Best practices in plant cytometry Flow cytometry (FCM) and flow cytometric sorting (FCS) systems have developed as experimental tools of remarkable power and are enjoying an ever-increasing impact in the general field of biology. 1 Application of these tools to plant biology has developed more slowly given that the natural form of plants infrequently resembles that of the single cell suspension, prototypically the hematopoietic system that drove the original development of FCM/FCS. Nevertheless, these systems have had a profound influence at all levels of plant biology, from the study of single cells and subcellular organelles, to the behavior of populations of plants, and ultimately to the performance of ecosystems. It is safe to say their impact has not plateaued, as further applications of this unique technology are increasingly developed by innovative scientists around the world to address questions both in the basic sciences, and to increasingly confront emerging problems in the applied sector. For example, in addressing the challenges of sustainable production of sufficient food resources based on plant breeding involving ploidy-based approaches (e.g., induction of polyploidy) 2 for the needs of our future global citizens, FCM, and FCS systems will play central roles in this effort. The degree to which FCM and FCS systems have impacted plant biology and applied agricultural sciences must not be understated. The major applications of DNA FCM are ploidy level and genome size estimations, and cell cycle analysis/endoreplication (with the later included in a lower percentage of studies). Indeed, FCM is currently/ extensively and almost exclusively employed as the method of choice for measurement of plant genome sizes. 3,4 Measurements of this type impact agriculture in terms of ploidy estimation, with applications ranging from plant biotechnology, breeding and seed quality testing to taxonomy and population biology. They also impact the fundamental plant sciences in terms of biosystematics, ecology, evolution, genomics, and conservation, among other applications. One of the most startling observations of the angiosperms is the bandwidth occupied by genome size, which spans almost 2400-fold. Flow sorting of higher plant chromosomes has provided invaluable information regarding the organization of DNA sequences within plant species. It has also greatly facilitated the process of wholegenome sequencing by permitting subdivision of large genomes into samples comprising entire chromosomes or chromosome arms. 5 FCS methods applied to wall-less cells (protoplasts) expressing fluorescent proteins (FPs) in a cell type-specific manner have allowed elucidation of patterns of co-regulated gene expression and plant hormone gradients identification 6,7 within organized tissues, such as roots. 8,9
