The squash aspartic proteinase inhibitor SQAPI is widely present in the cucurbitales, comprises a small multigene family, and is a member of the phytocystatin family.

The squash (Cucurbita maxima) phloem exudate-expressed aspartic proteinase inhibitor (SQAPI) is a novel aspartic acid proteinase inhibitor, constituting a fifth family of aspartic proteinase inhibitors. However, a comparison of the SQAPI sequence to the phytocystatin (a cysteine proteinase inhibitor) family sequences showed approximately 30% identity. Modeling SQAPI onto the structure of oryzacystatin gave an excellent fit; regions identified as proteinase binding loops in cystatin coincided with regions of SQAPI identified as hypervariable, and tryptophan fluorescence changes were also consistent with a cystatin structure. We show that SQAPI exists as a small gene family. Characterization of mRNA and clone walking of genomic DNA (gDNA) produced 10 different but highly homologous SQAPI genes from Cucurbita maxima and the small family size was confirmed by Southern blotting, where evidence for at least five loci was obtained. Using primers designed from squash sequences, PCR of gDNA showed the presence of SQAPI genes in other members of the Cucurbitaceae and in representative members of Coriariaceae, Corynocarpaceae, and Begoniaceae. Thus, at least four of seven families of the order Cucurbitales possess member species with SQAPI genes, covering approximately 99% of the species in this order. A phylogenetic analysis of these Cucurbitales SQAPI genes indicated not only that SQAPI was present in the Cucurbitales ancestor but also that gene duplication has occurred during evolution of the order. Phytocystatins are widespread throughout the plant kingdom, suggesting that SQAPI has evolved recently from a phytocystatin ancestor. This appears to be the first instance of a cystatin being recruited as a proteinase inhibitor of another proteinase family.

Expression of biotin-binding proteins, avidin and streptavidin, in plant tissues using plant vacuolar targeting sequences.

Tobacco plants have been developed which constitutively express high levels of the biotin-binding proteins, avidin and streptavidin. These plants were phenotypically normal and produced fertile pollen and seeds. The transgene was expressed and its product located in the vacuoles of most cell types in the plants. Targeting was achieved by use of N-terminal vacuolar targeting sequences derived from potato proteinase inhibitors which are known to target constitutively to vacuoles in potato tubers and, under wound-induction, in tomato leaves. Avidin was located in protein body-like structures within the vacuole and transgene protein levels remained relatively constant throughout the lifetime of the leaf. We describe two chimeric constructs with similar levels of expression. One comprised a potato proteinase inhibitor I signal peptide cDNA sequence attached to an avidin cDNA and the second a potato proteinase inhibitor II signal peptide genomic sequence (including an intron) attached to a core streptavidin synthetic sequence. We were unable to regenerate plants when transformation used constructs lacking the targeting sequences. The highest levels observed (up to 1.5% of total leaf protein) confirm the vacuole as the organelle of choice for stable storage of plant-toxic transgene products. The efficient targeting of these proteins did not result in any measured changes in plant biotin metabolism.