33398930 OR Best practices in plant cytometry Dotaz Zobrazit nápovědu
Flow cytometry (FCM) is now the most widely used method to determine ploidy levels and genome size of plants. To get reliable estimates and allow reproducibility of measurements, the methodology should be standardized and follow the best practices in the field. In this article, we discuss instrument calibration and quality control and various instrument and acquisition settings (parameters, flow rate, number of events, scales, use of discriminators, peak positions). These settings must be decided before measurements because they determine the amount and quality of the data and thus influence all downstream analyses. We describe the two main approaches to raw data analysis (gating and histogram modeling), and we discuss their advantages and disadvantages. Finally, we provide a summary of best practice recommendations for data acquisition and raw data analysis in plant FCM.
Microalgae are photosynthetic microorganisms with a major influence on global ecosystems. Further, owing to the production of various secondary metabolites, microalgae are also intensively studied for their enormous potential in biotechnology and its applications. While flow cytometry (FCM) is a fast and reliable method particularly suitable for genome size estimation in plant and animal studies, its application to microalgae often comes with many methodological challenges due to specific issues (e.g., cell wall composition, and presence of various secondary metabolites). Sample preparation requires considerable amounts of biomass, chemical fixation, and/or extraction of cellular components. In genome size estimation, appropriate methods for isolation of intact nuclei (using lysis buffers, razor-blade chopping, various enzymes, or bead-beating of cells) are essential for successful and high-quality analyses. Nuclear DNA amounts of microalgae diverge greatly, varying by almost 30,000-fold (0.01 to 286 pg). Even though new algal reference standards for genome size are now being introduced, animal red blood cells and nuclei from plant tissues are still predominantly used. Due to our limited knowledge of microalgal life cycles, particular caution should be taken during 1C/2C-value (or ploidy level) assignments.
- MeSH
- biomasa MeSH
- biotechnologie MeSH
- délka genomu MeSH
- ekosystém MeSH
- mikrořasy * MeSH
- průtoková cytometrie MeSH
- Publikační typ
- časopisecké články MeSH
A critical aspect for obtaining accurate, reliable, and high-resolution estimates of nuclear DNA content is the release of nuclei from the cytoplasm in sufficient amounts, while maintaining their integrity throughout the analysis, protecting their DNA from degradation by endonucleases, and enabling stoichiometric DNA staining. In embryophytes, the most common method consists of chopping the plant material with a sharp razor blade to release nuclei into an isolation buffer, filtering the homogenate, and staining the nuclei in buffered suspension with a fluorochrome of choice. Despite the recent description of alternative approaches to isolate nuclei, the chopping procedure remains the most widely adopted method, due to its simplicity, rapidity, and effectiveness. In this review article, we discuss the specifics of nuclei isolation buffers and the distorting effects that secondary metabolites may have in nuclear suspensions and how to test them. We also present alternatives to the chopping procedure, options for filtering and fluorochromes, and discuss the applications of these varied approaches. A summary of the best practices regarding the isolation of plant nuclei for the estimation of nuclear DNA content is also provided.
