cells remain close to the base of the pharynx, which then grows by distal displacement of older cells, and the other suggests that the new cells are intercalated between older cells throughout the pharynx. The second alternative, however, does not explain how new cells enter the pharynx or how they reach their final destination. In this study of myosin heavy-chain gene expression within planarian pharynx, a row of differentiating myocytes was detected all along the pharynx parenchyma. According to the hybridization pattern, all these myocytes appeared to be at early stages of differentiation. These data favour an intercalary model for muscle cell renewal within the pharynx. According to this model, neoblasts at the base of the pharynx would enter the pharynx, where they would start differentiation to myocytes, move to the subepithelial musculature and intercalate between the old muscle cells. The possible application of this intercalary model to other pharynx cell types is also discussed. Received: 30 July 1998 / Accepted: 20 November 1998     

Reconstruction of the pharyngeal corpus of Aphelenchus avenae (Nematoda: Tylenchomorpha), with implications for phylogenetic congruence

The corpus of the pharynx in the nematode Aphelenchus avenae (Nematoda: Tylenchomorpha) was three‐dimensionally reconstructed to address questions of phylogenetic significance. Reconstructed models are based on serial thin sections imaged by transmission electron microscopy. The corpus comprises six classes of radial cells, two classes of marginal cells, and 13 neurones belonging to eight classes. Between the arcade syncytia and isthmus cells, numbers of cell classes along the pharyngeal lumen and numbers of nuclei per cell class correspond exactly between A. avenae and Caenorhabditis elegans. The number of radial cell classes between the arcade syncytia and the dorsal gland orifice (DGO) in A. avenae is also identical with outgroups. Proposed homologies of the pharynx imply that expression of the anterior two cell classes as epithelial or muscular differs within both Rhabditida and Tylenchomorpha. Numbers of neurone cell bodies within the corpus correspond exactly to C. elegans, other free‐living outgroups, and other Tylenchomorpha. Neurone polarity and morphology support conserved relative positions of cell bodies of putative neurone homologues. The configuration of cells in the procorpus, including the length of individual cell classes along its lumen, differs across representatives of three deep Tylenchomorpha lineages. Nonhomology of the procorpus challenges the homology of DGO position within the metacorpus, the primary taxonomic character for circumscribing ‘Aphelenchoidea’. Comparison of A. avenae with Aphelenchoides blastophthorus shows that, despite gross pharynx similarity, these nematodes have several differences in corpus construction at a cellular level. The possibility of convergent evolution of an ‘aphelenchid’ pharynx in two separate lineages would be congruent with molecular‐based phylogeny. Putative homologies and conserved arrangement of pharyngeal neurones in Tylenchomorpha expand the experimental model of C. elegans. © 2010 The Linnean Society of London, Zoological Journal of the Linnean Society, 2010.     

The fine structure of the planarianPolycelis tenuis ijima

Summary The fine structure of the pharynx is presented and demonstrates that the pharyngeal epithelial system is a continuous one. The epithelial lining of the pharyngeal cavity with its characteristic fibrous secretory bodies merges with the outer pharyngeal epithelium at the point of anchorage of the pharynx. A few of these cells are insunk, the nuclei occurring beneath the underlying muscular layers. The nature of the outer epithelium changes towards the free end of the pharynx; the cells become ciliated and in contents come to resemble the inner epithelium which it joins at the tip.The gut cells merge at a transitional zone with the inner pharyngeal epithelium and at this point both bear microvilli and contain rod-shaped apical bodies. Some of these cells are also insunk. Towards the mouth the epithelium shows a greater degree of insinking and exhibits microapocrine secretion. Both inner and outer epithelia bear sense receptors which are concentrated at the lip.At the point of pharyngeal insertion, the sub-epithelial tissue resembles planarian parenchyma, but is rich in gland cells. These glands open on to the outer epithelium especially towards the free end of the pharynx.This research was supported by the Scientific Research Council. Grant No. B/RG/086.     

