Abstract
Matrotrophy and its most advanced mode—placentation—is a masterpiece of nature contributing to offspring fitness. It has been studied mainly in vertebrates, whereas so-called placental analogues in invertebrates are poorly known. Here we use an ultrastructural approach to report the first evidence of placentation in the ctenostome bryozoan Amathia verticillata. This marine colonial suspension-feeder incubates its progeny in the tentacle sheath, which is transformed into a brood chamber. When the fertilized egg is deposited into the brood cavity, the tentacle sheath wall, originally consisting of flattened epithelial cells, is modified into an embryophore (placental analogue) via cell multiplication and hypertrophy. The embryophore (nutritive) cells develop a massive secretory apparatus and acquire ‘microvillous’ apical membranes indicating the presence of exocytosis. In turn, the embryo surface cells also form a complex network of irregular projections and foldings. Coated pits beneath this network indicate active endocytosis. The developing embryo is adjacent to the embryophore and the narrow slit between them is filled with dense and flocculent (presumably nutritive) material. The embryo increases up to 24-fold in size indicating substantial matrotrophic provisioning. We compare the ultrastructural details of placentation in A. verticillata with those known in cheilostome bryozoans, and review the major structural principles of placentation in Bryozoa in general. We then discuss possible ways of nutrient transport to the embryophore in various bryozoan clades.
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Introduction
Extraembryonic nutrition (EEN) or matrotrophy is a continuous extra-vitelline provisioning of offspring during gestation. Various modes of EEN have evolved in both, vertebrates and invertebrates with placentation (placentotrophy) being structurally the most complex and one of the most effective modes (Blackburn 2015; Ostrovsky et al. 2016). Vertebrate placentas and their analogues in invertebrates involve an intimate direct apposition or fusion of embryonic tissues to the maternal ones providing/facilitating a bidirectional transfer of substances, nutrients and waste metabolites (Mossman 1937; Ostrovsky et al. 2016). Placentation is best known in mammals, reptiles, fishes and certain other chordates (e.g. salps) (Bauchot 1965; Wourms 1981; Bone et al. 1985; Blackburn 1999, 2005, 2015; Wooding and Burton 2008), but recently it was found to be rather common among invertebrates as well (Ostrovsky et al. 2016). Some placental analogues in Onychophora and Insecta resemble simple vertebrate placentae, representing striking examples of convergent evolution (Hagan 1951; Campiglia and Walker 1995).
Among aquatic invertebrates, Bryozoa has the widest within-phylum taxonomic distribution of placental analogues; these have evolved multiple times in various lineages (Ostrovsky et al. 2009a; Ostrovsky 2013a, b). This group of colonial suspension-feeders is classified into three clades: the non-calcified Phylactolaemata, which represent a small group of about 80 species living in freshwater, the exclusively marine, calcified Stenolaemata comprising approximately 600 recent species of the taxon Cyclostomata and the Gymnolaemata which constitute the largest part of over 5000 currently described species (Bock and Gordon 2013). The Gymnolaemata are further divided into the uncalcified paraphyletic ‘Ctenostomata’ and the calcified Cheilostomata. Only about 300 species of recent ctenostomes are described, whereas the bulk of the species diversity of gymnolaemates is cheilostomes. All studied phylactolaemates and cyclostomes are placental, and more than 130 placental species are known among various gymnolaemate taxa (reviewed in Ostrovsky 2013a; Ostrovsky et al. 2016).
Indications of placentotrophy include the development of temporary nourishing structure(s) formed by the parent (and sometimes the offspring) during incubation, and ultrastructural evidence of nutrient release and uptake accompanied by enlargement of the embryo. Cheilostome bryozoans are better studied in this respect because both anatomical and ultrastructural evidence of placentation has been obtained during the last 100 years for a number of species (reviewed in Ostrovsky 2013a). Placental analogues were studied only anatomically in phylactolaemates and cyclostomes (reviewed in Reed 1991; Mukai et al. 1997). In the case of Ctenostomata, evidence of matrotrophy and placental analogues is so far mostly based on the embryonic size increase recorded in nine species. Nonetheless, the significance of this has not been fully understood or simply ignored (e.g., Braem 1939; Silén 1944). Except for a short note published in Russian (Ostrovsky and Schwaha 2011), no anatomical or ultrastructural analysis of the respective structures and mechanisms is available for ctenostomes. To compare the latter situation with placentation in other matrotrophic bryozoans, we analyzed the extraembryonic nutrition in Amathia (Zoobotryon) verticillata, a cosmopolitan vesicularioidean ctenostome. Sexual reproduction and larval development of this species were previously studied in detail (Bogoiavlenskii 1905; Waters 1914; Zirpolo 1933), including a description and illustration of the embryo size increase during development. Moreover, Bogoiavlenskii suggested an extraembryonic nourishment. We confirm this suggestion here, review the distribution and evolution of matrotrophy among ctenostomes and comparatively analyze this phenomenon in other bryozoan clades.
