TY  - JOUR
AV  - public
A1  - Pandey, M K
A1  - Pandey, A K
A1  - Kumar, R
A1  - Nwosu, C V
A1  - Guo, B
A1  - Wright, G C
A1  - Bhat, R S
A1  - Chen, X
A1  - Bera, S K
A1  - Yuan, M
A1  - Jiang, H
A1  - Faye, I
A1  - Radhakrishnan, T
A1  - Wang, X
A1  - Liang, X
A1  - Liao, B
A1  - Zhang, X
A1  - Varshney, R K
A1  - Zhuang, W
TI  - Translational genomics for achieving higher genetic gains in groundnut
UR  - https://doi.org/10.1007/s00122-020-03592-2
JF  - Theoretical and Applied Genetics (TSI)
SN  - 0040-5752
PB  - Springer Verlag
N1  - The authors are thankful to Bill & Melinda Gates
Foundation (Tropical Legumes III); Department of Biotechnology
(DBT) of Government of India; National Agricultural Science Fund (NASF) of Indian Council of Agricultural Research, India; World
Bank-assisted Karnataka Watershed Development Project-II (KWDPII)
funded by Government of Karnataka (GoK), India; MARS-Wrigley
Inc., USA; and National Natural Science Foundation (NSF) of China
(U1705233 to W. Z.). The work reported in this article was undertaken
as a part of the CGIAR Research Program on Grain Legumes and Dryland
Cereals (GLDC). ICRISAT is a member of the CGIAR.
N2  - Cultivated groundnut or peanut (Arachis hypogaea), an allopolyploid oilseed crop with a large and complex genome,
is one of the most nutritious food. This crop is grown in more than 100 countries, and the low productivity has remained
the biggest challenge in the semiarid tropics. Recently, the groundnut research community has witnessed fast progress and
achieved several key milestones in genomics research including genome sequence assemblies of wild diploid progenitors,
wild tetraploid and both the subspecies of cultivated tetraploids, resequencing of diverse germplasm lines, genome-wide
transcriptome atlas and cost-effective high and low-density genotyping assays. These genomic resources have enabled
high-resolution trait mapping by using germplasm diversity panels and multi-parent genetic populations leading to precise
gene discovery and diagnostic marker development. Furthermore, development and deployment of diagnostic markers have
facilitated screening early generation populations as well as marker-assisted backcrossing breeding leading to development
and commercialization of some molecular breeding products in groundnut. Several new genomics applications/technologies
such as genomic selection, speed breeding, mid-density genotyping assay and genome editing are in pipeline. The integration
of these new technologies hold great promise for developing climate-smart, high yielding and more nutritious groundnut
varieties in the post-genome era.
KW  - Groundnut
KW  -  Genomics
Y1  - 2020/04//
SP  - 1679
ID  - icrisat11505
EP  - 1702
VL  - 133
IS  - 5
ER  -