Adhini S. Pazhany scite author profile

The transition from fossil fuels to more renewable sources of energy requires dedicated lignocellulosic feedstocks with desirable traits. The structural diversity and complexity of cell walls cause technological and scientific bottlenecks in the efficient utilization of plant biomass. The relative composition and content of the major cell wall components such as cellulose, hemicellulose, and lignin determines the downstream utility of plant biomass. Lignin in the secondary cell walls is a major hindrance in the effective processing of lignocellulosic biomass. Strategies for altering the lignin profile of biomass crops through targeted manipulation of lignin biosynthetic genes using novel genetic approaches can facilitate biomass processing. Tissue specific expressions of genes, transcriptional regulation of lignin biosynthesis, and novel approaches like genome editing can aid in improving cell wall composition and plant architecture.

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Physiological and Molecular Adaptation of Sugarcane under Drought vis-a-vis Root System Traits

Dhansu¹,

Raja²,

Vengavasi³

et al. 2022

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Among various abiotic stresses, water is reported as a rare entity in many parts of the world. Decreased frequency of precipitation and global temperature rise will further aggravate the situation in future. Being C4 plant, sugarcane requires generous water for the proper growth. Plant root system primarily supports above-ground growth by anchoring in the soil and facilitates water and nutrients uptake from the soil. The plasticity and dynamic nature of roots endow plants for the uptake of vital nutrients from the soil even under soil moisture conditions. In sugarcane, the major part of root system are generally observed in the upper soil layers, while limited water availability shifts the root growth towards the lower soil layer to sustained water uptake. In addition, root traits are directly related to physiological traits of the shoot to cope up with water limited situations via reduction in stomatal conductance and an upsurge in density and deep root traits, adaptations at biochemical and molecular level which includes osmotic adjustment and ROS detoxification. Under stressed conditions, these complex interactive systems adjust homeo-statically to minimize the adverse impacts of stress and sustain balanced metabolism. Therefore, the present chapter deals with physiological and biochemical traits along with root traits that helps for better productivity of sugarcane under water-limited conditions.

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Adhini S. Pazhany

Nuclear and cytoplasmic contributions from Erianthus arundinaceus (Retz.) Jeswiet in a sugarcane hybrid clone confirmed through genomic in situ hybridization and cytoplasmic DNA polymorphism

Genetic Modification of Biomass to Alter Lignin Content and Structure

Physiological and Molecular Adaptation of Sugarcane under Drought vis-a-vis Root System Traits

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