Factors influencing transient gene expression in bean (Phaseolus vulgaris L.) using an electrical particle acceleration device

Enhanced transgene expression in sugarcane by co-expression of virus-encoded RNA silencing suppressors

Post-transcriptional gene silencing is commonly observed in polyploid species and often poses a major limitation to plant improvement via biotechnology. Five plant viral suppressors of RNA silencing were evaluated for their ability to counteract gene silencing and enhance the expression of the Enhanced Yellow Fluorescent Protein (EYFP) or the β-glucuronidase (GUS) reporter gene in sugarcane, a major sugar and biomass producing polyploid. Functionality of these suppressors was first verified in Nicotiana benthamiana and onion epidermal cells, and later tested by transient expression in sugarcane young leaf segments and protoplasts. In young leaf segments co-expressing a suppressor, EYFP reached its maximum expression at 48-96 h post-DNA introduction and maintained its peak expression for a longer time compared with that in the absence of a suppressor. Among the five suppressors, Tomato bushy stunt virus-encoded P19 and Barley stripe mosaic virus-encoded γb were the most efficient. Co-expression with P19 and γb enhanced EYFP expression 4.6-fold and 3.6-fold in young leaf segments, and GUS activity 2.3-fold and 2.4-fold in protoplasts compared with those in the absence of a suppressor, respectively. In transgenic sugarcane, co-expression of GUS and P19 suppressor showed the highest accumulation of GUS levels with an average of 2.7-fold more than when GUS was expressed alone, with no detrimental phenotypic effects. The two established transient expression assays, based on young leaf segments and protoplasts, and confirmed by stable transgene expression, offer a rapid versatile system to verify the efficiency of RNA silencing suppressors that proved to be valuable in enhancing and stabilizing transgene expression in sugarcane.

Factors affecting the genetic engineering of plants by microprojectile bombardment

Since its development in the mid-1980s, microprojectile bombardment has been widely employed as a method for direct gene transfer into a wide range of plants, including the previously difficult-to-transform monocotyledonous species. Although the numerous instruments available for microprojectile-mediated gene delivery and their applications have been widely discussed, less attention has been paid to the critical factors which affect the efficiency of this method of gene delivery. In this review we do not wish to describe the array of devices used for microprojectile delivery or their uses which have already been definitively described, but instead wish to report on research developments investigating the factors which affect microprojectile-mediated transformation of plants.

Transient expression of GUS and the 2S albumin gene from Brazil nut in peanut (Arachis hypogaea L.) seed explants using particle bombardment

The effect of parameters involved in the transformation efficiency of peanut (Arachis hypogaea L.) seed tissues by direct gene transfer using a helium inflow particle bombardment device was evaluated. Transient gene expression was affected by both particle and DNA amounts, and was positively correlated with gene copy number, as determined byβ-glucuronidase (GUS) activity assays. No influence of plasmid size on GUS gene expression was observed. Transcriptional control of GUS by either the CaMV 35S or the 2S promoter from Brazil nut 2S albumin gene varied with the developmental stage of the seed and was approximately tenfold greater under the influence of the 35S promoter than under the 2S promoter. The gene products of both the Brazil nut methionine-rich 2S albumin and GUS genes under the transcriptional control of the 35S promoter were detected by ELISA assays.

Particle bombardment: a universal approach for gene transfer to cells and tissues

In the past year, significant progress in the field of gene transfer has been made possible by refinement of the technique of particle bombardment. The process has been utilized for the study of gene expression in plastids and mitochondria, the production of transgenic crop plants and gene transfer into live animals. Bombarding tissues of live animals with genes that code for antigenic proteins may provide an effective means of vaccination.