Nüsslein-Volhard was born in
Magdeburg on 20 October 1942, the second of five children to Rolf Volhard, an architect, and Brigitte Haas Volhard, a nursery school teacher.[5] She has four siblings: three sisters and one brother. She grew up and went to school in south
Frankfurt,[5] where she was exposed to art and music and thus was "trained in looking at things and recognizing things".[6] Her great-grandfather was the chemist
Jacob Volhard, and her grandfather was the known
internistFranz Volhard. She is also the aunt of the Nobel laureate in chemistry
Benjamin List.[7]
After the
Abitur in 1962, she briefly considered pursuing medicine, but dropped the idea after doing a month’s nursing course in a hospital. Instead, she opted to study biology at
Goethe University Frankfurt.[5] In 1964 Nüsslein-Volhard left Frankfurt for the
University of Tübingen, to start a new course in biochemistry. She originally wanted to do
behavioral biology, "but then somehow I ended up in biochemistry (...) and molecular genetics because at the time this was the most modern aspect, and I was ambitious — I wanted to go where the leaders were. The old-fashioned botanists and zoologists were such dull people— there was nothing interesting there."[6]
In 1975, Nüsslein-Volhard became a postdoctoral researcher in
Walter Gehring´s laboratory at the
Biozentrum, University of Basel. She was a specialist in the developmental biology of Drosophila melanogaster (fruit fly) supported by a long-term fellowship from the
European Molecular Biology Organization (EMBO).
In 1977, she continued in the laboratory of
Klaus Sander at
University of Freiburg, who was an expert in embryonic patterning.
In 1978, she set up her own lab in the newly founded
European Molecular Biology Laboratory in Heidelberg with
Eric Wieschaus, whom she had met in Basel. Over the next three years they examined about 20,000 mutated fly families, collected about 600 mutants with an altered body pattern and found that out of the approximately 5,000 essential genes only 120 were essential for early development. In October 1980, they published the mere 15 genes controlling the segmented pattern of the Drosophila larva.[5]
In 2001, she became a member of the Nationaler Ethikrat (National Ethics Council of Germany) for the
ethical assessment of new developments in the
life sciences and their influence on the individual and society. Her primer for the lay-reader, Coming to Life: How Genes Drive Development, was published in April 2006.
In 2004, she started the Christiane Nüsslein-Volhard Foundation (Christiane Nüsslein-Volhard Stiftung) which aids promising young female German scientists with children. The foundation's main focus is to facilitate childcare as a supplement to existing stipends and day care.[4]
During the late 1970’s and early 1980’s, little was known about the genetic and molecular mechanisms by which multicellular organisms
develop from single cells to morphologically complex forms during
embryogenesis. Nüsslein-Volhard and Wieschaus identified genes involved in embryonic development by a series of
genetic screens, generating random
mutations in fruit flies using
ethyl methanesulfonate. Some of these mutations affected genes involved in the development of the embryo. They took advantage of the
segmented form of Drosophila larvae to address the logic of the genes controlling development. They looked at the pattern of segments and denticles in each mutant under the microscope, and were therefore able to work out that particular genes were involved in different processes during development based on their differing mutant phenotypes (such as fewer segments, gaps in the normal segment pattern, and alterations in the patterns of denticles on the segments). Many of these genes were given descriptive names based on the appearance of the mutant larvae, such as
hedgehog, gurken (German: "cucumbers"), and Krüppel ( "cripple").[10] Later, researchers Pavel Tomancal, Amy Beaton, et. Al, identified exactly which gene had been affected by each mutation, thereby identifying a set of genes crucial for
Drosophila embryogenesis.
The subsequent study of these mutants and their interactions led to important new insights into early Drosophila development, especially the mechanisms that underlie the step-wise development of body segments.[11] These experiments are not only distinguished by their sheer scale (with the methods available at the time, they involved an enormous workload), but more importantly by their significance for organisms other than fruit flies.
Her findings led to important realizations about evolution – for example, that
protostomes and
deuterostomes are likely to have had a relatively well-developed
common ancestor with a much more complex body plan than had been conventionally thought.
Additionally, they greatly increased our understanding of the regulation of
transcription, as well as cell fate during development.[citation needed]
Nüsslein-Volhard is associated with the discovery of Toll, which led to the identification of
toll-like receptors.[12]
Nüsslein-Volhard married in the mid-1960s while studying at the
Goethe University Frankfurt, but divorced soon afterward and did not have any children.[5] She lives in
Bebenhausen, Germany.[14] She has said that she loves to sing, play the flute and do chamber music.[6] She published a cookbook in 2006.[15]
^Nüsslein-Volhard, Christiane (1974). Zur spezifischen Protein-Nukleinsäure-Wechselwirkung : die Bindung von RNS-Polymerase aus Escherichia coli an die Replikative-Form-DNS des Bakteriophagen fd und die Charakterisierung der Bindungsstellen (PhD thesis). University of Tübingen.
OCLC793770536.
Christiane Nüsslein-Volhard on Nobelprize.org including the Nobel Lecture on 8 December 1995 The Identification of Genes Controlling Development in Flies and Fishes