Comparative Assessment of Morphological, Cytological, and Photosynthetic Characteristics of the Induced Octoploid and Its Tetraploid Counterpart of Celosia Argentea L

Overview

Journal BMC Plant Biol

Publisher Biomed Central

Specialty Biology

Date 2024 Dec 21

PMID 39709350

Authors

Rohit Bharati

Yamen Homaidan Shmeit

Jana Hanzal Sediva

Tomas Thanh Nguyen Cong

Jiban Kumar Kundu

Lucie Severova

Roman Svoboda

Eloy Fernandez-Cusimamani

Affiliations

Soon will be listed here.

Abstract

Background: Celosia argentea is a widely recognized plant for its ornamental qualities and therapeutic uses in traditional medicine. As demand for such multipurpose plants grows, enhancing its phenotypic and physiological traits could further expand its commercial potential. Polyploidization, particularly through chemical treatments like oryzalin, offers a method to induce genetic variation and potentially improve desirable traits in plants.

Results: Tetraploid (2n = 4×= 36) nodal segments of C. argentea were treated with oryzalin under in vitro conditions, resulting in successful induction of octoploidy (2n = 8×= 72). Flow cytometry and chromosome counting confirmed polyploidization, with the highest induction rate achieved using 40 µM oryzalin for 24 h. Comparative analyses between octoploid and tetraploid plants revealed significant differences in morphological traits, including increased stem and leaf thickness, larger leaf area, inflorescence characteristics and more compact growth in the octoploids. Additionally, octoploids exhibited enhanced chlorophyll content and altered photosynthetic characteristics, along with notable changes in stomatal size and density. Ploidy stability was maintained across generations, ensuring the heritability of the induced traits.

Conclusions: In vitro polyploidization in C. argentea led to significant phenotypic and physiological improvements, demonstrating its potential for application in ornamental horticulture and plant breeding. This research contributes to the understanding of the impact of in vitro polyploidization on plant development, offering insights for the commercial cultivation and enhancement of C. argentea.

Clinical Trial Number: Not applicable.

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