Browsing by Person "Hagemann, Michael Helmut"

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    Physiological and molecular mechanisms of fruitlet abscission in mango
    (2015) Hagemann, Michael Helmut; Wünsche, Jens Norbert
    Compared to the typical high initial fruit set of mango (Mangifera indica L.), only a small share of those fruits reach harvest-maturity. This extensive fruitlet drop is a major yield-limiting factor, leading to substantial economic losses for mango growers world-wide. The numerous causes of fruitlet drop include infections with pests or diseases and unsuitable environmental or crop management conditions. Due to the high impact of fruitlet drop for mango production, the overall objective of this study was to further the understanding of the underlying mechanisms and to develop strategies for reducing fruitlet drop in mango. Different experimental approaches have been applied to reduce mango fruitlet drop, however, almost as numerous methods have been used for data interpretation, which makes the comparison of data between studies difficult. Therefore a model was developed for defining the timely pattern of fruitlet drop more generally, thus allowing inter-study comparisons of results. The model was tested and validated by monitoring the fruitlet drop in different management systems: traditional monocropping orchard versus 1) intercropping; 2) irrigation; and 3) plant growth regulator applications, respectively. The timely pattern of fruitlet drop was best described with a sigmoid function, which also formed the basis for defining the post-bloom, the midseason and the pre-harvest fruitlet drop stage. Results of the crop management evaluation show that intercropping of maize with mango has no detrimental effect on fruitlet drop. Irrigation resulted in approximately three times higher fruit retention compared with the non-irrigated control. A single application of 40 ppm 1 naphthaleneacetic acid at the end of the post-bloom drop stage resulted consistently in the highest fruit retention. The developed model permits for example the evaluation the treatment efficacies during midseason drop or yield forecasting at the beginning of the pre-harvest stage. It was suggested that especially during the midseason drop stage tree resources are limited, which results in inter-organ concurrence and subsequently induces fruitlet drop. This is supported by the current findings that during midseason drop mango trees show low rates of photosynthesis, which indicates drought stress. Such stress can induce ethylene-dependent fruitlet abscission. Therefore the ethylene releasing substance ethephon was used in order to study the onset and time-dependent course of fruitlet abscission. The results show that ethephon at a concentration of 7200 ppm (ET7200) is a reliable abscission inducer. The experiment was extended using ethephon at an additional concentration of 600 ppm (ET600). Both ethephon treatments reduced significantly the capacity of polar auxin transport (PAT) in the pedicel at 1 day after treatment (DAT) and thereafter compared to untreated pedicels. The transcript levels of the ethylene receptor genes MiETR1 and MiERS1 were significantly upregulated already at 1 DAT in the ET7200 while only at 2 DAT in the ET600 when compared to the control fruitlets. Specifically, a significant increase of MiETR1 in the pericarp at 2 DAT and of MiERS1 in the pedicel at 2 and 3 DAT was induced by ET600. In contrast, both genes were significantly upregulated in both tissues, except MiETR1 in the pedicel, at 1 DAT and thereafter by ET7200. The last parameter that significantly changed in response to the ethephon treatments was the concentration of sucrose in fruitlet pericarps, which was reduced at 2 DAT compared to control fruitlets. Based on these results, it is postulated that the ethephon-induced abscission process commences with a reduction of the PAT capacity in the pedicel, followed by an upregulation of ethylene receptors and finally a decrease of the sucrose concentration in the fruitlets. Ethylene receptors are key elements of abscission and other processes of the plants life cycle. Therefore the ethylene receptors were further studied at the molecular level in mango. Additionally to the previously known receptors MiETR1 and MiERS, two novel versions of the MiERS1 were identified in mango. These receptor genes, MiERS1m and MiERS1s, translate into truncated proteins with deletions of functional domains and show different expression patterns compared to MiERS1. The receptors were further studied through transient expression of fluorescent fusion proteins in the leaves of the model plant tobacco. All receptors are localized at the endoplasmic reticulum. Specific dimerization assays via bi-molecular fluorescence complementation indicate, that MiERS1m can dimerize with itself and with MiERS1, but not with MiETR1. In contrast, no dimerization of MiERS1s with the other receptors could be detected.
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    Publication
    Prevalence, genetic diversity, and molecular detection of the apple hammerhead viroid in Germany
    (2025) Zikeli, Kerstin; Berwarth, Constanze; Born, Ute; Leible, Thomas; Jelkmann, Wilhelm; Hagemann, Michael Helmut; Zikeli, Kerstin; Julius Kühn-Institute, Federal Research Centre for Cultivated Plants, Institute for Plant Protection in Fruit Crops and Viticulture, Dossenheim, Germany; Berwarth, Constanze; Julius Kühn-Institute, Federal Research Centre for Cultivated Plants, Institute for Plant Protection in Fruit Crops and Viticulture, Dossenheim, Germany; Born, Ute; Department of Production Systems of Horticultural Crops, University of Hohenheim, Stuttgart, Germany; Leible, Thomas; Julius Kühn-Institute, Federal Research Centre for Cultivated Plants, Institute for Plant Protection in Fruit Crops and Viticulture, Dossenheim, Germany; Jelkmann, Wilhelm; Julius Kühn-Institute, Federal Research Centre for Cultivated Plants, Institute for Plant Protection in Fruit Crops and Viticulture, Dossenheim, Germany; Hagemann, Michael Helmut; Department of Production Systems of Horticultural Crops, University of Hohenheim, Stuttgart, Germany
    Introduction: Apple hammerhead viroid (AHVd) is an emerging plant pathogen infecting apple orchards worldwide. Its genetic variability and geographical distribution remain poorly understood, limiting effective diagnostics and management strategies. Methods: In this study, 192 samples from German apple orchards were analyzed using reverse transcription (RT) and real-time PCR, one-step RT real-time PCR, and Sanger sequencing. Next-generation sequencing (NGS) was employed on pooled RNA extracts to explore genetic diversity. Phylogenetic relationships were inferred using maximum likelihood methods, and viroid-derived small RNAs (vd-sRNAs) were identified from small RNA sequencing data. Results and discussion: AHVd was detected in 78% of samples, with prevalence varying by region: southern (82%), eastern (90%), northern (72%), and western (70%) states of Germany. Phylogenetic analysis revealed distinct clusters linked to geographical origins, indicating isolated evolutionary pathways. NGS analysis uncovered 39% inter-sample variability and 169 polymorphic positions, while Sanger sequencing of RT real-time PCR products derived from the same samples showed only 3% variability, reflecting dominant quasispecies populations. Small RNA analysis mapped 128,388 reads to the AHVd genome, identifying hotspots within and outside the rod-like structure, suggesting structural and regulatory functions of vd-sRNAs. These findings underline AHVd’s genetic diversity. The complex relationship between AHVd genetic variability and symptom expression necessitates the development of highly sensitive diagnostic tools and adaptive management strategies to effectively monitor and control its spread in apple production.