Retardation of testis development in the armyworm,Pseudaletia separata,parasitized by the braconid wasp,Cotesia kariyai

Summary

In order to complete growth and development, the endoparasitoid wasp, Cotesia (=Apanteles) kariyai, inhibits pupation of its armyworm host, Pseudaletia (=Leucania) separata. In host larvae retardation of testis and spermatocyst development caused by the parasitoid was also observed. The agents causing the retardation were found in the ovaries and venom of the female adult parasitoid. When an unparasitized male host larva was artificially injected with calyx fluid obtained from ovaries together with venom, it showed the same degree of developmental retardation of testes and spermatocysts as in natural parasitization. Testes implanted in isolated abdomens of healthy larvae did not increase in size by ecdysteroid stimulation after exposure to calyx fluid plus venom. It is suggested that both symbiotic polydnavirus existing in calyx fluid and venom in the parasitoid, C. kariyai, are responsible for the parasitic retardation of the male reproductive organs in the host, P. separata.     

Testis differentiation in the glowworm, Lampyris noctiluca, with special reference to the apical tissue.

The gonads of Lampyris noctiluca are sexually undifferentiated during the first larval instars. They consist of many gonadal follicles that include the germ stem cells enclosed by the somatic cells of the follicle wall. Follicle wall cells are more numerous at the follicle apices than at the distal parts, but different cell types cannot be distinguished. In male larvae, the appearance of apical follicle tissue, derived from follicle wall cells, marks the onset of testis differentiation. When maximally expressed, the apical tissue occupies about the upper half of the testis follicles and can be observed in larvae of the fifth and sixth instar. The apical tissue is characterized by its "light" appearance (due to poor stainability) caused by the small number cellular organelles, especially a paucity of free ribosomes. Maximal expression of the apical tissue must be very brief, since in most examined fifth and sixth instar larvae the apical tissue is partly or mostly translocated into the center of the upper half of the follicles and spermatogonia then occupy the apical follicle tips. During and after translocation apical cells form projections that grow around clusters of spermatogonia (spermatocysts). Thus, the apical cells transform into spermatocyst envelope cells. They retain their "light" appearance but undergo dramatic subcellular differentiation: smooth ER becomes extremely prominent, forming stacks and whorls of parallel cisternae. Golgi complexes are also conspicuous. The cellular organization suggests secretory activity. The possibility of ecdysteroid production and its function is discussed. The spermatocyst envelope cells persist into the pupal stage. When spermiohistogenesis takes place in cysts, cyst envelope cells show signs of regression. At all stages of testis development apical cells and their derivatives, the spermatocyst envelope cells, phagocytize degenerating spermatogonia. Although this is an important task of these cells, the impressive formation of sER in the cyst envelope cells is indicative of an additional, as yet unknown, function.     

In Vitro Spermatogenesis in Lepidopteran Larvae: Role of the Testis Sheath

Summary

Premeiotic spermatocysts from testes of Heliothis virescens larvae were cultured in vitro. These eupyrene cysts progressed through meiosis and elongation in a medium containing calf serum in the absence of ecdysteroids. However, they also required the presence of the testis sheaths. The spermatogenesis-promoting effect of testis sheaths was dose dependent and varied with the donor's age. The active material was extractable from the tissue and was heat stable.     

Structure of the testis and spermatogenesis of the viviparous teleost Poecilia mexicana (Poeciliidae) from an active sulfur spring cave in Southern Mexico

We describe the histological characteristics of the testis and spermatogenesis of the cave molly Poecilia mexicana, a viviparous teleost inhabiting a sulfur spring cave, Cueva del Azufre, in Tabasco, Southern Mexico. P. mexicana has elongate spermatogonial restricted testes with spermatogonia arranged in the testicular periphery. Germ cell development occurs within spermatocysts. As spermatogenesis proceeds, the spermatocysts move longitudinally from the periphery of the testis to the efferent duct system, where mature spermatozoa are released. The efferent duct system consists of short efferent duct branches connected to a main efferent duct, opened into the genital pore. Spermatogenesis consisted of the following stages: spermatogonia (A and B), spermatocytes (primary and secondary), spermatids, and spermatozoa. The spermatozoa are situated within spermatocysts, with their heads oriented toward the periphery and flagella toward the center. Once in the efferent duct system, mature spermatozoa are packaged as unencapsulated sperm bundles, that is, spermatozeugmata. We suggest that the histological characteristics of the testis and spermatogenesis of P. mexicana from the Cueva del Azufre, and the viviparous condition where the spermatozoa enter in the female without been in the water, have allowed them to invade sulfurous and/or subterranean environments in Southern Mexico, without requiring complex morphofunctional changes in the testis or the spermatogenetic process.