Shooting of sporidium by “gun” cells in Haptoglossa heterospora and H. zoospora and secondary zoospore formation in H. zoospora

Haptoglossa spp. (Lagenidiales, Oomycetes) have been known to parasitize microscopic animals by means of a “gun” cell that shoots an infection cell, named the sporidium, into the body of the animal. A thallus grown from the sporidium changes into a zoosporangium at maturation to produce a number of zoospores that encyst after a swarming period, and the resulting cysts germinate to produce gun cells. In Haptoglossa zoospora, endoparasitic in nematodes, the cysts of primary zoospores that swam for about 5min did not develop gun cells but produced secondary zoospores that swam for about 3h. After encystment of the secondary zoospores, each secondary cyst germinated to produce a gun cell. In the present study, the secondary zoospores of the genus Haptoglossa could be recorded with a videocassette recorder for the first time. The videocassette recording also revealed the infection of a nematodes by H. zoospora and H. heterospora to be composed of two steps of injection of a sporidium by the gun cell, in which the gun cell came in contact with the cuticle of a nematode and produced a spherical adhesorium on the tip of the cell in 0.07–0.1 s in both species. The adhesorium was ~2 μm in H. zoospora and ~4 μm in H. heterospora. When the adhesorium inflated to full size, it shot the sporidium into the nematode's body in 0.5–0.65 s and in 0.2–0.5 (or rarely 1.0) s in H. zoospora and H. heterospora, respectively. After shooting, the empty gun cell with an empty cyst case was separated from the cuticle immediately in both species.     

Chemical constituents from Dendropanax morbiferus H. Lév. Stems and leaves and their chemotaxonomic significance

The phytochemical investigation of Dendropanax morbiferus H. Lév. Led to the isolation of 28 known compounds: 4 alkaloids (1–4), 1 pyranoglucoside (5), 1 benzoic acid and 5 benzoic acid derivatives (6–11), 10 phenylpropanoids (12–21), 4 flavone glucoside derivatives (22–25), 1 neolignan (26) and 2 sesquiterpenes (27–28). The structures of these compounds were identified using spectroscopic methods; their nuclear magnetic resonance spectra were compared with those previously reported. This is the first report on compounds 2–4, 10, and 12 isolated from D. morbiferus. Compounds 5 and 26 from the genus Dendropanax and 1, 6–9, 11, 13, 14–25, 27 and 28 from the family Araliaceae were isolated for the first time. Additionally, to the best of our knowledge, this is the first comprehensive chemical investigation of D. morbiferus stems and leaf compounds. Chemotaxonomic relationship between D. morbiferus and other Dendropanax species is also discussed.     

History of Ichnology: The Origins of Trace Fossil Taxonomy and the Contributions of Joseph F. James and Walter H. Häntzschel

The taxonomy of trace fossils has had a somewhat controversial history because they do not represent the actual animal remains but rather their work on and in the substrate. As such, traditional palaeontologists and zoologists have viewed them with some skepticism. Ichnologists owe a great debt to two geologists: Joseph F. James of Cincinnati and Walter H. Häntzschel of Hamburg, who took it upon themselves to impose some order on the chaos that constituted trace fossil taxonomy at the time. James, working independently and in ignorance of Alfred Nathorst, arrived at and utilized many of the same criteria his Swedish counterpart employed to criticize the fucoid origins of many trace fossils in the late 19th century. With his restudy of the systematics of Fucoides, Skolithos, and Arthrophycus, James brought to light many of the taxonomical nightmares that faced—and are still facing—the fledging science and can be rightfully considered the first trace fossil taxonomist. During the 1940s and 1950s, Häntzschel collected the widely scattered pertinent data from the literature, an immense task that, when published in 1962 (and later revised and expanded in 1975), made trace fossils accessible to further research and started a worldwide boom in trace fossil research.     

Solomon H.Snyder

Snyder博士现任美国巴尔的摩市约翰·霍布金斯大学神经科学系主任,他在有关突触机制的研究中做出不少的贡献,其中最负盛名的就是神经递质和药物受体分子生物学特征方面的研究。1973年他与学生一道