Screening of Necrotizing Spiders in Korea Using Nonradioactive Sphingomyelinase Assay (I) Wandering Spiders

There are now more than 40,000 identified spider species in the world, and considered about 100 species as actually dangerous to human. Spider bites cause a range of symptoms from simple swellings to disfiguring necrotic lesions, and occasionally death. While spider bites are not a major medical problem in Korea, it would be of great value to know which species of spiders pose a threat to human health. A middle molecular weight protein, sphingomyelinase D, has been identified in the venom of the brown recluse spider and strong evidence suggests that they have a major role in spider bite necrosis. For the identification of necrotizing species, we have investigated using recently developed non‐radioactive assay of sphingomyelinase for rapidly screening the necrotizing venoms. Here, we demonstrate the fetal toxicity of total 57 species (32 genera, 9 families) of the wandering spiders among 622 identified spider species in Korea. It has been revealed that two species of the Thomisidae spider, Ozyptila nongae (0.2467) and Diaea subdola (0.2020) have the strongest sphingomyelinase activities among themselves. In addition one species of the family Pisauridae, Dolomedes sulfureus (0.2341) has also relatively higher value comparing to other wandering spiders. However comparing to that of the brown recluse spider, Loxosceles reclusa (1.814) in North America the necrotizing activities of these Korean wandering species are still very low state, so there seems to be little possibilities to create serious medical problems by the necrotizing arachnidism in Korean peninsula.     

Screening of Necrotizing Spiders in Korea Using Nonradioactive Sphingomyelinase Assay(II) Web-building Spiders

Spider bites cause a range of symptoms from simple swellings to disfiguring necrotic lesions, and occasionally death. While spider bites are not a major medical problem in Korea, it would be of great value to know which species of spiders pose a threat to human health. A middle molecular weight protein, sphingomyelinase D, has been identified in the venom of the brown recluse spider and strong evidence suggests that they have a major role in spider bite necrosis. For the identification of necrotizing species, we have investigated using recently developed non‐radioactive assay of sphingomyelinase for rapidly screening the necrotizing venoms. Here, we demonstrate the fetal toxicity of total 65 species (24 genera, 9 families) of the web‐building spiders among 622 identified spider species in Korea. It has been revealed that four species of the orb‐weaving spider, Araneus ventricosus (family Araneidae, 0.3509), Dipoena castrata (0.2413, family Theridiidae), Argiope minuta (0.1836, family Araneidae), and Paracoelotes spinivulva (0.1760, family Amaurobiidae) have relatively strong activities among themselves. However, comparing to that of the brown recluse spider, Loxosceles recluse (1.814) in North America, the necrotizing shpingomyelinase activities of these Korean web‐building spiders are still very low. Based on our results, we may thus conclude that there would be little possibilities in South Korea to create serious medical problems caused by necrotizing arachnidism.     

The evolution of parasite-defence grooming in ungulates

Grooming repertoires are exhibited by all terrestrial mammals, and removal of ectoparasites is an important ancestral and current function. Parasite‐defence grooming is regulated both by a central control mechanism (programmed grooming model) and by cutaneous stimulation from bites (stimulus‐driven model). To study the evolution of parasite‐defence grooming in ungulates, we compared species‐typical grooming behaviour with host morphology and habitat to test predictions of the programmed grooming model while taking into account phylogenetic relatedness. We observed grooming in 60 ungulate species at ectoparasite‐free zoological parks in which the confound of differential tick exposure was controlled for and stimulus‐driven grooming was ruled out. Concentrated‐changes tests indicated that sexually dimorphic grooming (in which breeding males groom less than females) has coevolved with sexual body size dimorphism, suggesting that intrasexual selection has favoured reduced grooming that enhances vigilance of males for oestrous females and rival males. Concentrated‐changes tests also revealed that the evolution of complex oral grooming (involving alternate use of both teeth and tongue) and adult allogrooming (whereby conspecifics oral groom body regions not accessible by self grooming) was concentrated in lineages inhabiting closed woodland or forest habitat associated with increased tick exposure, with such advanced grooming being most concentrated in Cervidae. Regression analyses of independent contrasts indicated that both host body size and habitat play a role in the evolution of species‐typical oral grooming rates, as previously reported. These results indicate that the observed grooming represents centrally driven grooming patterns favoured by natural selection in each lineage. This is the first phylogenetically controlled comparative study to report the evolution of parasite‐defence grooming behaviours in response to selection pressures predicted by the programmed grooming hypothesis. © 2004 The Linnean Society of London, Biological Journal of the Linnean Society, 2004, 81 , 17–37.     

