Your search keyword '"Asfa B"' showing total 7 results

1. Root-to-shoot signaling positively mediates source-sink relation in late growth stages in diploid and tetraploid wheat

Author

Asfa Batool, Shi-Sheng Li, Dong-Xia Yue, Fazal Ullah, Ling Zhao, Zheng-Guo Cheng, Chao Wang, Hai-Xia Duan, Guang-Chao Lv, Zeeshan ul Haq, Khalil Ahmed, Yan-Wen Gui, Li Zhu, Yun-Li Xiao, and You-Cai Xiong

Subjects

Abscisic acid, Non-hydraulic signaling, Source-sink relations, Cytokinin, Primitive wheat, Yield formation, Botany, QK1-989

Abstract

Abstract Non-hydraulic root source signaling (nHRS) is a unique positive response to soil drying in the regulation of plant growth and development. However, it is unclear how the nHRS mediates the tradeoff between source and sink at the late growth stages and its adaptive mechanisms in primitive wheat. To address this issue, a root-splitting design was made by inserting solid partition in the middle of the pot culture to induce the occurrence of nHRS using four wheat cultivars (MO1 and MO4, diploid; DM22 and DM31, tetraploid) as materials. Three water treatments were designed as 1) both halves watered (CK), 2) holistic root system watered then droughted (FS), 3) one-half of the root system watered and half droughted (PS). FS and PS were designed to compare the role of the full root system and split root system to induce nHRS. Leaves samples were collected during booting and anthesis to compare the role of nHRS at both growth stages. The data indicated that under PS treatment, ABA concentration was significantly higher than FS and CK, demonstrating the induction of nHRS in split root design and nHRS decreased cytokinin (ZR) levels, particularly in the PS treatment. Soluble sugar and proline accumulation were higher in the anthesis stage as compared to the booting stage. POD activity was higher at anthesis, while CAT was higher at the booting stage. Increased ABA (nHRS) correlated with source-sink relationships and metabolic rate (i.e., leaf) connecting other stress signals. Biomass density showed superior resource acquisition and utilization capabilities in both FS and PS treatment as compared to CK in all plants. Our findings indicate that nHRS-induced alterations in phytohormones and their effect on source-sink relations were allied with the growth stages in primitive wheat.

Published

2024

2. Plant facilitation shifts along with soil moisture and phosphorus gradients via rhizosphere interaction in the maize-grass pea intercropping system

Author

Shuang-Guo Zhu, Zheng-Guo Cheng, Asfa Batool, Yi-Bo Wang, Jing Wang, Rui Zhou, Aziz Khan, Sai-Yong Zhu, Yu-Miao Yang, Wei Wang, Hao Zhu, Bao-Zhong Wang, Hong-Yan Tao, and You-Cai Xiong

Subjects

Competition, Biodiversity, Productivity, Environmental gradients, Phosphatase, Ecology, QH540-549.5

Abstract

Plant-plant facilitation is widely studied to increase productivity and resource utilization in cereal-legume intercropping system. However, physiological and ecological mechanisms driving interspecific interaction shift along the environmental gradients is largely unknown. To clarify this issue, we first tested plant-plant facilitation along with four phosphorus (P) gradients in maize-grass pea intercropping system. Results illustrated a progressive transition of seed yield-based facilitation from mutually facilitated (+/+) to maize facilitated but grass pea as facilitator (+/-) along with low to high P gradients. Secondly, above trend was evidently enhanced when combining with drought stress gradients, in which severe drought amplified facilitative effects, whereas the magnitude of facilitation was relatively weak under well-watered condition. Interestingly, biomass-based facilitation transition did not synchronize with seed-based one, in which occurred in a broader threshold range of water and P gradients. Specifically, total yield, biomass, N and P uptake increased by 0.5%, 4.1%, 1.8% and 2.9% under the sufficient P and water availability, whereas these indicators increased by 25.3%, 18.5%, 20.5% and 21.4% in P and water deficient soils. And the total net effect was positive under all the environmental conditions. Rhizosphere interaction plays a crucial role in facilitation judgment, and the driving mechanism was associated with soil acidification and microbial community promotion under P-deficient condition. Under low soil moisture and available P, soil acidification and lower rhizosphere soil pH of intercropped maize were observed. Rhizosphere phosphatase secretion were significantly activated in P-deficient soils and accelerated the mineralization of soil organophosphorus, and the microbial biomass P was improved for stronger facilitation. Taken together, our findings confirmed the P and water driven facilitation shift along with stress gradients and highlighted the roles of rhizosphere interaction in affecting species diversity advantage. In conclusion, our work provided a relatively full picture for plant facilitation evaluation and more accurate management regarding intercropping productivity.

