Can exposure to neem oil affect the spermatogenesis of predator Ceraeochrysa claveri?

Novel biological control methods and integrated pest management strategies are basic requirements for the development of sustainable agriculture. As a result, there is a growing demand for research on the use of plant extracts and natural enemies such as the green lacewing, Ceraeochrysa claveri, as natural pest control methods. Studies have shown that although natural compounds such as neem oil (Azadirachta indica) are effective as pest control strategies, they also cause sublethal effects on nontarget insects, such as C. claveri. The aim of this study was to examine the effects of neem oil on C. claveri testes. C. claveri larvae were fed Diatraea saccharalis eggs, which were pretreated with 0.5%, 1%, and 2% neem oil. Testes were collected from larvae, pupae, and adults and analyzed using light and electron (transmission and scanning) microscopy. Changes in cellular stress and possible cell death were also determined by TUNEL assay and the marker HSP-70. The results showed that neem oil affects the organization and distribution of cysts in the testes and the normal sequence of cyst development, causing a delay in spermatogenesis in the testes of treated insects. Tests for cellular stress and DNA fragmentation indicated there was no cellular alteration in the treated groups. Although neem oil does not induce cell death or changes in HSP-70 expression, this biopesticide negatively impacts the process of spermatogenesis and could decrease the perpetuation of this species in the agroecosystem, indicating that the use of neem oil in association with green lacewings as a biological control should be carefully evaluated.

Authentication of the 31 species of toxic and potent Chinese Materia medica (T/PCMM) by microscopic technique, part 1: three kinds of toxic and potent animal CMM.

Microscopic authentication is an effective method for quality control of Chinese Materia Medica (CMM) because of its speed, convenience and low cost. However, the application of modern microscopic technique in quality evaluation of Toxic and Potent Chinese Materia Medica (T/PCMM) of animal origin is seldom reported. This gap in published knowledge is increasingly serious because confusion in T/PCMM has led to serious medical problems in China and other countries in recent years. To ensure the safe and effective use of T/PCMM, an accurate and convenient method, based on macroscopic and microscopic techniques, was developed for the authentication of animal T/PCMM. The color microscopic photos of the crude drug were acquired with the light microscope, and from these their morphological and microscopic characters were described. The present method was successfully applied in the analysis of 31 T/PCMM including 17 samples originating from plants, 3 from animals, 9 from minerals, and the remaining 2 from secreta. The macro- and microscopic characters of three animal T/PCMM, namely Mylabris (Mylabris phalerata or Mylabris cichorii), Huechys (Huechys sanguinea), and Lytta (Lytta caraganae) were conclusively determined and are here presented. The results demonstrated that it was feasible to use the present microscopic characters for the authentication of the above three animal T/PCMM.

Variable pressure and environmental scanning electron microscopy: imaging of biological samples.

The use of elevated gas pressures in the sample chamber of a scanning electron microscope (i.e., variable pressure SEM, or VPSEM) together with specialized electron detectors create imaging conditions that allow biological samples to be examined without any preparation. Specific operating conditions of elevated pressures combined with sample cooling (usually restricted to the environmental SEM range) can allow hydrated samples to be maintained in a pristine state for long periods of time. Dynamic processes also can be easily observed. A wider range of detector options and imaging parameters introduce greater complexity to the VPSEM operation than is present in routine SEM. The current instrumentation with field emission electron sources has nanometer-scale beam resolution (approx 1 nm) and low-voltage beam capability (0.1 kV). However, under the more extreme variable pressure conditions, useful biological sample information can be achieved by skilled operators at image resolutions to 2 to 4 nm and with primary electron beam voltages down to 1.0 kV. Imaging relating to electron charge behavior in some biological samples, generally referred to as charge contrast imaging, provides information unique to this VPSEM and environmental SEM that closely relates to luminescence imaged by confocal microscopy.

Development of embryonic membranes in the silverfish Lepisma saccharina linnaeus (insecta: Zygentoma, Lepismatidae).

Development and fate of embryonic membranes in the silverfish Lepisma saccharina was examined throughout embryogenesis. The amnioserosal folds first arise as serosal folds that are completed by the later addition of the amnion from the embryo's margins as in archaeognaths. The close link between production of the amnion and formation of the folds should not be assigned to Dicondylia but to Pterygota as an autapomorphy. During fold formation, folding of embryonic membranes beneath the embryo is less extensive and the ventral cupping of the embryo plays a larger role comparable to that occurring in archaeognath embryos. In L. saccharina, the embryonic membrane pore (the amniopore) varies in its manner of closure, either by complete fusion of serosal folds or by formation of a serosal cuticular plug between them as in archaeognaths. Although, in many aspects of its embryogenesis, L. saccharina retains the primitiveness of archaeognaths, its amnioserosal folds persist and are well integrated into its embryogenesis as the amnioserosal fold-amniotic cavity system is established and as occurs in many pterygote embryos; this may be thus regarded as an autapomorphy of Dicondylia.

