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. 2024 Jan 19;19(1):e0297202.
doi: 10.1371/journal.pone.0297202. eCollection 2024.

Study on the genetic variability and adaptability of turmeric (Curcuma longa L.) genotypes for development of desirable cultivars

Md Ashraful Alam  1 Srabanti Roy  2 Md Atikur Rahman  3 Md Riazul Islam  4 Md Mushfiqur Rahman  5 Abu Jafor Obaidullah  6 Md Nasirul Farid  7 Md Marufur Rahman  8 Md Rafiqul Islam  9 Shailendra Nath Mozumder  10 Riyadh S Almalki  11 Ahmed Gaber  12 Akbar Hossain  13
Affiliations

Study on the genetic variability and adaptability of turmeric (Curcuma longa L.) genotypes for development of desirable cultivars

Md Ashraful Alam et al. PLoS One. .

Abstract

Turmeric, a globally cultivated spice, holds significance in medicine, and cosmetics, and is also a very popular ingredient in South Asian cuisine. A study involving 53 turmeric genotypes evaluated for rhizome yield and related traits at Spices Research Center, Bogura, Bangladesh over three years (2019-22). A randomized complete block design was followed with two replications. ANOVA revealed significant trait variations among genotypes. Genotype T0015 emerged as the highest yielder at 28.04 t/ha. High heritability (0.58-0.99) and genetic advance characterized plant height (PH), mother rhizome weight (WMR), primary and secondary finger weights (WPF and WSF), and yield per plant (YPP) across seasons. Genetic gain (GG) was prominent in these traits. Genotypic and phenotypic coefficient variations (GCV and PCV) (6.24-89.46 and 8.18-90.88, respectively) across three years highlighted mother rhizome weight's importance followed by numbers of primary finger (NPF), and WPF. Positive and significant correlations, especially with PH, WMR, WPF, and YPP, emphasized their relevance to fresh yield (FY). Multiple linear regression identified PH, number of mother rhizome (NMR) and WMR as key contributors, explaining 37-79% of FY variability. Cluster analysis grouped genotypes into five clusters with maximum distance observed between clusters II and III. The geometric adaptability index (GAI) assessed adaptability and superiority, revealing nine genotypes outperforming the best existing cultivar. Genotype T0117 as the top performer based on GAI, followed by T0103 and T0094. Mean rank analysis favoured T0121 as the best performer, succeeded by T0117, T0082 and T0106. The top ten genotypes (T0015, T0061, T0082, T0085, T0094, T0103, T0106, T0117, T0121 and T0129) were identified as superior based on yield and overall ranking, warranting further evaluation. These findings may induce a window for improving turmeric research and ultimately play a role in enhancing its cultivation and productivity.

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Conflict of interest statement

The authors have declared that no competing interests exist.

Figures

Fig 1
Fig 1. Graph displaying contributions of different traits to the fresh yield variation.
[Here the abbreviation represents as: PH = Plant Height; NB = Number of branches; NL = Number of leaves; NMR = Number of mother rhizome; WMR = Weight of mother rhizome; NPF = Number of primary fingers; WPF = Weight of primary finger; NSF = Number of secondary fingers; WSF = Weight of secondary finger; MRL = Length of mother rhizome; YPP = Yield per plant; FY = Fresh yield].
Fig 2
Fig 2. Dendrogram showing the grouping of turmeric genotypes based on all the trait’s performances over the years.
See this image and copyright information in PMC

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