Wang, H.; Zhang, Y.; Qu, W.; Zhang, X.; Qu, H.

There are two main technical bottlenecks in plant genetic transformation: the intracellular delivery of exogenous genes and tissue culture. This study is an elaboration of a method combining needle-free jet injection (NFJI) and vacuum infiltration technology to efficiently introduce exogenous genes into pear (Rosaceae) plant pollen. This method was verified with the model plant tobacco (Solanaceae) wherein the GFP reporter gene was successfully introduced into the pollen and expressed. Then, the gene was transferred to the seeds via pollination, and after the seeds were sown, gene expression was observed at the roots of the seedlings. Furthermore, in this study, the apple (Rosaceae) gene MdGH3.1 was introduced into tobacco using NFJI, resulting in transgenic seedlings that were shorter than the seedlings in the control group and presented fewer, shorter root hairs, confirming that the MdGH3.1 gene was functional. In addition, the applicability of this method to other plant species, including dicotyledonous and monocotyledonous plants, was explored. In particular, when the MdGH3.1 gene was introduced into Arabidopsis (Brassicaceae), the phenotype of the resulting plants was consistent with that of the transgenic tobacco. The results indicate that genes can be effectively delivered into plants by this method without on the need for tissue culture. Moreover, the instruments used in this method are portable, affordable, and easy to operate, allowing for direct utilization in the field, indicating the great application potential of this method.