Process of cytoplasmic elimination during spermiogenesis in two cyprinodontidae (Teleostean fishes)

Ultrastructure evidence for vesicles and double-membrane structures involved in cytoplasmic elimination during spermiogenesis in large yellow croaker, Larimichthys crocea (Teleostei, Perciformes, Scienidae)

Spermatids eliminate excess cytoplasm to form streamlined sperm during spermiogenesis, which mechanism is insufficiently elucidated in fish. In this study, we investigated the cytoplasmic elimination procedure in spermatid during spermiogenesis in the large yellow croaker (Larimichthys crocea) using transmission electron microscopy. The early spermatid is subrotund with a centrally located nucleus. With further development, nucleus polarizes into one side of the cell while the cytoplasm with numerous vesicles near the membrane migrates to the caudal region. Furthermore, exocytosis-like structures were detected in middle spermatid. In late spermatid, the vesicles are reduced and rarely observed. These findings indicate that vesicles may be involved in cytoplasmic elimination possibly via exocytosis. In the later spermatid, a double-membrane, autophagosome-like structure envelopes the cytoplasm, which may develop into a single-membrane structure, and gets discarded from the cell as a residual body from the caudal region. This suggests its potential functions in the formation of residual body and cytoplasmic elimination. Overall, our results revealed that polarized development of spermatid causes polarized distribution of cytoplasm necessary for cytoplasmic elimination. Moreover, they provide ultrastructure evidence for vesicles and double-membrane structures involved in discarding spermatid cytoplasm in large yellow croaker, thus offering novel insights into cytoplasmic elimination during spermiogenesis in fish.

Process of cytoplasm elimination during spermiogenesis in Octopus tankahkeei: Polarized development of the spermatid and discarding of the residual body

The elimination of the spermatid cytoplasm during spermiogenesis enables the sperm to acquire a streamlined architecture, which allows for unhindered swimming. While this process has been well described in vertebrates, it has rarely been reported in invertebrates. In this study, we observed the process of cytoplasm elimination during spermiogenesis in Octopus tankahkeei (Mollusca, Cephalopoda) using light microscopy, transmission electron microscopy, and immunofluorescence. In the early spermatid, the cell is circular, and the nucleus is centrally located. With spermatid development, the cell becomes polarized. The nucleus gradually elongates and moves toward the end of the cell where the tail is forming. As a result, the cytoplasm moves past the nucleus at the anterior region of the future sperm head (the foreside of the acrosome). Following this, during the late stage of spermiogenesis, the cytoplasm condenses and collects on the foreside of the acrosome until finally the residual body is discarded from the top of the sperm head. This represents a distinct directionality for the development of cytoplasmic polarity and discarding of residual body compared with that reported for vertebrates (in which the cytoplasm of the elongating spermatids is polarized toward the caudal region). The fact that the cytoplasm also becomes concentrated suggests that water pumps may be involved in the elimination of water from the cytoplasm before the residual body is discarded. Furthermore, we found that microtubules, forming a manchette-like structure, are involved not only in reshaping of the nucleus but also in the transport of mitochondria and vesicles to the foreside of the acrosome, subsequently allowing them to be discarded with the residual body. This study broadens our understanding of the development of polarization and elimination of cytoplasm from spermatids in animals.

Continuous gametogenesis in the neotropical freshwater teleost, Bryconops affinis (Pisces:Characidae)

The gametogenesis of Bryconops affinis was studied by light, transmission and scanning electron microscopy. The spermatogenesis is semi-cystic and spermatids are released into the lumen of seminiferous tubules, where spermiogenesis is completed. Spermatozoa have an ovoid head, a rudimentary middle piece with a small number of mitochondria and long flagellum (primitive spermatozoa). The Sertoli and Leydig cells show secretory activity during spermatogenesis. By the end of this phenomenon, the Sertoli cells phagocytize the residual spermatozoa, while the Leydig cells show involuted characteristics. With regard to the oogenesis process, the oocyte development was divided into four stages based on the cytological characteristics of the oocyte and its surrounding layers. Ultrastructural analysis revealed that the zona pellucida is formed during the previtellogenic stage. Specializations associated to the outer layer of the zona pellucida may be related to the egg's adherence to the substrata.