First description of collar receptors in Temnocephalidae (Platyhelminthes)

Two species of Temnocephala (Platyhelminthes, Temnocephalida, Temnocephalidae), namely Temnocephala iheringi and Temnocephala haswelli, have collar receptors in the epidermis of the tentacles and general body surface, but not in the sucker region. These receptors were seen associated with clusters of 20–22 monociliary receptors. All collar receptors found in these temnocephalids bore six stereocilia. Other neoophoran platyhelminths have a constant number of eight stereocilia per collar receptor, the only exception being members of another family of Temnocephalida, the Didymorchidae, where collar receptor cells with five and six stereocilia have been recorded. Therefore, the presence of a lower number of stereocilia per collar receptor is likely to be an apomorphic trait of the Temnocephalida.     

ULTRASTRUCTURE OF SWARMERS IN THE LAMINARIALES (PHAEOPHYCEAE). II. SPERM1

The ultrastructure of sperm from 13 species in 11 genera of Laminariales collected in the northeast Pacific Ocean is unique in the brown algae. The sperm are elongate, and possess a nucleus, several mitochondria and two or three chloroplasts, but no eyespot. The anterior flagellum bears mastigonemes on the proximal half of its length; a distal “whiplash” portion lacks mastigonemes and is an extension of only the two central singlet microtubules of the axoneme. A peculiar feature of these sperm is the posterior flagellum, which is longer than the anterior flagellum and tapers distally as the doublet microtubules become singlets and decrease in number. This feature contrasts with the laminarialean zoospore, which possesses a short posterior flagellum with the usual “9 + 2” axoneme. The structure of these sperm differs from that reported for Chorda, the sperm of which resembles a primitive brown algal zoospore. The facts support the concept that Chorda is the most primitive member of the Laminariales.     

Ultrastructural Observations on the Spermatozoon,Oocyte and Fertilization Process in Gonapodasmius,a Gonochoristic Trematode (Trematoda: Digenea: Didymozoidae)

Observations were performed in the uterus of a female Gonapodasmius sp., a gonochoristic didymozoid Trematode. The oocyte is a round cell 6 μm in diameter, which shows a ‘nucleolus-like cytoplasmic body’ and cortical granules. The spermatozoon is filiform, mobile and about 50 μm long. There is no acrosome. The anterior tip of the spermatozoon contains two centrioles made up of singlets and cortical microtubules with associated glycocalyx. The centrioles are continued as two axonemes of the classical 9 + ‘1’ pattern of flatworms, accompanied by a mitochondrion and a short row of cortical longitudinal microtubules. It is the posterior part of the sperm cell which contains the nucleus. At the outset of fertilization, the anterior part of the spermatozoon coils around the oocyte and penetrates it by lateral fusion. The posterior region of the spermatozoon, with the nucleus, is the last part to enter the oocyte, after passing through a perforation in the forming eggshell. The whole spermatozoon thus penetrates the female cell.     

Microtubular system during spermiogenesis and in the spermatozoon of Convoluta saliens (platyhelminthes,acoela): Tubulin immunocytochemistry and electron microscopy

Spermiogenesis and the spermatozoon were studied in Convoluta saliens, an acoel platyhelminth, by transmission electron microscopy, labelling of nuclei and immunocytochemistry of tubulin with various antibodies. Spermiogenesis involves formation of a long spermatid shaft containing two axonemes. It is established that the nucleus, after a stage of elongation, does not migrate up to the distal extremity of the spermatid, and that the centriolar derivatives are located at the distal extremity of the shaft. This contrasts with the parasitic Platyhelminthes. The mature spermatozoon, 180 μm in length, comprises a nuclear region, 50 μm in length, and a cytoplasmic region, with a short region of overlap. The cytoplasmic region contains two lateral axonemes with a 9 + 2 pattern of microtubules, granules of two different sizes, and two rows of longitudinal microtubules in the center. Each row consists of 5–6 singlet microtubules, with links between them. Whereas the two axonemes are labelled by antibodies against alpha, acetylated‐alpha, and beta tubulin, the microtubule rows are labelled only by the anti‐beta‐tubulin antibody. This suggests that acetylation does not occur in this part of the cytoskeleton, and that the epitope recognized by the anti‐alpha‐tubulin antibody (DM1A) is different in these units. Mol. Reprod. Dev. 52:74–85, 1999. © 1999 Wiley‐Liss, Inc.     

