Abstract
Plant development is highly malleable, as evidenced by the ability of cultured cells, tissues and organs to regenerate into whole plants in vitro. The ability of plants to regenerate in vitro is influenced by many different factors, including the donor plant growth conditions and the type of explant. Empirical trial and error manipulation of these and other culture parameters is the basis for improving plant regeneration protocols, but the mechanisms underlying the effects of these parameters on plant regeneration are unknown. Somatic embryogenesis (SE) is a type of in vitro plant regeneration where somatic/vegetative cells are induced to form embryos. Here we show that seed maturation is one of the parameters that affects the ability of germinating embryos to undergo auxin-induced somatic embryogenesis in Arabidopsis thaliana. Late maturation stage seeds harvested from yellow siliques have a higher capacity for somatic embryogenesis than seeds harvested later from brown siliques, a process that can be mimicked by post-harvest storage. Physiological and genetic analyses suggest that an oxidizing environment and ABA metabolism enhance the rate at which germinating embryos lose capacity to reactivate embryogenic growth. Our data suggest that there is a narrow window during late seed maturation in which embryogenic competence is reduced, and that this process also takes place, albeit more slowly, during seed storage. This knowledge provides a framework for identifying new plant totipotency factors and for directing efficient SE in systems that make use of mature seed explants.
Highlights
Plant are able to undergo many types of regeneration, including the natural process of tissue and organ regeneration after wounding, and induced regeneration of organs and embryos in vitro (Ikeuchi et al 2016)
We examined the donor plant growth conditions and seed storage conditions as possible factors that could explain observed differences in Somatic embryogenesis (SE) efficiency from different batches of germinating arabidopsis Col-0 seeds
Younger seeds harvested from yellow siliques show an initially high SE capacity, which decreases with further storage, while physiologically older seeds harvested a few weeks later from brown siliques, have a lower SE capacity that does not decrease with further storage (Fig. 6)
Summary
Plant are able to undergo many types of regeneration, including the natural process of tissue and organ regeneration after wounding, and induced regeneration of organs and embryos in vitro (Ikeuchi et al 2016). These various plant regeneration systems are applied widely for commercial plant breeding and propagation (Bridgen et al 2018; Dwivedi et al 2015), and provide novel systems to understand how plant cells can be redirected toward new developmental fates (Kareem et al 2016; Horstman et al 2017). The mechanistic basis for the different responses of genotypes and explants to plant growth and culture parameters is not known
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
