[
Proc. Helminthological Society of Washington,
1972]
Caenorhabditis avicola sp. n. is described from one male and three female nematodes from the intestine of a plumbeous water redstart, Rhyacornis fuliginosus (Passeriformes, Turdidae), from Taiwan. It is characterized by the extension of the anterior margins of the peloderan bursa into sharp points, giving the male posterior end an arrowheadlike shape in ventral view, and by the spicules, which are 95 u long. It is postulated that the worms were pseudoparasites, possibly symbionts of an insect ingested by the bird.
[
Parasitol Res,
2010]
Strongyloides stercoralis infection is caused by skin penetration of third-stage larvae (L3s). We studied skin penetration of L3s of Strongyloides ratti using an in vitro assay that has been used previously to study Angiostrongylus cantonensis, an agarose membrane with a temperature gradient, and scanning electron microscopy. Our results revealed that skin penetration of L3s depended on host skin temperature. When the target temperature of the outer liquid was 37C, more than 80% of L3s penetrated the skin, but penetration was only 60% when the target temperature was 20C. Thirdstage larvae moved rapidly on the agarose membrane toward optimum temperature area for this parasite, which indicates that L3 has a sensor that is sensitive to temperature changes. Penetration rate for hosts such as cat (36%), dog (32%), and bird (13%) were significantly lower than that for rat (82%). Although we could not establish the reason, L3s seemed to have an ability to differentiate these hosts at the time of penetration. By using scanning electron microscopy, penetration of L3s could be observed within 10 min. We demonstrated thermotaxis of L3 of S. ratti, and this peculiar characteristic seemed to have a close relationship with the process of searching for the host.
[
FEBS J,
2013]
Thymidine kinase 1 (TK1) provides a crucial precursor, deoxythymidine monophosphate, for nucleic acid synthesis, and the activity of TK1 increases by up to 200-fold during the S-phase of cell division in humans. An important part of the regulatory checkpoints is the ATP and enzyme concentration-dependent transition of TK1 from a dimer with low catalytic efficiency to a tetramer with high catalytic efficiency. This regulatory fine-tuning serves as an additional control to provide a balanced pool of nucleic acid precursors in the cell. We subcloned and over-expressed 10 different TK1s, originating from widely different organisms, and characterized their kinetic and oligomerization properties. Whilst bacteria, plants and Dictyostelium only exhibited dimeric TK1, we found that all animals had a tetrameric TK1. However, a clear ATP-dependent switch between dimer and tetramer was found only in higher vertebrates and was especially pronounced in mammalian and bird TK1s. We suggest that the dimer form is the original form and that the tetramer originated in the animal lineage after the split of Dictyostelium and the lineages leading to invertebrates and vertebrates. The efficient switching mechanism was probably first established in warm-blooded animals when they separated from the rest of the vertebrates.