Detailed Colocalization Analysis of A- and B-type Nuclear Lamins: a Workflow Using Super-Resolution STED Microscopy and Deconvolution

Merel Stiekema, Owen N. Gibson, Rogier J.A. Veltrop, Frans C.S. Ramaekers, Jos L.V. Broers, Marc A.M.J. van Zandvoort
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Abstract

The inner nuclear membrane is covered by a filamentous network, the nuclear lamina, consisting of A- and B-type lamins as its major components. The A- and B-type lamins form independent but interacting and partially overlapping networks, as demonstrated by previous super-resolution studies. The nuclear lamina in fibroblast cultures derived from laminopathy patients shows an increased segregation of the A- and B-type lamin networks, which can be quantitatively expressed by the Pearson's Correlation Coefficient (PCC). Blurring and noise (convolution), however, significantly affect the quality of microscopy images, which led us to optimize the deconvolution approach for Confocal Scanning Laser Microscopy (CSLM) and Stimulated Emission Depletion (STED) microscopy images. For that purpose, the differences in using a theoretical, experimental, or semi-experimental Point Spread Function (PSF), an important parameter for deconvolution, was evaluated for its use in deconvolution of CSLM and STED microscopy images of double immunolabeled healthy and laminopathy patient fibroblasts. The semi-experimental is a new PSF introduced in this study, which combines the theoretical and experimental PSF to solve issues that arise from noisy PSF recordings due to very small and thereby low intensity fluorescent beads. From these deconvoluted images, the colocalization of the lamin networks could not only be quantified at the level of the nucleus as a whole, but also at a subnuclear level. The latter was achieved by dividing the nucleus into multiple equal rectangles using a custom-made ImageJ macro in Fiji. In this detailed analysis, we found heterogeneity in the colocalization of lamins A/C and B1 within and between nuclei in both healthy and laminopathy dermal fibroblasts, which cannot be detected in one single analysis for the entire nucleus.
A 型和 B 型核拉明蛋白的详细共定位分析:使用超分辨率 STED 显微镜和解卷积的工作流程
核内膜由一个丝状网络(核薄层)覆盖,核薄层的主要成分是 A 型和 B 型薄层蛋白。先前的超分辨率研究表明,A 型和 B 型薄片蛋白形成独立但相互作用且部分重叠的网络。来自板层病患者的成纤维细胞培养物中的核板层显示出 A 型和 B 型板层蛋白网络的分离增加,这可以用皮尔逊相关系数(PCC)来定量表示。然而,模糊和噪声(卷积)会严重影响显微镜图像的质量,这促使我们对用于共焦扫描激光显微镜(CSLM)和受激发射损耗(STED)显微镜图像的解卷积方法进行优化。为此,我们评估了使用理论、实验或半实验点扩散函数(PSF)(解卷积的一个重要参数)对健康和板层病患者纤维母细胞双重免疫标记的 CSLM 和 STED 显微图像进行解卷积的差异。半实验型 PSF 是本研究中引入的一种新 PSF,它结合了理论 PSF 和实验 PSF,以解决因荧光珠非常小从而强度低而导致的 PSF 记录噪声问题。从这些去卷积图像中,不仅可以量化整个细胞核水平上的层片网络共定位,还可以量化亚核水平上的层片网络共定位。后者是通过在 Fiji 中使用定制的 ImageJ 宏将细胞核划分为多个相等的矩形来实现的。在这一详细分析中,我们发现在健康和板层状真皮成纤维细胞的细胞核内和细胞核间,片段蛋白 A/C和 B1的共定位存在异质性,而这种异质性无法通过对整个细胞核的单一分析检测出来。
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