Analysis of double-stranded RNA and virus-like particles in trichothecene-producing strains of<Emphasis Type="Italic">Fusarium graminearum</Emphasis>

Double-stranded RNAs (dsRNAs) have been found in two isolates of the plant pathogenic fungus Fusarium graminearum which produce trichothecene mycotoxins. The isolates 8.2 and 19.2 had dsRNAs in the size of about 2.0 kb and 6.0 kb, respectively, which were associated with capsid proteins and persisted within the cytoplasm of the infected host cells as encapsidated virus-like particles (VLPs). The dsRNAs contained in the VLP pellets were the same size as the dsRNA isolated in total nucleic acid preparations. In the VLP pellets the isolate 19.2 had a second dsRNA with the size of about 1.6 kb. After mycovirus purification one icosahedral particle of about 28 nm in diameter from the isolate 8.2 and two icosahedral particles of about 28 nm and 38 to 40 nm in diameter from the isolate 19.2 could be identified with electron microscopy. SDS-PAGE analysis of the VLPs from the isolate 8.2 revealed one major protein component of approximately 65 kDa, while the isolate 19.2 had two major protein bands at about 94 kDa and 105 kDa. Both isolates were studied for potential trichothecene production. Tox5 PCR showed a 658 bp fragment in each isolate. In addition, both strains were able to produce the trichothecenes deoxynivalenol (DON), the derivatives acetyl-DON (3-A-DON, 15-A-DON) and nivalenol (NIV) in vitro.     

Phylogenetic status of the family Naididae (Oligochaeta, Annelida) as inferred from DNA analyses

Phylogenetic analyses based upon the D3 domain of the nuclear 23S rRNA gene and part of the mitochondrial COI gene indicate that the family Naididae is a subordinate group within the family Tubificidae and most closely related to the subfamily Rhyacodrilinae. Based upon relative genetic distances we hypothesize that the origin of Naididae occurred relatively early in the evolution of Tubificidae, but this was a fairly late event compared to the basic radiation among Annelida.     

Effects of hydroxyurea during final neuronal DNA synthesis in dorsal root ganglia of rats

The sequence of final neuronal DNA synthesis was investigated in developing lumbar dorsal root ganglia of rats. Patterns of final division were compared to permanent neuronal deficiencies produced by single doses of hydroxyurea (HU), a specific cytotoxic inhibitor of DNA synthesis. The purpose was to discern increased susceptibility of terminal cell cycles in order to evaluate possible phenotypic or mitotic commitments responsible for cessation of DNA synthesis. The normal period of final DNA synthesis was found to occur primarily on gestation Days 12, 13, and early 14. Precursors of larger (A cells) and smaller (B cells) neurons are generated in sequence, suggesting the presence of phenotypic commitments during terminal division. When HU was administered during the period of final DNA synthesis, severe neuronal depletions and altered phenotypic proportions were observed postnatally. With HU on Day 13, total neuronal numbers were reduced by an average of 62% and deficiencies were confined primarily to neurons originating at or near the time of treatment. Given 12 hr later (Day 13.5), HU produced a 48% depletion involving neurons of smaller diameters. With treatment on Day 14, some ganglia appeared normal histologically but quantitation revealed an average 21% numerical deficiency involving the smallest neuronal phenotypes. Later treatments did not appear to affect ganglion morphology even though other defects (primarily growth retardation and gait abnormalities) continued to occur. Earlier treatments, given during terminal division of large neurons on Day 12, produced resorption or early postnatal death. The results suggest the emergence of phenotypic commitments in final cell cycles which restrict the probability of continued DNA synthesis and, thus, the probability of regeneration.