Paul Schimmel Explained

Paul Schimmel
Birth Date:4 August 1940[1]
Birth Place:Hartford, Connecticut
Nationality:American
Fields:Biochemistry/Molecular Medicine
Doctoral Students:Maria Jasin, Lynne Regan
Awards:Pfizer Award in Enzyme Chemistry
Emily M. Gray Award for Significant Contributions to Education in Biophysics
Stein and Moore Award of the Protein Society
Kathryn C. Hach Award for Entrepreneurial Success

Paul Reinhard Schimmel (born August 4, 1940) is an American biophysical chemist and translational medicine pioneer.

Career

Paul Schimmel is a Professor of Molecular Medicine[2] at The Scripps Research Institute. Prior to joining The Scripps Research Institute, he was a John D. and Catherine T. MacArthur Professor of Biochemistry and Biophysics at MIT (Massachusetts Institute of Technology). Author or coauthor of many scientific research publications,[3] he is also coauthor of a widely used 3-volume textbook on biophysical chemistry.[4] His research interests have focused on aminoacyl tRNA synthetases as fundamental interpreters of the genetic information.[5] Through career-long investigations of this ancient and universal set of essential enzymes, his laboratory has worked on a universal mechanism for correcting errors in the interpretation of genetic information,[6] [7] and went on to show how this mechanism is essential for maintaining cellular homeostasis and for preventing serious pathologies and disease.[8] [9] He has also been listed as one of the leading translational researchers in the world, having one of the top five most cited patents for the period 2012-2016.[10]

His laboratory also discovered what others have referred to as a tRNA synthetase-directed primordial, or 'second', genetic code that eventually was incorporated into the modern code.[11] [12] [13] In a separate line of research published back in 1983, Schimmel developed the concept of what are now known as ESTs (expressed sequence tags) and the strategy of shotgun sequencing, approaches that several years later were adopted for the human genome project.[14] Nature magazine listed Schimmel's work on the development of ESTs as one of the four key developments that launched the human genome project.[15] Lastly, his laboratory established connections of synthetases to disease and, most recently, they reported the structural and functional metamorphosis of these proteins, whereby they are repurposed with novel activities, both inside and outside the cell, in a variety of cell signaling pathways[16] [17] [18]

Honors

Named to various society and university awards and honorary degrees, and elected to membership in the American Academy of Arts and Sciences,[19] the National Academy of Sciences,[20] the American Philosophical Society,[21] the Institute of Medicine (National Academy of Medicine)[22] and National Academy of Inventors.[23] Active in many scientific and academic organizations and committees, including past service as President of the Division of Biological Chemistry of the American Chemical Society (presently with over 7,000 members) and as an editorial board member of numerous scientific journals. In June 2020, he was named the 2020 winner of the Kathryn C. Hach Award for Entrepreneurial Success for "co-founding more than ten biotech companies and aiding others in their endeavors for nearly three decades."[24] Named the ARCS San Diego Chapter 2020 Scientist of the Year[25]

