Cell division and expansion are largely completed by 12 16 dpp, with some variation depending on cultivar and season. In addition to cell division and expansion, early devel opment also includes specialized tissue and organ devel opment and interaction with the abiotic and biotic environment. For example, developing cucumber fruit exhibit a distinct change in susceptibility to the soil borne, oomycete pathogen, Phytophthora capsici. young fruit are highly susceptible, while older fruit are resistant. There is a sharp transition in susceptibility that occurs at approximately 1012 dpp coinciding with the end of the period of rapid fruit elongation. This age related resistance suggests additional kinds of develop mental changes occurring in the young cucumber fruit.
Although a limited number of studies have examined gene expression during early fruit development, a picture reflecting cell division and expansion selleck chemicals PP242 is beginning to emerge based on transcriptomic studies of apple, cucum ber, grape, tomato and watermelon. Among the enriched categories associated with tomato fruit set, were genes associated with protein biosynthesis, histones, nucleo some and chromosome assembly and cell cycle, suggest ing a profile reflective of active cell division. In contrast, various water, sugar and organic acid transport associated genes were under represented, but then increased with the transition from cell division to cell ex pansion.
Highly expressed categories of genes expressed PF-562271 solubility in expanding cucumber, as well as apple, grape, tomato, melon and watermelon fruits, included cytoskeleton and cell wall modifying genes such as tubulins, expansins, endo 1,2 B glucanase, beta glucosidases, pectate lyases, and pectin methylesterases, and transport associated genes such as aquaporins, vacuolar HATPases, and phloem associated proteins . The most highly represented transcripts in rapidly expanding cu cumber fruit also were strongly enriched for defense related homologs including, lipid, latex, and defense related genes, e. g. chitinase, thionin, hevein, snakin, peroxidase, catalase, thioredoxin, and dehydrins. The early stages of fruit development, including fruit set and exponential growth, are clearly essential for all fruits. However, despite their importance as determi nants of fruit size and yield, there has been little detailed analysis of this phase of development. Most studies to date, including recent transcriptomic studies, have fo cused on late development, or a broad range of develop mental stages, with only a single snapshot during early development eg. In this study we combined morphological characterization with transcriptome ana lysis to provide new insight into important early fruit developmental stages and processes.