A Transcriptional Analysis of the Genes Involved in the Ascorbic Acid Pathways Based on a Comparison of the Juice and Leaves of Navel and Anthocyanin-Rich Sweet Orange Varieties.

Sweet oranges are an important source of ascorbic acid (AsA). In this study, the content of AsA in the juice and leaves of four orange clonal selections, different in terms of maturity time and the presence/absence of anthocyanins, was correlated with the transcription levels of the main genes involved in the biosynthesis, recycling, and degradation pathways. Within each variety, differences in the above pathways and the AsA amount were found between the analysed tissues. Variations were also observed at different stages of fruit development and maturation. At the beginning of fruit development, AsA accumulation was attributable to the synergic action of l-galactose and Myo-inositol, while the l-gulose pathway was predominant between the end of fruit development and the beginning of ripening. In leaves, the l-galactose pathway appeared to play a major role in AsA accumulation, even though higher GalUr isoform expression suggests a synergistic contribution of both pathways in this tissue. In juice, the trend of the AsA content may be related to the decrease in the transcription levels of the GME, GDH, MyoOx, and GalUr12 genes. Newhall was the genotype that accumulated the most AsA. The difference between Newhall and the other varieties seems to be attributable to the GLDH, GalUr12, APX2, and DHAR3 genes.

Target-Genes Reveal Species and Genotypic Specificity of Anthocyanin Pigmentation in Citrus and Related Genera.

BACKGROUND: Anthocyanin pigmentation characterizes a number of tissues of Citrus and its relatives. The gain and loss of pigmentation is intriguing and is inherited variously among species. METHODS: Citrus germplasm was used to investigate the anthocyanin pigmentation of tissues never before considered, including stamen, style and stigma, and of young leaves, petals, rind and flesh of 28 genotypes belonging to 14 species. Citrus genotypes encompassed citron, lemon, sweet orange, lime, and Citrus relatives included Microcitrus, Murraya, and Severinia. A relative qRT-PCR analysis was carried out on the structural and regulatory genes: phenylalanine ammonia-lyase (PAL), chalcone synthase (CHS), chalcone isomerase (CHI), flavanone 3'-hydroxylase (F3H), dihydroflavonol 4-reductase (DFR), anthocyanidin synthase (ANS), uridine diphosphate glucose flavonoid glucosyl-transferase (UFGT), glutathione S-transferase (GST), Ruby and Noemi. Image analysis and a genomic approach were employed to evaluate how the red pigmentation is inherited among tissues and species. RESULTS: Pigmentation of young leaves and petals is specific to citron and its hybrids. Ruby controls the pigmentation of petals, but not of leaves. The red color of the rind and flesh is a trait that particularly characterizes a diversity of sweet oranges, citron hybrids and Citrus relatives. Color expression depends on external factors and also on developmental stage. The coloration of stamen and style is citron-specific, while a red stigma is exclusive to Moro orange and its hybrids. CONCLUSION: It is hypothesized that there is a relationship among Citrus species and genes controlling anthocyanin pigmentation.

Use of a custom array to study differentially expressed genes during blood orange (Citrus sinensis L. Osbeck) ripening.

A flesh-specific oligonucleotide custom array was designed to study gene expression during blood orange ripening. The array included 301 probes derived from a subtracted SSH library, a cDNA-AFLP collection, and a set of regulatory genes from the Harvest citrus database. The custom array was hybridized using samples of Moro, a pigmented cultivar, and Cadenera, a common cultivar, at three different ripening stages: the immature phase, the halfway point of maturation (corresponding to the start of Moro pigmentation) and the full ripening. Of the 301 probes, 27 in total, corresponding to 20 different transcripts, indicated differential expression in stage-to-stage and/or cultivar-to-cultivar comparisons. Transcripts encoding for anthocyanin biosynthesis represented most of the total over-expressed probes. The remaining differentially expressed transcripts were functionally associated with primary metabolism as flavor biosynthesis, defense and signal transduction. The expressed products associated with probes indicating differential expression were confirmed by qRT-PCR. The microarray was designed considering a small collection of sequences useful for monitoring specific pathways and regulatory genes related to fruit ripening and anthocyanin pigmentation. The main novelty of this customization is the use of expressed sequences specifically derived from blood orange flesh to study different cultivars and ripening stages, and the provision of further information about processes related to anthocyanin pigmentation in citrus fruit flesh.

Proteome analysis of Citrus sinensis L. (Osbeck) flesh at ripening time.

A combination of 2-DE and LC-MSMS approaches was used to identify the differentially expressed proteome of a pigmented sweet orange (Citrus sinensis, cv. Moro) in comparison with a common cultivar (Cadenera) at ripening time. The comparison of the protein patterns of Moro and Cadenera showed 64 differential expressed protein spots. Fifty-five differentially expressed proteins were identified. Proteins were classified according to their putative function and known biosynthetic pathways. Most of the proteins related to sugar metabolism were overexpressed in Moro, while those related to stress responses were overexpressed in Cadenera. The abundance of proteins belonging to Unknown/Unnamed and Hypothetical classes could be associated to the incomplete data available on the Citrus genome. The relative abundance of Secondary metabolism and Oxidative process proteins substantiated the key role of the anthocyanin pathway in Moro, which is characterized by a strong pigmentation at ripening time. The potential role of protein differential expression between Moro and Cadenera fruits was discussed, and proteomic results were compared with the known variations of transcripts of the same fruits. The latter analyses highlighted many discrepancies, confirming the necessity to associate both proteomic and transcriptomic approaches in order to achieve a more complete characterization of the biological system.