Root exudates drive interspecific facilitation by enhancing nodulation and N
            <sub>2</sub>
            fixation

Li, Bai; Li, Yuying; Wu, Huamao; Zhang, Fang-Fang; Li, Chunjie; Li, Xuexian; Lambers, Hans; Li, Long

doi:10.1073/pnas.1523580113

Cited by 316 publications

(216 citation statements)

References 42 publications

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“…intercropping systems (Li et al 2007(Li et al , 2014. Positive plant-plant interactions, such as root-root facilitation, have been shown to play a significant role for P acquisition (Li et al 2007;Brooker et al 2015;Li et al 2016;Zhang et al 2016). Tang et al (2016) further demonstrated the greater performance of such intercropping systems compared to single crop systems under field conditions along a P fertility gradient.…”

Section: Nutrient Acquisition and Nutrient Cyclingmentioning

confidence: 97%

“…Through their nutritive effects, exudates will affect the structure of soil microbial communities, favoring cell division of bacteria able to catabolize them. Though microbe-plant chemical dialogues are well-known in the case of symbiotic interactions between legumes and nitrogen-fixing rhizobia (Limpens et al 2015;Li et al 2016) or in plant mycorrhiza (Parniske 2008), these are less well characterized in plant-PGPR interactions.…”

Section: Communication In the Rhizospherementioning

confidence: 99%

“…However, this is not a unidirectional path as the root microbiome also produces many metabolites and thus also able to affect the composition of the chemical cocktail in the rhizosphere.. These mutual interactions ultimately affect nutrient availability for all partners (Lambers et al 2008), plant health (Berendsen et al 2012) and root-root interactions (Semchenko et al 2014), cascading into ecosystem functions such as productivity (Latz et al 2012;Li et al 2016) and soil formation (Lambers et al 2009;Keiluweit et al 2015;Lange et al 2015). The challenge now is to reveal the functionality of these multifacetted interactions between plant roots, root exudates, microbial metabolites, the root microbiome and the soil..Management of this multicomponent complexity of the rhizosphere and its relationship to soil fertility will become crucial in order to maintain food production with reduced fertiliser and pesticide inputs .…”

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confidence: 99%

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Advances in the rhizosphere: stretching the interface of life

et al. 2016

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Section: Nutrient Acquisition and Nutrient Cyclingmentioning

confidence: 97%

Section: Communication In the Rhizospherementioning

confidence: 99%

mentioning

confidence: 99%

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Advances in the rhizosphere: stretching the interface of life

et al. 2016

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“…These genes play a critical role in different biological processes associated with NUE such as uptake, assimilation, and utilization efficiency (Han et al, 2016). Early nodulation 93 (ENOD93) gene play a significant role in cell wall reorganization during nodulation in legumes (Li et al, 2016). ENOD93 is an active member of early nodulin-like proteins family.…”

Section: Introductionmentioning

confidence: 99%

“…Overexpression of OsENOD93-1 in transgenic rice plant increased the shoot dry biomass and seed yield. Li et al, (2016) suggested that ENOD93 gene showed up-regulation and promoted nitrogen fixation in faba beans. Despite the critical interplay of ENOD93-1 gene in N regulation, no efforts were made in past to identify ENOD93-1 gene in wheat.…”

Section: Introductionmentioning

confidence: 99%

Identification and Functional Characterization an Ortholog of OsENOD93-1 Gene in Wheat Using in-silico Approach

Kumar¹,

Kumar²,

Tyagi³

et al. 2018

Int.J.Curr.Microbiol.App.Sci

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Nitrogen is an essential macromolecule necessary for suitable growth and development of plants by playing a vital role in biochemical and physiological functions throughout the life cycle. Early node 93 (ENOD93-1) gene is well known for significantly responding to both N induction and N reduction in plants, but little is known about the structure and function of the ENOD93-1 protein in cereal crops. In this study, a putative ortholog of rice OsENOD93-1 gene was identified in the wheat genome. BLASTP analysis showed the OsENOD93-1 shared the 80% similarity with wheat TRIAE_CS42_4AL_TGACv1_ 288261_AA0942630.1 scaffold. Present study describes the location of TaENOD93-1 gene on4AL chromosome of wheat. MicroRNA target analysis revealed that TaENOD93-1 gene targeting by miR6201. Phylogeny tree suggested that identified putative ortholog shared the evolutionary relationship with monocots. The three dimensional structure of TaENOD93-1 protein was predicted using computer-aided molecular modeling technique followed by structure evaluation using Ramachandran plot. The primary goal of this study was to mapping the chromosomal location and functional annotation of TaENOD93-1 gene in wheat using bioinformatics approach. The identification of putative ortholog of OsENOD93-1 gene in wheat has opened up new opportunities to improve the nitrogen use efficiency (NUE) in wheat through molecular breeding approach. K e y w o r d s

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Stability of grassland soil C and N pools despite 25 years of an extreme climatic and disturbance regime

2016

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Global changes are altering many important drivers of ecosystem functioning, with precipitation amount and disturbance frequency being especially important. Carbon (C) and nitrogen (N) pools are key contemporary attributes of ecosystems that can also influence future C uptake via plant growth. Thus, understanding the impacts of altered precipitation amounts (through controls of primary production inputs) and disturbance regimes (through losses of C and N in biomass) is important to project how ecosystem services will respond to future global changes. A major difficulty inherent within this task is that drivers of ecosystem function and processes often interact, resulting in novel ecosystem responses. To examine how changes in precipitation affect grassland ecosystem responses under a frequent disturbance regime (annual fire), we assessed the biogeochemical and ecological consequences of more than two decades of irrigation in an annually burned mesic grassland in the central United States. In this experiment, precipitation amount was increased by 31% relative to ambient and 1 in 3 years were statistically extreme relative to the long‐term historical record. Despite evidence that irrigation decreased root:shoot ratios and increased rates of N cycling—each expected to reduce soil C and N with annual burning—we detected no changes in these biogeochemical pools. This surprising biogeochemical resistance highlights the need to explore additional mechanisms within long‐term experiments concerning the consequences of global change impacts on ecosystems.

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Root exudates drive interspecific facilitation by enhancing nodulation and N ₂ fixation

Cited by 316 publications

References 42 publications

Advances in the rhizosphere: stretching the interface of life

Advances in the rhizosphere: stretching the interface of life

Identification and Functional Characterization an Ortholog of OsENOD93-1 Gene in Wheat Using in-silico Approach

Stability of grassland soil C and N pools despite 25 years of an extreme climatic and disturbance regime

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Root exudates drive interspecific facilitation by enhancing nodulation and N 2 fixation

Cited by 316 publications

References 42 publications

Advances in the rhizosphere: stretching the interface of life

Advances in the rhizosphere: stretching the interface of life

Identification and Functional Characterization an Ortholog of OsENOD93-1 Gene in Wheat Using in-silico Approach

Stability of grassland soil C and N pools despite 25 years of an extreme climatic and disturbance regime

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Root exudates drive interspecific facilitation by enhancing nodulation and N ₂ fixation