Application of cryo-FIB-SEM for investigating organelle ultrastructure in guard cells of higher plants

Bastian L Franzisky, Xudong Zhang, Claus Jakob Burkhardt, Endre Majorovits, Eric Hummel, Andreas Schertel, Christoph-Martin Geilfus, Christian Zoerb
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Abstract

Stomata are vital for CO2 and water vapor exchange, with guard cells' aperture and ultrastructure highly responsive to environmental cues. However, traditional methods for studying guard cell ultrastructure, which rely on chemical fixation and embedding, often distort cell morphology and compromise membrane integrity, leaving no suitable methodology until now. In contrast, plunge-freezing in liquid ethane rapidly preserves cells in a near-native vitreous state for cryogenic electron microscopy. Using this approach, we applied Cryo-Focused Ion Beam-Scanning Electron Microscopy (cryo-FIB-SEM) to study the guard cell ultrastructure of Vicia faba, a higher plant model chosen for its sensitivity to external factors and ease of epidermis isolation, advancing beyond previous cryo-FIB-SEM applications in lower plant algae. The results firstly introduced cryo-FIB-SEM volume imaging, enabling subcellular ultrastructure visualization of higher plants like V. faba in a vitrified, unaltered state. 3D models of organelles such as stromules, chloroplast protrusions, chloroplasts, starch granules, mitochondria, and vacuoles were reconstructed from cryo-FIB-SEM volumetric data, with their surface area and volume initially determined using manual segmentation. Future studies using this near-native volume imaging technique hold promise for investigating how environmental factors like drought or salinity influence stomatal behavior and the morphology of guard cells and their organelles.
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应用低温 FIB-SEM 技术研究高等植物防护细胞的细胞器超微结构
气孔对二氧化碳和水蒸气交换至关重要,保卫细胞的孔径和超微结构对环境线索反应灵敏。然而,研究保卫细胞超微结构的传统方法依赖于化学固定和包埋,往往会扭曲细胞形态并破坏膜的完整性,直到现在才找到合适的方法。相比之下,在液态乙烷中急速冷冻可将细胞以接近原生玻璃体的状态保存下来,用于低温电子显微镜观察。利用这种方法,我们应用低温聚焦离子束扫描电子显微镜(cryo-FIB-SEM)研究了蚕豆(Vicia faba)的保卫细胞超微结构。蚕豆是一种高等植物模型,因其对外部因素敏感且表皮易于分离而被选中,这超越了之前低温聚焦离子束扫描电子显微镜在低等植物藻类中的应用。该成果首次引入了冷冻-FIB-SEM 体积成像技术,实现了像蚕豆这样的高等植物在玻璃化、未改变状态下的亚细胞超微结构可视化。根据冷冻-FIB-SEM体积成像数据重建了细胞器的三维模型,如基质、叶绿体突起、叶绿体、淀粉粒、线粒体和液泡,其表面积和体积最初是通过人工分割确定的。利用这种近乎原生的体积成像技术进行的未来研究有望研究干旱或盐度等环境因素如何影响气孔行为以及保卫细胞及其细胞器的形态。
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