TY - CHAP
T1 - Emerging advances in computational omics tools for systems analysis of gramineae family grass species and their abiotic stress responsive functions
AU - Muthuramalingam, Pandiyan
AU - Jeyasri, Rajendran
AU - Kalaiyarasi, Dhamodharan
AU - Pandian, Subramani
AU - Krishnan, Subramanian Radhesh
AU - Satish, Lakkakula
AU - Pandian, Shunmugiah Karutha
AU - Ramesh, Manikandan
N1 - Publisher Copyright:
© 2019 Scrivener Publishing LLC. All rights reserved.
PY - 2019/3/1
Y1 - 2019/3/1
N2 - C3 and C4 grass species (C3: rice, C4: foxtail millet, sorghum, maize) are simultaneously exposed to one or more abiotic stresses (AbS) either independently or in combination, which leads to loss of nutritional value and yield loss. Throughout the life cycle, these plants face unique and combined AbS (CAbS). A large number of studies have been conducted to understand the molecular mechanisms imparting plant tolerance to diverse unique stresses. Still, the CAbS tolerance mechanism has not been sufficiently studied due to multiple complexities involved. In recent past, several computational omics databases and NGS-based sequencing technologies helped researchers to understand the molecular cross-talks and cellular systems of the plants especially in Gramineae grass species. An innovation in omics and NGS-based research has provided much needed platform to characterize and identify the significance, gain molecular insights, and potential CAbS responsible genes, and promote translational research through available integrated multiple omics approaches. In view of these, this chapter elaborates the novel aspects of the plant cellular systems and CAbS responsive genes via various integrative omics approaches. The chapter also delineates the current status, challenges, and future prospects of plant cellular systems and CAbS responsive gene functional discovery for candidate gene selection and also for understanding their role in enhancing crop yield and tolerance level.
AB - C3 and C4 grass species (C3: rice, C4: foxtail millet, sorghum, maize) are simultaneously exposed to one or more abiotic stresses (AbS) either independently or in combination, which leads to loss of nutritional value and yield loss. Throughout the life cycle, these plants face unique and combined AbS (CAbS). A large number of studies have been conducted to understand the molecular mechanisms imparting plant tolerance to diverse unique stresses. Still, the CAbS tolerance mechanism has not been sufficiently studied due to multiple complexities involved. In recent past, several computational omics databases and NGS-based sequencing technologies helped researchers to understand the molecular cross-talks and cellular systems of the plants especially in Gramineae grass species. An innovation in omics and NGS-based research has provided much needed platform to characterize and identify the significance, gain molecular insights, and potential CAbS responsible genes, and promote translational research through available integrated multiple omics approaches. In view of these, this chapter elaborates the novel aspects of the plant cellular systems and CAbS responsive genes via various integrative omics approaches. The chapter also delineates the current status, challenges, and future prospects of plant cellular systems and CAbS responsive gene functional discovery for candidate gene selection and also for understanding their role in enhancing crop yield and tolerance level.
KW - Abiotic stress
KW - Gramineae grass species
KW - Omics
KW - Systems biology
UR - http://www.scopus.com/inward/record.url?scp=85088211999&partnerID=8YFLogxK
U2 - 10.1002/9781119509967.ch10
DO - 10.1002/9781119509967.ch10
M3 - Chapter
AN - SCOPUS:85088211999
SN - 9781119509936
SP - 185
EP - 215
BT - OMICS-Based Approaches in Plant Biotechnology
PB - wiley
ER -