Plants contain many unique biosynthetic pathways producing a diverse array of natural products that are important for plant function, agriculture, and human nutrition. The tocochromanols define one such class of compounds, comprised of four tocopherols and four tocotrienols that are collectively termed vitamin E. Tocochromanols are synthesized only by plants and other oxygenic, photosynthetic organisms, and the eight individual compounds vary widely in their vitamin E activities. Vitamin E was recognized as an essential component in mammalian diets in the 1920s and the tocochromanol biosynthetic pathway elucidated from radiotracer studies in the mid 1980s. However, it is only recently that genetic and genomics-based approaches in model photosynthetic organisms have allowed the genes and proteins for tocochromanol synthesis to be isolated, setting the stage for targeted manipulation of tocochromanol levels and types in various crops. This article reviews advancements in our molecular and genetic understanding of the tocochromanol biosynthetic pathway in the model photosynthetic organisms Arabidopsis thaliana and Synechocystis sp. PCC6803 and highlights ongoing efforts to use this knowledge to manipulate the levels of this essential nutrient in food crops.