In vitro organogenesis and genetic transformation of mandarin varieties (Citrus reticulata Blanco e Citrus clementina hort. ex Tan.).

Currently, Huanglongbing (HLB), associated to Candidatus Liberibacter spp., is the main threat to the citrus culture. The conventional plant breeding shows limitations to the obtain new varieties of rootstock and scion, due to factors related to the biology of the genus. In attempt to overcome these barriers, genetic engineering is notable for allowing the introduction of foreign genes, which, besides reducing the time to obtain genetically improved material may confer disease resistance in varieties of agronomic interest. Thus, the objective of the research was the study of in vitro organogenesis, and obtain transgenic plants of \'Fremont\', \'Thomas\' and \'Nules\' mandarins via Agrobacterium tumefaciens with the gene encoding the antibacterial peptide attacin A (attA), controlled by the promoters AtSUC2 and AtPP2, aiming to preferential gene expression in phloem. In addition, the genetic transformation of cell suspensions, via A. tumefaciens, of \'W-Murcott\' mandarin, \'Hamlin\' sweet orange and \'Page\' tangelo and the direct genetic transformation, via PEG, of \'W-Murcott\' mandarin protoplasts were evaluated with VvmybA1 and Ruby transcription factors driven by 6105 and DC3 promoters, with preferential expression in embryonic tissues. The in vitro organogenesis of the varieties studied was influenced by the type of explant and BAP concentration. After genetic transformation experiments of epicotyl and internodal segments of \'Fremont\', \'Thomas\' and \'Nules mandarins, regenerated plants were analyzed by PCR, Southern blot and RT-qPCR and confirmed as transgenic by presence and transcription of attA gene. The genetic transformation of cell suspensions was efficient with high anthocyanin production in the somatic embryos regenerated of \'W-Murcott\' mandarin, \'Hamlin\' sweet orange and \'Page\' tangelo. The direct genetic transformation of \'W-Murcott\' mandarin protoplasts revealed to be viable and it was also possible to obtain transgenic somatic embryos. The VvmybA1 and Ruby transcription factors were useful tools for visual detection of transgenic material (AU)