Yang Lujia, Li Lili, Song Yingying, Zhang Yongsheng, Yang Jie, Cui Hongying, Guo Wenxiu, Lv Suhong, Men Xingyuan
Shandong Key Laboratory for Green Prevention and Control of Agricultural Pests, Institute of Plant Protection, Shandong Academy of Agricultural Science, Jinan, China.
College of Plant Protection, Hunan Agricultural University, Changsha, China.
Front Plant Sci. 2025 May 23;16:1554915. doi: 10.3389/fpls.2025.1554915. eCollection 2025.
Southern corn rust (SCR), caused by , is a major foliar disease that threatens global maize production. Current SCR management strategies prioritize genetic resistance and chemical control, but how foliar endophytic fungal communities modulate host susceptibility to remains poorly understood. In this study, we profiled the endophytic communities in -infected and non-infected maize leaves across 14 geographically distinct regions in eastern China. Our results revealed that infection significantly altered the foliar endophytic community, with infected leaves exhibiting higher operational taxonomic unit (OTU) richness (722 vs. 572 OTUs) while reducing community evenness. Diversity metrics were significantly altered, with significant reductions in Shannon diversity and Chao1 index values for non-infected states. Network analysis revealed that infection caused a notable reduction in microbial connectivity and complexity, particularly in low- and medium-susceptibility regions, where positive intertaxon associations declined by 42.6% and 35.3%, respectively. High-susceptibility region networks retained greater stability, suggesting differential microbial resilience under pathogen pressure. Redundancy analysis further demonstrated that temperature was the dominant environmental factor shaping microbial assemblages, especially under infection conditions. Notably, correlation analysis further revealed that was positively associated with host resistance ( = 0.37, = 0.05), underscoring its potential role in enhancing resistance to . Conversely, and were negatively correlated with resistance ( = -0.36, = 0.056; and = -0.34, = 0.074, respectively), implying potential roles in facilitating infection. This study reveals key mechanistic links between foliar endophytic communities and SCR infection, providing a basis for sustainable biocontrol interventions in maize.
南方玉米锈病(SCR)由[病原体名称未给出]引起,是一种威胁全球玉米生产的主要叶部病害。当前的SCR管理策略优先考虑遗传抗性和化学防治,但叶内生真菌群落如何调节宿主对[病原体名称未给出]的易感性仍知之甚少。在本研究中,我们分析了中国东部14个地理上不同区域的感染和未感染玉米叶片中的内生群落。我们的结果表明,[病原体名称未给出]感染显著改变了叶内生群落,感染叶片表现出更高的操作分类单元(OTU)丰富度(722个OTU对572个OTU),同时降低了群落均匀度。多样性指标发生了显著变化,未感染状态下的香农多样性和Chao1指数值显著降低。网络分析表明,感染导致微生物连通性和复杂性显著降低,特别是在低敏感性和中等敏感性区域,其中分类群间的正相关分别下降了42.6%和35.3%。高敏感性区域网络保持了更大的稳定性,表明在病原体压力下微生物的恢复力存在差异。冗余分析进一步表明,温度是塑造微生物群落的主要环境因素,尤其是在感染条件下。值得注意的是,相关性分析进一步表明,[某内生真菌物种名称未给出]与宿主抗性呈正相关(r = 0.37,P = 0.05),强调了其在增强对[病原体名称未给出]抗性方面的潜在作用。相反,[另外两种内生真菌物种名称未给出]与抗性呈负相关(分别为r = -0.36,P = 0.056;r = -0.34,P = 0.074),这意味着它们在促进感染方面的潜在作用。本研究揭示了叶内生群落与SCR感染之间的关键机制联系,为玉米的可持续生物防治干预提供了依据。