Spermatozoon ultrastructure of Aponurus laguncula (Digenea: Lecithasteridae), a parasite of Aluterus monoceros (Pisces: Teleostei)

The mature spermatozoon of Aponurus laguncula, a parasite of the unicorn leatherjacket Aluterus monoceros, was studied by transmission electron microscopy. The spermatozoon possesses 2 axonemes of the 9 + “1” trepaxonematan pattern, attachment zones, a nucleus, a mitochondrion, external ornamentation of the plasma membrane and cortical microtubules. The major features are the presence of: 1) external ornamentation in the anterior part of the spermatozoon not associated with cortical microtubules; 2) one mitochondrion; and 3) cortical microtubules arranged as a single field in the ventral side. The maximum number of microtubules is in the nuclear region. The extremities of the axonemes are characterized by the disappearance of the central core and the presence of microtubule doublets or singlets. This study is the first undertaken with a member of the Lecithasteridae and exemplifies the sperm ultrastructure for the superfamily Hemiuroidea.     

Spermiogenesis in the Pycnogonid Pycnogonum littorale (Ström)

Abstract Spermatids in different stages of development are connected by intercellular bridges. Later the disappearance of these is correlated with sloughing off the residual cytoplasm. At the onset of spermiogenesis, chromatin is agglomerated at the periphery of the nucleus. Later this disperses and no chromatin condensation takes place. There is a steady reduction in the nucleus size. This is correlated with increase in the number of small vesicles and microtubules in the cytoplasm. Eventually the nucleus becomes very small, and is surrounded by a complex system of microtubules. Following spermiogenesis process the mitochondria lose their cristae and contain adielectronic material. The mature sperm is spindle-shaped, tapering at both ends. In both ends there are only microtubules present terminating freely in the cytoplasm. In its middle there are a number of rod-shaped mitochondria containing an electron dense material. The microtubules in the middle part of the sperm are arranged in a hexagonal pattern and in others in rows interspersed with single ones. The structure of Pycnogonum littorale sperm is highly modified, which may explain the special mode of fertilisation.     

Characteristics of the sperm tail of the velvet worm, Euperipatoides leuckarti (Onychophora)

The onychophoran sperm tail contains several kinds of microtubulcs; probably more than that of any other animal group. There are thus a peripheral manchette consisting of many tightly spaced microtubules, a ring of nine 'peripheral singlets' and a central axoneme of the classical 9 + 2 type (nine doublets and two central singlets). The protofilament organization of these various microtubules was examined and compared to the structure and mode of formation of the peripheral singlets with that of its analogues in other animal groups. The onychophoran peripheral singlets were found to differ in two respects from those in insects: they are formed from the manchette rather than from the axonemal doublets and their transient connection to the axoneme is to the A-subtubules of the doublet rather than to the B-subtubules. The manchette microtubules as well as the peripheral singlets consist of 13 protoh'laments. The manchette may serve a mechanical function (to strengthen the unusually thick sperm tail) hut the role of the peripheral singlets remains unknown.     

