Abstract
Recently, advances in fluorescent in-situ hybridization techniques and in imaging technology have enabled visualization and counting of individual RNA molecules in single cells. This has greatly enhanced the resolution in our understanding of transcriptional processes. Here, we adapt a recently published smiFISH protocol (single-molecule inexpensive fluorescent in-situ hybridization) to whole embryos across a range of arthropod model species, and also to non-embryonic tissues. Using multiple fluorophores with distinct spectra and white light laser confocal imaging, we simultaneously detect and separate single RNAs from up to eight different genes in a whole embryo. We also combine smiFISH with cell membrane immunofluorescence, and present an imaging and analysis pipeline for 3D cell segmentation and single-cell RNA counting in whole blastoderm embryos. Finally, using whole embryo single-cell RNA count data, we propose two alternative single-cell variability measures to the commonly used Fano factor, and compare the capacity of these three measures to address different aspects of single-cell expression variability.
Highlights
Advances in fluorescent in-situ hybridization techniques and in imaging technology have enabled visualization and counting of individual RNA molecules in single cells
The spatial context of the cells with respect to both their neighbouring cells, and to the larger tissue or embryo is often still lost[13]. These limitations have been overcome by the development of single-molecule fluorescent in situ hybridization, which employs multiple short ~20 nt gene-specific DNA probes directly labelled with fluorophores[14,15]
Adaptation of single-molecule inexpensive FISH (smiFISH) to arthropod embryos and tissues. smiFISH was originally tested in cultured mammalian cells[16]
Summary
Advances in fluorescent in-situ hybridization techniques and in imaging technology have enabled visualization and counting of individual RNA molecules in single cells. This has greatly enhanced the resolution in our understanding of transcriptional processes. The spatial context of the cells with respect to both their neighbouring cells, and to the larger tissue or embryo is often still lost[13] These limitations have been overcome by the development of single-molecule fluorescent in situ hybridization (smFISH), which employs multiple short ~20 nt gene-specific DNA probes directly labelled with fluorophores[14,15].
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