Giuseppina Las Casas

Microsatellite markers help to assess genetic diversity among Opuntia ficus indica cultivated genotypes and their relation with related species.

Opuntia spp. belong to the Cactaceae family and are native to Central America. The most economically important species is O. ficus indica, cultivated both for fruits and cladodes. The genus includes other important edible species (from diploid to octoploid) that occur worldwide as either wild or cultivated species in many arid or semiarid areas (e.g., the Mediterranean region). Several accessions are cultivated in different growing regions, but little is known about their ancestries and levels of genetic diversity. The aim of this study was to investigate the level of intraspecific genetic diversity among O. ficus indica cultivated varieties and some related species. Specifically, six highly polymorphic simple sequence repeats (SSR) and two expressed sequence tag (EST)-SSR loci were investigated in 62 wild and cultivated genotypes belonging to 16 Opuntia species. The clusters identified by the distance and model-based analyses clearly separated the wild opuntias from the cultivated ones. However, the O. ficus indica accessions did not cluster separately from other arborescent cactus pear species, such as O. amyclaea, O. megacantha, O. streptacantha, O. fusicaulis, and O. albicarpa, indicating that their current taxonomical classifications do not fit with their genetic variability. In general, the genotypes cultivated in Mexico showed high levels of diversity, whereas most of the spineless accessions collected in other countries had a very narrow genetic base. This study increases our knowledge of the variability among some of the most diffused Opuntia cultivated accessions. This study also points to the inconsistencies of previous taxonomical genotype assignments that were based solely on morphological characteristics.

Polyamines and transglutaminase activity are involved in compatible and self-incompatible pollination of Citrus grandis

Pollination of pummelo (Citrus grandis L. Osbeck) pistils has been studied in planta by adding compatible and self-incompatible (SI) pollen to the stigma surface. The pollen germination has been monitored inside the pistil by fluorescent microscopy showing SI altered morphologies with irregular depositions of callose in the tube walls, and heavy callose depositions in enlarged tips. The polyamine (PA) content as free, perchloric acid (PCA)-soluble and -insoluble fractions and transglutaminase (TGase) activity have been analyzed in order to deepen their possible involvement in the progamic phase of plant reproduction. The conjugated PAs in PCA-soluble fraction were definitely higher than the free and the PCA-insoluble forms, in both compatible and SI pollinated pistils. In pistils, pollination caused an early decrease of free PAs and increase of the bound forms. The SI pollination, showed highest values of PCA-soluble and -insoluble PAs with a maximum in concomitance with the pollen tube arrest. As TGase mediates some of the effects of PAs by covalently binding them to proteins, its activity, never checked before in Citrus, was examined with two different assays. In addition, the presence of glutamyl-PAs confirmed the enzyme assay data and excluded the possibility of a misinterpretation. The SI pollination caused an increase in TGase activity, whereas the compatible pollination caused its decrease. Similarly to bound PAs, the glutamyl-PAs and the enzyme activity peaked in the SI pollinated pistils in concomitance with the observed block of the pollen tube growth, suggesting an involvement of TGase in SI response.

Changes in Anthocyanin Production during Domestication of Citrus

Ruby, a regulatory gene encoding a MYB transcription factor, is essential for anthocyanin production, and differences in its activity determine most of the natural variation in pigmentation in Citrus and related genera. Mandarin (Citrus reticulata), citron (Citrus medica), and pummelo (Citrus maxima) are important species of the genus Citrus and parents of the interspecific hybrids that constitute the most familiar commercial varieties of Citrus: sweet orange, sour orange, clementine, lemon, lime, and grapefruit. Citron produces anthocyanins in its young leaves and flowers, as do species in genera closely related to Citrus, but mandarins do not, and pummelo varieties that produce anthocyanins have not been reported. We investigated the activity of the Ruby gene, which encodes a MYB transcription factor controlling anthocyanin biosynthesis, in different accessions of a range of Citrus species and in domesticated cultivars. A white mutant of lemon lacks functional alleles of Ruby, demonstrating that Ruby plays an essential role in anthocyanin production in Citrus. Almost all the natural variation in pigmentation by anthocyanins in Citrus species can be explained by differences in activity of the Ruby gene, caused by point mutations and deletions and insertions of transposable elements. Comparison of the allelic constitution of Ruby in different species and cultivars also helps to clarify many of the taxonomic relationships in different species of Citrus, confirms the derivation of commercial varieties during domestication, elucidates the relationships within the subgenus Papeda, and allows a new genetic classification of mandarins.

