Transcriptomic Events Involved in Melon Mature-Fruit Abscission Comprise the Sequential Induction of Cell-Wall Degrading Genes Coupled to a Stimulation of Endo and Exocytosis

Background: Mature-fruit abscission (MFA) in fleshy-fruit is a genetically controlled process with mechanisms that, contrary to immature-fruit abscission, has not been fully characterized. Here, we use pyrosequencing to characterize the transcriptomes of melon abscission zone (AZ) at three stages during AZ-cell separation in order to understand MFA control at an early stage of AZ-activation. Principal Findings: The results show that by early induction of MFA, the melon AZ exhibits major gene induction, while by late induction of MFA, melon AZ shows major gene repression. Although some genes displayed similar regulation in both early and late induction of abscission, such as EXT1-EXT4, EGase1, IAA2, ERF1, AP2D15, FLC, MADS2, ERAF17, SAP5 and SCL13 genes, the majority had different expression patterns. This implies that time-specific events occur during MFA, and emphasizes the value of characterizing multiple time-specific abscission transcriptomes. Analysis of gene-expression from these AZs reveal that a sequential induction of cell-wall-degrading genes is associated with the upregulation of genes involved in endo and exocytosis, and a shift in plant-hormone metabolism and signaling genes during MFA. This is accompanied by transcriptional activity of small-GTPases and synthaxins together with tubulins, dynamins, V-type ATPases and kinesin-like proteins potentially involved in MFA signaling. Early events are potentially controlled by down-regulation of MADS-box, AP2/ERF and Aux/IAA transcription-factors, and up-regulation of homeobox, zinc finger, bZIP, and WRKY transcription-factors, while late events may be controlled by up-regulation of MYB transcription-factors. Significance: Overall, the data provide a comprehensive view on MFA in fleshy-fruit, identifying candidate genes and pathways associated with early induction of MFA. Our comprehensive gene-expression profile will be very useful for elucidating gene regulatory networks of the MFA in fleshy-fruit

Genome Sequencing, Transcriptomics, and Proteomics

This review encompasses the current status of major areas of progress in olive tree genome sequencing, including insights into genome function derived from large-scale gene expressing profiling, and studies on genomic architecture of repetitive sequences, smaller RNA, and proteomics. Olive tree genomics, as well as other omics, is progressing owing to recent developments in next-generation sequencing (NGS) technologies. Biological insights, therefore, are not only resulted from the sequencing initiative, since from genetic mapping, gene expression profiling, gene discovery research, and proteomics over nearly last seven years a large amount of information has been provided by different laboratories. The availability of highquality genome assembly provides olive biologists with valuable new tools to improve and develop new varieties more efficiently, enabling the implementation of marker-assisted selection and genomic selection, and contributing to the comprehension of the molecular determinants of key traits peculiar to the species of olive tree and giving important clues concerning the evolution of its complex genome