Recovery and genotyping ancient Sicilian monumental olive trees

The long-lived and evergreen olive tree dominates the Mediterranean landscape, representing an agroecological and cultural symbol and a genetic heritage of inestimable value. Sicily, for historical, geographical, and cultural reasons, has a very rich and distinctive olive germplasm. In this work, a large survey was conducted to discover, collect, and characterize the genetic diversity of centennial monumental olive trees from historical sites, such as the Greek Temple Valley (Agrigento), ancient gardens, or farmland present in the western part of the island. Trees were chosen based on their height, trunk, stump size, and presumed age; particularly, only olive trees with an age estimated at more than 400 years old were taken into consideration. For the morphological characterization, the leaf, fruit, and endocarp traits were analyzed. For the molecular characterization, 11 polymorphic microsatellite markers largely used for fingerprinting analysis were used. Reference cultivars were included in the analysis for comparison. Nuclear DNA was extracted from different parts of the plant (young leaves of shoots taken from the canopy and young leaves taken from suckers, which arose from the basal part of the tree) to check if the trees were grafted and to explore their diversity. Most of the monumental trees have been grafted at least one time during their long life, and some genotypes showed unique genetic profiles combined with peculiar phenotypic traits. Suckers (rootstock of the trees) showed a strict genetic relationship with an ancient monumental oleaster tree, also included in the study. “Patriarch” (original mother plants) trees of local cultivars were also identified. This research revealed a high level of the still unexplored genetic diversity of the Sicilian olive germplasm and highlighted its importance as a gene reservoir, which could support new breeding programs for the evaluation and possible selection of traits linked to putative resilience to abiotic and biotic stresses (particularly Xylella fastidiosa subsp. pauca ST53 or soil- borne diseases or insects). The results will be useful for improving the conservation process, enriching existing collections of olive genetic resources, and supporting on-farm conservation projects

Production of ipt-expressing white poplar lines (Populus alba L.) with abnormal root morphology

Agrobacterium-mediated transformation of white poplar explants was performed using the pMAT-MT construct derived from the ipt-type MAT22 plasmid carrying the PsMTA1 cDNA encoding a pea metallothionein. In vitro shoot regeneration occurred on antibiotic-free medium and transformants were identified by visual selection. Beside the expected abnormal ipt-shooty phenotype, shoots with normal morphology were recovered. Interestingly, an additional phenotype characterised by a remarkable root development was also observed

Expression of the pea metallothionein 2A gene in white poplar: implication for heavy metal stress response.

none9noneCARBONERA D.; BALESTRAZZI A; BOTTI S; ZELASCO S; BIONDI S; LINGUA G; FRANCHIN C; CESARO P; CALLIGARI P.CARBONERA D.; BALESTRAZZI A; BOTTI S; ZELASCO S; BIONDI S; LINGUA G; FRANCHIN C; CESARO P; CALLIGARI P