Your search keyword '"Hytonen, Timo"' showing total 3 results

1. Additive QTLs on three chromosomes control flowering time in woodland strawberry (Fragaria vesca L.)

Author

University of Helsinki, Department of Agricultural Sciences, Samad, Samia, Kurokura, Takeshi, Koskela, Elli, Toivainen, Tuomas, Patel, Vipul, Mouhu, Katriina, Sargent, Daniel James, Hytonen, Timo, University of Helsinki, Department of Agricultural Sciences, Samad, Samia, Kurokura, Takeshi, Koskela, Elli, Toivainen, Tuomas, Patel, Vipul, Mouhu, Katriina, Sargent, Daniel James, and Hytonen, Timo

Abstract

Flowering time is an important trait that affects survival, reproduction and yield in both wild and cultivated plants. Therefore, many studies have focused on the identification of flowering time quantitative trait locus (QTLs) in different crops, and molecular control of this trait has been extensively investigated in model species. Here we report the mapping of QTLs for flowering time and vegetative traits in a large woodland strawberry mapping population that was phenotyped both under field conditions and in a greenhouse after flower induction in the field. The greenhouse experiment revealed additive QTLs in three linkage groups (LG), two on both LG4 and LG7, and one on LG6 that explain about half of the flowering time variance in the population. Three of the QTLs were newly identified in this study, and one co-localized with the previously characterized FvTFL1 gene. An additional strong QTL corresponding to previously mapped PFRU was detected in both field and greenhouse experiments indicating that gene(s) in this locus can control the timing of flowering in different environments in addition to the duration of flowering and axillary bud differentiation to runners and branch crowns. Several putative flowering time genes were identified in these QTL regions that await functional validation. Our results indicate that a few major QTLs may control flowering time and axillary bud differentiation in strawberries. We suggest that the identification of causal genes in the diploid strawberry may enable fine tuning of flowering time and vegetative growth in the closely related octoploid cultivated strawberry.

Published

2017

2. Virus-induced gene silencing for Asteraceae-a reverse genetics approach for functional genomics in Gerbera hybrida

Author

Deng, Xianbao, Elomaa, Paula, Nguyen, Cuong X., Hytonen, Timo, Valkonen, Jari P. T., Teeri, Teemu H., Department of Agricultural Sciences, Plant Pathology and Virology, Asteraceae developmental biology and secondary metabolism, Plant Production Sciences, and Strawberry research group

Subjects

EXPRESSION, education, Gerbera, MOSAIC-VIRUS, TOBACCO-RATTLE-VIRUS, MADS-BOX GENE, DIHYDROFLAVONOL-4-REDUCTASE DFR, TRV, Asteraceae, infiltration, ARABIDOPSIS, MODEL, gene silencing, VIGS, silencing, PLANTS, BIOSYNTHESIS, 1183 Plant biology, microbiology, virology, CHALCONE SYNTHASE

Published

2012

3. Control of Flowering in Strawberries

Author

Timo Hytönen, Elli A. Koskela, Hytonen, Timo, Graham, Julia, Harrison, Richard, Doctoral Programme in Plant Sciences, Department of Agricultural Sciences, Viikki Plant Science Centre (ViPS), Plant Production Sciences, and Strawberry research group

Subjects

0106 biological sciences, 0301 basic medicine, Perennial plant, Vegetative reproduction, fungi, food and beverages, 414 Agricultural biotechnology, Meristem, Biology, Fragaria, 01 natural sciences, Sexual reproduction, 03 medical and health sciences, Horticulture, 030104 developmental biology, Inflorescence, Axillary bud, 1183 Plant biology, microbiology, virology, 010606 plant biology & botany, Plant stem

Abstract

Strawberries (Fragaria sp.) are small perennial plants capable of both sexual reproduction through seeds and clonal reproduction via runners. Because vegetative and generative developmental programs are tightly connected, the control of flowering is presented here in the context of the yearly growth cycle. The rosette crown of strawberry consists of a stem with short internodes produced from the apical meristem. Each node harbors one trifoliate leaf and an axillary bud. The fate of axillary buds is dictated by environmental conditions; high temperatures and long days (LDs) promote axillary bud development into runners, whereas cool temperature and short days (SDs) favor the formation of branch crowns. SDs and cool temperature also promote flowering; under these conditions, the main shoot apical meristem is converted into a terminal inflorescence, and vegetative growth is continued from the uppermost axillary branch crown. The environmental factors that regulate vegetative and generative development in strawberries have been reasonably well characterized and are reviewed in the first two chapters. The genetic basis of the physiological responses in strawberries is much less clear. To provide a point of reference for the flowering pathways described in strawberries so far, a short review on the molecular mechanisms controlling flowering in the model plant Arabidopsis is given. The last two chapters will then describe the current knowledge on the molecular mechanisms controlling the physiological responses in strawberries.

Published

2018