Ultrastructure of sperms in Acoela (Acoelomorpha) and its concordance with molecular systematics

Abstract. The sperms of the Acoela, a group of lower worms, are filiform cells with 2 flagella incorporated into the cell body. Their axonemes can variously have 9+2, 9+1, or 9+0 patterns of microtubules; and singlet microtubules in the cell body can be arranged in axial or cortical positions. An analysis of phylogenetic relationships of acoels based on molecular characters (18S rDNA sequence data) showed that these patterns of microtubules, where known, fell into discrete monophyletic groups. To test this hypothesis, we have expanded the database of sperm characters by examining the ultrastructure of a further 10 species representing 4 acoel families. As expected, the Convolutidae fell into 2 unrelated groups: “small‐bodied convolutids”(Convoluta pulchra, Praeconvoluta tigrina, Pseudaphanostoma smithrii) having 9+2 axonemes and cortical microtubules, and “large‐bodied convolutids” (including Wulguru cuspidata) having 9+0 axonemes and axial microtubules. Also, as expected, a member of the Mecynostomidae (Paedomecynostomum bruneum) has 9+1 axonemes and axial microtubules. Members of a family that appears intermediate by molecular characters, the Otocelididae, significantly have a variety of patterns: axonemes with both 9+2 and 9+0 patterns (Notocelis gullmarensis) or just 9+2 (the other species), and either axial (Philocelis brueggemanni), both axial and cortical (N. gullmarensis) microtubules, or microtubules that bend between axial and cortical positions along the length of the sperm (Otocelis sandara). Members of the Dakuidae (Daku woorimensis) also belong to this intermediate group, having 9+2 axonemes and axial microtubules, while in a fifth otocelidid (Stomatricha hochbergi), sperm characters are like those of the “large‐bodied convolutids” (9+0 axonemes and axial microtubules). Characters of sperm morphology generally support the molecular hypothesis of relationships and confirm a suspected polyphyly of the families Convolutidae, Otocelididae, and Actinoposthiidae.     

Spermatological characters in the diphyllobothriidean Schistocephalus solidus (Cestoda)

Levron, C., Yoneva, A. and Kalbe, M. 2011. Spermatological characters in the diphyllobothriidean Schistocephalus solidus (Cestoda). —Acta Zoologica (Stockholm) 00 : 1–8. The spermiogenesis and the mature spermatozoon of Schistocephalus solidus (Cestoda: Diphyllobothriidea) are described using transmission electron microscopy. Spermiogenesis in S. solidus begins with the formation in the spermatid of a differentiation zone surrounded by cortical microtubules and delimited by arching membranes. This conical area presents two centrioles associated with striated rootlets and a median cytoplasmic extension between them. The centrioles are separated by an intercentriolar body composed of three electron‐dense plates dividing four electron‐lucent plates. The centrioles give rise to two flagella that undergo a rotation and later fuse proximodistally with the median cytoplasmic expansion. The presence of an electron‐dense material in the distal part of the differentiation zone is observed in the early stage of spermiogenesis. This pattern corresponds to Type I spermiogenesis according to the classification proposed by Bâ and Marchand (Mémoires du Muséum National d’Histoire Naturelle 1995; 166 : 87). The mature spermatozoon of S. solidus presents the Type I pattern defined by Levron et al. (Biological Reviews 2010; 85 : 523). It consists of five regions that exhibit two axonemes, parallel cortical microtubules, nucleus and electron‐dense zones. The anterior tip of the spermatozoon possesses only a few singlets. The axonemes are of a 9 + ’1’ trepaxonematan pattern and do not reach the posterior extremity of the mature spermatozoon.     

The fine structure of the sperm bundles of the coccid,Aspidiotus perniciosus Cumst., and sperm movement

The mature sperm of A. perniciosus are organized into bundles, about 350 μm long by 9–10 μm wide. Each bundle contains 32 sperm enclosed by a common sheath. The sperm contains an elongated ‘central core’, representing nuclear material, surrounded by a spiral microtubular sheath and cytoplasm. The electron-dense nuclear material is localized in the more pointed half of the sperm. The spiral microtubular sheath is composed of 30— 100 microtubules (depending on the cross-sectional level), situated parallel to the longitudinal axis of the sperm. On the basis of this ultrastructural organization, the motility of the sperm and sperm bundle as a whole is discussed. The sperm of A. perniciosus provide strong evidence that the microtubules arranged asymmetrically represent the elements directly involved in sperm motility.     

