The phyllosphere, encompassing the aerial surfaces of plants, represents one of the largest microbial habitats on Earth and plays a pivotal yet underutilized role in sustainable agriculture and environmental health. Colonized by diverse bacterial, fungal, and yeast communities, the phyllosphere microbiome significantly influences plant growth, disease resistance, nutrient dynamics, and abiotic stress tolerance. These microorganisms engage in complex interactions with host plants, often functioning as biofertilizers, biopesticides, and stress protectants by producing phytohormones, antimicrobial metabolites, and stress-responsive compounds. Importantly, phyllospheric microbes also contribute to atmospheric and ecological balance by participating in carbon and nitrogen cycling, degrading volatile organic compounds (VOCs), and mitigating air pollution. However, despite their immense potential, the practical application of phyllospheric microbes remains limited by challenges such as environmental instability, poor field persistence, and incomplete functional characterization. The highly variable microclimate of the leaf surface poses survival barriers to both native and introduced microbial inoculants. Moreover, the specificity of plant-microbe associations and the complexity of microbial interactions necessitate precision-based approaches for successful deployment. Recent advances in omics technologies, microbial consortia engineering, and nano-enabled delivery systems provide new opportunities to overcome these limitations. A deeper understanding of phyllosphere microbial ecology, combined with innovations in synthetic biology and ecological modeling, can facilitate the development of robust microbial tools tailored to specific crops and climates. Harnessing the potential of phyllospheric microorganisms is not merely an academic pursuit, it is a strategic imperative for transitioning toward climate-resilient, low-input, and ecologically sound agricultural systems.
Keywords: Biotechnological applications; Diversity; Microorganism; Phyllosphere; SDSs goals.
© 2026. The Author(s), under exclusive licence to Springer Nature B.V.