An efficient and rapid procedure for plantlet regeneration from chicory mesophyll protoplasts

An efficient procedure for plantlet regeneration from chicory mesophyll protoplasts has been developed in order to perform protoplast fusion experiments. Protoplasts were isolated from a genotype of Italian red chicory (CH 363) and purified by centrifugation in a solution containing 13% (w/v) sucrose to collect uniform protoplasts in size. After 2 days culture at a density of 2×10⁴ protoplasts ml⁻¹ of liquid medium, protoplasts were cultured following three different procedures: in liquid medium, stratified in semi-solid medium, and embedded in Ca-alginate droplets. Four different media were used and culture procedures were evaluated recording the protoplast viability, protoplast division frequency and plating efficiency for each experiment. The embedding of protoplasts in Ca-alginate droplets enhanced both division frequency and plating efficiency for chicory mesophyll cells. Furthermore, this procedure shortened the cycle of plant regeneration from protoplasts, which could be completed in eight weeks. This revised version was published online in June 2006 with corrections to the Cover Date.     

Immature embryos culture in Italian red chicory

Chicory (Cichorium intybus L.) embryo maturation in vitro was achieved in B5 medium without growth regulators. Immature embryos were collected at different developmental stages 4–168 h after pollination. Only a few plantlets were obtained from ovules collected shortly after pollination since the embryos at these early stages developed abnormal leaves and roots which regenerated shoots ‘via’ organogenesis. Zygotic embryos collected 24–72 h after pollination needed one month of culture in vitro before acclimation. Embryos collected at the heart or early torpedo stage of development (three days after pollination) produced green plantlets after two weeks of in vitro culture and thus they could be transferred to the greenhouse for acclimation. Culture of zygotic embryos in vitro has shown to be a suitable technique to accelerate the breeding process in biennial cultivated Italian red chicory. In fact it is possible to obtain plantlets ready for performing the selection for the desired agronomic traits one month after pollination. Since flowering occurs after vernalization, the selection can be performed in the correct season before flowering. This revised version was published online in June 2006 with corrections to the Cover Date.     

A first linkage map of Cichorium intybus L. using a one-way pseudo-testcross and PCR-derived markers

We have used a one-way pseudo-testcross mapping strategy in combination with different types of PCR-based markers (RAPD, AFLP, SAMPL) to construct a first linkage map for variegated chicory (Cichorium intybus L. var. silvestre Biskoff, n=9), a self-incompatible vegetable species. The success of such a strategy depends on the presence of sufficiently high levels of heterozygosity in the individual plant which is being mapped and on the informativeness of the marker system that is used. A total of 371 markers, comprising 16 RAPDs, 72 SAMPLs and 283 AFLPs, were scored in 46 F₁ individuals obtained from an interspecific cross between a C. intybus outbred individual and a C. endivia inbred line. Grouping of the markers at a LOD score of 4.0 resulted in 13 linkage groups covering 1330 cM. A framework map covering 1201.4 cM was assembled by using all markers that could be ordered with a LOD greater than 2.0. We estimate the total genome size of chicory to be ca. 1405 cM, thus considerably smaller than that estimated for lettuce (1950 cM). The usefulness of the different marker systems that were applied is analysed in terms of level of heterozygosity and marker index, i.e. number of different genetic loci that may be simultaneously analysed per experiment. Out of the 371 markers, 50 of them showed segregation distortion which is discussed in terms of the hybrid origin of the variegated chicory.     

Linkage mapping in tetraploid willows: segregation of molecular markers and estimation of linkage phases support an allotetraploid structure for Salix alba x Salix fragilis interspecific hybrids

Salix alba-Salix fragilis complex includes closely related dioecious polyploid species, which are obligate outcrossers. Natural populations of these willows and their hybrids are represented by a mixture of highly heterozygous genotypes sharing a common gene pool. Since nothing is known about their genomic constitution, tetraploidy (2n=4x=76) in willow species makes basic and applied genetic studies difficult. We have used a two-way pseudotestcross strategy and single-dose markers (SDMs) to construct the first linkage maps for both pistillate and staminate willows. A total of 242 amplified fragment length polymorphisms (AFLPs) and 50 selective amplifications of microsatellite polymorphic loci (SAMPL) markers, which showed 1:1 segregation in the F(1) mapping populations, were used in linkage analysis. In S. alba, 73 maternal and 48 paternal SDMs were mapped to 19 and 16 linkage groups covering 708 and 339 cM, respectively. In S. fragilis, 13 maternal and 33 paternal SDMs were mapped in six and 14 linkage groups covering 98 and 321 cM, respectively. For most cosegregation groups, a comparable number of markers linked in coupling and repulsion was identified. This finding suggests that most of chromosomes pair preferentially as occurs in allotetraploid species exhibiting disomic inheritance. The detection of 10 pairs of marker alleles from single parents showing codominant inheritance strengthens this hypothesis. The fact that, of the 1122 marker loci identified in the two male and female parents, the vast majority (77.5%) were polymorphic and as few as 22.5% were shared between parental species highlight that S. alba and S. fragilis genotypes are differentiated. The highly difference between S. alba- and S. fragilis-specific markers found in both parental combinations (on average, 65.3 vs 34.7%, respectively) supports the (phylogenetic) hypothesis that S. fragilis is derived from S. alba-like progenitors.     