Crocodilians and Their Helminth Parasites: Macroevolutionary Considerations

Crocodilian relationships supported by the phylogenetic relationshipsof digenean and nematode parasites are compared with currentestimates of crocodilian phylogeny. The parasite data support(1) the placement of Gavialis as the sister-group of the alligatoridsand the crocodylids, (2) the monophyly of alligators and caimans,(3) the placement of Caiman (as a monophyletic group) as thesister-group of Melanosuchus plus Paleosuchus, and (4) ancientorigins of Crocodylus consistent with patterns of continentaldrift. The parasite data do not support the monophyly of Crocodylus,but the "misplaced" species (C. palustris and Osteolaemus) havehad few parasites reported from them. There is evidence of widespreadhost-switching, but most of the ambiguity appears to resultfrom uneven representation of parasite groups in host species.This is probably due both to uneven sampling by parasitologistsand to parasite extinctions associated with crocodilian extinctions.     

Fate of Maturation Protein during Infection by Coliphage MS2

RNA coliphages contain two species of protein: coat protein, the major structural component; and maturation protein, which is probably present in only one copy per virion^1–3. The precise function of maturation protein is uncertain, but it is required for phage adsorption to F-pili of the E. coli host⁴ and for reconstitution of infectious phage⁵. In infected cells, newly synthesized maturation protein is found associated with viral RNA⁶, suggesting that an RNA-maturation protein complex may be present in virus particles.     

Regulation of mRNA Utilization and Degradation by Amino-acid Starvation

Amino-acid starvation of a stringent strain of E. coli relieves the polar effect on distal messenger RNA imposed by a nonsense mutation. There is no relief of polarity starvation of a relaxed strain. In fact, starvation of a relaxed (but not of a stringent) strain by itself causes an artificial polar effect on distal mRNA. These findings are consistent with a mechanism for polarity based on mRNA degradation.     

Structure of Hypotrichomonas acosta (Moskowitz) (Monocercomonadidae,Trichomonadida) as Revealed by Electron Microscopy*

SYNOPSIS. The fine structure of Hypotrichomonas acosta resembles in many respects that of Trichomonadidae, and especially of members of the sub-family Trichomonadinae which have been examined to date by electron microscopy. In addition, the flagellate has certain ultrastructural differences from the latter organisms, some of which are of phylogenetic significance. Among these, the structure of the undulating membrane and the apparently occasional presence of a fine filament which may be considered as homologous to the costa of Trichomonadidae are the most important. The undulating membrane is represented by a rather low and otherwise poorly developed dorsal cytoplasmic fold with an ill-defined distal marginal lamella; the recurrent flagellum is applied near the dorsum of the fold. In a very few preparations a relatively short filament, of a diameter falling below the resolution limits of light microscope, is seen in a position which corresponds to that of the costa of Trichomonadidae. The identity of the filament as a probable rudimentary costa is supported also by the character of its periodicity. The rare appearance of the rudimentary costa among hundreds of sections may be explained either by its minute dimensions or by its absence from many hypotrichomonads. Other structures recorded for the first time in trichomonads are: the fine filamentous connections of the axostylar microtubules; the branching of parabasal filament 2; and the unusually organized, perhaps helical, polysomes, which are found in addition to the ribosomal complexes associated with the endoplasmic reticulum and commonly found in trichomonads. A detailed analysis of interconnections among various mastigont structures is presented and several kinds of cytoplasmic inclusions are described. H. acosta is of interest in the study of the nuclear envelope and presence of nuclear pores, which are numerous and conspicuous in this flagellate. The fine structure of the hypotrichomonad is discussed in relation to that of other trichomonads and in some instances to that of other protozoa.     

Degradation of Poliovirus Polypeptides <Emphasis Type="Italic">in vivo</Emphasis>

CELLS infected with attenuated type 1 poliovirus (LSc) at 39° C synthesize only 20% of the viral proteins produced at 35° C. Polyacrylamide gel electrophoresis of viral peptides shows that only four peptides (with molecular weights of 230,000, 212,000, 196,000 and 160,000) are produced at the restrictive temperature¹. It was suggested that the last three are cleavage products of the 230,000 molecular weight peptide. Furthermore, since smaller peptides were never observed it was suggested that proteolysis might eliminate them from infected cells at 39° C. Nonsense and deletion mutations cause degradation of incomplete peptides of β-galactosidase² and the lac repressor³. We have studied whether there is significant proteolysis of the peptides of attenuated poliovirus in vivo at 39° C. There is extensive degradation of viral peptides at the restrictive temperature and essentially no degradation at the permissive temperature. The peptides of wild type virulent virus are not degraded at either 35° C or 39° C.