Preparing Maize Synaptonemal Complex Spreads and Sequential Immunofluorescence and Fluorescence In Situ Hybridization

A Method of Well-Spread Pachytene Chromosome Preparations for Plant Species with Large Genomes Suitable for the Immunolocalization of Meiotic Proteins

Well-spread pachytene chromosomes are critical for studying the location of meiotic proteins along individual chromosomes. However, producing good spreads in species with large genomes is challenging due to the tangling of pachytene chromosomes. Existing protocols often fail to achieve proper separation of large chromosomes in spreads. Here, we describe in detail an improved protocol that ensures the effective separation of large pachytene chromosomes and demonstrates its suitability for protein immunodetection. To develop the protocol, pollen mother cells at the middle-late pachytene stage from Allium fistulosum, a species with a large genome and chromosomes, were used. The protocol involved three main steps: fixing anthers in Clark's solution (ethanol-acetic acid, 3:1), digestion in an enzyme mixture, and gentle squashing in 45% acetic acid. A clear ZYP1 signal on all separated chromosomes was observed. The high quality of well-spread pachytene chromosomes obtained with the modified protocol allowed for the easy extraction of individual chromosomes for more precise detection and analysis of the proteins of interest.

Live Cell Imaging of Male Meiosis in Arabidopsis by a Landmark-based System

Live cell imaging has tremendously promoted our understanding of cellular and subcellular processes such as cell division. Here, we present a step-by-step protocol for a robust and easy-to-use live cell imaging approach to study male meiosis in the plant Arabidopsis thaliana as recently established. Our method relies on the concomitant analysis of two reporter genes that highlight chromosome configurations and microtubule dynamics. In combination, these reporter genes allowed the discrimination of five cellular parameters: cell shape, microtubule array, nucleus position, nucleolus position, and chromatin condensation. These parameters can adopt different states, e.g., the nucleus position can be central or lateral. Analyzing how tightly these states are associated gives rise to landmark stages that in turn allow a quantitative and qualitative dissection of meiotic progression. We envision that such an approach can also provide valuable criteria for the analysis of cell differentiation processes outside of meiosis.