Hormesis and paradoxical effects in plants upon exposure to formaldehyde are common phenomena
Lobachevsky University researchers have first demonstrated that hormesis and paradoxical effects widely occur in plants under the influence of formaldehyde
For the first time, hormesis and paradoxical effects have been shown to occur commonly in plants upon exposure to formaldehyde, which is a widespread pollutant.
To assess the level of chemical pollution of the environment, different indicators of plant status are widely used as bioindicators, since plants have an attached lifestyle and are unable to avoid exposure to unfavorable factors.
Until recently, it was believed that in most cases, an increase in the level of pollution causes deterioration in the state of plants, so the values of the indicators of plant status reflect the quality of the environment.
However, in recent years there has been growing recognition that the nonmonotonic responses of living organisms, when the direction of the organism’s reaction changes with increasing strength of the acting factor, can occur quite often. These include hormesis and paradoxical effects. In case of hormesis, low doses of pollutants have a positive effect on the state of the living organism, while high doses cause a negative effect. Paradoxical effects include complex dose-effect relationships, when an increased dose of a toxicant results in a decrease in its damaging effect and, conversely, the damaging effect increases with a decrease in the toxicant dose.
Nonmonotonic changes in plant indicators used to determine the quality of the environment can result in an incorrect assessment of the pollution level. Therefore, it is important to know how often hormosis and paradoxical effects occur when plants are exposed to various pollutants.
Lobachevsky University biologists have for the first time conducted a study of this problem for formaldehyde, one of most common environmental pollutants, which is released into the atmosphere as part of vehicle emissions and is often found in indoor air after evaporating from synthetic materials. A wide range of concentrations of this pollutant was investigated, from values close to lethal levels to those several orders of magnitude smaller.
For all the plant parameters studied, nonmonotonic dose-effect relationships were established. Hormesis was revealed for growth parameters, while various variants of paradoxical effects were found for biochemical indicators.
The results of the study can contribute to improving bioindicative methods for environmental assessment based on the plant organism parameters. These results also shed new light on the patterns of plant adaptation to stressful environmental conditions. In the future, this can be used to develop methods for managing plant resistance and thus agricultural plant productivity.