Abstract
Reverse transfection microarrays were described recently as a high throughput method for studying gene function. We have investigated the use of this technology for determining the subcellular localization of proteins. Genes encoding 16 proteins with a variety of functions were placed in Gateway expression constructs with 3′ or 5′ green fluorescent protein (GFP) tags. These were then packaged in transfection reagent and spotted robotically onto a glass slide to form a reverse transfection array. HEK293T cells were grown over the surface of the array until confluent and GFP fluorescence visualized by confocal microscopy. All C-terminal fusion proteins localized to cellular compartments in accordance with previous studies and/or bioinformatic predictions. However, less than half of the N-terminal fusion proteins localized correctly. Of those that were not in concordance with the C-terminal tagged proteins, half did not exhibit expression and the remainder had differing subcellular localizations to the C-terminal fusion protein. This data indicates that N-terminal tagging with GFP adversely affects the protein localization in reverse transfection assays, whereas tagging with GFP at the C-terminal is generally better in preserving the localization of the native protein. We discuss these results in the context of developing high-throughput subcellular localization assays based on the reverse transfection array technology.
Highlights
Reverse transfection (Ziauddin, 2001) is a powerful new technology with the potential to provide a high throughput screen of gene function, identification of novel drug targets and determination of the subcellular localization of proteins (Wu, 2002; Bailey, 2002)
Replicate working plates were prepared in LB media containing 8% glycerol (Sigma, Dorset, UK) and 50 μg/ml ampicillin (Sigma), grown at 37 ◦C overnight and stored at −70 ◦C. 5 primers were designed with CACC plus a further 18 bp from the first bp of the start codon. 3 primers were designed with 18 bp before the first bp of the stop codon
Sixteen genes were chosen from three different functional classes; kinase, transcription factor and surface receptor, with differing subcellular localizations to ensure that the findings were widely applicable
Summary
Reverse transfection (Ziauddin, 2001) is a powerful new technology with the potential to provide a high throughput screen of gene function, identification of novel drug targets and determination of the subcellular localization of proteins (Wu, 2002; Bailey, 2002). Reverse transfection technology entails inserting full-length open reading frames (ORFs) of genes of interest (GOI) into an expression vector. These vectors are packaged into a transfection reagent and printed onto a glass slide to form a microarray. If the expression vector contains a ‘tag’, the subcellular localization of the transgene can be analysed. Using this approach, large numbers of assays can be performed in a single study
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