Published

2022

3. Partial and full root-zone drought stresses account for differentiate root-sourced signal and yield formation in primitive wheat

Author

Asfa Batool, Zheng-Guo Cheng, Nudrat Aisha Akram, Guang-Chao Lv, Jun-Lan Xiong, Ying Zhu, Muhammad Ashraf, and You-Cai Xiong

Subjects

Abscisic acid, Drought, Partial root-zone stress, Yield formation, Water use efficiency, Plant culture, SB1-1110, Biology (General), QH301-705.5

Abstract

Abstract Background Partial and full root-zone drought stresses are two widely used methods to induce soil drying in plant container-culture experiments. Two methods might lead to different observational results in plant water relation, such as non-hydraulic root-sourced signal (nHRS). We compared partial and full stress methods to induce nHRS in two diploids (MO1 and MO4) and two tetraploids (DM 22 and DM 31) wheat varieties under pot-culture conditions. Partial root-zone stress (PS) was performed using split-root alternative water supply method (one half wetting and the other drying) to induce the continuous operation of nHRS, and full root-zone stress (FS) was exposed to whole soil block to induce periodic operation of nHRS since jointing stage. Results We tested the two drought methods whether it influenced the nHRS mediated signalling and yield formation in primitive wheat species. Results showed that partial root-zone stress caused more increase in abscisic acid (ABA) production and decline in stomatal closure than full root-zone stress method. The incline in ABA was closely related to triggering reactive oxygen species (ROS) generation, and reducing cytokinin synthesis which, thereby, led to crosstalk with other signalling molecules. Furthermore, PS up-regulated the antioxidant defense system and proline content. Water use efficiency and harvest index was significantly increased in PS, suggesting that PS was more likely to simulate the occurrence of nHRS by increasing the adaptive strategies of plants and closer to natural status of soil drying than FS. Conclusion These findings lead us to conclude that partial root-zone stress method is more feasible method to induce nHRS which has great capacity to reduce water consumption and enhance plant adaptation to constantly changing environment. These observations also suggest that different root-zone planting methods can be considered to improve the plant phenotypic plasticity and tolerance in water-limited rainfed environments.

Published

2019

4. Mechanistic Insights into Arbuscular Mycorrhizal Fungi-Mediated Drought Stress Tolerance in Plants

Author

Ali Bahadur, Asfa Batool, Fahad Nasir, Shengjin Jiang, Qin Mingsen, Qi Zhang, Jianbin Pan, Yongjun Liu, and Huyuan Feng

Subjects

arbuscular mycorrhizal fungi, drought tolerance mechanisms, phytohormones, biochemical responses, aquaporins, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Arbuscular mycorrhizal fungi (AMF) establish symbiotic interaction with 80% of known land plants. It has a pronounced impact on plant growth, water absorption, mineral nutrition, and protection from abiotic stresses. Plants are very dynamic systems having great adaptability under continuously changing drying conditions. In this regard, the function of AMF as a biological tool for improving plant drought stress tolerance and phenotypic plasticity, in terms of establishing mutualistic associations, seems an innovative approach towards sustainable agriculture. However, a better understanding of these complex interconnected signaling pathways and AMF-mediated mechanisms that regulate the drought tolerance in plants will enhance its potential application as an innovative approach in environmentally friendly agriculture. This paper reviews the underlying mechanisms that are confidently linked with plant−AMF interaction in alleviating drought stress, constructing emphasis on phytohormones and signaling molecules and their interaction with biochemical, and physiological processes to maintain the homeostasis of nutrient and water cycling and plant growth performance. Likewise, the paper will analyze how the AMF symbiosis helps the plant to overcome the deleterious effects of stress is also evaluated. Finally, we review how interactions between various signaling mechanisms governed by AMF symbiosis modulate different physiological responses to improve drought tolerance. Understanding the AMF-mediated mechanisms that are important for regulating the establishment of the mycorrhizal association and the plant protective responses towards unfavorable conditions will open new approaches to exploit AMF as a bioprotective tool against drought.

