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Que Q, Chilton MDM, Elumalai S, Zhong H, Dong S, et al. 2019. Repurposing macromolecule delivery tools for plant genetic modification in the era of precision genome engineering. In Transgenic Plants, eds Kumar S, Barone P, Smith M. Volume 1864. pp. 3−18. doi: 10.1007/978-1-4939-8778-8_1

Cunningham FJ, Goh NS, Demirer GS, Matos JL, Landry MP. 2018. Nanoparticle-mediated delivery towards advancing plant genetic engineering. Trends in Biotechnology 36:882−97

Mini P, Demurtas OC, Valentini S, Pallara P, Aprea G, et al. 2018. Agrobacterium-mediated and electroporation-mediated transformation of Chlamydomonas reinhardtii: a comparative study. BMC Biotechnology 18:11

O'Brien JA, Lummis SCR. 2006. Diolistic labeling of neuronal cultures and intact tissue using a hand-held gene gun. Nature Protocols 1:1517−21

Eapen S. 2011. Pollen grains as a target for introduction of foreign genes into plants: an assessment. Physiology and Molecular Biology of Plants 17:1−8

Gad MA, Li MJ, Ahmed FK, Almoammar H. 2020. Nanomaterials for gene delivery and editing in plants: challenges and future perspective. In Multifunctional Hybrid Nanomaterials for Sustainable Agri-Food and Ecosystems, ed. Abd-Elsalam KA. Amsterdam: Elsevier. pp. 135−53. doi: 10.1016/b978-0-12-821354-4.00006-6

Yin Y, Wang C, Xiao D, Liang Y, Wang Y. 2021. Advances and perspectives of transgenic technology and biotechnological application in forest trees. Frontiers in Plant Science 12:786328

Codjoe JM, Miller K, Haswell ES. 2022. Plant cell mechanobiology: greater than the sum of its parts. The Plant Cell 34:129−45

Jaffri SRF, MacAlister CA. 2021. Sequential deposition and remodeling of cell wall polymers during tomato pollen development. Frontiers in Plant Science 12:703713

Zhao X, Meng Z, Wang Y, Chen W, Sun C, et al. 2017. Pollen magnetofection for genetic modification with magnetic nanoparticles as gene carriers. Nature Plants 3:956−64

Clough SJ, Bent AF. 1998. Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. The Plant Journal 16:735−43

Sommer A, Geist B, Da Ines O, Gehwolf R, Schäffner AR, et al. 2008. Ectopic expression of Arabidopsis thaliana plasma membrane intrinsic protein 2 aquaporins in lily pollen increases the plasma membrane water permeability of grain but not of tube protoplasts. New Phytologist 180:787−97

Zhang M, Ma X, Jin G, Han D, Xue J, et al. 2023. A modified method for transient transformation via pollen magnetofection in Lilium germplasm. International Journal of Molecular Sciences 24:15304

Saunders J, Matthews BF. 1995. Pollen Electrotransformation in Tobacco. In Plant Cell Electroporation and Electrofusion Protocols, ed. Nickoloff JA. Totowa, NJ: Springer. Volume 55. pp. 81−88. doi: 10.1385/0-89603-328-7:81

Menzel CM. 2023. Fruit set is moderately dependent on insect pollinators in strawberry and is limited by the availability of pollen under natural open conditions. The Journal of Horticultural Science and Biotechnology 98:685−714

Wang T, Zheng Y, Xu C, Deng Y, Hao X, et al. 2024. Movement of ACC oxidase 3 mRNA from seeds to flesh promotes fruit ripening in apple. Molecular Plant 17:1221−35

Lee HS, Wicker L. 1991. Quantitative changes in anthocyanin pigments of lychee fruit during refrigerated storage. Food Chemistry 40:263−70

Hu DG, Sun CH, Ma QJ, You CX, Cheng L, et al. 2016. MdMYB1 regulates anthocyanin and malate accumulation by directly facilitating their transport into vacuoles in apples. Plant Physiology 170:1315−30

Xia J, Guo Z, Yang Z, Han H, Wang S, et al. 2021. Whitefly hijacks a plant detoxification gene that neutralizes plant toxins. Cell 184:3588

Kehr J. 2006. Phloem sap proteins: their identities and potential roles in the interaction between plants and phloem-feeding insectsFree. Journal of Experimental Botany 57:767−74

Jakobs R, Schweiger R, Müller C. 2019. Aphid infestation leads to plant part-specific changes in phloem sap chemistry, which may indicate niche construction. New Phytologist 221:503−14

Huang D, Peng W, Gong N, Qiu L, Wang Y, et al. 2024. The role of the auxin-response genes MdGH3.1 and MdSAUR36 in bitter pit formation in apple. Horticultural Plant Journal 10:1085−98

Feng L, Li G, He Z, Han W, Sun J, et al. 2019. The ARF, GH3 and Aux/IAA gene families in Castor bean (Ricinus communis L.): genome-wide identification and expression profiles in high-stalk and dwarf strains. Industrial Crops and Products 141:111804

Zou X, Long J, Zhao K, Peng A, Chen M, et al. 2019. Overexpressing GH3.1 and GH3.1L reduces susceptibility to Xanthomonas citri subsp. citri by repressing auxin signaling in Citrus (Citrus sinensis Osbeck). PLoS One 14:e0220017

Xu H, Wang X, Zhao H, Liu F. 2008. An intensive understanding of vacuum infiltration transformation of pakchoi (Brassica rapa ssp. chinensis). Plant Cell Reports 27:1369−76

Wang ZP, Zhang ZB, Zheng DY, Zhang TT, Li XL, et al. 2022. Efficient and genotype independent maize transformation using pollen transfected by DNA-coated magnetic nanoparticles. Journal of Integrative Plant Biology 64:1145−56

Vejlupkova Z, Warman C, Sharma R, Scheller HV, Mortimer JC, et al. 2020. No evidence for transient transformation via pollen magnetofection in several monocot species. Nature Plants 6:1323−24

Yang L, Zhang J, Liu S, Zhang Y, Wang L, et al. 2024. Establishment of transgenic fluorescent mice for labeling synapses and screening synaptogenic adhesion molecules. eLife 13:e81884

Dunker S, Motivans E, Rakosy D, Boho D, Mäder P, et al. 2021. Pollen analysis using multispectral imaging flow cytometry and deep learning. New Phytologist 229:593−606

Zhang D, Wengier D, Shuai B, Gui CP, Muschietti J, et al. 2008. The pollen receptor kinase LePRK2 mediates growth-promoting signals and positively regulates pollen germination and tube growth. Plant Physiology 148:1368−79

Predieri S. 2002. The importance of induced mutations in pear improvement. Acta Horticulturae 596:161−66

Stern DL. 2013. The genetic causes of convergent evolution. Nature Reviews Genetics 14:751−64