Chapter 1 - High efficiency transit peptides for protein transport into leucoplasts Plastids differentiate into various functional types in different tissues, for instance, chloroplasts in leaves for photosynthesis, chromoplasts in orange-colored fruits for carotenoid synthesis, and leucoplasts for nutrient synthesis and storage in white-colored roots and seeds. Plastid proteins are encoded by the nucleus and are translated in the cytosol. Under the direction of the transit peptide at the N-terminus, the proteins are targeted to plastids to function. It is known that different transit peptides prefer different plastid types. Most transit peptides characterized so far are for targeting proteins to chloroplasts. There is no tool available for high efficiency delivery of proteins into leucoplasts. However, leucoplasts are the plastids in major human food crops like rice, wheat, and potatoes. We therefore selected a few transit peptides that show high import efficiency into leucoplasts in vitro. We transformed GFP fusion constructs of these transit peptides into Arabidopsis thaliana. GFP fusion with the transit peptide of the precursor to the small subunit of RuBP carboxylase (RBCStp), the most commonly used chloroplast-targeting transit peptide, was also constructed and transformed into Arabidopsis to be used as a control. Then I used real-time PCR, western blotting and microscopy to analyze the efficiency of these transit peptides in delivering GFP proteins to leucoplasts. My results show that our candidate transit peptides all have higher efficiency in delivering GFP to leucoplasts than RBCStp. Interestingly, most candidate transit peptides also have better efficiency in delivering GFP to leaf chloroplasts than RBCStp. Meanwhile, I found that different transit peptides show different preference between petals and roots. In summary, these transit peptides could be valuable tools for delivering desired proteins into leucoplasts for biotechnology applications in the future. Chapter 2 - Genetic screening to identify cytosolic sorting factors for chloroplast and mitochondrion protein import In plant cells, mitochondria and chloroplast are essential organelles that perform important functions such as ATP production and photosynthesis. Most proteins in mitochondria and chloroplasts are encoded by the nuclear genome. These proteins are first synthesized in the cytosol as precursor proteins with an N-terminal targeting signal. How precursor proteins are targeted from the cytosol to the mitochondrion or chloroplast is unknown. Although some general chaperone proteins, such as HSP70 and 14-3-3 proteins, have been shown to interact with cytosolic precursor proteins, no factors that can specifically target cytosolic precursor proteins to chloroplasts or mitochondria have been identified. To identify cytosolic targeting factors for mitochondria and chloroplasts, we designed a genetic screen for identifying Arabidopsis mutants defective in protein sorting to mitochondria. We fused the mitochondrial targeting signal of alternative oxidase (AOX) to the N terminus of an EPSP synthase variant (EPSPS-TIPS), which confers glyphosate resistance when localized in chloroplasts. We transformed the fusion construct into wild-type Arabidopsis. Mutagenized M2 seeds of the transformant were grown on MS medium containing 12.5 μM glyphosate for 12 days. Plants with expanded true leaves, which suggest potential glyphosate resistance, were selected. The mutant locus of a confirmed glyphosate resistant mutant was mapped by PCR-based markers and next generation sequencing. The mutation was mapped to the gene AT2G28800, which is named ALB3 (albino 3) because loss-of-function mutations of this gene cause an albino phenotype.