THE EFFECT OF COLD STORAGE OF POTTED AZALEA ON BROAD MITE INFECTION.

In potted azalea (Rhododendron simsii hybrids) the broad mite Polyphagotarsonemus latus (Banks) is considered a severe pest with an important economic impact. Although chemical control is available, permitted acaricides are limited and have a restricted number of applications. Therefore, growers have a keen interest in alternative control measures. Recently, research on the behaviour and population dynamics of P. latus on azalea leaf disks stored at different temperatures indicated that survival and reproductive capacity of broad mite is reduced drastically when temperature drops below 7°C. In Flanders, storage of azalea plants at 3°C is common practice to pause flower development (in function of the date that plants have to be ready for sale) before forcing them to flower in a heated greenhouse. Hence, an experiment was set-up to verify and quantify the effect of cold storage of azalea on broad mite infection. Azalea plants were infected with P. latus and stored at 3°C for 2, 3 or 4 weeks. Then, plants were transferred to a heated greenhouse for 2 weeks to check whether surviving female broad mites were still able to reproduce. The number of P. latus on azalea was assessed before cold treatment, immediately after treatment, and 2 weeks after transfer to the heated greenhouse. Results confirmed that cold storage can play a role in broad mite control as the P. latus population was significantly reduced (up to 90%) immediately after treatment. A further decrease in the number of P. latus during storage in the heated greenhouse indicated that cold treatment during 4 weeks had also an effect on the reproduction capacity of P. latus. We conclude that cold storage of azalea plants (at least 4 weeks at maximum 3°C) should be considered as an additional and alternative control method for P. latus at the end of the azalea production cycle.

Micronucleation by mitosis inhibitors in developing microspores of Spathiphyllum wallisii Regel.

KEY MESSAGE : We developed an efficient protocol for chromosome scattering in Spathiphyllum microspores. The effects of plant material, developmental age, genotype and antimicrotubular toxin type, exposure and concentration were evaluated. Asymmetric hybridization through microprotoplast-mediated chromosome transfer (MMCT) is a known method for overcoming sexual breeding barriers between distantly related plant species. To obtain microprotoplasts, it is necessary to induce mass micronucleation either in somatic or gametic cells. We have tested the efficiency for micronuclei induction of five mitosis inhibitors, amiprophos-methyl (APM), butamiphos (BUT), chlorpropham (CIPC), oryzalin (ORY) and propyzamide (PRO), on developing microspores of diploid Spathiphyllum wallisii Regel. Besides the used toxins, also the effect of their concentrations and incubation period as well as plant genotypes and material was tested. We observed micronuclei (MNi) in pollen mother cells, dyads and tetrads as well as other abnormalities such as ball metaphases and chromosome bridges. The flower position on the spadix and the type of starting material (dissected anthers vs. complete spadices) did not significantly influence micronucleation frequencies. The highest micronucleation index of 86 % was obtained in microspores treated with 10 µM ORY during 72 h. All six genotypes tested formed micronuclei after this particular treatment, although the efficiency varied between cultivars. Next to ORY, CIPC was also a very efficient MNi inducer. The average number of MNi found in micronucleated cells varied between 1.67-6.44 for CIPC and 0.83-5.50 for ORY. The maximal number of MNi observed was 12 for CIPC and 9 for ORY. Our results demonstrate that CIPC and ORY can be applied for mass micronucleation on developing microspores of S. wallisii as a first step of MMCT in aroid interspecific or intergeneric breeding.

Meiotic aberrations during 2n pollen formation in Begonia.

Unreduced gametes are the driving force for the polyploidization of plants in nature, and are also an important tool for ploidy breeding. The final heterozygosity of a 2n pollen grain depends on the cytological mechanism behind 2n pollen formation. In this study, chromosome pairing and chromosome segregation during the microsporogenesis of seven Begonia genotypes were analysed using fluorescent chromosome staining on (squashed) pollen mother cells. Among the seven genotypes, five genotypes produce 2n pollen (B. 'Bubbles', B. 'Florence Rita', B. 'Orococo', B. 'Tamo' and B276) and two genotypes produce only normal n pollen (B. fischeri and B243). All 2n pollen producers showed a mechanism equivalent to first division restitution (FDR), in which chromosomes did not segregate during meiosis I but only during meiosis II. This FDR was the result of (a) an irregular chromosome pairing in B. 'Tamo', (b) stickiness of chromosomes associated with numerous chromosome bridges in B. 'Florence Rita' and B276, and (c) a combination of irregular chromosome pairing and stickiness of chromosomes in B. 'Bubbles'. The exact mechanism of the nuclear restitution in B. 'Orococo' could not be determined. Other mechanisms, such as early asymmetric cytokinesis, omission of meiosis II, parallel or tripolar spindle formation, were rather uncommon. Unpaired chromosomes (univalents) were observed in all genotypes, but they had moved to one of the poles by the end of anaphase I or II. Only B. 'Tamo' formed a high number of micronuclei. Consequently, this genotype formed a large number of malformed pollen. Obviously, chromosome behaviour during meiosis in Begonia is very dynamic, which may have important consequences for chromosome evolution and biodiversity within the genus.

Characterisation of powdery mildew resistance in a segregating diploid rose population.

Powdery mildew (Podosphaera pannoso) is one of the most serious fungal diseases on both greenhouse and field grown roses. Improvement of disease resistance is a major selection aim for garden rose breeders. For rose cultivars, being mostly tetraptoid, it is complicated to develop molecular markers for resistance. Hence, a segregating diploid population was established from a cross between 'Yesterday', a commercial available rose variety susceptible to powdery mildew, and R. wichurana, a rose species with resistance to certain isolates of powdery mildew. A progeny of 94 seedlings was planted in the field. The segregation of powdery mildew resistance was studied in this population by means of a bioassay with two different monoconidial isolates of powdery mildew. Based on the response to these inoculations different groups were selected: a first group of genotypes was susceptible to both isolates, other groups were susceptible to one of both isolates and a last group was resistant to both tested isolates. The disease resistance inherits for both isolates in a quantitative way. A genetic map based on AFLP and SSR markers was established and will be used for QTL analysis of powdery mildew resistance.