Cit1,2RhaT and two novel CitdGlcTs participate in flavor-related flavonoid metabolism during citrus fruit development.

Neohesperidosides are disaccharides that are present in some flavonoids and impart a bitter taste, which can significantly affect the commercial value of citrus fruits. In this study, we identified three flavonoid-7-O-di-glucosyltransferase (dGlcT) genes closely related to 1,2-rhamnosyltransferase (1,2RhaT) in citrus genomes. However, only 1,2RhaT was directly linked to the accumulation of neohesperidoside, as demonstrated by association analysis of 50 accessions and co-segregation analysis of an F1 population derived from Citrus reticulata × Poncirus trifoliata. In transgenic tobacco BY2 cells, over-expression of CitdGlcTs resulted in flavonoid-7-O-glucosides being catalysed into bitterless flavonoid-7-O-di-glucosides, whereas over-expression of Cit1,2RhaT converted the same substrate into bitter-tasting flavonoid-7-O-neohesperidoside. Unlike 1,2RhaT, during citrus fruit development the dGlcTs showed an opposite expression pattern to CHS and CHI, two genes encoding rate-limiting enzymes of flavonoid biosynthesis. An uncoupled availability of dGlcTs and substrates might result in trace accumulation of flavonoid-7-O-di-glucosides in the fruit of C. maxima (pummelo). Past human selection of the deletion and functional mutation of 1,2RhaT has led step-by-step to the evolution of the flavor-related metabolic network in citrus. Our research provides the basis for potentially improving the taste in citrus fruit through manipulation of the network by knocking-out 1,2RhaT or by enhancing the expression of dGlcT using genetic transformation.

Boron reduces aluminum-induced growth inhibition, oxidative damage and alterations in the cell wall components in the roots of trifoliate orange.

Aluminum (Al) toxicity is a major restriction for crops production on acidic soils. The primary symptom of aluminum toxicity is visible in the roots of plants. Recently, several studies reported the alleviation of Al toxicity by the application of Boron (B), however, the information how B alleviates Al toxicity is not well understood. Thus, we investigated the ameliorative response of B on Al-induced growth inhibition, oxidative damages, and variations in the cell wall components in trifoliate orange roots. The results indicated that plants under Al stress experienced a substantial decrement in root length and overall plant growth. The supply of B improved the root elongation by eliminating oxidative stress, membrane peroxidation, membrane leakage, and cell death produced under Al toxicity. Moreover, accumulation of Al on the cell wall and alteration in the cell wall components might be one of the causes resulting in the quick inhibition of root elongation under B-starvation circumstances by providing susceptible negative charges on pectin matrix for binding of Al. The results provide a useful understanding of the insight into mechanisms of B-induced mitigation of Al toxicity especially in the trifoliate orange that might be helpful in the production of crops on acidic soils.

PtSVP, an SVP homolog from trifoliate orange (Poncirus trifoliata L. Raf.), shows seasonal periodicity of meristem determination and affects flower development in transgenic Arabidopsis and tobacco plants.

A MADS-box gene was isolated using the suppressive subtractive hybridization library between early-flowering mutant and wild-type trifoliate orange (Poncirus trifoliata L. Raf.). This gene is highly homologous with Arabidopsis SHORT VEGETATIVE PHASE (SVP). Based on real-time PCR and in situ hybridization during bud differentiation, PtSVP was expressed intensively in dormant tissue and vegetative meristems. PtSVP transcripts were detected in apical meristems before floral transition, then down-regulated during the transition. PtSVP expression was higher in differentiated (flower primordium) than in undifferentiated cells (apical meristems). The PtSVP expression pattern during apical meristem determination suggested that its function is not to depress flower initiation but to maintain meristem development. Transcription of PtSVP in Arabidopsis svp-41 showed partially rescued SVP function. Ectopic overexpression of PtSVP in wild-type Arabidopsis induced late flowering similar to the phenotypes induced by other SVP/StMADS-11-like genes, but transformants produced additional trichomes and floral defects, such as flower-like structures instead of carpels. Ectopic expression of PtSVP in tobacco also caused additional florets. Overexpression of PtSVP in tobacco inhibited early transition of the coflorescence and prolonged coflorescence development, thus causing additional florets at the later stage. A yeast two-hybrid assay indicated that PtSVP significantly interacted with PtAP1, a homolog of Arabidopsis APETALA1 (AP1). These findings suggest that citrus SVP homolog genes are involved in flowering time regulation and may influence inflorescence meristem identity in some conditions or genetic backgrounds. SVP homologs might have evolved among plant species, but the protein functions are conserved between Arabidopsis and citrus.

[Effects of arbuscular mycorrhizal fungi on growth and iron uptake of Poncirus trifoliata under different pH].

OBJECTIVE: We studied the effects of arbuscular mycorrhizal fungus ( Glomus versiforme) on growth and iron uptake of trifoliate orange [Poncirus trifoliata (L.) Raf.] at different pH levels of nutrient solution. METHODS: P. trifoliata seedlings were grown in substrates watered by nutrient solution with 50 microM Feethylenediaminetetraacetic acid (EDTA) at pH values of 5.0, 6.0 (as control), 7.0 and 8.0 with a sand culture. Mycorrhizal colonization was tested by trypan blue staining method. Chlorophyll concentratration and root Fe (III) chelate reductase activity were determined by spectrophotometer. Potassium and active iron contents were quantified by atomic spectrometry, and phosphorus contents was through phospho-vanado- molybdate colorimetry. RESULTS: The colonization of Glomus versiforme significantly increased the plant height, stem diameter, leaf numbers, and dry mass. Arbuscular mycorrhizal fungus significantly enhanced the accumulation of chlorophyll, active iron, total iron and root Fe(III) chelate reductase activity, and decreased P/Fe and 50 (10P + K)/Fe ratios. All biomass, iron contents and root Fe(III) chelate reductase activities of P. trifoliata seedlings at pH 6.0 level were the maximum both in inoculated and non-inoculated treatments. CONCLUSION: Arbuscular mycorrhizal fungi could remedy chlorosis caused by iron-deficiency in citrus, and 6.0 was the optimal pH value for the growth of P. trifoliata seedlings.