Multi-position photoactivation and multi-time acquisition for large-scale cell tracing in avian embryos.

Vertebrate development is a complex orchestration of cell and tissue movements. Tracing individual cell positions can rapidly become a large-scale problem because cell numbers often grow exponentially in the early embryo. A typical approach consists of fluorescently marking small numbers of cells within a large number of embryos, followed by comprehensive three-dimensional static or time-lapse imaging to map cell positions. However, for large-scale cell tracing, such as during organogenesis, the time, effort, and expense of this approach can be limiting. The multi-position acquisition method can be used to capture more than one location on a microscope stage and allow for multi-specimen imaging. When combined with photoactivation cell labeling, a tool for selective cell marking using laser excitation, multi-position imaging offers a powerful tool for rapid data acquisition. This protocol describes the technique and demonstrates its use to map cell movements in the chick spinal cord, using slice culture explants. The details of multiple slice culture preparation, multi-position photoactivation, and multi-time acquisition are described. These events are coordinated by setting up blocks of microscope instructions that execute sequentially. This method significantly decreases the time, effort, microscopy, and embryo costs by a factor of the number of specimens imaged per session, typically six.

Watching the assembly of an organ a single cell at a time using confocal multi-position photoactivation and multi-time acquisition.

Tracing cell movements in vivo yields important clues to organogenesis, yet it has been challenging to accurately and reproducibly fluorescently mark single and small groups of cells to build a picture of tissue assembly. In the early embryo, the small size (hundreds of cells) of progenitor cell regions has made it easier to identify and selectively mark superficially located cells by glass needle injection. However,during early organogenesis,subregions of interest may be several millions of cells in volume located deeper within the embryo requiring an alternative approach. Here, we combined (confocal and 2-photon) photoactivation cell labeling and multi-position, multi-time imaging to trace single cell and small subgroups of cells in the developing brain and spinal cord. We compared the photostability and photoefficiency of a photoswitchable fluorescent protein, PSCFP2, with a novel nuclear localized H2B-PSCFP2 protein. We showed that both fluorescent proteins have similar photophysical properties and H2B-PSCFP2 is more effective in single cell identification in dense tissue. To accurately and reproducibly fluorescently trace subregions of cells in a 3D tissue volume, we developed a protocol for multi-position photoactivation and multi-time acquisition in the chick spinal cord in up to eight tissue sections. We applied our techniques to address the formation of the sympathetic ganglia,a major component of the autonomic nervous system,and showed there are phenotypic differences between early and later emerging neural crest cells and their positions in the developing ganglia. Thus, targeted fluorescent cell marking by confocal or 2-photon multi-position photoactivation and multi-time acquisition offer a more efficient, less invasive technique to trace cell movements in large regions of interest and move us closer towards mapping the cellular events of organogenesis.