Materials and methods
Reproducing colonies of Amathia verticillata (delle Chiaje 1822) (Ctenostomata, Vesicularioidea) carrying embryos of different developmental stages were collected by wading at the shore of Rovinj, Croatia, in July, 2010. The long, ‘spaghetti’-like colonies were cut into smaller pieces prior to fixation in 2.5% glutaraldehyde in 0.1 M sodium-cacodylate buffer containing 10% sucrose (pH = 7.4) for 1 h at room temperature. After fixation, the samples were rinsed three times in the buffer. Postfixation was conducted with 1% osmiumtetroxide for 1 h at room temperature. Specimens were then washed three times in the buffer prior to dehydration with acidified 2,2-dimethoxypropane or a graded acetone series. Dehydrated samples were embedded into Agar Low Viscosity Resin (Agar Scientific, Stansted, England) using acetone as intermedium. Cured resin blocks were concomitantly sectioned with a Reichert S-Cut or a Leica UC6 ultramicrotome (Leica Microsystems, Wetzlar, Germany) for semithin (1 µm) to ultrathin (60‒70 nm) sections. Semithin sections were collected on standard glass microscope slides, stained with toluidine blue, sealed with resin and then analyzed and photographed with a Nikon Eclipse E800 (Nikon, Tokyo, Japan) light microscope equipped with a Nikon DS-Fi2 U3 microscope camera. Ultrathin sections were collected on copper mesh-grids, stained with uranyl acetate for 40 min and afterwards with lead citrate for 5‒10 min. Stained sections were analyzed with a Zeiss EM902 (Zeiss, Oberkochen, Germany) transmission electron microscope equipped with a digital CCD camera. Images were enhanced with Adobe Photoshop CS5 (Adobe Systems Incorporated, 345 Park Avenue, San Jose, CA). We should admit that zooidal coelom is strongly reduced because of shrinkage and folding of the thin cystid wall during dehydration of fixed material and its preparation for embedding in plastic. This did not affect tissues or cell ultrastructure, however.
A total of 15 fertile zooids, with ovaries and brooded embryos, were sectioned for both light and transmission electron microscopy (TEM). Twenty embryos of various ages were measured in fixed colonies to find the smallest and the largest stages and to calculate the embryo size increase.
Results
Oogenesis, oviposition and brooding
Colonies of Amathia verticillata consist of ellipsoid and oval autozooids located in dense groups along thick cylindrical stolons (Figs. 1, 2). Swollen brooding zooids are larger than non-brooding ones (Figs. 1, 2a–c). Early oocytes (size 21.9‒23.1 × 43.9‒50.0 µm in our sections) were detected in pairs in the ovary, which is situated in the lower part of fertile zooids (Fig. 3a). Mature oocytes were not present in our material, but we found an aborted early embryo (gastrula-stage, 52 × 65 µm) surrounded by a fertilization envelope in a stolon (Fig. 3b). Judging from its appearance, the relatively small eggs are mesolecithal in this species.
Oogenesis is accompanied by partial degeneration of the polypide. Whereas the tentacle crown (Figs. 1, 3d), gut and retractor muscles degrade to a brown body (Figs. 1, 2a, b, d, 3a), the thin-walled tentacle sheath and the vestibular wall with its four apertural muscles persist (Figs. 1, 2a, b, d, 3d, e, h). After fertilization (presumably near ovulation) the oldest mature oocyte is transferred into the tentacle sheath which becomes a brood chamber that is isolated from the zooidal body cavity. The proximal side of the tentacle sheath, which contains the embryo, is now connected with a thick and short funicular cord going to the stolon to join its funicular system (Figs. 1, 2d and insert). The apertural muscles attached to the vestibular wall are probably important in larval release.