The embryonic development of the triclad <Emphasis Type="Italic">Schmidtea polychroa</Emphasis>

Triclad flatworms are well studied for their regenerative properties, yet little is known about their embryonic development. We here describe the embryonic development of the triclad Schmidtea polychroa, using histological and immunocytochemical analysis of whole-mount preparations and sections. During early cleavage (stage 1), yolk cells fuse and enclose the zygote into a syncytium. The zygote divides into blastomeres that dissociate and migrate into the syncytium. During stage 2, a subset of blastomeres differentiate into a transient embryonic epidermis that surrounds the yolk syncytium, and an embryonic pharynx. Other blastomeres divide as a scattered population of cells in the syncytium. During stage 3, the embryonic pharynx imbibes external yolk cells and a gastric cavity is formed in the center of the syncytium. The syncytial yolk and the blastomeres contained within it are compressed into a thin peripheral rind. From a location close to the embryonic pharynx, which defines the posterior pole, bilaterally symmetric ventral nerve cord pioneers extend forward. Stage 4 is characterized by massive proliferation of embryonic cells. Large yolk-filled cells lining the syncytium form the gastrodermis. During stage 5 the external syncytial yolk mantle is resorbed and the embryonic cells contained within differentiate into an irregular scaffold of muscle and nerve cells. Epidermal cells differentiate and replace the transient embryonic epidermis. Through stages 6–8, the embryo adopts its worm-like shape, and loosely scattered populations of differentiating cells consolidate into structurally defined organs. Our analysis reveals a picture of S. polychroa embryogenesis that resembles the morphogenetic events underlying regeneration.Edited by D. Tautz     

Studies on the tardigrades. II. Fine structure of the pharynx of milnesium tardigradum doyère

The fine structure of the pharynx and associated valve of the tardigrade Milnesium tardigradum is presented. The pharynx consists of a triradiate, cuticle lined lumen surrounded by radially arranged muscle cells and special apical cells which cap each of the ventricles of the lumen. The valve is an unusual structure marking the anterior limit of the pharynx. It is a specialization of the cuticular lining of the foregut and the apical cells of the pharynx. The significance and phyletic affinities of these structures are discussed.     

Pharyngeal and Gastrodermal Ultrastructure of Prorhynchus stagnalis Schultze, 1851 (Turbellaria,Lecithoepitheliata)

The digestive tract of a freshwater Lecithoepitheliata turbellarian, Prorhynchus stagnalis, has been studied at the ultrastructural level. The buccal tube connecting the mouth opening to the pharynx is lined by an insunk epithelium, and is provided with two kinds of secretory cells. The bulbous pharynx itself, typical of the genus, is a highly muscular organ, also lined internally by an insunk epithelium; it also bears at least two different types of gland cells. Externally the pharynx is enveloped by a thin, flat epithelium. The gastrodermis consists of phagocytes and Minotian gland cells, as typical for most Tricladida. No ciliary covering was observed along the whole digestive system; instead, phagocytic cells have long microvillar projections. Preliminary attempts to follow the digestive process using external markers and cytochemical reaction for acid phosphatase were successful in demonstrating endocytic activity in the phagocytes. These data, besides being a contribution to morphology and systematics, also speak in favour of the general digestive theory of Turbellaria proposed by Jennings and serve as a starting point for experimental studies on intracellular digestion within the Lecithoepitheliata.     

Functional Morphology of the Introvert and Digestive System of Myzostoma cirriferum (Myzostomida)

Myzostoma cirriferum feeds by diverting food particles carried by the ambulacral grooves of its comatulid host Antedon bifida. When searching for food, the myzostome uses its protrusible introvert to fulfil two major functions: sensory perception and the capture of food particles. The digestive system is composed of four parts, viz. a pharynx, that is contained within the introvert, a stomach, a series of paired caeca and an intestine that lie in the myzostome's trunk. The pharynx is supplied with a thick muscle which, thanks to peristaltic movements, carries food particles from the mouth to the stomach. Both stomach and caecal cells are able to absorb dissolved nutriments and to store lipids, whereas intestinal cells are only capable of absorption. Due to the beating of their cilia, stomach cells also carry food particles into the caecal lumen, where they are subjected to endocytosis and intracellular digestion by caecal cells. Undigested food fragments eventually gather in a very large, apical vacuole, and the cell apices containing vacuoles are eliminated into the caecal lumen by an apocrinal process. Detached cell apices reach the stomach, where they are embedded in a matrix, together forming a spindle-shaped faecal mass that is expelled through the postero-ventral anus. The observed digestive process—entailing the regular elimination of the apical part of the caecal digestive cells—appears to be unique among the Spiralia.     

