Paolo De Franceschi

Identifying a Carotenoid Cleavage Dioxygenase (ccd4) Gene Controlling Yellow/White Fruit Flesh Color of Peach

Peach flesh color is a monogenic trait with the white phenotype being dominant over the yellow; its expression has been reported to be determined by a carotenoid degradative enzyme. In the present study, a carotenoid cleavage dioxygenase (ccd4) gene was analyzed to test whether it can be responsible for the flesh color determinism. The analysis was conducted on chimeric mutants with white and yellow sectors of the fruit mesocarp; it was then extended to a pool of cultivars and a segregating F1 population. A ccd4 functional allele is consistently associated with the ancestral white flesh color; on the other hand, the yellow phenotype originated from at least three independent mutations disrupting ccd4 function, thus preventing carotenoid degradation. In addition, retro-mutations recovering ccd4 function and re-establishing the ancestral white flesh color were detected. Our results show that ccd4 is the gene controlling flesh color in peach; its expression results in the degradation of carotenoids in white-fleshed genotypes, while the yellow color arises as a consequence of its inactivation.

Genetic Diversity, Population Structure and Construction of a Core Collection of Apple Cultivars from Italian Germplasm

Apple germplasm collections are increasingly appreciated as a repository for the genetic improvement of species, and their evaluation is an essential prerequisite for their utilization in apple breeding. A set of 418 apple genotypes, including 383 accessions from the Italian germplasm and 35 International cultivars as reference, was analyzed using 15 SSRs with the aim of assessing the genetic diversity within this panel of varieties, evaluating relationships among them and determining their genetic structure. Genetic analyses performed by Bayesian model-based clustering revealed a clear differentiation of two major groups (G1 and G2). Local Italian accessions were grouped mainly in G2 while all except one of the reference cultivars were found in G1. Each of these two clusters has been further divided into two subgroups by a nested approach. These results were confirmed by factorial correspondence (FCA) and molecular variance (AMOVA) analyses. A core collection of 55 accessions, representative of the Italian apple germplasm and capable of retaining all the 238 SSR alleles detected on 192 unique genotypes, was established by the M-strategy method. The Italian apple germplasm represents an important source of genetic diversity which can be used, in addition to other characterized European germplasm collections, to optimize the efficiency of genome-wide association studies aimed at identifying the genomic regions controlling major horticultural traits.

Rosaceae conserved orthologous sequences marker polymorphism in sweet cherry germplasm and construction of a SNP-based map

The Rosaceae Conserved Orthologous Set (RosCOS) provides a gene-based genome-wide set of markers that have been used in comparative analyses of peach (Prunus persica), apple (Malus × domestica), and strawberry (Fragaria spp.). In order to extend the use of these RosCOS to sweet cherry (Prunus avium L.), we identified markers that are polymorphic in breeding germplasm. Ninety-five percent (595/627) of previously designed RosCOS primer pairs amplified a product in six sweet cherry cultivars predicted to represent the range of genetic diversity in breeding germplasm. A total of 45% (282/627) RosCOS were polymorphic among the six cultivars, and allele number ranged from 2 to 6, with a genome-wide mean of 2.35. A subset of 92 genome-wide single nucleotide polymorphisms (SNPs) corresponding to 76 RosCOS was analyzed in 36 founder accessions and progeny. The expected and observed heterozygosity suggested that 83% of the RosCOS were in Hardy–Weinberg equilibrium, implying that most RosCOS behave as neutral markers. Principal coordinate analysis (PCO) identified one wild accession and two Spanish landraces that clustered differently from the other accessions. The relatively high number of unique alleles found in the three differentially clustered selections suggested that their use as parents has potential to increase the genetic diversity in future US-bred cultivars. Of the 92 RosCOS SNPs, 81 SNPs that represented 68 genome-wide RosCOS segregated in four mapping populations. These RosCOS were mapped in four F1 populations, thereby greatly improving the genetic linkage map of sweet cherry.

Cloning and mapping multiple S-locus F-box genes in European pear ( Pyrus communis L.)