During incubation the embryo grows significantly and becomes a larva that occupies about half of the zooidal cavity (Fig. 2a–c). The tentacle sheath increases in size correspondingly. The smallest brooded embryo measured 71 × 100 µm. The largest larvae reached 233–246 µm in diameter. Thus, the embryonic enlargement was more than 24-fold.
Extraembryonic nourishment
Early stage
Further cleavages yield a hollow early embryo (Fig. 3c). The embryonic surface is closely adjoined to the tentacle sheath wall, which becomes a thickened, nourishing epithelium (embryophore). Originally small and flattened (3–4 µm thick in sections) (Fig. 3d), the cells of the tentacle sheath hypertrophy, becoming cuboidal (Fig. 3c, e), and obviously multiply since two cells constituted the embryophore width in some instances. The cell height varies within the same tentacle sheath up to two times reaching 8–11 µm. Each of these nutritive cells contains a large and active nucleus with a basal or central position. Also, histological sections reveal dark granules in their cytoplasm. The embryophore is underlined by a thin basal membrane (Fig. 3e) that separates it from the zooidal coelom (strongly reduced during preparation of the material for sectioning, see above). The epithelium of the body wall also possesses a basal membrane which is unusual for gymnolaemate bryozoans (Fig. 5c).
The ultrastructure of the nutritive cells shows an extensive synthetic machinery. The largest part is the rough endoplasmatic reticulum (RER), which fills most of the cytoplasm in some cells (Fig. 4a). Numerous free ribosomes are evenly distributed within the cytoplasm. We also detected large presumably protein platelets with electron-dense, homogeneous content, lipid droplets, abundant mitochondria, multivesicular-like bodies, Golgi complexes and rare autophagosomes in the cells (Fig. 4a and insert, c). Most of the apical membrane in the nutritive cells is covered by numerous projections and shallow infoldings that give it an irregular ‘microvillous’ appearance; this strongly increases the surface area towards the embryo (Fig. 4). Non-folded areas are rare. Small electron-lucent vesicles (sometimes in stacks) are present underneath the membrane; some of these fuse with the latter (Fig. 4d, e), suggesting exocytosis.
The embryo is surrounded by a thin fertilization envelope (Fig. 4b–e). The superficial cells of the embryo also form numerous projections and infoldings. These, however, are often much longer and deeper than those observed in the embryophore cells and sometimes even form three-dimensional labyrinths (Fig. 4b, e). In some instances, the deep folds/slits are formed parallel to the apical cell surface (Fig. 4c). Structures reminiscent of coated pits and a complex network of projections and infoldings suggest an active transport of nutrients. The cytoplasm of the superficial cells of the embryo contains abundant mitochondria and yolk granules (larger, electron-lucent proteinaceous platelets and smaller, electron-dense lipid droplets). Multivesicular-like bodies and cisterns of the RER are occasionally present. Ribosomes are abundant and mostly distributed non-evenly in the cytoplasm.
The narrow space between the embryophore and the embryonic cells is filled with massive flocculent or homogenous (supposedly, nutritive) material that is visible on both sides of the fertilization envelope, which therefore is apparently permeable for this substance (Fig. 4).
Mid-stage
Further embryonic development is accompanied by changes in the structure of the embryophore (Figs. 3f, 5). The nutritive cells thicken, become trapezoidal and extend to 14–14.5 µm height (Fig. 3f). Some cells show a clear polarity, with the RER situated in the basal part of the cell (Fig. 5c), whereas it is evenly distributed in the cytoplasm in others. Moreover, nuclei are present in the basal as well as central and apical part of the cells (Figs. 3f, 5c). The cytoplasm contains more than earlier electron-lucent proteinaceous platelets and various types of vacuoles or other inclusions with either homogeneous or heterogeneous content (Fig. 5a, c). Large multivesicular-like bodies were detected close to the cells’ apical membrane (Fig. 5b). Both the embryophore and the embryonic surface cells form projections and infoldings, which are more numerous in some areas and less in the others (Fig. 5a, b, d). Coated pits are present in the cells of the embryo (Fig. 5d). The narrow space between the embryophore and the embryo is filled with homogeneous material.
