The potential of SNP-based PCR-RFLP capillary electrophoresis analysis to authenticate and detect admixtures of Mediterranean olive oils.

Authentication and traceability of extra virgin olive oil is a challenging research task due to the complexity of fraudulent practices. In this context, the monovarietal olive oils of Protected Designation of Origin (PDO) and Protected Geographical Indication (PGI) require new tests and cutting edge analytical technologies to detect mislabeling and misleading origin. Toward this direction, DNA-based technologies could serve as a complementary to the analytical techniques assay. Single nucleotide polymorphisms are ideal molecular markers since they require short PCR analytical targets which are a prerequisite for forensic applications in olive oil sector. In the present study, a small number of polymorphic SNPs were used with an SNP-based PCR-RFLP capillary electrophoresis platform to discriminate six out of 13 monovarietal olive oils of Mediterranean origin from three different countries, Greece, Tunisia, and Lebanon. Moreover, the high sensitivity of capillary electrophoresis in combination with the DNA extraction protocol lowered the limit of detection to 10% in an admixture of Tsounati in a Koroneiki olive oil matrix.

454 Pyrosequencing of Olive (Olea europaea L.) Transcriptome in Response to Salinity.

Olive (Olea europaea L.) is one of the most important crops in the Mediterranean region. The expansion of cultivation in areas irrigated with low quality and saline water has negative effects on growth and productivity however the investigation of the molecular basis of salt tolerance in olive trees has been only recently initiated. To this end, we investigated the molecular response of cultivar Kalamon to salinity stress using next-generation sequencing technology to explore the transcriptome profile of olive leaves and roots and identify differentially expressed genes that are related to salt tolerance response. Out of 291,958 obtained trimmed reads, 28,270 unique transcripts were identified of which 35% are annotated, a percentage that is comparable to similar reports on non-model plants. Among the 1,624 clusters in roots that comprise more than one read, 24 were differentially expressed comprising 9 down- and 15 up-regulated genes. Respectively, inleaves, among the 2,642 clusters, 70 were identified as differentially expressed, with 14 down- and 56 up-regulated genes. Using next-generation sequencing technology we were able to identify salt-response-related transcripts. Furthermore we provide an annotated transcriptome of olive as well as expression data, which are both significant tools for further molecular studies in olive.

A SNP-based PCR-RFLP capillary electrophoresis analysis for the identification of the varietal origin of olive oils.

Authenticity and traceability of high quality monovarietal extra virgin olive oils is a major concern for markets and consumers. Although analytical chemistry techniques are widely used to satisfy these needs recently developed DNA-based methods can serve as complementary approaches. A SNP database comprising 10 Greek olive varieties was constructed and five SNPs, residing in restriction sites, were selected for the development of a PCR-RFLP capillary electrophoresis method to discriminate these varieties using leaf DNA as template. An identification key was constructed indicating that five SNPs were adequate to discriminate nine out of the 10 varieties. As a proof of principle the assay was applied on DNA extracted from five of their corresponding monovarietal olive oils. Three SNPs were able to identify the varietal origin of these olive oils confirming the validity of this approach.

Characterization of two carnation petal prolyl 4 hydroxylases.

Prolyl 4-hydroxylases (P4Hs) catalyze the proline hydroxylation, a major post-translational modification, of hydroxyproline-rich glycoproteins. Two carnation petal P4H cDNAs, (Dianthus caryophyllus prolyl 4-hydroxylase) DcP4H1 and DcP4H2, were identified and characterized at the gene expression and biochemical level in order to investigate their role in flower senescence. Both mRNAs showed similar patterns of expression with stable transcript abundance during senescence progression and differential tissue-specific expression with DcP4H1 and DcP4H2 strongly expressed in ovaries and stems, respectively. Recombinant DcP4H1 and DcP4H2 proteins were produced and their catalytic properties were determined. Pyridine 2,4-dicarboxylate (PDCA) was identified as a potent inhibitor of the in vitro enzyme activity of both P4Hs and used to determine whether inhibition of proline hydroxylation in petals is involved in senescence progression of cut carnation flowers. PDCA suppressed the climacteric ethylene production indicating a strong correlation between the inhibition of DcP4H1 and DcP4H2 activity in vitro by PDCA and the suppression of climacteric ethylene production in cut carnation flowers.

Involvement of Arabidopsis prolyl 4 hydroxylases in hypoxia, anoxia and mechanical wounding.

Arabidopsis prolyl 4 hydroxylases (P4Hs) catalyze an important post-translational modification in plants, though the only information on their patterns of expression is solely based on Arabidopsis microarray analysis data. In addition, the expression patterns of plants P4Hs in response to hypoxia, anoxia and other abiotic stresses such as mechanical wounding have never been studied extensively, despite their central role in hypoxic response of several other organisms through the regulation of stability of the HIF-1alpha transcription factor, the global regulator of hypoxic response. The 13 putative Arabidopsis P4Hs are low abundance transcripts with differential patterns of expression in response to two hypoxic, 1.5% and 5% O(2), anoxic conditions and mechanical wounding. Hypoxia of 1.5% O(2) induced the expression of six At-P4Hs while hypoxia of 5% O(2) and anoxia induced the expression of three and two At-P4Hs, respectively. Moreover, 308 Arabidopsis genes including 25 transcription factors were identified in silico among the differentially expressed genes under hypoxia that contain proline hydroxylation motifs. These results suggest involvement of this post-translational modification in the processing of hypoxia induced proteins providing an alternative level of regulation for responses to oxygen deficiency conditions.