A normal zebrafish embryo (left) and an embryo without Mib1 (right). The embryo lacking Mib1 exhibits wider tissues (in the center of the image) because it cannot perform convergent extension. Image credit: Max Fürthauer (CC BY 4.0)
Animal embryonic development involves producing an entire animal from a single starting cell, the zygote. To do this, the zygote must divide to make new cells, and these cells have to arrange themselves into the correct body shape. This requires a lot of cells to move in a coordinated fashion. One of these movements is called ‘convergent extension’, in which a typically round group of cells rearranges into a long, thin shape, for example, to increase the distance between the head and the tail of the animal. In order to coordinate this movement, cells need to communicate with each other. One of the signaling pathways cells use to guide them to the right positions is the planar cell polarity (PCP) pathway.
Zebrafish are used to study PCP in convergent extension because they are transparent, making it easy to track their cell movements under the microscope. Interestingly, when a protein called Mindbomb1 (Mib1) is inactivated in zebrafish embryos, convergent extension is reduced. Mib1 helps control the activity of other proteins by attaching a chemical marker called ubiquitin to them, which tags these proteins to be relocated from the cell surface to small vesicles within the cell. The protein is known to be involved in the formation of neurons – the cells that make up the brain and nerves – but its links to cell movement and the PCP pathway had not been explored.
Saraswathy et al. used a technique called Crispr/Cas9 mutagenesis to genetically modify zebrafish and then used observations under the microscope to determine the role of Mib1 in PCP and convergent extension. Their experiments show that Mib1 helps internalize a protein called Ryk from the cell surface into the cell. This internalization of Ryk is required to relay signals through the PCP pathway. When Mib1 is missing, Ryk stays on the surface of the cell, instead of moving to the inside, blocking PCP signaling between cells and therefore blocking convergent extension.
Understanding the role of Mib1 in PCP signaling sheds light on how cell movements are coordinated during the embryonic development of zebrafish. Future research will involve determining whether Mib1 plays the same role in other animals, offering further insights into embryonic development. Additionally, PCP is known to have a role in disease, including the spread of cancer. It will be important to determine whether Mib1 is involved in this process as well.
