The application of 28-homocatasterone brassinosteroid reduces blossom end rot in ‘BRS Montese’ tomatoes

Paulo Sérgio Gularte; Aquidauana Miqueloto Zanardi; Tiago Miqueloto; Odimar Zanuzo Zanardi; Cristiano André Steffens; Cassandro Vidal Talamini do Amarante

doi:10.5965/223811712142022428

Authors

Paulo Sérgio Gularte Santa Catarina State University https://orcid.org/0000-0003-2399-3546
Aquidauana Miqueloto Zanardi Instituto Federal de Santa Catarina https://orcid.org/0000-0001-6051-2882
Tiago Miqueloto Santa Catarina State University https://orcid.org/0000-0002-1846-4466
Odimar Zanuzo Zanardi Instituto Federal de Santa Catarina https://orcid.org/0000-0002-1872-0749
Cristiano André Steffens Santa Catarina State University https://orcid.org/0000-0003-0936-8656
Cassandro Vidal Talamini do Amarante Santa Catarina State University https://orcid.org/0000-0003-0563-2093

DOI:

https://doi.org/10.5965/223811712142022428

Keywords:

Solanum lycopersicum, calcium, physiological disorder, Lycopersicon esculentum, xylem

Abstract

We assessed the effect of 28-homocatasterone on xylem functionality and its relationship with blossom end rot (BER) occurrence and the quality of 'BRS Montese' tomatoes. Tomato plants were cultivated in a protected environment, with a semi-hydroponic system. During full flowering, open flowers were selected, marked, and pollinated. After two days, the flowers received the application of 28-homocatasterone at a concentration of 10^-6 M or deionized water (control). Treatments were reapplied weekly up to 24 days after the first application (DAFA). At 24 DAFA, fruits were harvested and evaluated for fresh mass, texture (skin rupture and pulp penetration forces), skin color, xylem functionality, membrane permeability, apoplastic calcium concentration, and BER incidence. The application of 28-homocatasterone at 10^-6 M did not increase the fresh mass nor change the fruits' texture attributes. However, 28-homocatasterone increased or kept xylem functionality, which was assicated with increased apoplastic calcium concentration and reduced BER occurrence in 'BRS Montese' tomatoes. Thus, the application of 10^-6 M catasterone could be an alternative for BER control in tomatoes.

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References

ANDRADE IGV et al. 2020. Quality of Italian tomatoes grown with different forms of calcium application. Research, Society and Development 9: e-10191210837.

AYUB RA & REZENDE BLA. 2010. Contribuição do ácido giberélico no tamanho de frutos do tomateiro. Biotemas 23: 25-28.

BARTLETT MS. 1937. Properties of sufficiency and statistical tests. Proceedings of the Royal Society of London 160: 268-282.

ALCANTARA-CORTES JS et al. 2019. Principales reguladores hormonales y sus interacciones en el crecimiento vegetal. Nova 17: 109-129.

DRAŽETA L et al. 2004. Causes and Effects of Changes in Xylem Functionality in Apple Fruit. Annals of Botany 93: 275-282.

FAQUIN V. 2005. Nutrição mineral de plantas. 1.ed. Lavras: UFL.

FREITAS ST et al. 2010. Cellular approach to understand bitter pit development in apple fruit. Postharvest Biology and Technology 57: 6-13.

FREITAS ST et al. 2014. Calcium partitioning and allocation and blossom-end rot development in tomato plants in response to whole-plant and fruit-specific abscisic acid treatments. Journal of Experimental Botany 65: 235-247.

FREITAS ST et al. 2011. Dynamic alternations in cellular and molecular components during blossom-end rot development in tomatoes expressing CAX1, a constitutively active Ca2+/H+ antiporter from Arabidopsis. Plant Physiology 156: 844-855.

FREITAS ST et al. 2017. Transcriptome approach to understand the potential mechanisms inhibiting or triggering blossom-end rot development in tomato fruit in response to plant growth regulators. Journal of Plant Growth Regulation 37: 183-198

FUKUDA H. 2004. Signals that control plant vascular cell differentiation. Nature Reviews Molecular Cell Biology 5: 379-391.

GARCÍA-MARTÍNEZ I & HERNÁNDEZ SILVA E. 2016. Brasinoesteroides en la agricultura. Revista Mexicana de Ciencias Agrícolas 7: 451-462.

MIQUELOTO A et al. 2018. Mechanisms regulating fruit calcium content and susceptibility to bitter pit in cultivars of apple. Acta Horticulturae 1194: 469-474.

NAGATA N et al. 2001. Brassinazole, an inhibitor of brassinosteroid biosynthesis, inhibits development of secondary xylem in Cress plants (Lepidium sativum). Plant and Cell Physiology 42: 1006-1011.

OLLE M & WILLIAMS IH. 2017. Physiological disorders in tomato and some methods to avoid them. The Journal of Horticultural Science and Biotechnology 92: 223-230.

PEET MM. 2009. Physiological disorders in tomato fruit development. Acta Horticulturae 821: 151-160.

PLANAS-RIVEROLA A et al. 2019. Brassinosteroid signaling in plant development and adaptation to stress. Development 146: e-151894.

RAIOLA A et al. 2014. Enhancing the Health-Promoting Effects of Tomato Fruit for Biofortified Food. Mediators of Inflammation 2014: 1-16.

RAMOS AP et al. 2019. Effects of an Auxin and a brassinosteroid on physical, chemical and biochemical attributes of “Galaxy” apples. Ciência Rural 49: e-20180311.

REITZ NF et al. 2021. Differential effects of excess calcium applied to whole plants vs. excised fruit tissue on blossom-end rot in tomato. Scientia Horticulturae 290: e-110514.

RIBOLDI et al. 2018. 24-Epibrassinolide Mechanisms Regulating Blossom-End Rot Development in Tomato Fruit. Journal of Plant Growth Regulation 38: 812-823.

SAITO M et al. 2018. BES1 and BZR1 Redundantly Promote Phloem and Xylem Differentiation. Plant and Cell Physiology 59: 590-600.

SAS INSTITUTE. 2002. Getting started with the SAS learning edition. Cary: SAS Institute Inc.

SAURE MC. 2005. Calcium translocation to fleshy fruit: its mechanism and endogenous control. Scientia Horticulturae 105: 65-89.

SHAPIRO SS & WILK MB. 1965. An analysis of variance test for normality (complete samples). Biometrika 52: 591-611.

SOLDATELI FJ et al. 2020. Crescimento e produtividade de cultivares de tomate cereja utilizando substratos de base ecológica. Colloquium Agrariae 16: 1-10.

SONG WP et al. 2018. Ca Distribution Pattern in Litchi Fruit and Pedicel and Impact of Ca Channel Inhibitor, La3+. Frontiers in Plant Science 8: 1-11.

SOUSA VF et al. 2011. Irrigação e fertirrigação em frutíferas e hortaliças. 1.ed. Brasília: Embrapa Informação Tecnológica.

TAIZ L & ZEIGER E. 2017. Fisiologia e Desenvolvimento Vegetal. 6.ed. Porto Alegre: Artmed. 888p.

VILLEGAS-TORRES OG et al. 2017. Relación del calcio con las enfermedades de los cultivos. Investigación Agropecuaria 4: 77-86.

VINH TD et al. 2018. Comparative Analysis on Blossom-end Rot Incidence in Two Tomato Cultivars in Relation to Calcium Nutrition and Fruit Growth. The Horticulture Journal 87: 97-105.

The application of 28-homocatasterone brassinosteroid reduces blossom end rot in ‘BRS Montese’ tomatoes

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