Recently, we published a microinjection method for generating transgenic cattle using the DNA transposon system and their analysis by next-generation sequencing (Yum et al. Sci Rep. 2016 Jun 21;6:27185). In that study, we generated transgenic cattle using two different types of DNA transposon system, sleeping beauty (SB) and piggybac (PB), carrying Yellow fluorescent protein with SB (SB-YFP, female) and green fluorescent protein with PB (PB-GFP, male) under the control of the ubiquitous CAG promoter, respectively. The female and male founder cattle have been grown up to date (the female age: 40 months old, the male age: 33 months old) without any health issues. In genomic instability and blood analysis, there was no significant differences between wild type and founder cattle. In the present study, we confirmed germ-line transmission of the transposon-mediated transgene integrations and ubiquitous and persistent expression of transgene in second generation of offspring (F1). The F1 was born without any assistance and expressed GFP in the eyes without UV light. The ubiquitous expression of GFP was detected in skin fibroblast from the ear tissue and confirmed by genomic DNA PCR, which suggest that the transgene from the PB-GFP was successfully transmitted. Unfortunately, no transgene from SB-YFP were identified. To confirm the transgene integration site, the genomic DNA from blood was extracted and performed next-generation sequencing (NGS). The GFP gene was integrated in chromosome 4 (two copies), and 6. As results, a total of two copies of paternal transgene transmitted into the F1. All the integrated position was not related with coding region and there was no significant difference in genomic variants between transgenic and non-transgenic cattle. To our knowledge, this is the first report of germ-line transmission through non-viral transgenic founder cattle. Those transgenic cattle will be valuable resource to many fields of biomedical research and agricultural science.

Legume and rhizobia symbiosis plays an important role in conversion of atmospheric dinitrogen to ammonia. On a global scale, this interaction represents a key entry point for reduced nitrogen into the biosphere, and as a consequence this symbiosis is important in both natural and agricultural systems. Symbiotic development of nodule organ is triggered by chito-oligosaccharide signals (Nod factors) from the bacterium which are perceived by the legume root. Understanding the molecular and cellular processes that underlie Nod factor perception is one focus of legume biology. Although forward genetics has proved to be an important tool to identify key players in Nod factor perception, we still know relatively little regarding the functional networks of genes and proteins that connect the earliest steps of Nod factor perception to immediate downstream outcomes. To elucidate genes and proteins that link Nod factor perception to cellular and physiological responses we are taking a discovery-based strategy based on whole transcriptome profiling using RNA-seq analysis in the roots of Medicago truncatula in response to Sinorhizobium meliloti. Functional characterization of a number of candidate genes is currently in progress to further examine their role in nodulation such as generating transgenic plants

Legume and rhizobia symbiosis plays an important role in conversion of atmospheric dinitrogen to ammonia. On a global scale, thin interaction represent a key entry point for reduced nitrogen into the biosphere, and as a consequence this symbiosis in important in both natural and agricultural systems. Symbiotic development of nodule organ in triggered by chito-oligosaccharide signals(Nod factors) from the bacterium which are perceived by the legume root. Understanding the molecular and cellular processes that underlie Nod factor perception is one focus of legume biology. Although forward genetics has proved to be an important tool to elucidate key players in Nod factor perception, we still know relatively little regarding the functional networks of genes and proteins that connect the earliest steps of Nod factor perception to immediate downstream outcomes. To identify genes and proteins that link Nod factor perception to cellular and physiological responses we are taking a discovery-based strategy on large-scale transcriptome profiling using RNA sequencing in the roots of Medicago truncatula in response to Sinorhizobium meliloti. Functional characterization of a number of candidate genes is currently in progress to further examine their role in nodulation.