South China Agricultural University | China
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Summary
Professor Wang Xiaolin, a leading researcher at south china agricultural university, specializes in plant microbiome studies and ecological restoration. working within the state key laboratory of conservation and utilization of subtropical agricultural bioresources and the lingnan modern agricultural science and technology guangdong provincial laboratory, he has developed pioneering models for rhizosphere microbial community assembly, uncovered co-evolutionary symbiosis mechanisms, and linked microbial imbalances to major crop diseases. his concept of “agricultural precision microbiome” and leadership in the “thousand plant microbiome project” have set new directions for sustainable agriculture. with publications in nature, cell, annual review of plant biology, and other high-impact journals, his research is globally recognized and widely cited.
Early academic pursuits
Professor Wang Xiaolin began his academic journey with a strong focus on agricultural sciences, laying a foundation in soil biology, microbiome research, and ecological restoration. during his formative research years, he built expertise in plant microbiome systems, combining traditional agricultural studies with modern molecular tools. his early work aligned with the goals of south china agricultural university, Microbiome a national "double first-class" construction university, known for its advanced laboratories and interdisciplinary research approach.
Professional endeavors
Over the years, Professor Wang has been a key figure at the state key laboratory of conservation and utilization of subtropical agricultural bioresources and the lingnan modern agricultural science and technology guangdong provincial laboratory. as the backbone of multiple high-impact projects, he has led initiatives in sample collection, database construction, and policy formulation. Microbiome while his main expertise lies in agricultural microbiome systems, he also draws on interdisciplinary knowledge, intersecting with applied technologies that have parallels in advanced fields like power electronics for data acquisition and precision agriculture control systems.
Contributions and research focus
Professor Wang’s major contributions include: establishing the "amplification-selection" assembly model of plant rhizosphere microbial communities. Revealing co-evolutionary mechanisms of arbuscular mycorrhizal symbiosis and nodule symbiosis at the rhizosphere level. Linking bacterial flora imbalance to geminivirus infections, explaining the soybean “green syndrome” mechanism. Pioneering the "agricultural precision microbiome" concept. Leading the "thousand plant microbiome project" and discovering protozoa and fungi as core players in rhizosphere cross-kingdom networks. His research integrates multi-omics linkage technology and precision analysis, much like Microbiome how power electronics integrates complex signals for efficient system operation.
Impact and influence
Professor Wang’s work has been published in prestigious journals such as nature, cell, annual review of plant biology, molecular plant, science bulletin, nature communications, plant biotechnology journal, soil biology and biochemistry, Microbiome, and abiotech. His findings have significantly advanced the understanding of plant–microbe interactions, influencing both fundamental research and practical applications in sustainable agriculture.
Academic cites
With publications in top-tier journals, his work is frequently cited by peers in plant sciences, microbiology, Microbiome and biotechnology. His citation network reflects a global academic influence, and his research outcomes often serve as a reference point for further exploration in precision agriculture and related technologies.
Legacy and future contributions
Professor Wang’s legacy lies in bridging fundamental plant microbiome research with innovative agricultural practices. moving forward, his work is expected to further enhance sustainable crop production, inform agricultural policies, and inspire interdisciplinary collaborations. given his leadership in microbiome studies Microbiome and his alignment with cutting-edge technological methodologies, his future contributions may also intersect more deeply with advanced monitoring systems, potentially adapting methodologies inspired by power electronics to agricultural bioresource management.
Publications
Title: MHZ3: a key regulator of ethylene signaling in rice
Authors: Arif Ali Khattak, Yingshan Huang, Muhammad Afzal, Xiaolin Wang
Journal: aBIOTECH
Publication Date: December 6, 2024
Title: Decoding the microbiome for sustainable agriculture
Authors: Kai Sun, Wei Zhang, Xiaolin Wang, Chuan-Chao Dai
Journal: aBIOTECH
Publication Date: May 7, 2024
Title: Heterosis of endophytic microbiomes in hybrid rice varieties improves seed germination
Authors: Yuanhui Liu, Kankan Zhao, Erinne Stirling, Xiaolin Wang, Zhenyu Gao, Bin Ma, Chunmei Xu, Song Chen, Guang Chu, Xiufu Zhang et al.
Journal: mSystems
Publication Date: April 9, 2024
Title: Comparative analysis of rhizobial and bacterial communities in experimental cotton fields: Impacts of conventional and conservation soil management in the Texas High Plains
Authors: Amin Jannatul Ferdous, Xiaolin Wang, Katie Lewis, John Zak
Journal: Soil and Tillage Research
Publication Date: February 2024
Title: Dynamic root microbiome sustains soybean productivity under unbalanced fertilization
Authors: Mingxing Wang, An-Hui Ge, Xingzhu Ma, Xiaolin Wang, Qiujin Xie, Like Wang, Xianwei Song, Mengchen Jiang, Weibing Yang, Jeremy D. Murray et al.
Journal: Nature Communications
Publication Date: February 23, 2024
Conclusion
Professor Wang’s career demonstrates a rare blend of deep scientific insight, innovative thinking, and practical impact. his integration of multi-omics technologies with agricultural applications has reshaped how plant–microbe relationships are studied and managed. his ongoing work promises to further influence agricultural sustainability, policy development, and global food security. by linking biological research platforms with advanced analytical frameworks—similar in precision to the systematic control seen in power electronics—he is poised to leave a lasting legacy in both science and applied agricultural technology.