Replicating minichromosomes as a new tool for plastid genome engineering.

Plant molecular farming, that is, using plants as hosts for production of therapeutic proteins and high-value compounds, has gained substantial interest in recent years. Chloroplasts in particular are an attractive subcellular compartment for expression of foreign genes. Here, we present a new method for transgene introduction and expression in chloroplasts that, unlike classically used approaches, does not require transgene insertion into the chloroplast genome. Instead, the transgene is amplified as a physically independent entity termed a 'minichromosome'. Amplification occurs in the presence of a helper protein that initiates the replication process via recognition of specific sequences flanking the transgene, resulting in accumulation of extremely high levels of transgene DNA. Importantly, we demonstrate that such amplified transgenes serve as a template for foreign protein expression, are maintained stably during plant development and are maternally transmitted to the progeny. These findings indicate that the minichromosome-based approach is an attractive tool for transgene expression in chloroplasts and for organelle genome engineering.

Induction of phenotypic variation by activation of genes harbouring a maize Spm element in their promoter regions using a TnpA-VP16 fusion protein.

For many crops, a narrowing genetic base is becoming an increasingly significant problem for improvements made through breeding. Commonly used breeding procedures systematically reduce genetic diversity within elite gene pools. Here we describe a new technique for activation of genes in lines carrying Spm or dSpm transposon insertions. Activation of genes in Arabidopsis harbouring Spm or dSpm insertions in their promoters can be induced by over-expression of the TnpA-VP16 fusion protein, which binds Spm ends and activates local transcription. As a result, a variety of phenotypes are recovered from multiple-copy Spm lines in Arabidopsis. Application of this technique to a number of Spm insertion collections in Arabidopsis provides a valuable approach for new insights into plant gene functions. It also provides a proof-of-principle demonstration that the method could be used to generate new variation in elite lines of maize.