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Abstract
SummaryPlant synthetic biology and cereal engineering depend on the controlled expression of transgenes of interest. Most engineering in plant species to date has relied heavily on the use of a few, well‐established constitutive promoters to achieve high levels of expression; however, the levels of transgene expression can also be influenced by the use of codon optimization, intron‐mediated enhancement and varying terminator sequences. Most of these alternative approaches for regulating transgene expression have only been tested in small‐scale experiments, typically testing a single gene of interest. It is therefore difficult to interpret the relative importance of these approaches and to design engineering strategies that are likely to succeed in different plant species, particularly if engineering multigenic traits where the expression of each transgene needs to be precisely regulated. Here, we present data on the characterization of 46 promoters and 10 terminators in Medicago truncatula, Lotus japonicus, Nicotiana benthamiana and Hordeum vulgare, as well as the effects of codon optimization and intron‐mediated enhancement on the expression of two transgenes in H. vulgare. We have identified a core set of promoters and terminators of relevance to researchers engineering novel traits in plant roots. In addition, we have shown that combining codon optimization and intron‐mediated enhancement increases transgene expression and protein levels in barley. Based on our study, we recommend a core set of promoters and terminators for broad use and also propose a general set of principles and guidelines for those engineering cereal species.
Highlights
Plant synthetic biology seeks to engineer novel traits into plants and these engineering efforts need to be directed in crop species to be of agronomic relevance (Kotopka et al, 2018; Liu and Stewart, 2015)
This allowed us to define a library of standard genetic parts consisting of 46 different promoter sequences, and these were classified according to three different attributes relevant to the needs of our engineering project and of the cereal engineering community in general: constitutive promoters; symbiosis-related promoters; and root-specific promoters
The decision to include each promoter sequence was based on the original publications reporting the initial characterisation of each individual genetic part
Summary
Plant synthetic biology seeks to engineer novel traits into plants and these engineering efforts need to be directed in crop species to be of agronomic relevance (Kotopka et al, 2018; Liu and Stewart, 2015). Engineering of complex traits requires the expression of multiple stacked transgenes and the repetitive use of genetic parts (e.g. promoters and terminators) is not desirable due to potential problems of T-DNA stability/integrity and gene silencing in future generations (Meyer and Saedler, 1996). Such complex traits may require precise control and accurate regulation of transgene expression, e.g. at the level of individual cells and tissues, and at particular times during development. At present the number of genetic parts for plant synthetic biology and cereal engineering is limited, and there is need to expand the number of characterised standard genetic parts to realise the opportunities in plant engineering (Schaumberg et al, 2016)
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