Drought affects aquaporins gene expression in important pulse legume chickpea (Cicer arietinum L.)

Azeem, Farrukh; Ahmed, Bilal; Atif, Rana Muhammad; Ali, Muhammad Amjad; Nadeem, Habibullah; Hussain, Sabir; Rasool, Sumaira; Manzoor, Hamid; Ahmad, Usama; Afzal, Muhammad

doi:10.30848/pjb2019-1(30)

Cited by 13 publications

(8 citation statements)

References 44 publications

(51 reference statements)

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“…These gene families have been identified in other legume crops, such as groundnut (Shivaraj et al, 2019). In a subsequent study, RT-PCR based expression analysis revealed that the PIP2; 2 and NIP6; 3 genes expressed in roots increase drought tolerance in chickpea, while contrary role has been observed for other genes SIP1; 1 and PIP2; 3 as their expression increased the sensitivity to drought (Azeem et al, 2019).…”

Section: Transcriptomics and Elucidation Of Network Genes Controlling Root Traitsmentioning

confidence: 94%

“…These gene families have been identified in other legume crops, such as groundnut (Shivaraj et al, 2019). In a subsequent study, RT‐PCR based expression analysis revealed that the PIP2; 2 and NIP6; 3 genes expressed in roots increase drought tolerance in chickpea, while contrary role has been observed for other genes SIP1; 1 and PIP2; 3 as their expression increased the sensitivity to drought (Azeem et al, 2019). Similarly, candidate genes associated with different functional groups, including molecular, cellular, and biological processes, expressed under drought conditions have been identified in lentil through transcriptome analysis (Singh et al, 2017).…”

Section: Root Characteristics For Improving Water Productivitymentioning

confidence: 96%

“…Next‐generation sequencing‐based transcriptome analysis has identified ESTs, candidate genes, and metabolic pathways expressed in the roots of many food legumes under drought conditions (Azeem et al, 2019; Bhaskarla et al, 2020; Singh et al, 2017). However, further investigation is needed to validate the function of these genes and establish how to incorporate these genes in breeding programs to manipulate root architecture or improve water use efficiency.…”

Section: Future Perspectivesmentioning

confidence: 99%

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Root‐omics for drought tolerance in cool‐season grain legumes

Kumar

Gupta

Djalović

et al. 2020

Physiologia Plantarum

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Root traits can be exploited to increase the physiological efficiency of crop water use under drought. Root length, root hairs, root branching, root diameter, and root proliferation rate are genetically defined traits that can help to improve the water productivity potential of crops. Recently, high-throughput phenotyping techniques/ platforms have been used to screen the germplasm of major cool-season grain legumes for root traits and their impact on different physiological processes, including nutrient uptake and yield potential. Advances in omics approaches have led to the dissection of genomic, proteomic, and metabolomic structures of these traits. This knowledge facilitates breeders to improve the water productivity and nutrient uptake of cultivars under limited soil moisture conditions in major cool-season grain legumes that usually face terminal drought. This review discusses the advances in root traits and their potential for developing drought-tolerant cultivars in cool-season grain legumes. | INTRODUCTIONRoot system architecture (RSA) involves in situ spatial distribution of roots within the rooting volume (Hinsinger et al., 2011;Lynch, 1995Lynch, , 2007Manschadi et al., 2013). Roots are important for plant survival and growth because they enable the exploration of soil zones and acquisition of soil water and nutrients (Gregory et al., 2009;Hammond et al., 2009;Lynch & Brown, 2012). Besides the mechanical support to plants, these also serve as active sites of food storage and interactions with pathogenic as well as beneficial organisms in the rhizosphere. The plastic and dynamic nature of roots allow plants to take up important soil resources under various soil moisture conditions and thus respond to corresponding environments (Zhu et al., 2011). There is a need to explore such root traits that efficiently facilitate the uptake of water and nutrients from soils for higher productivity under water-limited situations (Wasson et al., 2012). However, plant breeders are not generally interested in selecting for root traits due to the complex phenotyping protocols, low heritability, and variable expression depending on soil type and rainfall pattern (Malamy, 2005;Tuberosa, Salvi, et al., 2002a). Plant breeders often assume that direct selection for yield will indirectly select varieties with the optimum root system for achieving increased yields (Wasson et al., 2012).However, there is evidence that a more direct selection for RSA traits can help to develop water-efficient genotypes with improved desirable agronomic and physiological traits leading to enhanced biomass, yield, drought resistance, and tolerance to nutrient deficiencies in dry regions (Chen et al., 2018). For example, wheat genotypes with a deeper and denser root system are able to capture more soil water and nitrogen leading to increased duration of green leaf area and yield (Lilley & Kirkegaard, 2011;Manschadi et al., 2006). Therefore, root traits have become important for developing genetically improved genotypes for rainfed cropping systems. ...

