AUTHOR=Ergon Åshild , Melby Tone I. , Höglind Mats , Rognli Odd A. 

TITLE=Vernalization Requirement and the Chromosomal VRN1-Region can Affect Freezing Tolerance and Expression of Cold-Regulated Genes in Festuca pratensis

JOURNAL=Frontiers in Plant Science

VOLUME=7

YEAR=2016

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2016.00207

DOI=10.3389/fpls.2016.00207

ISSN=1664-462X

ABSTRACT=<p>Plants adapted to cold winters go through annual cycles of gain followed by loss of freezing tolerance (cold acclimation and deacclimation). Warm spells during winter and early spring can cause deacclimation, and if temperatures drop, freezing damage may occur. Many plants are vernalized during winter, a process making them competent to flower in the following summer. In winter cereals, a coincidence in the timing of vernalization saturation, deacclimation, downregulation of cold-induced genes, and reduced ability to reacclimate, occurs under long photoperiods and is under control of the main regulator of vernalization requirement in cereals, <italic>VRN1</italic>, and/or closely linked gene(s). Thus, the probability of freezing damage after a warm spell may depend on both vernalization saturation and photoperiod. We investigated the role of vernalization and the <italic>VRN1</italic>-region on freezing tolerance of meadow fescue (<italic>Festuca pratensis</italic> Huds.), a perennial grass species. Two F<sub>2</sub> populations, divergently selected for high and low vernalization requirement, were studied. Each genotype was characterized for the copy number of one of the four parental haplotypes of the <italic>VRN1</italic>-region. Clonal plants were cold acclimated for 2 weeks or vernalized/cold acclimated for a total of 9 weeks, after which the F<sub>2</sub> populations reached different levels of vernalization saturation. Vernalized and cold acclimated plants were deacclimated for 1 week and then reacclimated for 2 weeks. All treatments were given at 8 h photoperiod. Flowering response, freezing tolerance and expression of the cold-induced genes <italic>VRN1, MADS3, CBF6, COR14B, CR7</italic> (<italic>BLT14</italic>), <italic>LOS2</italic>, and <italic>IRI1</italic> was measured. We found that some genotypes can lose some freezing tolerance after vernalization and a deacclimation–reacclimation cycle. The relationship between vernalization and freezing tolerance was complex. We found effects of the <italic>VRN1</italic>-region on freezing tolerance in plants cold acclimated for 2 weeks, timing of heading after 9 weeks of vernalization, expression of <italic>COR14B, CBF6</italic>, and <italic>LOS2</italic> in vernalized and/or deacclimated treatments, and restoration of freezing tolerance during reacclimation. While expression of <italic>VRN1, COR14B, CBF6, LOS2</italic>, and <italic>IRI1</italic> was correlated, <italic>CR7</italic> was associated with vernalization requirement by other mechanisms, and appeared to play a role in freezing tolerance in reacclimated plants.</p>