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1. Ultrastructure of the extraordinary pedal gland in Asplanchna aff. herricki (Rotifera: Monogononta)

   https://doi.org/10.1002/jmor.21765  

   Hochberg, Rick; Wallace, Robert L; Walsh, Elizabeth J; Araújo, Thiago Q (August 2024, Journal of Morphology)

   Abstract Rotifers possess complex morphologies despite their microscopic size and simple appearance. Part of this complexity is hidden in the structure of their organs, which may be cellular or syncytial. Surprisingly, organs that are cellular in one taxon can be syncytial in another. Pedal glands are widespread across Rotifera and function in substrate attachment and/or egg brooding. These glands are normally absent inAsplanchna, which lack feet and toes that function as outlets for pedal glandular secretions in other rotifers. Here, we describe the ultrastructure of a pedal gland that is singular and syncytial inAsplanchnaaff.herricki, but is normally paired and cellular in all other rotifers.Asplanchnaaff.herrickihas a single large pedal gland that is active and secretory; it has a bipartite, binucleate, syncytial body and a cytosol filled with rough endoplasmic reticulum, Golgi, and several types of secretory vesicles. The most abundant vesicle type is large and contains a spherical electron‐dense secretion that appears to be produced through homotypic fusion of condensing vesicles produced by the Golgi. The vesicles appear to undergo a phase transition from condensed to decondensed along their pathway toward the gland lumen. Decondensation changes the contents to a mucin‐like matrix that is eventually exocytosed in a “kiss‐and‐run” fashion with the plasma membrane of the gland lumen. Exocytosed mucus enters the gland lumen and exits through an epithelial duct that is an extension of the syncytial integument. This results in mucus that extends from the rotifer as a long string as the animal swims through the water. The function of this mucus is unknown, but we speculate it may function in temporary attachment, prey capture, or floatation. 

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2. The retrocerebral organ (RCO) of Trichocerca similar with a review of the RCO in other Rotifera.

   HOCHBERG, Rick1·; WALSH, Elizabeth2; WALLACE, Robert3 (September 2022, The International Rotifer Symposium - R0TIFERA XVI September 5-9 2022, Zagreb, Croatia)

   The retrocerebral organ (RCO) of rotifers is hypothesized to be an exocrine gland that secretes mucus to the apical field of the corona. The secretions presumably aid in locomotion ofbenthic rotifers but may also function to help attach eggs to a surface. While the RCO is widely distributed across Rotifera, its ultrastructure is mostly unknown. Here, we use TEM to inspect the RCO of Trichocerca similis, a planktonic rotifer with an RCO that is composed of a subcerebral gland, a reservoir, and a single duct that traverses the cerebral ganglion. Results reveal the subcerebral gland to be binucleate and with a cytoplasm containing abundant mitochondria, rough endoplasmic reticulum, Golgi, and secretory granules. Electron-dense, immature secretion granules accumulate at the apical end of the gland and undergo homotypic fusion to create larger granules with mesh-like contents. Mature secretion granules combine into larger globule-shaped secretions that are exocytosed to the reservoir lumen, eventually taking on a long, spindle shape. During exocytosis, the secretions appear to lose their plasma membranes, probably through a membrane-recycling pathway. The secretions maintain their shapes in the reservoir because each is bound by electron-dense filaments that replace the plasma membrane. The secretions become tightly coiled within the reservoir prior to extrusion through an anterior duct. Secretion ultrastructure suggests they are likely to be hydrated glycoproteins. We also present a review of the RCOs across the Rotifera to compare what is known about their structure, functions, chemistries, and potential homologies. 

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3. On the ultrastructure of subitaneous eggshells of monogonont rotifers

   https://doi.org/10.1590/s1984-4689.v42.e25012  

   Araújo, Thiago Q; Vandyke, Joanna; Yang, Hui; Walsh, Elizabeth J; Wallace, Robert L; Hochberg, Rick (January 2025, Zoologia (Curitiba))

   ABSTRACT Eggshell characteristics can be important components of fitness, providing protection to the developing embryo against environmental stressors. Many invertebrates, however, produce multiple egg types as part of their reproductive strategies. In monogonont rotifers, for example, reproduction occurs via cyclical parthenogenesis-a process involving extended periods of asexual reproduction interrupted by brief phases of sexuality. Asexual reproduction yields diploid subitaneous (amictic) eggs or haploid eggs that develop into males, while sexual reproduction produces diploid diapausing (resting) eggs. To date, only the eggshells of diapausing eggs have received substantial ultrastructural investigation. Here, we examine the ultrastructure of subitaneous eggshells in monogonont rotifers across diverse taxa and lifestyles, using light and electron microscopy. Our results reveal considerable variation in eggshell thickness, layering, and staining properties among taxa. Generally, sessile rotifers exhibited thinner eggshells with fewer layers and limited morphological diversity, whereas species that brood or oviposit eggs on substrates had thicker, more layered shells with more complex staining profiles. These findings indicate that subitaneous eggshell ultrastructure is more diverse than previously recognized and may hold value for future ecological and evolutionary studies. 

