Abstract:
A field experiment was conducted with 22 Brassica napus L. advanced lines at the
experimental farm of Sher-e-Bangla Agricultural University, Dhaka to study the genetic
variability, interrelationship, path coefficient and genetic diversity in Brassica napus L.
during November 2008 to March 2009. The genotypes were found to differ
significantly for all the characters studied except days to 80% maturity. The characters
days to 80% maturity, plant height, number of primary branches per plant, number of
seeds per siliqua, number of siliqua per plant and seed yield per plant showed higher
influence of environment whereas, siliqua length and 1000-seed weight showed least.
Moreover, the number of primary branches per plant, number of secondary branches
per plant, siliqua length, number of seeds per siliqua, number of siliqua per plant,
1000-seed weight and seed yield per plant showed moderate broad base heritability
while plant height exhibits the highest heritability. The significant positive correlation
with seed yield per plant was found in plant height, number of primary branches per
plant and number of siliqua per plant. However, the highest significant positive
correlation was found between days to 50% flowering and plant height. Path
coefficient analysis showed that the plant height had maximum positive direct effect
on seed yield followed by number of siliqua per plant and siliqua length. Plant height,
number of primary branches per plant and number of siliqua per plant were the most
important contributors to seed yield per plant which could be taken in consideration for
future hybridization program. Different multivariate analysis techniques were used to
classify 22 Brassica napus genotypes. The genotypes were grouped into four clusters.
The highest inter-cluster distance was observed between clusters II and IV whereas
the maximum intra-cluster distance was found in cluster II. Therefore, the genotypes
belonging to cluster I and cluster II, cluster II and cluster Ill and cluster Ill and cluster
IV have been selected for future hybridization program. The role of number of
secondary branches per plant and number of siliqua per plant in both the vectors were
important components for genetic divergence in these materials. Considering group
distance and other agronomic performance the inter-genotypic crosses between 01
and 02, 02 and G6; G6 and 07; 06 and G8 and G7 and 08 might be suggested for
future hybridization program.
Description:
A Thesis
Submitted to the Faculty of Agriculture,
Sher-e-Bangla Agricultural University, Dhaka,
in partial fulfillment of the requirements
for the degree of
MASTER OF SCIENCE
IN
GENETICS AND PLANT BREEDING
SEMESTER: JULY-DECEMBER, 2009