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In flowering plants, pollen tubes communicate with ovular cells to achieve precise one-to-one pollen tube reception. The final step of this communication between the pollen tube and synergid cells has been extensively investigated and visualized by calcium imaging. Synergid cells exhibit characteristic cytoplasmic calcium concentration oscillations, which are thought to play a critical role in pollen tube reception. However, their significance and relationship with calcium dynamics in the entire ovule remain unclear. Here, we show, using the calcium sensor GCaMP6s, that proteins involved in asparagine-linked glycosylation (N-linked glycosylation) are required for normal calcium oscillations in synergid cells but are not essential for pollen tube reception. Using a semi- in vivo assay in Arabidopsis thaliana , we found that the amplitude of these oscillations prior to rapid pollen tube growth across the filiform apparatus was reduced in mutants lacking the oligosaccharyltransferase (OST) 3/6 subunit or alpha1,2-glucosyltransferase (ALG) 10, both of which are involved in N-linked glycosylation. Notably, these mutants did not exhibit reduced fertility attributable to defects in the female gametophyte but instead showed a polytubey phenotype due to a sporophytic defect. These findings suggest that N-linked glycans mediate communication between synergid cells and the pollen tube and indicate that the typical pattern of calcium oscillations in synergid cells is not essential for triggering pollen tube rupture. Furthermore, we show that sporophytic tissues of the ovule exhibit calcium waves that propagate toward the funiculus in correlation with pollen tube contact and rupture, implying that ovular tissues can potentially transmit these signals distantly beyond the ovule. Together, these findings reveal previously unrecognized intercellular calcium signaling and its significance in pollen tube reception by the ovule.