TY - THES A1 - Gramma, Vladislav T1 - Potato FLC-like and SVP-like proteins jointly control growth and distinct developmental processes N2 - Based on worldwide consumption, Solanum tuberosum L. (potato) is the most important non-grain food crop. Potato has two ways of stable propagation: sexually via flowering and vegetatively via tuberization. Remarkably, these two developmental processes are controlled by similar molecular regulators and mechanisms. Given that FLC and SVP genes act as key flowering regulators in the model species Arabidopsis and in various other crop species, this study aimed at identifying FLC and SVP homologs in potato and investigating their roles in the regulation of plant development, with a particular focus on flowering and tuberization. Our analysis demonstrated that there are five FLC-like and three SVP like proteins encoded in the potato genome. The expression profiles of StFLCs and StSVPs throughout potato development and the detected interactions between their proteins indicate tissue specificity of the individual genes and distinct roles of a variety of putative protein complexes. In particular, we discovered that StFLC-D, as well as StFLC-B, StSVP-A, and StSVP-B play a complex role in the regulation of flowering time, as not only increased but also decreased levels of their transcripts promote earlier flowering. Most importantly, StFLC-D has a marked impact on tuberization under non-inductive conditions and susceptibility to temperature-induced tuber malformation, also known as second growth. Plants with decreased levels of StFLC-D demonstrated a strong ability to produce tubers under long days and appeared to be insensitive to temperature-induced second growth. Lastly, our data also suggests that StFLCs and StSVPs may be involved in the nitrogen-dependent regulation of potato development. Taken together, this study highlights the functional importance of StFLC and StSVP genes in the regulation of distinct developmental processes in potato. KW - potato KW - Solanum tuberosum KW - tuberization KW - flowering KW - FLOWERING LOCUS C KW - FLC KW - short vegetative phase KW - SVP KW - tuber second growth Y1 - 2023 ER - TY - JOUR A1 - Sprenger, Heike A1 - Rudack, Katharina A1 - Schudoma, Christian A1 - Neumann, Arne A1 - Seddig, Sylvia A1 - Peters, Rolf A1 - Zuther, Ellen A1 - Kopka, Joachim A1 - Hincha, Dirk K. A1 - Walther, Dirk A1 - Koehl, Karin T1 - Assessment of drought tolerance and its potential yield penalty in potato JF - Functional plant biology : an international journal of plant function N2 - Climate models predict an increased likelihood of seasonal droughts for many areas of the world. Breeding for drought tolerance could be accelerated by marker-assisted selection. As a basis for marker identification, we studied the genetic variance, predictability of field performance and potential costs of tolerance in potato (Solanum tuberosum L.). Potato produces high calories per unit of water invested, but is drought-sensitive. In 14 independent pot or field trials, 34 potato cultivars were grown under optimal and reduced water supply to determine starch yield. In an artificial dataset, we tested several stress indices for their power to distinguish tolerant and sensitive genotypes independent of their yield potential. We identified the deviation of relative starch yield from the experimental median (DRYM) as the most efficient index. DRYM corresponded qualitatively to the partial least square model-based metric of drought stress tolerance in a stress effect model. The DRYM identified significant tolerance variation in the European potato cultivar population to allow tolerance breeding and marker identification. Tolerance results from pot trials correlated with those from field trials but predicted field performance worse than field growth parameters. Drought tolerance correlated negatively with yield under optimal conditions in the field. The distribution of yield data versus DRYM indicated that tolerance can be combined with average yield potentials, thus circumventing potential yield penalties in tolerance breeding. KW - performance prediction KW - Solanum tuberosum KW - tolerance index KW - target environment Y1 - 2015 U6 - https://doi.org/10.1071/FP15013 SN - 1445-4408 SN - 1445-4416 VL - 42 IS - 7 SP - 655 EP - 667 PB - CSIRO CY - Clayton ER - TY - JOUR A1 - Licausi, Francesco A1 - Giorgi, Federico Manuel A1 - Schmaelzlin, Elmar A1 - Usadel, Björn A1 - Perata, Pierdomenico A1 - van Dongen, Joost Thomas A1 - Geigenberger, Peter T1 - HRE-Type Genes are regulated by Growth-Related Changes in internal Oxygen Concentrations During the normal development of Potato (Solanum tuberosum) Tubers JF - Plant & cell physiology N2 - The occurrence of hypoxic conditions in plants not only represents a stress condition but is also associated with the normal development and growth of many organs, leading to adaptive changes in metabolism and growth to prevent internal anoxia. Internal oxygen concentrations decrease inside growing potato tubers, due to their active metabolism and increased resistance to gas diffusion as tubers grow. In the present work, we identified three hypoxia-responsive ERF (StHRE) genes whose expression is regulated by the gradual decrease in oxygen tensions that occur when potato tubers grow larger. Increasing the external oxygen concentration counteracted the modification of StHRE expression during tuber growth, supporting the idea that the actual oxygen levels inside the organs, rather than development itself, are responsible for the regulation of StHRE genes. We identified several sugar metabolism-related genes co-regulated with StHRE genes during tuber development and possibly involved in starch accumulation. All together, our data suggest a possible role for low oxygen in the regulation of sugar metabolism in the potato tuber, similar to what happens in storage tissues during seed development. KW - Co-expression KW - ERF KW - Hypoxia KW - Potato KW - Solanum tuberosum KW - Tuber Y1 - 2011 U6 - https://doi.org/10.1093/pcp/pcr128 SN - 0032-0781 VL - 52 IS - 11 SP - 1957 EP - 1972 PB - Oxford Univ. Press CY - Oxford ER -