[Study on the micro-identification of insect material medicine].

OBJECTIVE: To seek microstructure characters and method of insect material medicines. METHOD: Insect material medicines and Chinese patent medicines containing these medicines were observed and compared with OLYMPUS. RESULT: The texture of integumentary cells, the shape and size of hair socket and bristle were important characters for species identification. CONCLUSION: This method can effectively identify 8 insect medicines, which provides some data and foundation for Chinese patent medicines' identification containing insects medicines and making quality standard for new drugs.

Actin-myosin interactions visualized by the quick-freeze, deep-etch replica technique.

A new method of preparing biological samples for electron microscopy has been used to re-examine the structure of actin filaments, actin filaments decorated by myosin subfragment-1 (S1), and insect flight muscles. Samples were quick-frozen by contact with a block of copper cooled to approximately 4 K; then were freeze-fractured, deep-etched, rotary-replicated with platinum, and viewed in a transmission electron microscope. By this approach, actin filaments display prominent transverse bands whose repeat (approximately 5.5 nm) and pitch (approximately 15 to 20 degrees) fit with the expected left-handed "genetic" helix. Freeze-etched actin filaments do not, however, display the usual two-start helix as prominently as is seen after negative staining, and they also appear substantially thicker than after negative staining (9 to 10 nm versus 8 nm). The latter two-start helix appears very clearly after S1 decoration. Nevertheless, freeze-etched acto-S1 does not display the "arrowheads" that are seen after negative staining. Instead it displays the outer envelope of the helically deployed S1, and as would be expected from current models derived from optical reconstruction of negatively stained samples, this surface view looks only slightly polarized. Finally, the quick-freeze, deep-etch approach provides particularly distinct images of the crossbridges in insect flight muscles. These are plentiful and regularly arranged in rigor muscles, but rare in muscles relaxed with ATP before freezing. In rigor muscles fixed with aldehydes, these crossbridges assume a broad distribution of inclination, ranging from 45 degrees to 90 degrees with a mean of approximately 80 degrees, which is less tilt than has been seen before in thin-sectioned muscles. However, when aldehyde fixation is followed by exposure to tannic acid with or without uranyl acetate block-staining, crossbridges assume a more acute angle with respect to the fiber axis, centering around 45 degrees. This is associated with a commensurate reduction in interfilament spacing within the muscle fibers, such that tilted crossbridges are not any longer than untilted ones (both measuring approximately 15 nm). At the opposite extreme, crossbridges often become stretched in unfixed muscles, owing to an unnatural increase in interfilament spacing that occurs during sample preparation; in such regions, crossbridges display narrow "stalks", which invariably emerge from the thick filaments at close to 90 degrees. We conclude that crossbridge shape and orientation is strongly affected by different methods of sample preparation, and this will make it difficult to visualize natural crossbridge movements by electron microscopy.

The preparation, examination and analysis of frozen hydrated tissue sections by scanning transmission electron microscopy and x-ray microanalysis.

A method is reported for preparing, examining and analysing frozen hydrated tissue sections using transmission electron microscopy and X-ray microanalysis. Use of this method permits localization and measurement of water soluble or diffusible elements within the hydrated cell matrix. Since any change in total fresh weight of the specimen will affect the concentration of all components, great care has been taken to demonstrate that the mass neither increases nor decreases and to ensure that the tissue remains frozen-hydrated. Criteria for assessing whether or not the tissue remains frozen-hydrated are reported. After quench freezing, 1-2 mum thick sections of mouse liver were cut at 193 degrees K and picked up on a specially designed annular specimen holder covered with an aluminium coated nylon film. Using a transfer device which prevents contamination of the tissue sections while maintaining them at a low temperature (below 143 degrees K), the sections are transferred either to the vacuum evaporator cold stage or the scanning microscope cold stage. The tissue sections may be coated with an aluminium layer to improve electrical and thermal conductivity. The specimens are examined in the scanning transmission imaging mode and analysed using an energy dispersive X-ray analyser. Concentration of intra-nuclear and intra-cytoplasmic K, P, S and Cl are reported for mouse hepatocytes as ratios of the characteristic radiation to the continuum radiation used as a measure of mass. Ratios for all four elements were higher in the nucleus than the cytoplasm. Examples are given of this method as applied to plant and insect tissue.