Reproducing Singlets with an Inverted Oral Apparatus in Glaucoma scintillans (Ciliophora,Hymenostomatida)1

A fragment with only an abnormal oral apparatus (OA) was obtained by operation from a doublet of Glaucoma scintillans possessing one normal and one abnormal OA. This singlet could reproduce and produced a cell line. Singlets frequently possessed an inverted OA, whose antero-posterior axis was rotated 180°. This inversion of the OA has been perpetuated through a considerable number of generations. Oral replacement commonly occurred in singlets with an abnormal OA regardless of growth phases of a culture. The position of the contractile vacuole pore, the direction of curvature of ciliary rows surrounding the OA, and the organization of postoral ciliary rows were mirror-images of those of a normal singlet.     

The aflagellate spermatozoon of Diplozoon (Platyhelminthes: Monogenea: Polyopisthocotylea): a demonstrative case of relationship between sperm ultrastructure and biology of reproduction

Diplozoon is known to display an exceptional biology of reproduction: the hermaphroditic adults are permanently fused together and their genital ducts communicate. In contrast to all other polyopisthocotylean monogeneans in which the spermatozoa show an homogeneous biflagellate structure, the spermatozoon of Diplozoon is aflagellate. It is filiform, and composed of a cytoplasmic region and a nuclear region. The cytoplasmic region exhibits mitochondria, a well-developed smooth endoplasmic reticulum, and up to 450 longitudinal singlet microtubules. The microtubules show links between them; seen in cross section, they are arranged as rows or polygons. The spermatozoon nuclear region contains the nucleus surrounded by cortical longitudinal microtubules. The spermiogenesis shows no zone of differentiation, a typical structure found in all other parasitic Platyhelminthes. Diplozoon is the first case of aflagellate spermatozoon found in the parasitic Platyhelminthes. The atypical sperm structure is not linked with phylogeny, but is well correlated with the atypical biology of reproduction.     

Temnocephalan symbionts of the freshwater crayfish Cherax quadricarinatus from northern Australia

Four species of turbellarian temnocephalan symbionts (Platyhelminthes: Temnocephalida) are reported for the first time from the external surfaces of Cherax quadricarinatus, a freshwater crayfish from northern Australia. Three of these species — Temnocephala rouxii Merton, 1913, Notodactylus handschini (Baer, 1945), and Diceratocephala boschmai Baer, 1953 — are known previously from related crayfish in New Guinea. The newly discovered fourth species, Decadidymus gulosus n. gen., n. sp., has an unusual combination of characters linking it with both the Temnocephalidae and the Scutariellidae. Together the four species possess an array of characters that challenges current concepts of families in the order. D. boschmai has an almost completely ciliated epidermis, a feature otherwise unknown in the order.     

Sperm Storage in the Yellow Dung Fly Scathophaga stercoraria: Identifying the Sperm of Competing Males in Separate Female Spermathecae

We examined the effects of male and female behaviour and morphology on the process of sperm storage in the yellow dung fly Scathophaga (Scatophaga) stercoraria. The larger of two males was more successful in transferring sperm to females' spermathecae the greater the difference in weight to his smaller competitor, as expected from previous studies by other authors. Sperm length, which is not correlated to body size, affected sperm access to the spermathecae, the female storage organs; longer sperm were more likely to be found in the spermathecae. A female typically had a singlet spermatheca and two spermathecae arranged as a pair, a doublet. However, there was variation from this pattern, which influenced the pattern of sperm storage. We measured the proportion of sperm from two competing males in females' singlet and doublet spermathecae. When the larger male's sperm were longer than his competitor's, they were more often in a female's singlet when he was her first mate and equally likely to be in the singlet or doublet when he was her second mate. When the larger male's sperm were shorter than his competitor's, the pattern was more complicated, principally because his sperm were not as successful at entering the female's doublet when he was her second mate. Counts of sperm, made using the same experimental procedure, showed that these effects were due to greater numbers of sperm entering the females' doublets when the larger male mated second. Sperm length was thus the factor with the largest single influence on the pattern of sperm storage. However, our most important result is that it was the interactions between male and female characters that were significant. Males mostly determine the early, especially precopulatory, events and females strongly influence the later ones.     