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4. Multi-level analysis of reproduction in an Antarctic midge identifies female and male accessory gland products that are altered by larval stress and impact progeny viability

   https://doi.org/10.1038/s41598-020-76139-6  

   Finch, Geoffrey; Nandyal, Sonya; Perretta, Carlie; Davies, Benjamin; Rosendale, Andrew J.; Holmes, Christopher J.; Gantz, J. D.; Spacht, Drew E.; Bailey, Samuel T.; Chen, Xiaoting; et al (December 2020, Scientific Reports)

   null (Ed.)

   Abstract The Antarctic midge, Belgica antarctica , is a wingless, non-biting midge endemic to Antarctica. Larval development requires at least 2 years, but adults live only 2 weeks. The nonfeeding adults mate in swarms and females die shortly after oviposition. Eggs are suspended in a gel of unknown composition that is expressed from the female accessory gland. This project characterizes molecular mechanisms underlying reproduction in this midge by examining differential gene expression in whole males, females, and larvae, as well as in male and female accessory glands. Functional studies were used to assess the role of the gel encasing the eggs, as well as the impact of stress on reproductive biology. RNA-seq analyses revealed sex- and development-specific gene sets along with those associated with the accessory glands. Proteomic analyses were used to define the composition of the egg-containing gel, which is generated during multiple developmental stages and derived from both the accessory gland and other female organs. Functional studies indicate the gel provides a larval food source as well as a buffer for thermal and dehydration stress. All of these function are critical to juvenile survival. Larval dehydration stress directly reduces production of storage proteins and key accessory gland components, a feature that impacts adult reproductive success. Modeling reveals that bouts of dehydration may have a significant impact on population growth. This work lays a foundation for further examination of reproduction in midges and provides new information related to general reproduction in dipterans. A key aspect of this work is that reproduction and stress dynamics, currently understudied in polar organisms, are likely to prove critical in determining how climate change will alter their survivability. 

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5. Muscle-directed mechanosensory feedback activates egg-laying circuit activity and behavior in Caenorhabditis elegans

   https://doi.org/10.1016/j.cub.2023.05.008  

   Medrano, Emmanuel; Collins, Kevin M. (June 2023, Current Biology)

   Mechanosensory feedback of the internal reproductive state drives decisions about when and where to reproduce. For instance, stretch in the Drosophila reproductive tract produced by artificial distention or from accumulated eggs regulates the attraction to acetic acid to ensure optimal oviposition. How such mechanosensory feedback modulates neural circuits to coordinate reproductive behaviors is incompletely understood. We previously identified a stretch-dependent homeostat that regulates egg laying in Caenorhabditis elegans. Sterilized animals lacking eggs show reduced Ca2+ transient activity in the presynaptic HSN command motoneurons that drive egg-laying behavior, while animals forced to accumulate extra eggs show dramatically increased circuit activity that restores egg laying. Interestingly, genetic ablation or electrical silencing of the HSNs delays, but does not abolish, the onset of egg laying, with animals recovering vulval muscle Ca2+ transient activity upon egg accumulation. Using an acute gonad microinjection technique to mimic changes in pressure and stretch resulting from germline activity and egg accumulation, we find that injection rapidly stimulates Ca2+ activity in both neurons and muscles of the egg-laying circuit. Injection-induced vulval muscle Ca2+ activity requires L-type Ca2+ channels but is independent of presynaptic input. Conversely, injection-induced neural activity is disrupted in mutants lacking the vulval muscles, suggesting "bottom-up" feedback from muscles to neurons. Direct mechanical prodding activates the vulval muscles, suggesting that they are the proximal targets of the stretch-dependent stimulus. Our results show that egg-laying behavior in C. elegans is regulated by a stretch-dependent homeostat that scales postsynaptic muscle responses with egg accumulation in the uterus. 

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