Top: Cartoon depicting the reproductive system of a sexually mature Smed hermaphrodite. Ventral view. O: ovary. OD: oviduct. SD: sperm duct. P: penis papilla. G: gonopore. Genital atrium: purple region immediately posterior to the pharynx. Bottom: Brightfield image of a live Smed hermaphrodite. Anterior: right. Dorsal view. Scale bar: 100 µm. White asterisk: pharynx.
Sexually reproducing Smed are cross-fertilizing hermaphrodites that contain a pair of ovaries, situated immediately posterior to the brain and adjacent to the ventral nerve cords, and numerous testes located along the dorsolateral flanks of the animal. Oocytes are fertilized internally by sperm from a partner as they enter the oviducts. Smed embryos are ectolecithal: yolk is not contained within oocytes, but rather is produced by somatic vitellaria (yolk glands) arrayed ventrolaterally beneath the testes (Chong et al., 2011;Steiner et al., 2016;Stevens, 1904). One or more zygotes are packaged, along with yolk cells, into an egg capsule in the genital atrium (Chong et al., 2011;Hyman, 1951;Newmark et al., 2008;Stevens, 1904). Egg capsules are laid through the gonopore. Smed embryos gestate in egg capsules for approximately two weeks at 20˚C prior to hatching.
For more information on Smed hermaphrodite anatomy and gametogenesis, please visit the Newmark and Rouhana lab websites.
Brightfield image of a live Smed newborn hatchling (Stage 8, 14 days post-egg capsule deposition). Anterior: right. Dorsal view. Scale bar: 100 µm.
Smedflatworms are direct developers: newborn hatchlings grow and mature into adult worms without an intervening larval stage (Sánchez Alvarado, 2003). At hatching, juveniles are sexually immature but otherwise possess a body plan grossly similar to the adult hermaphrodite (Sánchez Alvarado, 2003; Wang et al., 2007).
Stage 2 embryo undergoing dispersed cleavage, stained with piwi-1 riboprobes (red, blastomeres) and antibodies raised against the mitotic epitope H3S10p (green). Nuclei: DAPI (blue). Yellow arrow: dividing blastomere.
Smedembryos undergo an evolutionarily divergent mode of development that bears little resemblance to the ancestral Spiralian cleavage programs utilized by many Lophotrochozoans. In contrast to the synchronous, oriented blastomere cleavage patterns of Spiralian embryos (Lambert, 2010), blastomeres in freshwater planarian embryos undergo dispersed cleavage among yolk cells: they divide asynchronously and are not in direct contact with one another (Bardeen, 1902; Cardona et al., 2005;Hallez, 1887;Ijima, 1884;Le Moigne, 1963;Metschnikoff, 1883;Vara et al., 2008).
Rich Media File 1: S3 embryo architecture. SPIM reconstructed S3 embryo costained with EF1a-like-1 (red) and sytox green nuclear counterstain. EF1a-like-1 is a pan-embryonic cell marker that stains primitive ectoderm cells, the temporary embryonic pharynx and undifferentiated blastomeres in the embryonic wall. EF1a-like-1 staining is absent from yolk cells in the embryonic wall and gut cavity.
Paraffin embedded S3 embryo sectioned and stained with hematoxylin and eosin (left) or piwi-1 riboprobes (blue) and eosin (pink, right). Black brackets denote embryonic wall. Yellow arrowhead: temporary embryonic pharynx. GC: yolk-filled gut cavity. Cyan arrows: piwi-1+ undifferentiated blastomeres. Scale bars: 100 µm. Inset (right): magnified view of a piwi-1+ cell. Inset scale bar: 25 µm.
piwi-1 is expressed in all undifferentiated blastomeres of S3 embryos. SPIM reconstructed S3 embryo costained with piwi-1 (red) and EF1a-like-1 (green). piwi-1 is expressed in all undifferentiated blastomeres in the embryonic wall (piwi-1+, EF1a-like-1+ cells). piwi-1 is not expressed in differentiated tissues marked by EF1a-like-1 alone, including the primitive ectoderm and temporary embryonic pharynx (green). Several fluorescent beads used for 3-dimensional reconstruction are visible (red).
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