Phylogenetic relationships of the Temnocephaloidea (Platyhelminthes)

Temnocephala novaezealandiae (family Temnocephalidae) and Troglocaridicola mrazeki and Scutariella georgica (family Scutariellidae) were studied by electron microscopy in an attempt to reveal characters that would indicate their phylogenetic relationship to other members of the Platyhelminthes. Ultrastructural features of the epidermis in these temnocephaloideans are like those of the neoophoran turbellarians. The epidermis is syncytial, is honeycombed by a multitude of gland necks whose secretions produce an epidermal surface film, and is underlaid by a thick basement membrane. Some cells in the parenchyma are compartmentalized by intrusive cell processes from neighboring parenchymal cells in a fashion similar to parenchymal structure in the Monogenea and Digenea. The spermatozoa have a pair of free 9+1 flagella and contain aligned dense bodies. The Temnocephaloidea is evidently derived from an early rhabdocoel-turbellarian-like ancestor.     

Bizarre flagellum of thrips spermatozoa (Thysanoptera,Insecta)

The flagellum of the thysanopteran spermatozoon has been examined by electron microscopy and computer-aided image analysis. The flagellum consists of 27 microtubular elements that probably are formed as outgrowths from three separate basal bodies. Nine of the elements are normal microtubular doublets that carry dynein arms and nine are doublets without dynein arms. The remaining nine elements are microtubular singlets that apparently bear dynein arms and have the same appearance as A-subtubules of microtubular doublets. The 27 elements are arranged in a fixed pattern that consists of nine groups, each of which begins with a microtubular singlet and ends with an arm-less microtubular doublet. Computer-aided image analysis has shown that the A-subtubules of the doublets and the microtubular singlets have lumens with very similar patterns. The sperm tail is known to have some motility; it generates fast waves running along its length. The amalgamated axonemes hence act as a functional flagellum. The thysanopteran sperm tail is the only type of flagellum known to us that consists of microtubules in a highly asymmetric array.     

ELECTRON MICROSCOPE STUDIES OF SPERMATOZOA OF RHYNCHOSCIARA SP : I. Disruption of Microtubules by Various Treatments

The flagellar complex of the unusual motile spermatozoon of the fungus gnat, Rhynchosciara sp, does not conform to the usual "9 + 2" filament pattern but rather consists of over 350 pairs of filaments (doublet microtubules) distributed in a spiral array. Experiments were designed to disrupt and extract flagellar microtubular components from spermatozoa of the fungus gnat. Pepsin, chymotrypsin, potassium iodide, urea, and heat were used to extract specific portions of microtubule walls Such experiments provide information on the composition of the wall and the existence of wall sites selectively sensitive to various treatments Results obtained include: (a) doublet microtubules are comprised at least in part of protein, and all subunits are probably not identical; (b) a portion of the B subfiber is apparently more sensitive to disruption than other portions of the doublet microtubule; and (c) the ac cessory singlet microtubules may be chemically different from the doublet microtubules     

The flagellar apparatus of Breviata anathema,a eukaryote without a clear supergroup affinity

