Concurrent exposure to SO2 and/or NO2 alters growth and yield responses of wheat and barley to low concentrations of O3

Abstract

Summary: During 1988 and 1989, single and interactive effects of low concentrations of O₃, SO_S and NO₂ (6–44, 9–63 and 10–43 μm^−a as 24 h daily means) on two varieties of spring barley (Hordeum vulgare L., ‘Arena’ and ‘Alexis’) and spring wheat (Triticum aestivum L., ‘Turbo’ and ‘Star’) were investigated in factorial experiments using open‐top chambers. Potted plants were exposed during the whole growing season to either charcoal‐filtered air (CF; control) or CF supplemented with one (SO₂, NO₂) or two (O₃) concentrations of the pollutants. While SO₂ was applied continuously, fumigation with O₃ and NO₂ occurred every day sequentially from 8.00 to 16.00 and from 16.00 to 8.00 h, respectively. Analysis of variance indicated that from the main treatments O₃ caused the most detrimental effects on growth and yield parameters. Depending on season and on variety, yield of wheat was reduced by O₃ between 20% and 40% compared with the control treatment; a significant reduction of yield of barley (−15%) was only registered for ‘Arena’ (1988), while ‘Alexis’ appeared to be insensitive towards this gas. SO₂ did not affect yield of barley significantly, while yield of wheat was either decreased (−7% for ‘Turbo’ in 1988) or increased (+11% for ‘Star’). NO₂ did not alter yield of wheat significantly but it increased yield of barley (‘Arena’) by 15% in 1988. Significant interactive effects between the pollutants were observed only for a few parameters. Among these the most sensitive ones were the length of ears, the 1000‐grain weight and the weight of straw. The interaction between the pollutants was mostly antagonistic, i.e. positive or negative effects of a single gas were cancelled or mitigated by the presence of other pollutants. However, a clear tendency towards a synergism was found for wheat in 1988: detrimental effects of O₃ on yield (e.g, –26%;‘Turbo’) were aggravated by the addition of either SO₂ (−38%) or, partially, NO₃ (−31%) or both pollutants together (−44%). Before the plants were fully mature, visible symptoms were only observed on wheat after exposure to the highest O₃ concentrations. The results showed that although effects of O₃ dominated, these responses were strongly modified by the presence of one or both of the other gases. It is evident that yield losses of O₃‐sensitive crop species may be enhanced under certain circumstances by low concentrations of other pollutants. Therefore, estimations of yield losses from open‐top chamber experiments should consider interactive effects between those pollutants which are relevant to ambient air.