External links

Notes and References

  1. Book: Who's who in the West: A Biographical Dictionary of Noteworthy Men and Women of the Pacific Coast and the Western States. 2001. A.N. Marquis Company. 9780837909325. March 24, 2015.
  2. Web site: TSRI Faculty Page.
  3. Web site: Complete List of Published Work in MyBibliography.
  4. Web site: Biophysical Chemistry Part I: The Conformation of Biological Macromolecules, Biophysical Chemistry Part II: Techniques for the Study of Biological Structure and Function, Biophysical Chemistry Part III: The Behavior of Biological Macromolecules. Cantor. Charles R.. Schimmel. Paul R.. Macmillan Learning.
  5. Web site: Schimmel Lab Website.
  6. Schmidt. E.. Schimmel. P.. April 8, 1994. Mutational isolation of a sieve for editing in a transfer RNA synthetase. Science. 264. 5156. 265–267. 0036-8075. 8146659. 10.1126/science.8146659. 1994Sci...264..265S .
  7. Song. Youngzee. Zhou. Huihao. Vo. My-Nuong. Shi. Yi. Nawaz. Mir Hussain. Vargas-Rodriguez. Oscar. Diedrich. Jolene K.. Yates. John R.. Kishi. Shuji. December 22, 2017. Double mimicry evades tRNA synthetase editing by toxic vegetable-sourced non-proteinogenic amino acid. Nature Communications. 8. 1. 2281. 10.1038/s41467-017-02201-z. 5741666. 29273753. 2017NatCo...8.2281S .
  8. Lee. Jeong Woong. Beebe. Kirk. Nangle. Leslie A.. Jang. Jaeseon. Longo-Guess. Chantal M.. Cook. Susan A.. Davisson. Muriel T.. Sundberg. John P.. Schimmel. Paul. September 7, 2006. Editing-defective tRNA synthetase causes protein misfolding and neurodegeneration. Nature. 443. 7107. 50–55. 10.1038/nature05096. 1476-4687. 16906134. 2006Natur.443...50L . 4395135.
  9. Liu. Ye. Satz. Jakob S.. Vo. My-Nuong. Nangle. Leslie A.. Schimmel. Paul. Ackerman. Susan L.. December 9, 2014. Deficiencies in tRNA synthetase editing activity cause cardioproteinopathy. Proceedings of the National Academy of Sciences of the United States of America. 111. 49. 17570–17575. 10.1073/pnas.1420196111. 4267364. 25422440. free. 2014PNAS..11117570L .
  10. Huggett. Brady. Paisner. Kathryn. December 1, 2017. Top 20 translational researchers of 2016. Nature Biotechnology. en. 35. 12. 1126. 10.1038/nbt.4028. 29220038. 205285596. 1546-1696.
  11. Francklyn. C.. Schimmel. P.. February 2, 1989. Aminoacylation of RNA minihelices with alanine. Nature. 337. 6206. 478–481. 10.1038/337478a0. 0028-0836. 2915692. 1989Natur.337..478F . 4268171.
  12. Francklyn. C.. Shi. J. P.. Schimmel. P.. February 28, 1992. Overlapping nucleotide determinants for specific aminoacylation of RNA microhelices. Science. 255. 5048. 1121–1125. 0036-8075. 1546312. 10.1126/science.1546312. 1992Sci...255.1121F .
  13. Schimmel. Paul. January 2018. The emerging complexity of the tRNA world: mammalian tRNAs beyond protein synthesis. Nature Reviews. Molecular Cell Biology. 19. 1. 45–58. 10.1038/nrm.2017.77. 1471-0080. 28875994. 5231605.
  14. Putney. S. D.. Herlihy. W. C.. Schimmel. P.. April 21, 1983. A new troponin T and cDNA clones for 13 different muscle proteins, found by shotgun sequencing. Nature. 302. 5910. 718–721. 0028-0836. 6687628. 10.1038/302718a0. 1983Natur.302..718P . 4364361.
  15. Lander. E. S.. Linton. L. M.. Birren. B.. Nusbaum. C.. Zody. M. C.. Baldwin. J.. Devon. K.. Dewar. K.. Doyle. M.. February 15, 2001. Initial sequencing and analysis of the human genome. Nature. 409. 6822. 860–921. 10.1038/35057062. 0028-0836. 11237011. free.
  16. Guo. Min. Schimmel. Paul. March 2013. Essential nontranslational functions of tRNA synthetases. Nature Chemical Biology. 9. 3. 145–153. 10.1038/nchembio.1158. 3773598. 23416400.
  17. Sajish. Mathew. Schimmel. Paul. March 19, 2015. A human tRNA synthetase is a potent PARP1-activating effector target for resveratrol. Nature. 519. 7543. 370–373. 10.1038/nature14028. 4368482. 25533949. 2015Natur.519..370S .
  18. Lo. Wing-Sze. Gardiner. Elisabeth. Xu. Zhiwen. Lau. Ching-Fun. Wang. Feng. Zhou. Jie J.. Mendlein. John D.. Nangle. Leslie A.. Chiang. Kyle P.. July 18, 2014. Human tRNA synthetase catalytic nulls with diverse functions. Science. 345. 6194. 328–332. 10.1126/science.1252943. 4188629. 25035493. 2014Sci...345..328L .
  19. Web site: American Academy of Arts and Sciences.
  20. Web site: National Academy of Sciences.
  21. Web site: American Philosophical Society.
  22. Web site: National Academy of Medicine.
  23. Web site: National Academy of Inventors.
  24. Web site: 2020 National Award Recipients Citations. June 13, 2020. American Chemical Society. en.
  25. Web site: ARCS 2020 Scientist of the Year San Diego. April 17, 2021. san-diego.arcsfoundation.org. September 28, 2020 .