Breviata anathema is an anaerobic amoeboid flagellate that does not branch within any established ‘supergroup’. Molecular phylogenies suggest affinities to Amoebozoa, Opisthokonta, or apusomonads. Here we describe its flagellar apparatus ultrastructure. Breviata has two basal bodies. The flagellated anterior basal body (AB) is associated with a fan of ～18 microtubules and a short singlet microtubular root. Three microtubular roots associate with the posterior basal body. One, the right root (RR), is initially a triplet that splits into two parts. The other two are singlets: the left root (LR), and the middle root (MR), which arises on the posterior side of the basal body. The MR, LR and smaller part of RR support the left ventral side of the cell, while the larger part of RR runs down the right. Outer dynein arms were not observed on the flagellar axoneme. The mitochondrion-like organelle sometimes contains some tubular cristae. The posterior flagellar apparatus resembles that of several eukaryotic lineages, particularly apusomonads, ancyromonads, excavates, and myxogastrid amoebozoans. This comparison suggests that the complex flagellar apparatus of myxogastrids is actually plesiomorphic within Amoebozoa. The widely distributed splitting right root and posterior singlet (MR in Breviata) may be plesiomorphies in many eukaryotic lineages, and thus could be features of the last eukaryotic common ancestor.     

Ultrastructural study of the male gamete of Glossobothrium sp. (Cestoda: Bothriocephalidea: Triaenophoridae) a parasite of Schedophilus velaini (Perciformes: Centrolophidae) in Senegal

This paper describes the ultrastructure of the male gamete of Glossobothrium sp. (Bothriocephalidea: Triaenophoridae). The mature spermatozoon of Glossobothrium sp. is filiform and possesses two axonemes, a single helicoidal crested body, a parallel nucleus, parallel cortical microtubules and granules of glycogen. In Glossobothrium sp. we describe for first time a 200-250 nm thick crest-like body in the Bothriocephalidean. The anterior part of the spermatozoon exhibits a ring of 27 electron-dense cortical microtubules encircling the first axoneme. This structure persists until the appearance of the second axoneme. When the ring of electron-dense cortical microtubules disappears, the spermatozoon exhibits two bundles of thin cortical microtubules. The posterior part of the spermatozoon contains the posterior extremity of the second axoneme, the posterior extremity of the nucleus and few cortical microtubules. Soon nucleus disappears and the axoneme is disorganized. Thus the posterior extremity of the spermatozoon of Glossobothrium sp. exhibits only singlets produced by the disorganization of the doublets of the second axoneme and few cortical microtubules. This type of posterior extremity of the mature spermatozoon has never been described previously in the Triaenophoridae.     

Ultrastructure of spermatogenesis and mature spermatozoa in the flatworm Prosthiostomum siphunculus (Polycladida,Cotylea)

This is the first study investigating spermatogenesis and spermatozoan ultrastructure in the polyclad flatworm Prosthiostomum siphunculus. The testes are numerous and scattered as follicles ventrally between the digestive ramifications. Each follicle contains the different stages of sperm differentiation. Spermatocytes and spermatids derive from a spermatogonium and the spermatids remain connected by intercellular bridges. Chromatoid bodies are present in the cytoplasm of spermatogonia up to spermatids. During early spermiogenesis, a differentiation zone appears in the distal part of spermatids. A ring of microtubules extends along the entire sperm shaft just beneath the cell membrane. An intercentriolar body is present and gives rise to two axonemes, each with a 9 + “1” micro‐tubular pattern. Development of the spermatid leads to cell elongation and formation of a filiform, mature spermatozoon with two free flagella and with cortical microtubules along the sperm shaft. The flagella exit the sperm shaft at different levels, a finding common for acotyleans, but so far unique for cotylean polyclads. The Golgi complex produces numerous electron‐dense bodies of two types and of different sizes. These bodies are located around a perinuclear row of mitochondria. The elongated nucleus extends almost along the entire sperm body. The nucleus is wide in the proximal part and becomes narrow going towards the distal end. Thread‐like chromatin mixed with electron‐dense intranuclear spindle‐shaped bodies are present throughout nucleus. The general sperm ultrastructure, the presence of intranuclear bodies and a second type of cytoplasmic electron‐dense bodies may provide characters useful for phylogenetic analysis.