Gene pool variation and phylogenetic relationships of an indigenous northeast Italian grapevine collection revealed by nuclear and chloroplast SSRs

A germplasm safeguard programme was set up with 19 grapevine varieties considered as indigenous to northeastern Italy. To better estimate how genetic structure can be used to obtain a conservation perspective of local varieties, genetic variability was examined at 30 nuclear and 3 chloroplast polymorphic microsatellite loci in the native varieties plus 7 European cultivars taken as reference. The genetic profiles of all the cultivars were searched for possible parentage relationships and several suspected cases of the same variety having different names were investigated. The alleles shared at the loci suggest a parent-offspring relationship between Merlot and Cabernet Franc, 'Gruaja' and 'Negrara Veronese', and Marzemina Nera and Marzemina Bianca. Alleles at the 30 nuclear loci are consistent with Raboso Veronese being the progeny of Marzemina Bianca and Raboso Piave. Chloroplast-specific haplotypes were singled out for the first time in this indigenous germplasm and should be considered typical of the region. It is hypothesized that there are many specific haplotypes for the local varieties due to a past contribution of wild grapevine to the cultivated gene pool. The majority of investigated cultivars were demonstrated to constitute an independent source of genetic variation, and therefore a possible valuable resource of genetic traits for breeders.     

Production of asymmetric somatic hybrid plants between Cichorium intybus L. and Helianthus annuus L.

In order to obtain male-sterile asymmetric somatic hybrids between chicory (Cichorium intybus L.) and a sunflower (Helianthus annuus L.) male-sterile cytoplasmic line, mesophyll chicory protoplasts inactivated with iodoacetic acid and hypocotyl sunflower protoplasts irradiated with γ-rays have been fused, using PEG and applying two different procedures. Thirty three plants were regenerated from putative hybrid calli. A cytological analysis of their root-tip cells indicated that most of them had 18 chromosomes, the same number as chicory. Through Southern hybridisation on total DNA using the maize mitochondrial specific gene probes Cox I, Cox II and Cob, three plants were identified as cytoplasmic asymmetric hybrids, as shown by hybridisation bands specific for both chicory and sunflower. One of the regenerated plants produced a novel pattern of hybridisation that was not detected in either parent. When hybridisation of total DNA was carried out with an atpA mitochondrial gene probe the same three cybrids presented both the fertile chicory fragment and the male-sterile sunflower fragment. Finally, Southern hybridisation with an ORF 522 probe, which in sunflower is co-transcribed with the atpA gene, confirmed the hybrid nature of the three plants. The morphology of the cybrids resembled the parental chicory phenotype, and at anthesis their anthers produced fewer pollen grains which could not germinate either ”in vitro” or ”in situ.” Cybrid plants grown in the field produced seeds when free-pollination occurred. Received: 26 April 2000 / Accepted: 28 August 2000     

Biodiversity studies in Phaseolus species by DNA barcoding

The potential of DNA barcoding was tested as a system for studying genetic diversity and genetic traceability in bean germplasm. This technique was applied to several pure lines of Phaseolus vulgaris L. belonging to wild, domesticated, and cultivated common beans, along with some accessions of Phaseolus coccineus L., Phaseolus lunatus L., and Vigna unguiculata (L.) Walp. A multilocus approach was exploited using three chloroplast genic regions (rbcL, trnL, and matK), four intergenic spacers (rpoB-trnC, atpBrbcL, trnT-trnL, and psbA-trnH), and nuclear ITS1 and ITS2 rDNA sequences. Our main goals were to identify the markers and SNPs that show the best discriminant power at the variety level in common bean germplasm, to examine two methods (tree based versus character based) for biodiversity analysis and traceability assays, and to evaluate the overall utility of chloroplast DNA barcodes for reconstructing the origins of modern Italian varieties. Our results indicate that the neighbor-joining method is a powerful approach for comparing genetic diversity within plant species, but it is relatively uninformative for the genetic traceability of plant varieties. In contrast, the character-based method was able to identify several distinct haplotypes over all target regions corresponding to Mesoamerican or Andean accessions; Italian accessions originated from both gene pools. On the whole, our findings raise some concerns about the use of DNA barcoding for intraspecific genetic diversity studies in common beans and highlights its limitations for resolving genetic relationships between landraces and varieties.