Genetic diversity and development of high fiber yield kenaf (Hibiscus cannabinus L.) mutant hybrids through diallel crosses
Kenaf (Hibiscus cannabinus L.) is an economically important fiber crop globally for multipurpose industrial uses such as paper making, car interior components and building boards. However, commercial cultivation of this fiber crop in Malaysia has limitations due to lack of superior varieties with...
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Main Author: | |
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Format: | Thesis |
Language: | English |
Published: |
2022
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Subjects: | |
Online Access: | http://psasir.upm.edu.my/id/eprint/109429/1/MD.%20AL-MAMUN%20-IR.pdf http://psasir.upm.edu.my/id/eprint/109429/ |
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Institution: | Universiti Putra Malaysia |
Language: | English |
Summary: | Kenaf (Hibiscus cannabinus L.) is an economically important fiber crop globally for
multipurpose industrial uses such as paper making, car interior components and building
boards. However, commercial cultivation of this fiber crop in Malaysia has limitations
due to lack of superior varieties with high fiber yield. This study was conducted to assess
the genetic diversity among kenaf mutants based on agro-morphological traits and
molecular markers diversity, analyze the combining ability of the selected parents and
hybrids, and estimate heterosis and the nature of gene actions. To achieve these
objectives, field trials and molecular diversity works were conducted at Universiti Putra
Malaysia (UPM), Serdang, Selangor, Malaysia, between 2019 and 2021. Data were
collected on the eight qualitative and 15 quantitative traits of the 31 kenaf genotypes.
The analysis of variance over two evaluation seasons showed significant differences
among genotypes for all traits except for stem top diameter. According to principal
component analysis (PCA), the first five PCA accounted for 85.16% variation between
genotypes based on a correlation matrix of all the quantitative traits. The mutant lines
derived from V36 parental variety were grouped into six clusters, indicating a wide range
of genetic variability. Path coefficient analysis revealed the maximum contribution of
fresh stem weight without leaves and pod to fiber yield, followed by plant height. For
molecular characterization, 10 out of the 72 expressed sequence tags - simple sequence
repeat (EST-SSR) primers produced clear polymorphic bands with a mean value of 5.2
alleles per primer. These EST-SSR primers were found to be extremely informative,
suggesting that among the 31 genotypes were genetically diverse. The polymorphism
information content (PIC) value ranged from 0.531 to 0.737, with a mean of 0.610,
indicating that the genotypes are genetically diverse. Shannon index estimation varied
from 0.982 to 1.515 among 31 genotypes, whereas 0.123 to 0.405 was recorded within
the early, intermediate and mid-late flowering groups. Genetic differentiation ranged
from 0.67 to 1.0 alongside the average gene flow (Nm) of 0.024. The analysis of
molecular variance (AMOVA) revealed 76% variation within three flowering groups.,
while among the groups recorded was 24%. Based on the unweighted pair group method
with arithmetic means (UPGMA) dendrogram the evaluated kenaf mutants were clustered into five major groups based on EST-microsatellites data. Combining
phenotypic and molecular data in the selection of parents for hybridization activities
would yield a more accurate summary and the cluster analysis identified eight mutant
lines (G5, G9, G13, G21, G22, G24, G30 and G31) and one inbred (G28) that were
selected for hybrid crossing using a half diallel method. The genotypes were chosen as
parental sources from each heterotic group at the genetic and phenotypic levels on
genetic distances and several important agronomic traits. Thirty-six hybrids were
successfully produced from nine morphologically distinct kenaf genotypes using half
diallel mating design. Field trials were carried out in two environments to evaluate the
yield performance of 36 F1 hybrid crosses and nine parental lines using seven qualitative
and 15 quantitative attributes. From the combined data of the two environments, the
combining ability analysis revealed significant general combining ability (GCA) for all
traits except stem top diameter, and significant specific combining ability (SCA) for all
traits except plant height and stem top diameter. The result indicated that additive and
non-additive gene actions were involved in the genetic control of the traits. The
magnitude of GCA variance was considerably higher than that of SCA variance except
for stem top diameter, node number, and fresh stem weight with leaves and pod, showing
that additive gene action predominates for these traits. The parental lines P1 (G5: ML5),
P3 (G13: ML36-10) and P4 (G21: ML36-24) had outstanding general combiners for fiber
yield and yield-related traits. Most traits showed over-dominant gene action, except for
plant height, stem middle diameter, stem top diameter, days to first flowering, dry stick
weight, dry fiber weight and 1000 seed weight, which showed a partial dominance.
Considering specific combining ability and heterosis values, the crosses P1 (G5) × P4
(G21), P1 (G5) × P9 (G31), P2 (G9) × P3 (G13), P2 (G9) × P5 (G22), P4 (G21) × P6 (G24),
P4 (G21) × P7 (G28), P4 (G21) × P9 (G31), P5 (G22) × P8 (G30), and P7 (G28) × P9 (G31)
were high heterotic response for fiber yield, stick yield, number of pods per plant and
smaller seed size. The nine hybrids are recommended for further evaluation at multilocation
trials to select several superior hybrids with high fiber yield for commercial
cultivation in Malaysia. |
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