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        Early development of primary motor neurons and somites in Zebrafish Embryos

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        Background:

        Zebrafish,or the teleost fish Danio rerio,is a rapidly developing organism that is a

        popular species for studying vertebrate development. Cleavage in the Zebrafish only occurs in

        the blastodisc,a region of cytoplasm in the animal cap of the egg. This type of meroblastic

        cleavage is called discoidal. Cell divisions are rapid in the zebrafish,with divisions taking

        about fifteen minutes each. Gastrulation is usually complete after a little over ten hours from

        fertilization. About 24 hours after fertilization,the embryo has formed most of its tissue and

        organ primordia and displays the tadpole like form.

        This experiment will look at the development of motor neurons in zebrafish at the 24

        hour stage. Motor neurons arise from neurons at the ventrolateral margin of the neural tube.

        These cells are first signaled by Sonic hedgehog from the notocord to instruct them to become

        ventral neurons,and later instructed by Sonic hedgehog from the floor plate cells to become

        motor neurons instead of an interneuron. Further motor neuron specification is required,

        since they must innervate all the various parts of the body. In mammals,motor neurons are

        grouped into three large columns according to their target. Motor neurons in the column of Terni

        (CT) project into the sympathetic ganglia,those in the lateral motor column (LMC) extend to

        the limb musculature,and those of the medial motor columns (MMC) project to the axial

        muscles. The migration patterns and proliferation of these motor neurons is thought to be

        regulated by the cell's age when it last divides.

        In addition,the development of somites in a 24 hour old zebrafish will also be

        examined. Somites give rise to the cells that form the vertebrae,ribs and the skeletal muscles

        of the back. They determine the migration pathways of neural crest cells and spinal nerve axons.

        They first appear in the anterior portion of the trunk,and form as a function of the

        developmental rate of the embryo. Therefore,it is possible to use the number of somites

        present to gauge how far the embryo has developed.

        To examine how thoroughly the motor neurons and somites have developed by the 24

        hour stage,the technique of whole mount antibody staining will be used. The ZNP-1 antibody

        will specifically bind to the primary motor neurons. Since ZNP-1 will not bind to the somites,

        another antibody,F6,will be used to bind to the somite boundaries. The ZNP-1 and F6

        treated embryos will be treated with a secondary antibody, Fluorescent Goat anti-mouse IgG,

        so that the stained neurons and somites can be observed under a fluorescent microscope.

        Procedure:

        1. Dechorionate 24 hour zebrafish embryos in the pharyngula stage with 2 fine forceps.

        2. Fix approximately of the embryos with 4%, and the other half in 1% paraformaldehyde in PBS for one hour.

        3. Wash embryos 3x in 5 ml PBS to remove fixative

        4. Incubate embryos in PBS with goat serum and 0.2% saponin

        5a. Add the primary antibody,ZNP-1 at 1/2000 to half the cells with 4% paraformaldehyde,keep the other half as a control,incubate for 24 hours.

        5b. Add the primary antibody,F6 at 1/500 to half the cells with 1% paraformaldehyde,keep the other half as a control,incubate for 24 hours.

        6. Wash embryos with several changes of 5 ml PBS to remove antibody

        7. Incubate with the secondary antibody,Fluorescent Goat anti-mouse IgG+ for 45 minutes

        8. Wash with several changes of PBS

        9. Mount with depression slides and observe stained embryos using the fluorescent microscope.

        10. Look for individual brightly stained cells in the tail region.

         

        Figure 1.

        Dechorionated Zebrafish embryo at approximately 24 hours

        <center> <font><img height="196" src="http://img.dxycdn.com/trademd/upload/asset/meeting/2013/09/05/A1378266663.jpg" width="245" /> </font></center>

        Results

        All four groups of embryos were observed under a fluorescent microscope. The trunk region was observed for areas of brighter cells. In picture A, vertical lines of cells are slightly brighter than surrounding cells. This is where the motor neurons will develop. In picture C, we see evidence of a row of somites developing along the trunk region. The controls show less evidence of developing motor neurons or somites.

        Figure 2.

        Pictures of fixed zebrafish embryos under a fluorescent microscope

        <center> <img height="379" src="http://img.dxycdn.com/trademd/upload/asset/meeting/2013/09/05/A1378266662.jpg" width="490" /></center>

        A-Trunk region of a 24 hour zebrafish embryo treated with motor neuron specific ZNP-1 antibodies

        B-Trunk region of a control, unstained 24 hour zebrafish embryo

        C-Trunk region of a 24 hour zebrafish embryo treated with somite boundary specific F6 antibodies

        D-Trunk region of a control, unstained 24 hour zebrafish embryo

        Discussion and Conclusion

        The staining of the motor neurons and the somites in the developing zebrafish is a difficult task. The zebrafish is a quickly developing organism, usually resembling the adult zebrafish after one day. The antibody for the motor neurons, will theoretically bind specifically to the developing motor neuron cells in the tail. However,given the small number of cells which are present at a given time, the resulting embryo does not show clear signs of the stained cells. In addition, a bigger factor may be the efficiency of the auto-fluorescent secondary antibody used. The cells of the zebrafish embryo often exhibit some auto fluorescence without any stimulation, so it may be difficult to differentiate the stained motor neurons from the surrounding cells, which also appear brightly stained.

        The somites are also located in the tail region. They will eventually give rise to the vertebrae and the skeletal muscles in the back. The cell specific F6 antibody was used to stain the embryo for somite boundaries. However, little staining is observable because of the relatively similar appearance between the stained somite cells and surrounding cells, due to the secondary antibody resulting in stained cells which resembled surrounding cells.

        The use of ZNP-1 and F6 coupled with the secondary antibody. Fluorescent Goat anti-mouse IgG+, to specifically stain the motor neurons and somites were not as successful as expected. The stain only resulted in few cells exhibiting a somewhat brighter color in the tail region,and was not conclusive. An alternate procedure using a horseradish peroxidase-conjugated secondary antibody, although more time consuming, resulted in a better signal-to-noise ratio and clearer staining .

         

         

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