Jan G. Schaart

Genomic cloning and linkage mapping of the Mal d 1 (PR-10) gene family in apple (Malus domestica).

Fresh apples can cause birch pollen-related food allergy in northern and central European populations, primarily because of the presence of Mal d 1, the major apple allergen that is cross-reactive to the homologous and sensitizing allergen Bet v 1 from birch. Apple cultivars differ significantly in their allergenicity. Knowledge of the genetic basis of these differences would direct breeding for hypoallergenic cultivars. The PCR genomic cloning and sequencing were performed on two cultivars, Prima and Fiesta, which resulted in 37 different Mal d 1 gDNA sequences. Based on the mapping of sequence-specific molecular markers, these sequences appeared to represent 18 Mal d 1 genes. Sixteen genes were located in two clusters, one cluster with seven genes on linkage group (LG) 13, and the other cluster with nine genes on the homoeologous LG 16. One gene was mapped on LG 6, and one remained unmapped. According to sequence identity, these 18 genes could be subdivided into four subfamilies. Subfamilies I–III had an intron of different size that was subfamily and gene-specific. Subfamily IV consisted of 11 intronless genes. The deduced amino acid sequence identity varied from 65% to 81% among subfamilies, from 82% to 100% among genes within a subfamily, and from 97.5% to 100% among alleles of one gene. This study provides a better understanding of the genetics of Mal d 1 and the basis for further research on the occurrence of allelic diversity among cultivars in relation to allergenicity and their biological functions.

The development of a cisgenic apple plant

Cisgenesis represents a step toward a new generation of GM crops. The lack of selectable genes (e.g. antibiotic or herbicide resistance) in the final product and the fact that the inserted gene(s) derive from organisms sexually compatible with the target crop should rise less environmental concerns and increase consumers acceptance. Here we report the generation of a cisgenic apple plant by inserting the endogenous apple scab resistance gene HcrVf2 under the control of its own regulatory sequences into the scab susceptible apple cultivar Gala. A previously developed method based on Agrobacterium-mediated transformation combined with a positive and negative selection system and a chemically inducible recombination machinery allowed the generation of apple cv. Gala carrying the scab resistance gene HcrVf2 under its native regulatory sequences and no foreign genes. Three cisgenic lines were chosen for detailed investigation and were shown to carry a single T-DNA insertion and express the target gene HcrVf2. This is the first report of the generation of a true cisgenic plant.

Functional analysis and expression profiling of HcrVf1 and HcrVf2 for development of scab resistant cisgenic and intragenic apples

Apple scab resistance genes, HcrVf1 and HcrVf2, were isolated including their native promoter, coding and terminator sequences. Two fragment lengths (short and long) of the native gene promoters and the strong apple rubisco gene promoter (PMdRbc) were used for both HcrVf genes to test their effect on expression and phenotype. The scab susceptible cultivar ‘Gala’ was used for plant transformations and after selection of transformants, they were micrografted onto apple seedling rootstocks for scab disease tests. Apple transformants were also tested for HcrVf expression by quantitative RT-PCR (qRT-PCR). For HcrVf1 the long native promoter gave significantly higher expression that the short one; in case of HcrVf2 the difference between the two was not significant. The apple rubisco gene promoter proved to give the highest expression of both HcrVf1 and HcrVf2. The top four expanding leaves were used initially for inoculation with monoconidial isolate EU-B05 which belongs to race 1 of V. inaequalis. Later six other V. inaequalis isolates were used to study the resistance spectra of the individual HcrVf genes. The scab disease assays showed that HcrVf1 did not give resistance against any of the isolates tested regardless of the expression level. The HcrVf2 gene appeared to be the only functional gene for resistance against Vf avirulent isolates of V. inaequalis. HcrVf2 did not provide any resistance to Vf virulent strains, even not in case of overexpression. In conclusion, transformants carrying the apple-derived HcrVf2 gene in a cisgenic as well as in an intragenic configuration were able to reach scab resistance levels comparable to the Vf resistant control cultivar obtained by classical breeding, cv. ‘Santana’.

Genetic modification of the commercial apple cultivars Gala, Golden Delicious and Elstar via an Agrobacterium tumefaciens-mediated transformation method

Abstract Modern biotechnological techniques, including genetic modification, offer important tools to plant breeders for the introduction of resistance genes into a fruit crop such as apple. However, the transformation methods necessary to generate transgenic apple plants from commercial cultivars are often tedious or unavailable. In this article we report on an Agrobacterium tumefaciens-mediated transformation method for the commerical apple cultivars Gala, Golden Delicious and Elstar. Southern blot analysis confirmed the integration of both selection and marker genes, nptII and gus, with one or two copies per genome being present. For transformation, leaf segments were co-cultivated with a supervirulent Agrobacterium strain, containing the nptII and gus genes. GUS-positive shoots were induced on calli which were able to proliferate on kanamycin-containing medium. The transformation efficiencies, based on the number of GUS-positive shoots, were 0.7–8% per leaf explant for Gala, 0.2–6% for Golden Delicious and 0.4–0.8% for Elstar. The GUS-positive clones tested were able to form roots on kanamycin-containing medium and developed into transgenic plants. The use of this transformation method for the introduction of antimicrobial genes is discussed.

