Physiological responses of plants to in vivo X-ray damage from X-ray fluorescence measurements: insights from anatomical, elemental, histochemical, and ultrastructural analyses.
Gabriel Sgarbiero Montanha, João Paulo Rodrigues Marques, Eduardo Santos, Michael W M Jones, Hudson Wallace Pereira de Carvalho
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引用次数: 2
Abstract
X-ray fluorescence spectroscopy (XRF) is a powerful technique for the in vivo assessment of plant tissues. However, the potential X-ray exposure damages might affect the structure and elemental composition of living plant tissues, leading to artefacts in the recorded data. Herein, we exposed in vivo soybean (Glycine max (L.) Merrill) leaves to several X-ray doses through a polychromatic benchtop microprobe X-ray fluorescence spectrometer, modulating the photon flux density by adjusting either the beam size, current, or exposure time. Changes in the irradiated plant tissues' structure, ultrastructure, and physiology were investigated through light and transmission electron microscopy (TEM). Depending on X-ray exposure dose, decreased K and X-ray scattering intensities and increased Ca, P, and Mn signals on soybean leaves were recorded. Anatomical analysis indicated the necrosis of epidermal and mesophyll cells on the irradiated spots, where TEM images revealed the collapse of cytoplasm and cell wall breaking. Furthermore, the histochemical analysis detected the production of reactive oxygen species and the inhibition of chlorophyll autofluorescence in these areas. Under certain X-ray exposure conditions, e.g. high photon flux density and long exposure time, XRF measurements may affect the soybean leaves structures, elemental composition, and cellular ultrastructure, inducing programmed cell death. Our characterization shed light on the plant's responses to the X-ray-induced radiation damage and might help to establish proper X-ray radiation limits and novel strategies for in vivo benchtop-XRF analysis of vegetal materials.
x射线荧光光谱(XRF)是一种强有力的植物组织体内评价技术。然而,潜在的x射线暴露损伤可能会影响活植物组织的结构和元素组成,导致记录数据中的伪影。在此,我们在体内暴露大豆(Glycine max (L.))通过多色台式微探针x射线荧光光谱仪,通过调整光束大小、电流或曝光时间来调节光子通量密度,从而获得几种x射线剂量。利用透射电镜和光镜观察辐照后植物组织结构、超微结构和生理机能的变化。根据不同的x射线照射剂量,记录到大豆叶片K和x射线散射强度降低,Ca、P和Mn信号增加。解剖分析显示辐照斑的表皮和叶肉细胞坏死,透射电镜显示细胞质塌陷,细胞壁破裂。此外,组织化学分析检测到这些区域活性氧的产生和叶绿素自身荧光的抑制。在一定的x射线照射条件下,如高光子通量密度和长曝光时间,XRF测量可能会影响大豆叶片的结构、元素组成和细胞超微结构,诱发程序性细胞死亡。我们的表征揭示了植物对x射线诱导的辐射损伤的反应,并可能有助于建立适当的x射线辐射限制和植物材料体内台式xrf分析的新策略。