Identification of the starting point for spermatogenesis resumption in the post-diapause development of the sweet potato hornworm, Agrius convolvuli L.

The resumption of spermatogenesis in post-diapause development was examined in the sweet potato hornworm (Agrius convolvuli) with in vivo bromodeoxyuridine (BrdU) incorporation experiments used to determine the starting point. Diapausing pupae were "overwintered" by chilling at 10 °C for over 4 months, after which they initiated post-diapause development by transferring the pupae to 25 °C with a 12-h light/12-h dark photoperiod. The testes of living, post-diapause pupae were injected with BrdU, which is incorporated into newly synthesized DNA strands. During the first 2 days after diapause termination, the nuclei of spermatogonia and spermatocytes failed to label with BrdU. However, on day 3 of post-diapause pupae (PDP3), labeling studies showed that cell proliferation was initiated by spermatogonia, but not by spermatocytes. In both hemolymph and testes, ecdysteroid concentrations rose gradually, reaching 0.3 µg/ml hemolymph at PDP3. These results led to the following three conclusions. The spermatogonial cell division is highly suppressed during diapause. After a long-term diapause, spermatogenesis resumes in the spermatogonia but not in the spermatocytes of diapause-terminated pupae. Cell division begins in advance of peak ecdysteroid concentrations. The latter result indicates that in post-diapause development, high concentrations of the hormone are not required to initiate spermatogonial proliferation.

Ultrastructure and function of long and short sperm in Cicadidae (Hemiptera).

The cicada, Graptopsaltria nigrofuscata, produces two distinct sizes of sperm, as determined by either nuclear volume of early spermatids or nuclear length of mature sperm. Between both sperm, there is no difference in location of the acrosome and flagellum during spermiogenesis. The acrosome is covered by an anteacrosomal bleb, which is inserted in a common mass, spermatodesm, derived from cyst cells. Both kinds of sperm linked to the spermatodesm form sperm bundles, respectively. During copulation, the sperm bundles are transported from the vesicula seminalis of the male to the bursa copulatrix of the female. Morphometric analyses of the nuclear length revealed that the two kinds of sperm reach the bursa copulatrix in the same condition as that found in the vesicula seminalis. Once transferred inside the latter, the sperm bundles disintegrated to individual sperm within a few hours, and the tail components, such as the axoneme and mitochondrial derivatives, become separated from each other over time. The tail completely splits from the sperm nucleus 24 h after copulation. Fertile sperm accumulate in the spermatheca, the final storage organ, where only long sperm survived for any length of time. Fertilized eggs examined by vital staining contain only sperm with long nuclei.

Characterization of outer arm dynein in sea anemone, Anthopleura midori.

Outer arm dynein was purified from sperm flagella of a sea anemone, Anthopleura midori, and its biochemical and biophysical properties were characterized. The dynein, obtained at a 20S ATPase peak by sucrose density gradient centrifugation, consisted of two heavy chains, three intermediate chains, and seven light chains. The specific ATPase activity of dynein was 1.3 micromol Pi/mg/min. Four polypeptides (296, 296, 225, and 206 kDa) were formed by UV cleavage at 365 nm of dynein in the presence of vanadate and ATP. In addition, negatively stained images of dynein molecules and the hook-shaped image of the outer arm of the flagella indicated that sea anemone outer arm dynein is two-headed. In contrast to protist dyneins, which are three-headed, outer arm dyneins of flagella and cilia in multicellular animals are two-headed molecules corresponding to the two heavy chains. Phylogenetic considerations were made concerning the diversity of outer arm dyneins.

Calcium-dependent bidirectional power stroke of the dynein arms in sea urchin sperm axonemes.

Active sliding between doublet microtubules of sea urchin sperm axonemes that were demembranated with Triton X-100 in the presence or absence of calcium was induced with ATP and elastase at various concentrations of Ca2+ to examine the effects of Ca2+ on the direction of the power stroke of the dynein arms. Dark-field light microscopy of microtubule sliding revealed that the sliding from the axonemes demembranated with Triton and millimolar calcium and disintegrated with ATP and elastase showed various patterns of sliding disintegration, including loops of doublet microtubules formed near the head or the basal body. These loops were often thicker than the remaining axonemal bundle. In contrast, only thinner loops were found from the axonemes demembranated with Triton in the absence of calcium and disintegrated with ATP and elastase at high Ca2+ concentrations. Electron microscopic examination of the direction of microtubule sliding showed that the doublet microtubules in the axonemes demembranated in the presence of millimolar calcium moved toward the base of the axonemes by the dynein arms on the adjacent doublet microtubule as well as by their own dynein arms. Doublet microtubules in the axonemes demembranated in the absence of calcium moved toward the base of the axonemes only by their own dynein arms. Similar observations have been obtained from the axonemes from which the outer dynein arms were selectively extracted. From these observations, we can conclude that the dynein arms generate force in both directions and this feature of the dynein arms arises from at least the inner dynein arms.