Late stage
During the continuous embryonic enlargement, the embryophore thickness decreases to 6–9 µm (Figs. 3g, h, 6a). Nonetheless, its cells still show a very high synthesis and transport activity. Their cytoplasm is filled with RER cisterns that are tightly packed and fill most of the cytoplasm (Fig. 6a, b). Numerous proteinaceous platelets and incidental lipid droplets are visible apically and basally. Numerous mitochondria and vesicles containing flocculent material are located underneath the apical cell membrane (Fig. 6b, d, f). Both smooth and folded apical membrane areas are visible in the nutritive cells. In addition, their membrane sometimes exhibits a fine microvillous appearance, either ‘chaotic’ or with a dense parallel packing of thin microvilli (Fig. 6d and insert). An important distinction is the presence of numerous autophagosomes in many embryophore cells (Fig. 6b). These cells sometimes overlap, giving the impression of two cell layers.
The space between the embryophore and the late embryo is mostly occupied by cilia of the late embryo (Figs. 3g, h, 6a, b) together with homogenous material that fills the space between the embryophore cells and the tips of the cilia (Fig. 6d, f). In its turn, the flocculent material fills the spaces between the cilia (Fig. 6c). The fertilization envelope is closely apposed to the embryophore. It is indiscernible in some areas, possibly destroyed. Numerous microvilli are developed between the bases of the cilia, with coated pits present between the bases of microvilli (Fig. 6c, e).
Discussion
Evidence of matrotrophy in Amathia verticillata
Our results demonstrate substantial matrotrophic nourishment in Amathia verticillata. All three lines of evidence—anatomical, ultrastructural and dimensional—support this conclusion. In general, the anatomical evidence of placentation involves the formation of temporary structure(s) (presumably providing gas exchange and nourishment) associated with the incubation chamber when it contains an embryo. After release of the offspring these structures degenerate, indicating that the incubation itself triggers their formation and persistence. In A. verticillata the strong hypertrophy and presumed multiplication of the tentacle sheath cells during incubation indicate their role as a placental analogue. Since the polypide degenerates in the brooding zooid and it can not feed itself, the transport of nutrients should be provided from the remaining colony via the elaborate funicular system characterizing Vesicularioidea (e.g., Bobin 1977). The funicular cord initially connects the gut of the functional polypide with colonial funicular strand in the stolon and thus supposedly transports nutrients to the colony. Upon polypide degeneration and oviposition to the tentacle sheath the cord becomes associated with the proximal side of the brood chamber (Bogoiavlenskii 1905; Zirpolo 1933). Here, the direction of transport should be reversed. It is also possible that the degenerating polypide (brown body) is a source of nutrients during oogenesis as well as brooding (see, e.g., Hastings 1932; Ostrovsky 2013a).
Importantly, Bogoiavlenskii (1905) was the first to suggest extraembryonic nutrition in A. verticillata. While some of his speculations were incorrect (e.g., he thought that the ‘embryonic sheath’ [embryophore] is developed from several funicular cells entering the tentacle sheath during oviposition), he correctly described many details of brooding including the multiplication of the embryophore cells and their transformation from cuboidal to flattened in the late stages of incubation. He also noted the appearance of granules in the funiculus (also mentioned by Waters 1914). Bogoiavlenskii suggested that the egg moves to the tentacle sheath when the gut of the degenerating polypide detaches from the tentacle sheath. Between the funicular and embryophore cells he described a ‘continuous homogeneous whitish mass’ that he thought to be the nutrients produced and delivered by the cells of the funiculus, absorbed by the cells of the ‘embryonic sheath’, and further released to the brood cavity (Bogoiavlenskii 1905, p. 12). Suggesting EEN, Bogoiavlenskii stressed, however, that the embryo is not attached to the embryophore wall and that there is no a placental contact as described for phylactolaemates.
The ultrastructural evidence includes the development of a massive secretory apparatus (including RER and Golgi complexes) in the embryophore cells, the formation of numerous projections and infoldings as well as microvilli-like outgrowth of the apical cell membrane and transport vesicles fusing with the latter. Together with the presence of homogenous and flocculent material in the space between the brood chamber wall and the embryo, these facts indicate an active production and release of nutrients via exocytosis. Note, however, that some of the vesicles were similar to coated pits, thus indicating endocytosis (of the embryo’s waste products), too. The surface cells of the embryos and larvae show a corresponding modification and exhibit a complex network of infoldings and microvilli together with the formation of coated pits. Similar trophic modifications were recorded in the studied cheilostome bryozoans (Woollacott and Zimmer 1975; Hughes 1987; Moosbrugger et al. 2012; Nekliudova et al. 2019). In contrast to A. verticillata, the thick cuticle of the body wall separates the embryophore cells from the brood cavity in the Cheilostomata. It is, however, permeable for nutrients.
