10.6084/m9.figshare.8312927.v1 Xia Wan Xia Wan Qing Liu Qing Liu Bei Dong Bei Dong Sapna Vibhakaran Pillai Sapna Vibhakaran Pillai Feng-Hong Huang Feng-Hong Huang Surinder Singh Surinder Singh Xue-Rong Zhou Xue-Rong Zhou MOESM5 of Molecular and biochemical analysis of the castor caruncle reveals a set of unique genes involved in oil accumulation in non-seed tissues Springer Nature 2019 Castor bean Caruncle Non-seed oil accumulation Transient expression Transcriptome 2019-06-24 05:00:00 Figure https://springernature.figshare.com/articles/figure/MOESM5_of_Molecular_and_biochemical_analysis_of_the_castor_caruncle_reveals_a_set_of_unique_genes_involved_in_oil_accumulation_in_non-seed_tissues/8312927 Additional file 5: Figure S1. Schematic view representing the major difference of gene expression and the distribution/channeling of the acetyl-CoA pool to fatty acid and TAG biosynthesis in caruncle and seed. The dominantly expressed gene member in the gene families identified (in bold) are highlighted in blue for caruncle and dark red for seed. In the case of oleosin genes, oleosin 1 was the dominant gene in both caruncle and seed, but lower in caruncle (indicated by non-bold) compared to seed. The genes for other steps that no significant difference identified here are not shown. The major fatty acids in the pathway and the ultimate profile in TAG are also indicated in blue for caruncle and dark red for seed. RA, ricinoleic acid (12OH-C18:1∆9). Other abbreviations are same as in Fig. 5.