European pear, as well as its close relatives Japanese pear and apple, exhibits S-RNase-based gametophytic self-incompatibility. The male determinant of this self-incompatibility mechanism is a pollen-expressed protein containing an F-box domain; in the genera Petunia (Solanaceae), Antirrhinum (Plantaginaceae), and Prunus (Rosaceae), a single F-box gene determines the pollen S. In apple and Japanese pear, however, multiple S-locus F-box genes were recently identified as candidates for the pollen S, and they were named S-locus F-Box Brothers. These genes were considered good candidates for the pollen S determinant since they exhibit S-haplotype-specific polymorphisms, pollen-specific expression, and linkage to the S-RNase. In the present study, S-locus F-Box Brothers homologs have been cloned from two of the most agronomically important European pear varieties, “Abbé Fétel” (S104-2/S105) and “Max Red Bartlett” (S101/S102), and they have been mapped on a genetic linkage map developed on their progeny. Our results suggest that the number of F-box genes linked to the S-locus of the European pear is higher than expected according with previous reports for apple and Japanese pear, since up to five genes were found to be linked to a single S-haplotype. Moreover, two of these genes exhibited an incomplete linkage to the S-RNase, allowing the identification of low-frequency recombinant haplotypes, generated by a crossing-over event between the two genes. These F-box genes are most likely placed in close proximity of the S-locus but do not belong to it, and they can thus be excluded from being responsible for the determination of pollen S function.

Evaluation of candidate F-box genes for the pollen S of gametophytic self-incompatibility in the Pyrinae (Rosaceae) on the basis of their phylogenomic context

The recent analysis of the S-locus region of apple and Japanese pear, two species of Pyrinae (Rosaceae), suggested multiple and different F-box genes (called SFBBs) as candidates for the male determinant (pollen S) of RNase-based gametophytic self-incompatibility in these two species. Here, we followed a phylogenetic approach to take advantage of the pattern of molecular evolution of the S-locus of Pyrinae in characterizing SFBB homologs belonging to S-haplotypes of apple and three species of Pyrus (European, Japanese, and Chinese pears). Our results suggested that the S-locus region of Pyrinae contains no less than six SFBB members and that its structure seems to be rather conserved between apple and pear species. In accordance with the prevailing theory on S-haplotype evolution, the pollen S is expected to have coevolved with the S-RNase and to show some common features derived from the long-term evolution under frequency-dependent balancing selection, i.e., high sequence diversity, evidence of positive selection, and shared ancestral polymorphisms. Using this conceptual framework, we present evidence that some SFBB genes may be better candidates for pollen S in Pyrinae than others. Overall, the SFBB genes analyzed exhibited much lower sequence diversity than their associated S-RNases; likewise, they showed little or no evidence of positive selection. However, evidence of coevolution with the S-RNase clearly emerged for two of them. Altogether our results suggested different evolutionary histories for different SFBBs putatively derived from their distinct involvement in self-incompatibility.

Genomic characterization of self-incompatibility ribonucleases in the Central Asian pear germplasm and introgression of new alleles from other species of the genus Pyrus

The Pyrus species exhibit the so-called S-RNase-based gametophytic self-incompatibility system, which is considered to be the most widespread self-incompatibility system among flowering plants. In this study, 57 Iranian pear (Pyrus communis L.) domestic cultivars and wild genotypes, plus 21 European pear cultivars used as references, were genotyped adopting a PCR-based genotyping assay using consensus and allele-specific primers. The results revealed traces of significant genetic contribution in the Iranian traditional varieties and genotypes from other Pyrus species; the genetic contribution of Japanese pear clearly emerged with the detection of some Pyrus pyrifolia S-RNase alleles. Moreover, our results highlighted the presence of three new S-RNase alleles (named S126, S127, and S128) that were not previously identified in P. communis, possibly introduced in the germplasm of cultivated pear through gene transfer from other cultivated or wild species.

Seed morphometry is suitable for apple-germplasm diversity-analyses

Abstract The main objective of this study was to evaluate the trustworthiness of seed image analysis as an approach to discriminate apple germplasm accessions. Digital images of seeds from 42 apple cultivars, acquired by a flatbed scanner, provided a phenotypic dataset with 106 morphometric variables. Stepwise Linear Discriminant Analysis (LDA) was used to examine this dataset, and the results were compared with available genetic data. The first comparison among cultivars provided a 38.8% cross-validation of correct identifications with a discriminant percentage ranging between 11.7 and 70%. In agreement with the genetic diversity analysis, the LDA could discriminate between the apples cultivars, identifying two main groups that could be further divided into additional subgroups. Based on our findings, we propose that seed image analysis is a valuable and affordable tool to investigate phenotypic diversity among a large number of apple cultivars.