The third line of evidence is a strong embryonic enlargement in A. verticillata as already described by earlier authors (Bogoiavlenskii 1905; Waters 1914; Zirpolo 1933). The substantial maternal provisioning normally results in a prominent growth/increase in embryo size. Although this evidence is indirect (in contrast to, e.g., the increase of dry weight, see Blackburn 2015; Ostrovsky et al. 2016 for discussion), the estimated 24-fold enlargement of the embryo and formation of the ‘solid’ larva in the studied species clearly indicate extraembryonic provisioning.
Our data on the early embryos found in histological sections and whole mounts differ to some extent, which could affect calculation of the embryonic enlargement during incubation. The diameter of the smallest brooded embryo we found in zooids was about 85 µm (see above) (which also corresponds to the size of the mature egg calculated from Table I, Fig. 1 of Bogoiavlenskii 1905). The early aborted embryo found in a stolon was smaller (about 60 µm in diameter). No strong decrease in egg size during fixation has ever been described in bryozoans (see, e.g., Ostrovsky 2013a), and the egg size variation could help to explain the above-mentioned difference. Since no mature eggs were detected in our material and early embryos were very rare, further research is required to clarify this situation.
Multiple origins of placentation among ctenostome bryozoans
Parental care in form of embryo incubation has evolved several times among ctenostome Gymnolaemata (Ostrovsky 2013a). The simplest is external brooding of multiple embryos in membranous brood sacs attached to the body wall of the fertile zooid, which in some species is accompanied by temporary withdrawal of the embryos (in case if they are attached to vestibular wall) to the vestibule during polypide retraction. The more advanced variant is an immersion of the developing embryos into the vestibular or cystid wall (reviewed by Ström 1977). The acquirement of brooding in an invagination of the body wall triggered the evolution of matrotrophy in some ctenostomes, which is indicated by embryo size increase and hypertorphy of the cells of the brood chamber wall (or both). Embryo enlargement was recorded in three species of the genus Nolella (Hincks 1880; Prouho 1892; Harmer 1915). Cell hypertrophy was additionally observed in the brood chamber wall in Sundanella sibogae (Braem 1939) and Labiostomella gisleni (Silén 1944) (although the ctenostome affinity of the latter species is disputable). Another type of incubation is brooding inside the tentacle sheath. Incubated embryos become larger in four species (including A. verticillata) from four different ctenostome clades (Joliet 1877; Bogoiavlenskii 1905; Pace 1906; Waters 1914; Zirpolo 1933; Banta 1968). A further incubation mode in a special outer embryo sac is known in certain boring ctenostomes. No EEN has been previously detected in this case, however (reviewed in Ström 1977; Ostrovsky 2013a).
Considering the differences in the incubation mode, reproductive patterns and the current position of matrotrophic ctenostomes on the phylogenetic tree (Todd 2000), extraembryonic nutrition could have evolved five times in this group. This needs to be confirmed based on newer molecular phylogenies. EEN has evolved at least 16 times among cheilostomes and once each in phylactolaemates and cyclostomes (Ostrovsky 2013a, b). Despite such diversity, the main principles of placental analogue organization are the same throughout Bryozoa. Incubated embryos are surrounded, totally or partially, by temporarily hypertrophied nourishing cells that form the embryophore. Incubation in internal brood sacs—as known in some matrotrophic Cheilostomata (Ostrovsky et al. 2009b) and in presumably all Phylactolaemata (e.g., Braem 1890, 1897, 1908; Marcus 1934; Mukai 1982)—is analogous to the ctenostome brooding in body wall invaginations or the tentacle sheath. In gymnolaemates, the ectodermal epithelium of the maternal cystid forms a chamber surrounding an embryo from all sides, and both ecto- and mesodermal cells form this sac in phylactolaemates. Similarly, developing embryos are embedded into the placental analogue in Cyclostomata, but embryogenesis is preparative in this viviparous group, and the placenta is mesodermal (e.g., Harmer 1893, 1896, 1898; Borg 1926). A similar situation is present in the viviparous cheilostome family Epistomiidae (Marcus 1941; Dyrynda 1981; Dyrynda and King 1982). Finally, in most matrotrophic cheilostomes embryos are incubated in external brood chambers (ovicells) (e.g., Harmer 1902, 1926; Marcus 1938; Corrêa 1948; Woollacott and Zimmer 1972, 1975; Dyrynda and King 1983; Hughes 1987; Santagata and Banta 1996; Ostrovsky 1998, 2013a, b; Ostrovsky et al. 2008, 2009a; Moosbrugger et al. 2012). The embryophore is associated with a so-called ooecial vesicle—a contractile outfolding of the maternal body wall that plugs the entrance to the brood cavity. In this case, the embryo is only partially surrounded by the placental analogue.
