Plant farnesyltransferase can restore yeast Ras signaling and mating.

Farnesyltransferase (FTase) is a heterodimeric enzyme that modifies a group of proteins, including Ras, in mammals and yeasts. Plant FTase alpha and beta subunits were cloned from tomato and expressed in the yeast Saccharomyces cerevisiae to assess their functional conservation in farnesylating Ras and a-factor proteins, which are important for cell growth and mating. The tomato FTase beta subunit (LeFTB) alone was unable to complement the growth defect of ram1 delta mutant yeast strains in which the chromosomal FTase beta subunit gene was deleted, but coexpression of LeFTB with the plant alpha subunit gene (LeFTA) restored normal growth, Ras membrane association, and mating. LeFTB contains a novel 66-amino-acid sequence domain whose deletion reduces the efficiency of tomato FTase to restore normal growth to yeast ram1 delta strains. Coexpression of LeFTA and LeFTB in either yeast or insect cells yielded a functional enzyme that correctly farnesylated CaaX-motif-containing peptides. Despite their low degree of sequence homology, yeast and plant FTases shared similar in vivo and in vitro substrate specificities, demonstrating that this enzymatic modification of proteins with intermediates from the isoprenoid biosynthesis pathway is conserved in evolutionarily divergent eukaryotes.

Organ-specific differential regulation of a promoter subfamily for the ribulose-1,5-bisphosphate carboxylase/oxygenase small subunit genes in tomato.

The tomato (Lycopersicon esculentum) gene family for the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (RBCS) has been investigated to determine the role of promoter regions and DNA-protein interactions in the differential organ-specific transcription of individual genes. Transgenic plants expressing RBCS-promoter-beta-glucuronidase fusion genes have confirmed that promoter fragments ranging from 0.6 to 3.0 kb of the RBCS1, RBCS2, and RBCS3A genes were sufficient to confer the temporal, organ-specific, and differential expression pattern observed for the endogenous genes. The individual temporal and organ-specific beta-glucuronidase enzyme activities closely reflect the qualitative and quantitative transcription activities of the respective RBCS genes, including the strongly reduced activity of RBCS3A (L.A. Wanner, W. Gruissem [1991] Plant Cell 3: 1289-1303). In particular, tissue-specific activity of all three promoters is similar in developing fruit, with high activity in the locular tissue and extremely reduced activity in the pericarp. This specific pattern of gene activity was further substantiated by in situ analysis of RBCS mRNA levels. Together, the data suggest an interesting correlation between RBCS gene activity and sink strength in different fruit tissues. DNA-protein interaction studies have revealed a novel fruit-specific DNA-binding protein called FBF that specifically interacts with a sequence element directly upstream of the G-box in the RBCS3A promoter. FBF binding thus correlates with the reduced activity of this promoter in developing tomato fruit, rendering it a candidate for a fruit-specific negative regulator of transcription in tomato.