Relationships among cultivated Opuntia ficus-indica genotypes and related species assessed by cytoplasmic markers

The taxonomic classification of the genus Opuntia, which includes several cultivated species, is complicated mainly because of inadequate morphological descriptors, the common intra- and inter-generic hybridization and the relationships between phenotypic variation and ecological conditions. The phylogenetic relationships among 72 cultivated genotypes, either selected for fruit or forage production, and wild accessions belonging to approximately 15 different species of Opuntia were inferred using cytoplasmic markers. Previous studies indicated as the most important cultivated accessions for fruit production have a polyphyletic origin but polyploidy hampered their clear phylogenetic assignment based on nuclear markers. Cytoplasmic markers are considered helpful for their maternal inheritance and for overcoming the multiple gene copy problem in polyploid phylogenetics already reported in the Opuntia genus. In particular, we combined in this work capillary electrophoresis for newly designed cpSSRs and high resolution melting for SNV analyses to identify chloroplast (ndhF-rpl32, psbJ-petA, atpB-rbcL, matK, ycf1) and mitochondrial (rpl5) DNA markers in a selected group of genotypes. The results revealed the presence of polymorphisms in the predicted cpSSRs and SNVs and clearly evidenced that most of the studied genotypes were closely related to Opuntia ficus-indica (L.) Miller. Plastid markers identified 11 chlorotypes and 8 unique genotypes. Interestingly the analysis evidenced a multiple maternal phylogeny for the fleshy fruit varieties classified as O. ficus-indica. These results allow questioning of the reliability of the current classification based on morphological parameters and reveal the narrow genetic base of the most common cultivated opuntias for fruit production, while forage genotypes evidenced greater variability.

Elucidating the contribution of wild related species on autochthonous pear germplasm: A case study from Mount Etna

The pear (genus Pyrus) is one of the most ancient and widely cultivated tree fruit crops in temperate climates. The Mount Etna area claims a large number of pear varieties differentiated due to a long history of cultivation and environmental variability, making this area particularly suitable for genetic studies. Ninety-five pear individuals were genotyped using the simple sequence repeat (SSR) methodology interrogating both the nuclear (nDNA) and chloroplast DNA (cpDNA) to combine an investigation of maternal inheritance of chloroplast SSRs (cpSSRs) with the high informativity of nuclear SSRs (nSSRs). The germplasm was selected ad hoc to include wild genotypes, local varieties, and national and international cultivated varieties. The objectives of this study were as follows: (i) estimate the level of differentiation within local varieties; (ii) elucidate the phylogenetic relationships between the cultivated genotypes and wild accessions; and (iii) estimate the potential genetic flow and the relationship among the germplasms in our analysis. Eight nSSRs detected a total of 136 alleles with an average minor allelic frequency and observed heterozygosity of 0.29 and 0.65, respectively, whereas cpSSRs allowed identification of eight haplotypes (S4 Table). These results shed light on the genetic relatedness between Italian varieties and wild genotypes. Among the wild species, compared with P. amygdaliformis, few P. pyraster genotypes exhibited higher genetic similarity to local pear varieties. Our analysis revealed the presence of genetic stratification with a ‘wild’ subpopulation characterizing the genetic makeup of wild species and the international cultivated varieties exhibiting the predominance of the ‘cultivated’ subpopulation.