Abstract
Soybean loss due to pests and pathogens is a serious problem worldwide. Soybean producers have few options to manage diseases caused by general pathogens where major genes for full resistance have not been discovered. The innate defense of soybean plants could be enhanced by improving content and composition of lignin by genetic engineering of the phenylpropanoid pathway. We used a novel technique of germ-line genetic transformation of soybean plants via natural pollen tubes as vectors. This technique uses Agrobacterium tumefaciens to mediate transfer of genes of interest to the zygote to introduce the key lignification genes (PtMYB4, PAL5, F5H, CAD1) into soybean genome. We observed 5.6% average transformation efficiency in the first generation of transgenic plants and in the second generation the presence of the transgene constructs was confirmed in more than 50% (for CsVMV/PtMYB4sens, 35SVTM/PAL5, C4H/F5H, CsVMV/CAD1 constructs) transgenic soybean lines. We confirmed the expression of the introduced genes at transcriptional level using RT-PCR and Northern blot. Functional analysis using lignin content determination and the activity of PAL5 and CAD1 enzymes demonstrated that the transgenes perform their function in planta. The proposed technique is effective and inexpensive and can be used to create novel stress and disease resistant soybean genotypes.
Highlights
The world-wide soybean (Glycine max, L.) production has increased several fold starting from 1960s’ and currently soybean is one of the largest source of vegetable oil and animal feed (Pagano & Miransari, 2016)
In this paper we propose a novel technique of germ-line genetic transformation via natural pollen tubes using A. tumefaciens mediated DNA transfer
Genetic transformation of soybean plants by Agrobacterium tumefaciens pipetting for introduction of genes of lignification
Summary
The world-wide soybean (Glycine max, L.) production has increased several fold starting from 1960s’ and currently soybean is one of the largest source of vegetable oil and animal feed (Pagano & Miransari, 2016). A large number of genes are associated with abiotic and biotic stress resistance in plants (Cabane, Afif, & Hawkins, 2012; PérezClemente et al, 2013; Tran & Mochida, 2010). They are related to the various metabolic and signaling pathways including reactive oxygen species signaling (Baxter, Mittler, & Suzuki, 2014), plant hormones, inorganic ion fluxes (Kissoudis, Van de Wiel, Visser, & Van der Linden, 2014) as well as transcription factors (Birkenbihl, Liu, & Somssich, 2017). Genetic manipulation of a single or a few genes involved in signaling/regulatory pathways are used to improve environmental stress resistance of soybean plants (Homrich, Strohm, Weber, & Zanettini, 2012)
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