The Potential of Transcription Factor-Based Genetic Engineering in Improving Crop Tolerance to Drought

Rabara, Roel C.; Tripathi, Prateek; Rushton, Paul J.

doi:10.1089/omi.2013.0177

Cited by 87 publications

(55 citation statements)

References 130 publications

(151 reference statements)

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“…Among these sciences are genomics-assisted breeding, other OMICs approaches or systems biology tools for improving crop resiliency for adverse growing environments owing to climate change (Kole et al, 2015, Rabara et al, 2014b, Tripathi et al, 2012. These tools increase the exploitability of rice genetic resources like wild rice species of which desirable traits have been incorporated in modern rice varieties through molecular approaches and tissue culture (Sanchez et al, 2013).…”

Section: Advances In Developing Climate-resilient Ricementioning

confidence: 99%

When water runs dry and temperature heats up: Understanding the mechanisms in rice tolerance to drought and high temperature stress conditions

Rabara¹,

Msanne²,

Ferrer³

et al. 2018

Preprint

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Rice production, owing to its high-water requirement for cultivation, is very vulnerable to the threat of changing climate, particularly prolonged drought and high temperature. Such threats heighten the need for abiotic stress-resilient rice varieties with better yield potential. This review examines the physiological and molecular mechanisms of rice varieties to cope with stress conditions of drought (DS), high temperature (HTS) and their combination (DS-HTS). It appraises research studies in rice about its various phenotypic traits, genetic loci and response mechanisms to stress conditions to help craft new breeding strategies for rice varieties with improved resilience to abiotic stresses. This review consolidates available information on promising rice cultivars with desirable traits as well as advocates synergistic and complementary approaches in molecular and systems biology to develop new rice breeds that favorably respond to climate-induced abiotic stresses. The development of new breeding and cultivation strategies for climate-resilient rice varieties is a challenging task. It requires a comprehensive understanding of the various morphological, biochemical, physiological, and molecular components governing yield under drought and high temperature, but possible by implementing cohesive approaches involving molecular and systems biology approaches in genomics and molecular breeding, including genetic engineering.

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Section: Advances In Developing Climate-resilient Ricementioning

confidence: 99%

When water runs dry and temperature heats up: Understanding the mechanisms in rice tolerance to drought and high temperature stress conditions

Rabara¹,

Msanne²,

Ferrer³

et al. 2018

Preprint

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“…Therefore, TFs are good candidates for systems-based genetic engineering to improve crop tolerance to various abiotic stresses because of their function as master regulators of clusters of genes. Various families of TFs were reported, such as CCAAT, homeodomain, NAC, bHLH, bZIP, AP2/ ERF, and WRKY that have the potential to be tools for improving abiotic stresses tolerance (Gao et al, 2010;Rabara et al, 2014;Shen et al, 2012;Ying et al, 2012;Zhang et al, 2009).…”

Section: Stress Tolerancementioning

confidence: 99%

“…Systems biology approaches define the underlying changes that result in better yields under abiotic stress conditions. These novel technologies help to show whether manipulating TFs can have effects on crop productivity under field conditions (Rabara et al, 2014).…”

Section: Stress Tolerancementioning

confidence: 99%

Systems Biology for Smart Crops and Agricultural Innovation: Filling the Gaps between Genotype and Phenotype for Complex Traits Linked with Robust Agricultural Productivity and Sustainability

Kumar¹,

Pathak²,

Gupta

et al. 2015

OMICS: A Journal of Integrative Biology

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In recent years, rapid developments in several omics platforms and next generation sequencing technology have generated a huge amount of biological data about plants. Systems biology aims to develop and use wellorganized and efficient algorithms, data structure, visualization, and communication tools for the integration of these biological data with the goal of computational modeling and simulation. It studies crop plant systems by systematically perturbing them, checking the gene, protein, and informational pathway responses; integrating these data; and finally, formulating mathematical models that describe the structure of system and its response to individual perturbations. Consequently, systems biology approaches, such as integrative and predictive ones, hold immense potential in understanding of molecular mechanism of agriculturally important complex traits linked to agricultural productivity. This has led to identification of some key genes and proteins involved in networks of pathways involved in input use efficiency, biotic and abiotic stress resistance, photosynthesis efficiency, root, stem and leaf architecture, and nutrient mobilization. The developments in the above fields have made it possible to design smart crops with superior agronomic traits through genetic manipulation of key candidate genes.

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“…Thus, the functions and mechanisms of these biomolecules in the maize stress response must be verified using molecular techniques (e.g., loss-and gain-of function). Major genes that control the response to stresses can be candidates for transforming maize plants to enhance maize stress tolerance (Rabara et al, 2014). Moreover, the interaction network among RNA, DNA, and proteins should be constructed to elucidate the maize stress response.…”

Section: Outlook and Executive Topline Pointsmentioning

confidence: 99%

“Omics” of Maize Stress Response for Sustainable Food Production: Opportunities and Challenges

Gong

Yang

Tai

et al. 2014

OMICS: A Journal of Integrative Biology

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Maize originated in the highlands of Mexico approximately 8700 years ago and is one of the most commonly grown cereal crops worldwide, followed by wheat and rice. Abiotic stresses (primarily drought, salinity, and high and low temperatures), together with biotic stresses (primarily fungi, viruses, and pests), negatively affect maize growth, development, and eventually production. To understand the response of maize to abiotic and biotic stresses and its mechanism of stress tolerance, high-throughput omics approaches have been used in maize stress studies. Integrated omics approaches are crucial for dissecting the temporal and spatial systemlevel changes that occur in maize under various stresses. In this comprehensive analysis, we review the primary types of stresses that threaten sustainable maize production; underscore the recent advances in maize stress omics, especially proteomics; and discuss the opportunities, challenges, and future directions of maize stress omics, with a view to sustainable food production. The knowledge gained from studying maize stress omics is instrumental for improving maize to cope with various stresses and to meet the food demands of the exponentially growing global population. Omics systems science offers actionable potential solutions for sustainable food production, and we present maize as a notable case study.

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The Potential of Transcription Factor-Based Genetic Engineering in Improving Crop Tolerance to Drought

Cited by 87 publications

References 130 publications

<strong>When water runs dry and temperature heats up: </strong><strong>Understanding the mechanisms in rice tolerance to drought and </strong><strong>high temperature stress conditions</strong>

<strong>When water runs dry and temperature heats up: </strong><strong>Understanding the mechanisms in rice tolerance to drought and </strong><strong>high temperature stress conditions</strong>

Systems Biology for Smart Crops and Agricultural Innovation: Filling the Gaps between Genotype and Phenotype for Complex Traits Linked with Robust Agricultural Productivity and Sustainability

“Omics” of Maize Stress Response for Sustainable Food Production: Opportunities and Challenges

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