Opportunities for Products of New Plant Breeding Techniques

Various new plant breeding techniques (NPBT) have a similar aim, namely to produce improved crop varieties that are difficult to obtain through traditional breeding methods. Here, we review the opportunities for products created using NPBTs. We categorize products of these NPBTs into three product classes with a different degree of genetic modification. For each product class, recent examples are described to illustrate the potential for breeding new crops with improved traits. Finally, we touch upon the future applications of these methods, such as cisgenic potato genotypes in which specific combinations of Phytophthora infestans resistance genes have been stacked for use in durable cultivation, or the creation of new disease resistances by knocking out or removing S-genes using genome-editing techniques.

Tissue-specific expression of the β-glucuronidase reporter gene in transgenic strawberry (Fragaria × ananassa) plants

Abstract. The strawberry (Fragaria spp) is regarded as a false fruit because it originates from the receptacle, which is a non-ovarian tissue. For this reason, fruit-specific promoters isolated from plant species in which the fruit is derived from the ovary wall might not be suited to control gene expression in a fruit-specific way in strawberry. In order to achieve (false) fruit-specific expression in strawberry, we tested the petunia FBP7 (floral binding protein7) promoter, which proved to be active in the receptacles of petunia flowers, in transgenic strawberry fruits. In strawberry plants containing the FBP7 promoter fused to the β-glucuronidase (GUS) reporter gene (gus), GUS activity was found in floral and fruit tissues of all developmental stages tested but not in leaf, petiole and root tissue. Surprisingly, Northern blot analysis showed the presence of gus-derived mRNAs in root (strong) and petiole (weak) tissue of fbp7-gus plants in addition to the floral and fruit tissues. Therefore, it is concluded that the histological GUS phenotype does not necessarily correspond with expression at the mRNA level. mRNA quantification using the TaqMan polymerase chain reaction technology confirmed the Northern results and showed that in red strawberry tissue the cauliflower mosaic virus 35S promoter is at least sixfold stronger than the FBP7 promoter.

Genomic characterization and linkage mapping of the apple allergen genes Mal d 2 (thaumatin-like protein) and Mal d 4 (profilin)

Four classes of apple allergens (Mal d 1, −2, −3 and −4) have been reported. By using PCR cloning and sequencing approaches, we obtained genomic sequences of Mal d 2 (thaumatin-like protein) and Mal d 4 (profilin) from the cvs Prima and Fiesta, the two parents of a European reference mapping population. Two copies of the Mal d 2 gene (Mal d 2.01A and Mal d 2.01B) were identified, which primarily differed in the length of a single intron (378 or 380 nt) and in one amino acid in the signal peptide. Both Mal d 2.01A and Mal d 2.01B were mapped at identical position on linkage group 9. Genomic characterization of four Mal d 4 genes (Mal d 4.01A and B, Mal d 4.02A and Mal d 4.03A) revealed their complete gDNA sequences which varied among genes in length from 862 to 2017 nt. They all contained three exons of conserved length: 123, 138, and 135 nt. Mal d 4.01 appeared to be duplicated in two copies and located on linkage group 9. Mal d 4.02A and Mal d 4.03A were single copy genes located on linkage group 2 and 8, respectively.

In vitro conservation of enset under slow-growth conditions

Studies on in vitro storage of enset under slow-growth conditions were carried out to develop an efficient protocol for conservation of the genetic diversity of the crop. The response to different growth retardation treatments was examined using three enset clones collected from southwestern Ethiopia. In vitro cultures could be effectively maintained for 6 months at 15 °C and 18 °C on MS medium supplemented with 10 μM BAP, in the presence of mannitol at concentrations of 0, 1 or 2% as a growth retardant. Shoots were subsequently recovered and multiplied on MS medium supplemented with 10 and 20 μM BAP at 25 °C and rooted shoots were successfully transferred to the greenhouse. Incubation at the lower temperature (15 °C) and the presence of mannitol in the culture medium had a significantly positive effect on maintenance, measured by the number of recovered shoots after storage.

Chromosome elimination and mutation in tetraploid somatic hybrids of Solanum tuberosum and Solanum phureja

The hybridity of eleven somatic hybrids between a diploidS. tuberosum and a diploidS. phureja clone could be verified because the parent karyotypes differed in their C-banding patterns. The hybrids were hypotetraploid and some carried structurally rearranged chromosomes and/or minute centric fragments. The nucleolar chromosomes ofS. phureja were eliminated preferentially. The function of the remaining nucleolar organizer regions was not suppressed. Nuclear DNA content was correlated with the hypotetraploid chromosome numbers.

One-Step Agrobacterium Mediated Transformation of Eight Genes Essential for Rhizobium Symbiotic Signaling Using the Novel Binary Vector System pHUGE

Advancement in plant research is becoming impaired by the fact that the transfer of multiple genes is difficult to achieve. Here we present a new binary vector for Agrobacterium tumefaciens mediated transformation, pHUGE-Red, in concert with a cloning strategy suited for the transfer of up to nine genes at once. This vector enables modular cloning of large DNA fragments by employing Gateway technology and contains DsRED1 as visual selection marker. Furthermore, an R/Rs inducible recombination system was included allowing subsequent removal of the selection markers in the newly generated transgenic plants. We show the successful use of pHUGE-Red by transferring eight genes essential for Medicago truncatula to establish a symbiosis with rhizobia bacteria as one 74 kb T-DNA into four non-leguminous species; strawberry, poplar, tomato and tobacco. We provide evidence that all transgenes are expressed in the root tissue of the non-legumes. Visual control during the transformation process and subsequent marker gene removal makes the pHUGE-Red vector an excellent tool for the efficient transfer of multiple genes.