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Advances in cellular microscopy: Transparent fruit flies

Date:
November 26, 2018
Source:
Vienna University of Technology
Summary:
A new kind of microscope has been developed: it creates 2D light sheets, penetrating biological tissues and causing special molecules to fluoresce. For the microscope to work, the tissue has to be made transparent, so the researchers developed new chemical procedures to 'clear' them. With this technique, extremely detailed pictures of intricate features of the nervous system of fruit flies are now possible.
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The nervous system of an animal can be studied by cutting it up into thin layers -- however this inevitably leads to the destruction of the cellular structures in the tissue. Analyzing complex nerve connections is then hardly possible. The far more elegant method is the so called optical "clearing" of the various tissues using chemical processes that make the animal transparent. Interesting structures in the tissue can be selectively marked and analyzed.

At the Vienna University of Technology, a clearing method has now been developed that can be applied to insects, which is a particularly difficult task. With an improved light-sheet microscope (a so-called ultramicroscope), it is now possible to image large nerve tissue samples and take high-resolution pictures of complex neural networks that have been labeled with fluorescent molecules. The new method has been published in the journal Nature Communications.

Fluorescent Molecules

"We can learn a lot about the nervous systems of animals by using genetic engineering to insert special molecules into the nerve tissues, which can then be made to fluoresce," says Marko Pende, a PhD student at TU Wien (Vienna). The big question is how these fluorescent molecules can be imaged without damaging the tissue.

One method that has been used with great success is ultramicroscopy. Transparent tissue is illuminated with a laser beam, which is widened by special optical elements, creating a two-dimensional flat surface of light. This surface penetrates the tissue and illuminates those fluorescent molecules that lie exactly in that plane. Layer by layer, the tissue can be analyzed with this light-sheet, creating a three-dimensional model from the two-dimensional frames on the computer.

"We focused on the fruit fly Drosophila melanogaster because it is of particular interest for research into the nervous system. Unfortunately, it is particularly difficult to develop a suitable clearing method for insects, "explains Marko Pende."For the tissue to become transparent, it has to be treated with special chemicals, and in insect tissues these chemicals have always destroyed the fluorescent molecules until now." In addition, insect tissue contains chitin, which can hardly be made transparent. Also, Drosophila has particularly robust pigments in it its eyes.

The team at TU Wien (Vienna), together with the University of Vienna and the Medical University, succeeded in finding a way to make Drosophila flies completely transparent without destroying the fluorescent marker molecules. This was achieved with the help of improved chemical mixtures. "It is an important step forward for the Drosophila research community," says Prof. Thomas Hummel from the Department of Neurobiology (University of Vienna).

The pictures were made possible by pioneering optical research by Saiedeh Saghafi (TU Wien). She was able to significantly improve the ultramicroscope: The light-sheet, with which the plane is illuminated layer by layer, used to be about 10 microns thick. The improved ultramicroscope now produces uniform light-sheets of only 3 ?m thickness over a large area. In addition, the microscope was equipped with an additional lens, which changes the focal point, much like to a pair of glasses: "So far, we could only focus on the outer area of the tissue, now we can take a centimeter-deep look into the tissue and still get sharp images," says Prof. Hans Ulrich Dodt, Head of the Department of Bioelectronics (TU Wien). "It will enable impressive, high-resolution images that will give us important insights into the way the Drosophila nervous system works."

The Connectome and Fruit Fly Behavior

The new technique should now help to study the so-called "connectome" of Drosophila. The connectome is the arrangement of interconnections throughout the nervous system, the "electrical circuit diagram" of the animal. This circuit diagram can then be related to behavioral patterns of Drosophila.

In addition, Drosophila is ideal for analyzing genes that lead to neurodegenerative diseases in humans, such as Alzheimer's and Parkinson's disease. Transparent flies now provide a unique opportunity to understand the complex changes in various areas of the nervous system during neurodegeneration.


Story Source:

Materials provided by Vienna University of Technology. Note: Content may be edited for style and length.


Journal Reference:

  1. Marko Pende, Klaus Becker, Martina Wanis, Saiedeh Saghafi, Rashmit Kaur, Christian Hahn, Nika Pende, Massih Foroughipour, Thomas Hummel, Hans-Ulrich Dodt. High-resolution ultramicroscopy of the developing and adult nervous system in optically cleared Drosophila melanogaster. Nature Communications, 2018; 9 (1) DOI: 10.1038/s41467-018-07192-z

Cite This Page:

Vienna University of Technology. "Advances in cellular microscopy: Transparent fruit flies." ScienceDaily. ScienceDaily, 26 November 2018. <www.sciencedaily.com/releases/2018/11/181126105500.htm>.
Vienna University of Technology. (2018, November 26). Advances in cellular microscopy: Transparent fruit flies. ScienceDaily. Retrieved November 14, 2024 from www.sciencedaily.com/releases/2018/11/181126105500.htm
Vienna University of Technology. "Advances in cellular microscopy: Transparent fruit flies." ScienceDaily. www.sciencedaily.com/releases/2018/11/181126105500.htm (accessed November 14, 2024).

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