3.2. Plant growth and mycorrhizal c

3.2. Plant growth and mycorrhizal colonization in the potexperimentShoot and root biomass were significantly affected by both cyclenumber and nicosulfuron dose rates (p < 0.001). Further analysisper cycle showed that the application of the x1000 dose rate signif-icantly decreased (p < 0.001) the shoot and root biomass of maizeplants at cycle 1 (Fig. 2a) and entirely prevented growth of maizefrom cycle 2 and onwards (Fig. 2b–e). On the other hand, theapplication of the x100 dose rate did not have a significant effect(p > 0.05) on plant biomass at cycle 1 but significantly impaired(p < 0.001) maize growth from cycle 2 and onwards. Finally theapplication of the x10 dose rate did not induce significant effects(p > 0.05) on plant growth with the only exception of cycle 4 wheremarginally significant decreases in shoot and root biomass wereobserved (Fig. 2d).Overall, maize plants were successfully colonized by AM fungiin the pot experiment with hyphal mycorrhizal colonization ran-ging from 20 to 80%. Hyphal colonization was significantly affectedby the dose rates (p < 0.05) and the culture cycle (p < 0.001). Furtheranalysis of dose effects per cycle showed that the x1000 dose rateinduced a significant reduction (p < 0.001) in hyphal colonizationat the end of cycle 1 (Fig. 3a), however the phytotoxicity observedin subsequent cycles did not allow any further measurements.The x100 dose rate of nicosulfuron induced a significant increase(p < 0.001) in hyphal colonization compared to the x10 dose rateand the control at cycle 2 (Fig. 3b), whereas the same dose rateinduced a significant decrease (p < 0.05) in hyphal colonization insubsequent cycles (Fig. 3c and e). In contrast, the x10 dose ratedid not induce any significant effects on hyphal colonization com-pared to the untreated samples with the exception of cycle 4 wherea significant reduction (p < 0.05) was observed (Fig. 3d).Arbuscular colonization was significantly affected by culturecycle (p < 0.001) but not by the different dose rates of nicosulfuron(p > 0.05), whereas significant interactions between these two maineffects were observed (p < 0.01). Further analysis of the effects ofdose rates per cycle showed that arbuscular colonization was signif-icantly affected (p < 0.05) by the x100 dose rates at cycle 3 (Fig. 3c)but even by the x10 dose rate at cycle 4 (Fig. 3d), whereas no arbus-cules were found in the plants at cycle 5. Vesicular colonizationwas limited throughout the experiment and was not significantlyaffected (p > 0.05) by the dose rates or the culture cycle and nosignificant interactions were observed.3.3. Mycorrhizal colonization on maize plants in the fieldexperimentMaize plants showed relatively high levels of hyphal coloniza-tion (30–40%) at 28 days post application (Supplementary DataFig. S1). No significant effect (p > 0.05) of nicosulfuron on hyphal,arbuscular and vesicular colonization was found.3.4. The impact of nicosulfuron on the AM fungal community3.4.1. Pot experimentResults of DGGE fingerprints revealed that nicosulfuron changedmarkedly the structure of the AM fungal community (Fig. 4). Thus,in cycle 1 the x1000-treated samples showed an altered communitycompared to the x10 and x100-treated samples which clusteredtogether and distantly from the untreated samples. In subsequentcycles, the x100 dose rate induced a gradual eradication of the AMfungal community with those samples clustering away from theother treatments (Figs. 4b, c and e). In contrast, the samples treatedwith the x10 dose rate clustered close to the control samples in allsubsequent cycles (Figs. 4b, c and e) with the exception of cycle4 where the x100 dose had a phytotoxic effect on maize plants(Fig. 4d).Clone libraries obtained from the different cycles showed thatin most cases bands from different treatments and/or cycles show-ing identical electrophoretic mobility represented the same fungalribotype. Based on this all DGGE bands where given a two-digitnumber where the first digit indicated the culture cycle numberand the second digit their relative electrophoretic mobility. Thusbands with the same first digit were obtained from treatments ofthe same culture cycle, while a common second digit suggestedidentical electrophoretic mobility regardless of the culture cycle