СУПЕРЭКСПРЕССИЯ ГЕНА ХРИЗАНТЕМЫ CDM44 ПОВЫШАЕТ УСТОЙЧИВОСТЬ РАСТЕНИЙ ТАБАКА К ПОНИЖЕННЫМ ТЕМПЕРАТУРАМ

1. Castelán-Muñoz N. et al. MADS-Box genes are key components of genetic regulatory networks involved in abiotic stress and plastic developmental responses in plants //Frontiers in plant science.2019.Т. 10.С. 853.

2. Ditta G. et al. TheSEP4 gene of Arabidopsis thaliana functions in floral organ and meristem identity //Current Biology.2004.Т. 14.№. 21.С. 1935-1940.

3. Dong T. et al. A non-climacteric fruit gene CaMADS-RIN regulates fruit ripening and ethylene biosynthesis in climacteric fruit //PLoS ONE.2014.Т. 9.№. 4.С. e95559.

4. Ferrario S. et al. The MADS box geneFBP2 is required for SEPALLATA function in petunia //The Plant Cell. 2003. Т. 15. №. 4. С. 914-925.

5. Jaakola L. et al. ASQUAMOSAMADS box gene involved in the regulation of anthocyanin accumulation in bilberry fruits //Plant Physiology. 2010. Т. 153.№. 4. С. 1619-1629.

6. Li S. et al. A Critical Evaluation of the Role of Ethylene and MADS Transcription Factors in the Network Controlling Fleshy Fruit Ripening. New Phytol. 2019. Т. 221. №. 4. С. 1724-1741.

7. Parenicová L. et al. Molecular and phylogenetic analyses of the complete MADS-box transcription factor family in Arabidopsis: new openings to the MADS world //The Plant Cell.2003.Т. 15.№. 7.С. 1538-1551.

8. Pelaz S. et al. B and C floral organ identity functions require SEPALLATA MADS-box genes //Nature.2000.Т. 405.№. 6783.С. 200-203.

9. Pelaz S. et al. APETALA1 andSEPALLATA3 interact to promote flower development //The Plant Journal.2001.Т. 26.№. 4.С. 385-394.

10. Smaczniak C. et al. Characterization ofMADS-domain transcription factor complexes in Arabidopsis flower development //Proceedings of the National Academy of Sciences.2012.Т. 109.№. 5.С. 1560-1565.

11. Theißen G., Melzer R., Rümpler F. MADS-domain transcription factors and the floral quartet model of flower development: linking plant development and evolution //Development.2016.Т. 143.№. 18.С. 3259-3271.