Impact of a Conserved N-terminal Proline-Rich Region of the Α-Subunit of CAAX-prenyltransferases on Their Enzyme Properties

The CAAX-prenyltransferases farnesyltransferase (FTase) and geranylgeranyltransferase I (GGTase I) are heterodimers with a common α- (FTα) and unique β-subunits. Recently, α-subunits of species (e.g., human) that harbour an N-terminal proline-rich region (PRR) showed different dimerization behaviours than α-subunits without PRR (e.g., yeast). However, the specific function of the PRR has not been elucidated so far. To determine whether the PRR is a conserved motif throughout eukaryotes, we performed phylogenetics. Elucidating the impact of the PRR on enzyme properties, we cloned human as well as rat PRR deficient FTα, expressed them heterologously and compared protein–protein interaction by pull-down as well as crosslinking experiments. Substrate binding, enzyme activity and sensitivity towards common FTase inhibitors of full length and PRR-deletion α-subunits and their physiological partners was determined by continuous fluorescence assays. The PRR is highly conserved in mammals, with an exception for marsupials harbouring a poly-alanine region instead. The PRR shows similarities to canonical SH3-binding domains and to profilin-binding domains. Independent of the PRR, the α-subunits were able to dimerize with the different physiological β-subunits in in vitro as well as in yeast two-hybrid experiments. FTase and GGTase I with truncated FTα were active. The KM values for both substrates are in the single-digit µM range and show no significant differences between enzymes with full length and PRR deficient α-subunits within the species. Our data demonstrate that an N-terminal PRR of FTα is highly conserved in mammals. We could show that the activity and inhibitability is not influenced by the truncation of the N-terminal region. Nevertheless, this region shows common binding motifs for other proteins involved in cell-signalling, trafficking and phosphorylation, suggesting that this PRR might have other or additional functions in mammals. Our results provide new starting points due to the relevant but only partly understood role of FTα in eukaryotic FTase and GGTase I.