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Biology and Biotechnology of Environmental Stress Tolerance in Plants, Volume 3
tools such as genomics and transcriptomics have further enabled the dissec
tion of genetic and phenotypic changes occurring in plants on being exposed
to unfavorable environmental conditions. In this chapter, we try to decipher
the major role played by metabolomics tools for crop improvement. Here,
we describe the workflow of plant metabolomics research, focusing on the
elucidation of biotic and abiotic stress tolerance mechanisms in plants along
with its potential future role in plant sciences.
14.1 INTRODUCTION
Metabolomics is one of the upcoming and most fascinating tools of omics
techniques that have extensively contributed towards the development of
crops which resulted in higher survival ability of plants on being exposed to
unfavorable environmental conditions. Metabolomics helps us to decipher the
total metabolite pool of any plant, which is further measured to characterize
the genetic changes occurring in plants in response to abiotic or biotic stresses
and metabolic assisted breeding. Till date, around 2,00,000 metabolites have
been identified in plants and a wide variety of metabolites is still unknown
(Razzaq et al., 2019). All the identified metabolites vary in their structure
and function and play a critical role in plant biology. Metabolome profile of
an organism refers to all the low weight metabolites. According to Deborde
et al. (2017), metabolomics study is mostly linked with identifications and
quantifications of small molecules and their functions and interactions
with other metabolites in an organism. Most of the metabolites identified
in plants are associated with their growth and development, crop yield and
tolerance capability against stressed environment (Han & Micallef, 2016).
Ecological metabolomics is one of the major branches of metabolomics that
help us to understand the interconnection between plant biochemical and
various spatial and temporal systems. Ecological metabolome study helps
to identify any change in the metabolites level or new metabolites formed in
plants in response to abiotic/biotic stresses. Additionally, it also explains the
biochemical changes that occur in plants in response to biotic stresses such as
infection, attack of parasite or disease occurrence. According to Garcia-Cela
et al. (2018), study of variations in the concentration of several metabolites
can help to decipher the mechanistic network that eventually explains the
physiological, biochemical, and phenotypic changes occurring in plants in
response to environmental fluctuations.