改进乙酰卡明和血苏木精染色方法,以观察丝状绿藻(Charophyta)中的染色体。

Nina Rittmeier, Andreas Holzinger
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摘要

Zygnema 属的基因组大小差异很大,不知道是否发生了多倍体化。由于高等植物的计数方法无法应用于绿藻,因此该属植物染色体的确切数目也不得而知。细胞壁中大量存在的果胶和阿拉伯半乳聚糖蛋白质影响了染色液的吸收;此外,绿藻的细胞分裂不像高等植物那样局限于分生组织,这也是另一个限制因素。由于藻丝的穿插生长,细胞分裂在菌丝体中随机发生。因此,我们通过改变光周期(10:14 小时光照/黑暗)来同步增加细胞分裂的次数。观察到的有丝分裂阶段数量在暗周期开始时达到峰值。本实验介绍了两种观察丝状绿藻 Zygnema 染色体的方法。对现有方案进行了修改,从而改进了乙酰卡明和血色素染色方法,并通过光学显微镜进行了研究。采用液氮冷冻粉碎法提高了血色素染料的可及性。这些改进后的方案可对姬蛙属进行可靠的染色体计数。主要特点 改进了丝状绿藻染色体染色的方法。针对 Zygnema 菌株 SAG 698-1a(Z. cylindricum)、SAG 698-1b(Z. circumcarinatum)和 SAG 2419(Zygnema 'Saalach')进行了优化。该方案借鉴了 Wittmann(1965 年)、Staker(1971 年)以及 Fujii 和 Guerra(1998 年)开发的绿藻染色体染色方法。培养和同步化:培养和同步:14 天;固定和通透:24 小时;染色:1 小时;图像分析和染色体数目定量:最多 20 小时。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Improved Methods for Acetocarmine and Haematoxylin Staining to Visualize Chromosomes in the Filamentous Green Alga Zygnema (Charophyta).

Genome sizes of Zygnema spp. vary greatly, being unknown whether polyploidization occurred. The exact number of chromosomes in this genus is unknown since counting methods established for higher plants cannot be applied to green algae. The massive presence of pectins and arabinogalactan proteins in the cell wall interferes with the uptake of staining solutions; moreover, cell divisions in green algae are not restricted to meristems as in higher plants, which is another limiting factor. Cell divisions occur randomly in the thallus, due to the intercalary growth of algal filaments. Therefore, we increased the number of cell divisions via synchronization by changing the light cycle (10:14 h light/dark). The number of observed mitotic stages peaked at the beginning of the dark cycle. This protocol describes two methods for the visualization of chromosomes in the filamentous green alga Zygnema. Existing protocols were modified, leading to improved acetocarmine and haematoxylin staining methods as investigated by light microscopy. A freeze-shattering approach with liquid nitrogen was applied to increase the accessibility of the haematoxylin dye. These modified protocols allowed reliable chromosome counting in the genus Zygnema. Key features Improved method for chromosome staining in filamentous green algae. Optimized for the Zygnema strains SAG 698-1a (Z. cylindricum), SAG 698-1b (Z. circumcarinatum), and SAG 2419 (Zygnema 'Saalach'). This protocol builds upon the methods of chromosomal staining in green algae developed by Wittmann (1965), Staker (1971), and Fujii and Guerra (1998). Cultivation and synchronization: 14 days; fixation and permeabilization: 24 h; staining: 1 h; image analysis and chromosome number quantification: up to 20 h.

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