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Section: Transcriptomics and Elucidation Of Network Genes Controlling Root Traitsmentioning

confidence: 94%

Section: Root Characteristics For Improving Water Productivitymentioning

confidence: 96%

Section: Future Perspectivesmentioning

confidence: 99%

See 1 more Smart Citation

Root‐omics for drought tolerance in cool‐season grain legumes

Kumar

Gupta

Djalović

et al. 2020

Physiologia Plantarum

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“…The prime limiting factors for realizing the higher yield of this crop can be attributed to lack of genetic variability, indeterminate growth habit, canopy architecture, poor harvest index, cultivation in marginal lands and susceptibility to pests and diseases (Azeem et. al., 2019).…”

Section: Introductionmentioning

confidence: 99%

Assessment of mutagenic sensitivity in blackgram variety CO 6

Tamilzharasi

Kumaresan²,

Venkatesan³

et al. 2021

EJPB

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The present study was conducted to examine the mutagenic effect of 60 Co gamma rays and a combination of 60 Co gamma rays with EMS in blackgram variety CO 6. Based on the LD 50 dose, the seeds were treated with three different doses of gamma rays (200, 300, 400 Gy) and recurrent doses of 20 mM and 30 mM EMS were treated with gamma ray irradiated seeds for combination treatments. The M 1 generation was evaluated in the field for the following parameters viz., germination percentage, plant survival percentage, plant height at 30 DAS and maturity, pollen fertility and seed fertility. A dose-dependent decrease was noticed for all the characters under this study in M 1 generation. Overall, the maximum reduction was noticed at a higher dose of 400 Gy gamma rays and 400 Gy + 30 mM EMS mutagenic treatments. Among the mutagenic treatments, a combination of 60 Co gamma ray + EMS exhibited the maximum effect with a higher percentage of reduction in all the traits while increased pollen sterility was found to be associated with a corresponding increase in dose/concentration of mutagenic agents. A significant positive correlation was observed between viable mutation frequency and biological damage caused by mutagens in M 1 generation. Hence, the higher doses of 60 Co gamma rays (300 and 400 Gy) and 60 Co gamma rays +EMS (300 Gy+ 30; 400 Gy+ 20 and 400 Gy+ 30 mM) proved to be efficient in increasing the mutation frequency towards desirable directions.

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“…A KUP member in plants was first identified in Arabidopsis (Quintero and Blatt, 1997). Since then, many KUP members have been reported in various flowering plants, such as Oryza sativa (Gupta et al, 2008), Zea mays (Zhang et al, 2012), Triticum aestivum (Cheng et al, 2018), Solanum lycopersicum (Hyun et al, 2014), Populus trichocarpa (He et al, 2012), Prunus persica (Song et al, 2015), Cicer arietinum (Azeem et al, 2018), Nicotiana tabacum (Song et al, 2019), and Manihot esculenta (Ou et al, 2018). Some KUP genes have been reported in cotton (Wang et al, 2018;Wang Y. et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Molecular Evolution and Expansion of the KUP Family in the Allopolyploid Cotton Species Gossypium hirsutum and Gossypium barbadense

et al. 2020

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The comprehensive analysis of gene family evolution will elucidate the origin and evolution of gene families. The K+ uptake (KUP) gene family plays important roles in K+ uptake and transport, plant growth and development, and abiotic stress responses. However, the current understanding of the KUP family in cotton is limited. In this study, 51 and 53 KUPs were identified in Gossypium barbadense and Gossypium hirsutum , respectively. These KUPs were divided into five KUP subfamilies, with subfamily 2 containing three groups. Different subfamilies had different member numbers, conserved motifs, gene structures, regulatory elements, and gene expansion and loss rates. A paleohexaploidization event caused the expansion of GhKUP and GbKUP in cotton, and duplication events in G. hirsutum and G. barbadense have happened in a common ancestor of Gossypium . Meanwhile, the KUP members of the two allopolyploid subgenomes of G. hirsutum and G. barbadense exhibited unequal gene proportions, gene structural diversity, uneven chromosomal distributions, asymmetric expansion rates, and biased gene loss rates. In addition, the KUP families of G. hirsutum and G. barbadense displayed evolutionary conservation and divergence. Taken together, these results illustrated the molecular evolution and expansion of the KUP family in allopolyploid cotton species.

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Drought affects aquaporins gene expression in important pulse legume chickpea (Cicer arietinum L.)

Cited by 13 publications

References 44 publications

Root‐omics for drought tolerance in cool‐season grain legumes

Root‐omics for drought tolerance in cool‐season grain legumes

Assessment of mutagenic sensitivity in blackgram variety CO 6

Molecular Evolution and Expansion of the KUP Family in the Allopolyploid Cotton Species Gossypium hirsutum and Gossypium barbadense

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