Y of polar cell growth. In our experiments, we used a simple medium containing AODNs for pollen tube germination and growth. The fluorescentlyAntisense ODN Inhibition in Pollen TubesFigure 6. Dosage dependent effect of A-ODN treatment on pollen tube length. A: the effect of ODN4 at different concentrations on pollen tubes inhibitor growth (n = 200610). Asterisks indicate P,0.05, double asterisks indicate P,0.01 between control (ck) and treated sample (SPSS IndependentSample T Test). Error bars in the columns represent SD. B: Dosage dependent effect of A-ODN treatment on NtGNL1 mRNA expression. doi:10.1371/journal.pone.0059112.glabeled ODNs were quickly observed in pollen tubes, indicating highly effective ODN uptake during pollen tube growth under our intended conditions. Recently, it has been found that sucrose, and active transport of mono- or disaccharides through sugar translocators, can greatly enhance ODN uptake [17]. This strategy was used to deliver ODNs into barley seeds, endosperm cells, and even human cells [17]. It was also reported that wheat is sensitive to osmotic stress; e.g., treatment with 200 mM sucrose [12]. The medium we used for pollen tube growth also contained a high concentration of sucrose (20 ). Our result supports the hypothesis that 15900046 the highly effective uptake of ODN is related to sugar; however, the detailed mechanism remains unclear. The overlap of fluorescently labeled ODNs and FM4-64 at the tip of the pollen tube suggested that the peculiar membrane trafficking at the apex might also facilitate the uptake of A-ODNs. Although the detailed mechanism of ODN uptake in both cases still requires careful investigation, the successful application of thetechnique in pollen tubes offers a convenient alternative procedure for gene function analysis using pollen tubes as a model system. Eliminating off-target effects is a great challenge when using ODNs in gene function analysis. In our experiments, we first compared the effects of different A-ODN (ON4 and ON6) sequences targeting nearly identical mRNAs, and observed similar phenotypes, suggesting specific binding to the same target. Furthermore, the two sequences avoided non-specific inhibition, such as G4 tracts [39,40] or the CpG motif backbone [41]. We then used reorganized sequences of ON4 and ON6 as additional controls (the random-designed ODNs). Both controls (sense and reorganized ODNs) showed no significant effect on normal pollen tube growth, even at higher concentrations. We also checked that the mRNA level of NtGNL1 in the A-ODN-treated pollen tubes was Autophagy clearly reduced (Fig. 2) and as the concentrations of ODN increased, the mRNA level in the pollen tubes decreased accordingly (Fig. 6B). Furthermore, we compared A-ODN-treatedAntisense ODN Inhibition in Pollen Tubesexperiments was negligible; generally, pollen tubes are very sensitive to any harmful influence and in this case the growthinhibiting effect was reversible [42,43]. This phenomenon also suggests that the A-ODN technique may be useful for transiently interrupting gene function, allowing researchers to non-destructively observe the roles of a target gene in different or specific developmental stages. Obviously, this is not possible when using traditional RNAi or gene mutation techniques for the same purpose.Entry of A-ODN into Pollen TubesThe biological effects of A-ODN have been attributed to 26001275 the uptake route. Alam [21] found that A-ODNs conjugated to a bivalent RGD vs. unconjugated ODNs were internalized.Y of polar cell growth. In our experiments, we used a simple medium containing AODNs for pollen tube germination and growth. The fluorescentlyAntisense ODN Inhibition in Pollen TubesFigure 6. Dosage dependent effect of A-ODN treatment on pollen tube length. A: the effect of ODN4 at different concentrations on pollen tubes growth (n = 200610). Asterisks indicate P,0.05, double asterisks indicate P,0.01 between control (ck) and treated sample (SPSS IndependentSample T Test). Error bars in the columns represent SD. B: Dosage dependent effect of A-ODN treatment on NtGNL1 mRNA expression. doi:10.1371/journal.pone.0059112.glabeled ODNs were quickly observed in pollen tubes, indicating highly effective ODN uptake during pollen tube growth under our intended conditions. Recently, it has been found that sucrose, and active transport of mono- or disaccharides through sugar translocators, can greatly enhance ODN uptake [17]. This strategy was used to deliver ODNs into barley seeds, endosperm cells, and even human cells [17]. It was also reported that wheat is sensitive to osmotic stress; e.g., treatment with 200 mM sucrose [12]. The medium we used for pollen tube growth also contained a high concentration of sucrose (20 ). Our result supports the hypothesis that 15900046 the highly effective uptake of ODN is related to sugar; however, the detailed mechanism remains unclear. The overlap of fluorescently labeled ODNs and FM4-64 at the tip of the pollen tube suggested that the peculiar membrane trafficking at the apex might also facilitate the uptake of A-ODNs. Although the detailed mechanism of ODN uptake in both cases still requires careful investigation, the successful application of thetechnique in pollen tubes offers a convenient alternative procedure for gene function analysis using pollen tubes as a model system. Eliminating off-target effects is a great challenge when using ODNs in gene function analysis. In our experiments, we first compared the effects of different A-ODN (ON4 and ON6) sequences targeting nearly identical mRNAs, and observed similar phenotypes, suggesting specific binding to the same target. Furthermore, the two sequences avoided non-specific inhibition, such as G4 tracts [39,40] or the CpG motif backbone [41]. We then used reorganized sequences of ON4 and ON6 as additional controls (the random-designed ODNs). Both controls (sense and reorganized ODNs) showed no significant effect on normal pollen tube growth, even at higher concentrations. We also checked that the mRNA level of NtGNL1 in the A-ODN-treated pollen tubes was clearly reduced (Fig. 2) and as the concentrations of ODN increased, the mRNA level in the pollen tubes decreased accordingly (Fig. 6B). Furthermore, we compared A-ODN-treatedAntisense ODN Inhibition in Pollen Tubesexperiments was negligible; generally, pollen tubes are very sensitive to any harmful influence and in this case the growthinhibiting effect was reversible [42,43]. This phenomenon also suggests that the A-ODN technique may be useful for transiently interrupting gene function, allowing researchers to non-destructively observe the roles of a target gene in different or specific developmental stages. Obviously, this is not possible when using traditional RNAi or gene mutation techniques for the same purpose.Entry of A-ODN into Pollen TubesThe biological effects of A-ODN have been attributed to 26001275 the uptake route. Alam [21] found that A-ODNs conjugated to a bivalent RGD vs. unconjugated ODNs were internalized.
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