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Microsc Res Tech,
2012]
Adenosine 5'-triphosphate (ATP) is the major energy currency and is involved in many biological processes. The ATP-monitoring system for cells in animals can be helpful to study the relationship between energy metabolism and biological processes. The fluorescent ATP biosensor ATeam (ATP indicator based on Epsilon subunit for Analytical Measurements), which has been reported to monitor ATP levels in cultured cells on the basis of fluorescence resonance energy transfer (FRET), was introduced into nematodes by microinjection and UV-irradiation method. To confirm whether ATeam functions as an ATP sensor in nematode cells, the authors measured FRET of ATeam in cells of transgenic nematode. The ATeam was expressed in target cells in nematode. In vulva cells, ATP levels in the cytosol were higher than those in mitochondria. ATeam also sensed ATP level change in cultured cells from the transgenic nematode. These experiments indicated that ATeam is available for detection of changes in ATP levels in nematode cells.
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Aging Cell,
2002]
The reviews by Braechman et al. and Van Voorhies in this issue of Aging Cell concur on the potential importance of metabolic rate and function to longevity in C. elegans. These reviews differ though, on their assessment of whether long-lived C. elegans mutants have a reduced metabolic rate compared to wild-type worms. At the centre of this disagreement are two main issues: the importance of measurement conditions when conducting metabolic assays on C. elegans, and which techniques are appropriate for measuring the metabolic rate of an organism and subsequent analysis of such data. These issues are interconnected; if the conditions under which an organism's metabolic rate are measured have a large impact on the resulting data, conclusions drawn from data collected from animals under different conditions may be invalid irrespective of the validity of the measurement methods. Conversely, measurement techniques which produce spurious data cannot be used to draw accurate conclusions about the metabolic rate of an organism, regardless of the conditions under which the organism was maintained.
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J Med Microbiol,
2013]
Stenotrophomonas maltophilia plays an important role as an opportunistic pathogen in immunocompromised individuals. Despite its clinical implication, the true knowledge regarding the pathogenicity of these bacteria remains unclear. Various methods have been employed to prove this bacterium to be pathogenic. However, the debate whether S. maltophilia is a true pathogen or a colonizer still remains unanswered as effective killing was not seen in earlier experiments with different animal models of infection (Denton et al., 1998; Adamak et al., 2011; Pompilo et al., 2011). Study by Rouf et al. (2011) on murine lung infection model illustrated that different strains of mice exhibited different outcome for S. maltophilia infection. Strains such as A/J and DBA/2 were permissive for clinical isolates of S. maltophilia and showed higher levels of pro-inflammatory cytokines. In contrast, BALB/c and C57BL/6 strains were non-permissive for S. maltophilia. While Huang et al. (2009) showed nematotoxic activity by environmental S. maltophilia strain against free-living nematode, Panagrellus redivivus, and plant-parasitic nematode, Bursaphelenchus xylophilus.