This essay will appear in our forthcoming book, “Making the Modern Laboratory,” which tells the story of how the various tools, materials, and methods of the molecular biology lab arrived there and how they might evolve in the future.
The Harz Mountains, whose low ridges sprawl across northern Germany, have been said to be teeming with witches. The poet Goethe wrote in Faust: “Da drängen sich Hexen zu tausend zuhauf” (“Witches throng together by the thousand”). But while such a coven has never actually been found in the Harz, something even more storied has — Arabidopsis thaliana, the premier model for plant biology.
Arabidopsis thaliana was first described by Johannes Thal, a German doctor and botanist born in 1542, who stumbled across it while on an alpine walk. From a young age, Thal had been transfixed by the nature of the Harz, collecting and cataloging grasses, herbs, and various resinous plants that might prove medically useful. No species was too unremarkable for Thal, fortunate given that Arabidopsis thaliana resembles one of those spindly flowers that sprout between cracks on sidewalks or in the window wells of abandoned cars.
A wood engraving of the Brocken in the Harz Mountains, ca. 1879.
An A. thaliana plant in the wild. Credit: Salicyna
While it may look like a weed, Arabidopsis belongs to the Brassicaceae, or mustard family. Native throughout Africa and Eurasia, it typically grows in rocky, sandy, and chalky soils. Sometimes called “thale cress” or “mouse-ear” cress, Arabidopsis does indeed have flowers whose pale petals resemble the soft, rounded tip of a mouse’s ear. Atop a 20-30 centimeter leaf-studded shoot grow several pale flowers, each with four petals arranged in a whorl.
Although Thal was the first person to pay any mind to this unprepossessing plant, another German botanist, Friedrich Laibach, took the first steps to bring Arabidopsis from the herbarium into the modern research laboratory. As part of his work as a Ph.D. candidate in Bonn in the early 1900s, Laibach spent his time analyzing the number of chromosomes in the various plants that he had collected around the city and his hometown of Limburg. He did this by staining the plant tissue with a special dye that binds to chromatin, the mixture of DNA and proteins that form chromosomes. By examining cells during meiosis — when chromosomes are most condensed and distinct — he could directly count the number of chromosomes possessed by each species. When Laibach turned his attention to Arabidopsis, he found that the plant carried only five pairs, one of the smallest numbers known at the time.
This genetic simplicity captivated Laibach, who began to collect seeds from every Arabidopsis type he could get his hands on, imploring colleagues to look out for new species while traveling. Between 1930 and 1950, he collected seeds from over 150 different ecotypes (later called “accessions”), which he maintained at the Botanical Institute at Goethe University in Frankfurt.
Drawings of the A. thaliana plant by Swedish botanist, Carl A.M. Lindman (1856-1928).
In 1943, Laibach published a paper in which he made a case for the use of the plant as a genetic model. A. thaliana, he asserted, was not only easily cultivated year-round but also self-fertilizing, meaning pure lines could be easily maintained. It was also able to be cross-pollinated by hand, which made it well-suited to experimental breeding. Finally, its small genome made it ideal for cytological and genetic studies, since its hereditary factors could be more easily traced.
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