We stress here that the oviposited egg is often much smaller than the incubation cavity. Thus, the initial and the following stages of embryonic nourishment are supported not by placentotrophy, but histotrophy—absorption of the nutrients by the embryo from the surrounding fluid. The progressive enlargement of the offspring during its development results in total occupation of the brood cavity. This is accompanied by an opposition of the embryo surface to the embryophore, which is formally considered as placentation (Mossman 1937).
In Phylactolaemata, Cyclostomata and most matrotrophic ‘Ctenostomata’ the nutrients required for embryonic development are supposedly obtained by the placenta from the surrounding fluid of the maternal body cavity. In the placental Cheilostomata and A. verticillata they are obviously transported via a funicular system whose cord(s) are associated with the embryophore (Woollacott and Zimmer 1975; Moosbrugger et al. 2012; Nekliudova et al. 2019; our data). In cheilostomes, the nutritive cells of the embryophore at the advanced stage are mainly covered by funicular cells; their multiplication points to an intense transport.
Conclusion
The degree of matrotrophic provisioning varies strongly, ranging from negligible to high in different taxa. This presumably reflects an evolutionary trend towards a transition from incipient to substantial matrotrophy (Blackburn 2015). Among bryozoans such a variation is especially well documented within Cheilostomata (reviewed in Ostrovsky 2013a, b). The ctenostomes are strongly understudied in this respect, but in two species—Sundanella sibogae and Amathia verticillata (Braem 1939; our data)—morphological evidence clearly points to a very high level of maternal provisioning by well developed placental analogues.
The taxon-wide distribution of placentation among bryozoans is remarkable. In this respect these colonial filter-feeders are outnumbered only by chordates, platyhelminths and arthropods (Ostrovsky et al. 2016). Bryozoans are very diverse structurally and ecologically (McKinney and Jackson 1989; Ryland 2005), and they also exhibit a wide spectrum of reproductive patterns including larval planktotrophy, lecithotrophy, and matrotrophy (Reed 1991; Ostrovsky 2013a). The selective pressures that could explain the multiple origins of placentation are unknown, but placentation potentially could play an important role in the evolutionary success of the ancient taxon Cyclostomata. In this clade the origin of EEN presumably stimulated the acquisition of polyembryony and sexual zooidal polymorphism (Ostrovsky 2013b). Their evolution in the late Triassic was followed by a long-term increase in cyclostome diversity (Jablonski et al. 1997). The only cyclostomes without gonozooids are Cinctiporidae, but placentation is conceivable inside their very large autozooids (Schwaha et al. 2018). In the Gymnolaemata placentation is known mostly in species with ephemeral erect colonies/colony parts. A possible benefit of EEN is accelerated larval production because embryonic growth and development occur simultaneously in matrotrophic species (Ostrovsky et al. 2009a). This interpretation needs to be confirmed by analyzing a wider range of both cheilostomes and ctenostomes.
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Acknowledgements
Open access funding provided by University of Vienna. We thank the Department for Cell Imaging and Ultrastructure Research, University of Vienna, and especially Daniela Gruber, for the use of the electron microscope facility. Dr M. Stachowitsch, University of Vienna, revised an early draft of the manuscript and improved its English. Two anonymous reviewers greatly helped to revise the text.
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This study was funded by the Austrian Science Fund (grant P 22696-B17) (microscopy) and the Russian Science Foundation (grant 18-14-00086) (data processing and MS preparation).
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Schwaha, T., Moosbrugger, M., Walzl, M. et al. First ultrastructural evidence of placental nutrition in a ctenostome bryozoan: example of Amathia verticillata. Zoomorphology 138, 221–232 (2019). https://doi.org/10.1007/s00435-019-00438-4
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DOI: https://doi.org/10.1007/s00435-019-00438-4