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Search for selectivity between optical isomers in reactions of polarised positive muons with alanines and octanols

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Abstract

ONE of the most intriguing problems in chemical evolution is the origin of optical asymmetry in biopolymers. The easiest way to state the problem is: why are proteins made almost exclusively of L-amino acid optical isomers and natural sugars of D-optical isomers?1 That proteins must be made of only one kind of optical isomer is understandable on the basis of their need for precise three-dimensional conformations in order to perform their catalytic roles as enzymes. But, is it just a matter of chance, as suggested in refs 2–4, that our proteins are L-, or is there (was there) some asymmetrical agent on our planet that made the protein L-configuration the one upon which life is based?

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Author notes

  1. F. N. GYGAX

    Present address: ETH Zürich, c/o SIN, 5234 Villigen, Switzerland

Authors and Affiliations

  1. Lawrence Berkeley Laboratory, University of California, Berkeley, California, 94720

    R. M. LEMMON, K. M. CROWE, F. N. GYGAX, R. F. JOHNSON & B. D. PATTERSON

  2. TRIUMF,

    J. H. BREWER & D. G. FLEMING

  3. Department of Chemistry, University of British Columbia, Vancouver, British Columbia, Canada

    J. H. BREWER & D. G. FLEMING

Authors
  1. R. M. LEMMON
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  2. K. M. CROWE
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  3. F. N. GYGAX
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  4. R. F. JOHNSON
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  5. B. D. PATTERSON
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  6. J. H. BREWER
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  7. D. G. FLEMING
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LEMMON, R., CROWE, K., GYGAX, F. et al. Search for selectivity between optical isomers in reactions of polarised positive muons with alanines and octanols. Nature 252, 692–694 (1974). https://doi.org/10.1038/252692a0

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  • DOI: https://doi.org/10.1038/252692a0

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