Abstract
The improvement of woody fruit species by traditional plant breeding techniques has several limitations mainly caused by their high degree of heterozygosity, the length of their juvenile phase and auto-incompatibility. The development of new biotechnological tools (NBTs), such as RNA interference (RNAi), trans-grafting, cisgenesis/intragenesis, and genome editing tools, like zinc-finger and CRISPR/Cas9, has introduced the possibility of more precise and faster genetic modifications of plants. This aspect is of particular importance for the introduction or modification of specific traits in woody fruit species while maintaining unchanged general characteristics of a selected cultivar. Moreover, some of these new tools give the possibility to obtain transgene-free modified fruit tree genomes, which should increase consumer's acceptance. Over the decades biotechnological tools have undergone rapid development and there is a continuous addition of new and valuable techniques for plant breeders. This makes it possible to create desirable woody fruit varieties in a fast and more efficient way to meet the demand for sustainable agricultural productivity. Although, NBTs have a common goal i.e., precise, fast, and efficient crop improvement, individually they are markedly different in approach and characteristics from each other. In this review we describe in detail their mechanisms and applications for the improvement of fruit trees and consider the relationship between these biotechnological tools and the EU biosafety regulations applied to the plants and products obtained through these techniques.
Highlights
Conventional breeding for genetic improvement of woody fruit crops is a slow and difficult process, with drawbacks caused by high heterozygosity, extended juvenile periods, and autoincompatibility (Petri and Burgos, 2005; Rai and Shekhawat, 2014)
Taking into consideration the gene editing approaches (CRISPR/Cas9 system, zinc finger nucleases (ZFNs), transcription activatorlike effector (TALE) Nucleases (TALENs)’s, and Oligonucleotide-Directed Mutagenesis (ODM)) it has been demonstrated that their application can result in mutations similar to those that occur in nature or by use of traditional breeding techniques, with the important difference that these new technologies act in a much more specific way (Curtin et al, 2011; Tzfira et al, 2012; Hartung and Schiemann, 2014; Ren et al, 2016)
Biotechnological techniques have undergone rapid development adding novel and valuable tools for plant breeders. These techniques make it possible to create desirable crop cultivars in fast and more efficient ways to meet the demand for improved crops to support sustainable agricultural productivity and in order to cater for the ever-increasing world population
Summary
Conventional breeding for genetic improvement of woody fruit crops is a slow and difficult process, with drawbacks caused by high heterozygosity, extended juvenile periods, and autoincompatibility (Petri and Burgos, 2005; Rai and Shekhawat, 2014). If RNAi-based rootstocks can efficiently transfer the silencing molecules to non-transformed scions, RNAi can be applied to obtain virus resistant transgenic plants (Schaart and Visser, 2009; Lemgo et al, 2013).
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