Published

2019

5. Rainwater resource utilization and ecosystem sustainability in arid agricultural areas: A review on 2013 international workshop on arid agriculture and ecosystem sustainability

Author

Wang, H. -L, Tian, T., Wang, J. -Y, Asfa, B., Zhao, X. -Z, Mo, F., Nudrat, A. A., and You-Cai Xiong

6. Dryland wheat domestication changed the development of aboveground architecture for a well-structured canopy.

Author

Pu-Fang Li, Zheng-Guo Cheng, Bao-Luo Ma, Jairo A Palta, Hai-Yan Kong, Fei Mo, Jian-Yong Wang, Ying Zhu, Guang-Chao Lv, Asfa Batool, Xue Bai, Feng-Min Li, and You-Cai Xiong

Subjects

Medicine, Science

Abstract

We examined three different-ploidy wheat species to elucidate the development of aboveground architecture and its domesticated mechanism under environment-controlled field conditions. Architecture parameters including leaf, stem, spike and canopy morphology were measured together with biomass allocation, leaf net photosynthetic rate and instantaneous water use efficiency (WUE(i)). Canopy biomass density was decreased from diploid to tetraploid wheat, but increased to maximum in hexaploid wheat. Population yield in hexaploid wheat was higher than in diploid wheat, but the population fitness and individual competition ability was higher in diploid wheats. Plant architecture was modified from a compact type in diploid wheats to an incompact type in tetraploid wheats, and then to a more compact type of hexaploid wheats. Biomass accumulation, population yield, harvest index and the seed to leaf ratio increased from diploid to tetraploid and hexaploid, associated with heavier specific internode weight and greater canopy biomass density in hexaploid and tetraploid than in diploid wheat. Leaf photosynthetic rate and WUEi were decreased from diploid to tetraploid and increased from tetraploid to hexaploid due to more compact leaf type in hexaploid and diploid than in tetraploid. Grain yield formation and WUEi were closely associated with spatial stance of leaves and stems. We conclude that the ideotype of dryland wheats could be based on spatial reconstruction of leaf type and further exertion of leaf photosynthetic rate.

Published

2014

7. [Growth plasticity and yield formation in dryland wheat (Triticum aestivum) under artificial selection].

Author

Liu YX, Wang JY, Cheng ZG, Asfa B, Zhu Y, Chen YL, Wang J, and Xiong YC

Subjects

Biomass, Water, Adaptation, Physiological, Photosynthesis, Triticum growth & development

Abstract

Dryland wheat has gone through double selections, including natural and artificial selection, in the evolutionary process. During this process, artificial selection played a key role in variety domestication and improvement. This paper summarized a few relatively independent but interrelated issues including evolutionary characteristics, physiological plasticity, morphological plasticity and population attribute transition in dryland wheat under artificial selection. It provided an overview on physiological and ecological mechanism of dryland wheat adapting to stress conditions, and an outline of wheat evolution route. In the long-term evolutionary history of dryland wheat from diploid to hexaploid, natural selection acted as a key role for wheat adaptation to stress environments. With the intervention of artificial selection, the yield-oriented phenotyping has been continuously strengthened, and morphological characteristics of wheat tended to display a fine adaptation to adverse environments at population level. As a product of artificial selection, water and nutrient use efficiencies were improved constantly, and biomass allocation pattern showed the characteristics of lowering below-ground parts and increasing above-ground parts. In the meantime, the tolerance to density and high temperature stresses tended to be enhanced, while photosynthetic rate per unit area was decreased gradually. Dryland wheat production was a complex population process, rather than a simple individual performance. Artificial selection increased population fitness and individual reproductive allocation in dryland wheat, which in turn strengthened its coordination with environment, but weakened its attributes of natural population. This paper also drew an outline of dryland wheat evolution, and provided a few suggestions for breeding strategies and cultivation management of dryland wheat under climate change.

Published

2017