Cytophotometric evidence for cell ‘transdifferentiation’ in planarian regeneration

Summary The role and fate of male germ cells in planarian regeneration was studied in a population ofDugesia lugubris s.1. which provided a suitable karyological marker to distinguish diploid male germ cells from triploid embryonic and somatic cells. The nuclear Feulgen-DNA content in non-replicating triploid muscle cells of the pharynx and in non-replicating male gonia of testes from intact animals were measured by the cytophotometric technique. The pharynx was then removed by transection and each anterior regenerant was allowed to completely regenerate this organ. Measurements of the Feulgen-DNA content in muscle cells of the regenerated pharynx showed that most of these cells (95%) have a DNA content typical of triploid cells; however, some muscle cells (5%) with a nuclear DNA content typical of male gonia alone were observed.These results were interpreted in the following way. After transection, young male germ cells move from the testes to the wound where they participate in blastema formation along with reserve and/or somatic dedifferentiated cells. During regeneration some of these cells of male origin differentiate into pharyngeal muscle cells. Our findings are discussed in relation to the occurrence of mataplasia in planarians.     

The pharynx of Caenorhabditis elegans.

The anatomy of the pharynx of Caenorhabditis elegans has been reconstructed from electron micrographs of serial sections. The pharynx is used for pumping food into the gut, and is composed of 34 muscle cells, 9 marginal cells, 9 epithelial cells, 5 gland cells and 20 neurones. Three regions of specialization in the cuticle lining of the pharyngeal lumen may aid in the accumulation of food particles. A basement membrane isolates the pharynx from the rest of the animal, making the pharyngeal nervous system a nearly self-contained unit which is composed primarily of five classes of motor neurones and six classes of interneurones. Three other classes have also been described, which by their morphology appear to be neurosecretory and motor, motor and interneuronal, and lastly one pair that only innervates three of the marginal cells. Some classes of neurone have free endings just under the cuticle lining the lumen of the pharynx, suggesting that these are mechano- or proprio-receptive endings. The connectivity of these neurones has been described at the level of individual synaptic regions, and after combining this information with video taped observations of the pharynx pumping, some interpretations of how these neurones function have been offered.     

Aspects of the ultrastructure of the alimentary canal and respiratory ducts in Xenopus laevis larvae

The pharynx, intestine and respiratory duct of Xenopus laevis were examined by light and electron microscopy, at different stages of the metamorphic cycle, through climax. It is well known that preclimactic larvae are suspension feeders and that after climax specimens feed on solid food. It is shown that the histology of the pharynx and the alimentary canal changes in adaptation to the change in the mode of feeding. Suspension feeding utilises ciliary activity but after climax cilia have disappeared from the pharynx and alimentary canal, when new neuromuscular mechanisms are utilised in feeding. Other morpho-histological changes in various intestinal and respiratory tissues are likewise considered in terms of functional activity.     

The Subchordal Cells of Oikopleura dioica and O. albicans (Appendicularia,Chordata)

Abstract Oikopleura dioica has two large subchordal cells which were studied in vivo and with light and electron microscopy. They have fixed positions within the haemocoel of the tail but change their morphology continually by protruding and withdrawing processes in an amoeboid manner. Also the fine structure varies considerably from one animal to the next. The cell surface sometimes indicates a strong pinocytotic activity with many coated pits and vesicles. In other cases there are many small vesicles which are interpreted as exocytotic. They are found both in the cytoplasm close to the plasma membrane and in the haemocoelic fluid. Subchordal cells with no pronounced surface activity have a large amount of rough endoplasmic reticulum, which suggests that they synthesize proteins. The presence of subchordal cells in the tail is correlated with the presence of the ontogenetically related bioluminescent oral gland cells in the pharynx; either both types exist simultaneously or both are lacking. It is speculated that the two cell types are also functionally co-ordinated. Oikopleura albicans has a multitude of tiny subchordal cells which have essentially the same fine structure as the two large Oikopleura dioica cells.     

