TY - CHAP
T1 - Super-Resolution Microscopy of Phloem Proteins
AU - Stanfield, Ryan C.
AU - Schulz, Alexander
PY - 2019
Y1 - 2019
N2 - Super-resolution microscopy bridges the gap between light and electron microscopy and gives new opportunities for the study of proteins that contribute to phloem function. The established super-resolution techniques are derived from fluorescence microscopy and depend on fluorescent dyes, proteins tagged with GFP variants or fluorochrome-decorated antibodies. Compared with confocal microscopy they improve the resolution between 2.5 and 10 times and, thus, allow a much more precise (co-) localization of membranes, plasmodesmata, and structural proteins. However, they are limited to thin tissue slices rather than intact plant organs and can only show immobilized or only slowly moving targets. Accordingly, the first super-resolution micrographs of the phloem were recorded from fixed tissue which was sectioned using a vibratome or microtome. As with transmission electron microscopy, preparation of phloem tissue for super-resolution microscopy is challenged by the sudden pressures release when dissecting the functional tissue (see Chapter 2 ). This chapter describes a protocol for investigation of proteins in the plasma membranes of sieve elements and companion cells. It illustrates how high-resolution fluorescence imaging can provide information that could not be obtained with confocal or electron microscopy. Further, a brief introduction outlines the theoretical background of super-resolution techniques suitable for phloem imaging and summarizes the findings of the first available super-resolution studies on the phloem. The protocol focusses on the crucial steps for super-resolution microscopy of immunolocalized phloem proteins, adjusted to the use of three-dimensional structured illumination microscopy (3D-SIM).
AB - Super-resolution microscopy bridges the gap between light and electron microscopy and gives new opportunities for the study of proteins that contribute to phloem function. The established super-resolution techniques are derived from fluorescence microscopy and depend on fluorescent dyes, proteins tagged with GFP variants or fluorochrome-decorated antibodies. Compared with confocal microscopy they improve the resolution between 2.5 and 10 times and, thus, allow a much more precise (co-) localization of membranes, plasmodesmata, and structural proteins. However, they are limited to thin tissue slices rather than intact plant organs and can only show immobilized or only slowly moving targets. Accordingly, the first super-resolution micrographs of the phloem were recorded from fixed tissue which was sectioned using a vibratome or microtome. As with transmission electron microscopy, preparation of phloem tissue for super-resolution microscopy is challenged by the sudden pressures release when dissecting the functional tissue (see Chapter 2 ). This chapter describes a protocol for investigation of proteins in the plasma membranes of sieve elements and companion cells. It illustrates how high-resolution fluorescence imaging can provide information that could not be obtained with confocal or electron microscopy. Further, a brief introduction outlines the theoretical background of super-resolution techniques suitable for phloem imaging and summarizes the findings of the first available super-resolution studies on the phloem. The protocol focusses on the crucial steps for super-resolution microscopy of immunolocalized phloem proteins, adjusted to the use of three-dimensional structured illumination microscopy (3D-SIM).
KW - Aquaporins
KW - Early Nodulin Like 9
KW - Plasma membrane domains
KW - Pore-plasmodesma units
KW - Sieve-element reticulum
UR - http://www.mendeley.com/research/superresolution-microscopy-phloem-proteins
U2 - 10.1007/978-1-4939-9562-2_7
DO - 10.1007/978-1-4939-9562-2_7
M3 - Book chapter
T3 - Methods in Molecular Biology
SP - 83
EP - 94
BT - Methods in Molecular Biology
PB - Humana Press
ER -