led to increased hydrogen peroxide

led to increased hydrogen peroxide concentrations, oxidized glutathione
(GSSG), increased peroxidase activity, and reduced photosynthetic
oxygen production (Kamara and Pflugmacher, 2008;
Nimptsch and Pflugmacher, 2008) – all symptoms of oxidative
stress; the latter as oxidative stress avoidance reaction (Mittler,
2002). These findings indicate also that litter leachates contain natural
xenobiotics which are responsible for the oxidative stress.
From previous studies with C. elegans, it is well understood that
mild oxidative stress by biogeochemicals can lead to multiple
stress resistance and extension of the individual lifespans (Steinberg
et al., 2007; Kampkötter et al., 2008; Saul et al., 2010). The
mitohormesis theory provides a possible explanation for these
observations and for the beneficial effects of the oxidatively acting
leachates in this study. Mitohormesis, or more precisely mitochondrial
hormesis, describes the assumption that an increase of mitochondrial
activity and the subsequent increase of ROS production
leads to a hormetic activation of the stress defense system (Tapia,
2006; Schulz et al., 2007; Ristow and Zarse, 2010; Ristow and Schmeisser,
2011). This might also apply as a potential background
mechanism for the leaf litter effects in Moina and should be considered
in future analyses.
Another assumption is based on the observation that longevity
is often combined with reduced offspring numbers and/or reduced
body growth (Kirkwood, 1977). Hence, it is interesting to identify
whether or not stressed Moina individuals showed either extended
lifespans, larger bodies, or produced more offspring