Formation of malformed pharynx and neoplasia in the planarian Bdellocephala brunnea following treatment with a carcinogen

The effect of benzo(a)pyrene on regeneration of the pharynx in Bdellocephala brunnea Ijima et Kaburaki was studied by inserting a 5-µg crystal of this carcinogen into the pharyngeal cavity of worms from which the pharynx had been extirpated 2 d previously. Multiple pharynges formed in the regenerates, and neoplasia was induced in a few cases. The malformed pharynges appeared as protrusions overlapping the anterior part of the main pharynx. Electron microscopy of the pharynx in normal, intact worms shows eight layers comprising inner and outer ciliated epithelia, muscle, and glands.     

Planarian pharynx regeneration revealed by the expression of myosin heavy chain-A

The pharynx is a distinctive organ in the center of the body of planarians. Although the process of pharynx regeneration has been studied previously, the details and mechanism of the process remain controversial. We examined the process of regeneration of the pharynx in the planarian Dugesia japonica in detail by in situ hybridization and immunohistochemistry for myosin heavy chain-A (DjMHC-A), which is mainly expressed in the pharynx muscles and pharynx-anchoring muscles. We also monitored the behavior of the neoblasts in this process. In the regenerating posterior body fragment, the pharyngeal rudiment was formed by accumulation of cells that were probably undifferentiated cells derived from the neoblasts. The pharynx muscles appeared to differentiate in the rudiment in a manner that was coordinated with the differentiation of the pharynx-anchoring muscles in the region surrounding the rudiment. During this process, all cells containing mRNA for DjMHC-A also contained the DjMHC-A protein. These results argue against a previously proposed hypothesis that in the mesenchyme, 'pharynx-forming cells', which are committed to differentiate into the pharyngeal cells but have not yet differentiated, gather in the rudiment to form the pharynx (Agata and Watanabe, 1999). Rather, the present observations suggest that regeneration of the planarian pharynx proceeds by accumulation of cells that are probably undifferentiated cells derived from neoblasts in the rudiment, followed by their differentiation into the pharyngeal cells there.     

Observations on the gastric epithelium of ascidians with special reference to Styela clava

Summary Transmission electron microscopy shows the gastric epithelium of Styela clava to comprise at least three distinct cell types. Ciliated mucous cells which form the crest of each stomach ridge produce mucus by an unexpected route. Vacuolated cells lining the ridge sides appear to be absorptive in function. Gastric enzymes are produced by typical protein secreting cells scattered amongst the vacuolated cells. Undifferentiated cells are found in the crypts between ridges. The structure and function of the gastric epithelium in Styela is discussed with special reference to the wider concepts of ascidian gut organization.The author is grateful to Mrs. L. Rolph for technical help with scanning electron microscopy and Mr. J. Calvert and Mr. R. Jones for assistance with the transmission electron microscopy. Animals were collected through the kind offices of Mr. J. Sturges and other staff of the Admiralty Marine Trials Station, Portsmouth. This research was carried out during the tenure of SRC grant No. B/RG 82919 -The localization of polypeptide hormones in the pharynx and gut of Protochordates     

Structure of the Digestive Tube in the Holothurian Eupentacta fraudatrix (Holothuroidea: Dendrochirota)

In the holothurian Eupentacta fraudatrix,the gut wall exhibits trilaminar organization. It consists of an inner digestive epithelium, a middle layer of connective tissue, and an outer mesothelium (coelomic epithelium). The pharynx, esophagus, and stomach are lined with a cuticular epithelium composed of T-shaped cells. The lining epithelium of the intestine and cloaca lacks a cuticle and consists of columnar vesicular enterocytes. Mucocytes are also encountered in the digestive epithelium. The connective tissue layer is composed of a ground substance, which houses collagen fibers, amoebocytes, morula cells, and fibroblasts. The gut mesothelium is a pseudostratified epithelium, which is dominated by peritoneal and myoepithelial cells and also includes the perikarya and processes of the neurons of the hyponeural plexus and vacuolated cells.