Angelika Amon


Angelika Amon, Ph.D. is an Austrian American molecular and cell biologist, and the Kathleen and Curtis Marble Professor in Cancer Research at the Massachusetts Institute of Technology in Cambridge, Massachusetts, United States. Amon's research centers on how chromosomes are regulated, duplicated, and partitioned in the cell cycle. Amon was elected to the American Academy of Arts and Sciences in 2017.

Personal life and career

Amon was born and raised in Vienna, Austria. She displayed an early interest in plant and animal biology as a child, keeping a notebook full of newspaper clippings, and was motivated to study biology after learning about Mendelian genetics and seeing time-lapse micrographs of the division of plant cells in middle school. As of 2007, Amon was married and had two daughters.
Amon received an undergraduate degree in biology from the University of Vienna. She continued her doctoral work there beginning in 1989 under a newly hired Professor Kim Nasmyth at the Research Institute of Molecular Pathology, receiving a Ph.D. in 1993. 1994 saw Amon leaving Austria for the United States, joining the Whitehead Institute in Cambridge, Massachusetts as a postdoc, and was named a Whitehead Fellow in 1996, which allowed her to start her own laboratory at the Institute.
Her independent work at the Whitehead Institute led directly to her securing a faculty appointment at the Koch Institute for Integrative Cancer Research at MIT in 1999, the same year she received the Presidential Early Career Award and was named a Howard S. and Linda B. Stern Career Development Assistant Professor. Amon became an associate investigator for the Howard Hughes Medical Institute in 2000, and was promoted to full professor at MIT in 2007; she had earlier achieved tenure as an assistant professor.
Amon was listed as a member of the Editorial Board for Current Biology in 2016, but no longer appears in this position as of 2019. She served on the Scientific Advisory Board of the Research Institute of Molecular Pathology from 2009 to 2019.
In 2017, Amon was elected to the American Academy of Arts and Sciences, by which time she had been named the Kathleen and Curtis Marble Professor of Cancer Research at MIT.
In 2019, Amon was recognized as among those who have "made extraordinary contributions to their fields" while being a foreign-born researcher in the United States, via the Vilcek Prize.

Research

Amon's research has investigated how cells control and organize the segregation of their chromosomes during cell division. More specifically, her research examines the regulation of exit from mitosis, the regulation of the meiotic cell cycle, and effects of aneuploidy on normal physiology and tumorigenesis.
As a student under Nasmyth, Amon made significant discoveries related to the biosynthesis and breakdown of cyclins during the cell cycle. More specifically, she demonstrated that CDC28 protein kinase is not required for the metaphase to anaphase transition and CLB2 proteolysis continues until reactivation of CDC28 toward the end of G1.
During her time as a post-doctoral fellow at the Whitehead Institute in the 1990s, Amon turned from yeast to fruit flies in the laboratory of Ruth Lehmann, though she found fruit flies to be a far less attractive model than yeast; "once you had worked with yeast, you were spoiled", she said.
The Amon lab primarily investigates yeast as a model for understanding the controls that govern cell-cycle progression and received an Early Career Award grant, a PECAS award, from he NIH for this work in 1998. The PECAS is "the highest honor bestowed by the United States government on young professionals in the early stages of their independent research careers". As a Whitehead Fellow, her team discovered that CDC20 plays a crucial role in cell division. Her Whitehead team identified an interaction between phosphatase and CDC14 which initiates the exit of cells from mitosis to the G1 phase. Amon's team demonstrated that CDC20 is the target protein in the spindle checkpoint during mitosis.
Amon's more recent work has investigated the regulation of chromosome segregation and how chromosomes are accurately transmitted to gametes in meiosis by examining gene regulatory networks. She identified two regulatory networks that promote the release of CDC14 which have the potential to identify the mechanisms that control the final stages of the mitotic cell cycle.
Her research group recently created haploid yeast cells containing extra copies of chromosomes and discovered that these aneuploid strains elicit phenotypes independent of the identity of the additional chromosome such as defects in cell cycle progression, increased energy demands, and interference with protein biosynthesis. Amon has also examined trisomy in the mouse as a model of mammalian cell growth and physiology and demonstrated that mammalian aneuploidy results in a stress response analogous to yeast aneuploidy. Amon's aneuploidy research has potential applications to cancer research. She found that aneuploidy can interfere with a cell's normal DNA repair mechanisms, allowing mutations to accumulate in tumor cells.

Awards and honors