Jane A. McLaughlin
Marine Biological Laboratory
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Publication
Featured researches published by Jane A. McLaughlin.
Science | 1967
Andrew G. Szent-Györgyi; L. G. Együd; Jane A. McLaughlin
Many problems are left open in this article. Its publication may be excused by the suffering cancer causes, which urges the researcher to publish as soon as he thinks he may have found a new trail, which also may be taken by others. What emerges clearly is that SH groups, with their specific reactivities, offer a hopeful target in the search for cancerostatic substances, among which the natural repressor of cell division may hold out the most promise. The glyoxal derivatives also have antiviral properties (7, 16) and may be in the center of a hitherto unknown system of equilibria which deserves a thorough study. The low molecular weight of the glyoxal derivative reported justifies the hope of an early clarification of its structure, as well as its synthesis (17).
Science | 1963
Albert Szent-Györgyi; Andrew Hegyeli; Jane A. McLaughlin
Two substances, one promoting growth (promine) of ascites tumors in mice and the other inhibiting it (retine) have both been found in several tissues, namely, thymus, aorta, muscle, and tendon. In spite of similar solubilities in the solvents used for their extraction, the substances could be roughly separated. The value of the ratio between these substances in the same tissue may be significant.
Electromagnetic Biology and Medicine | 1983
Albert Szent-Györgyi; Jane A. McLaughlin
As biologists we can contribute to quantum chemistry only by clearing up the mechanism of some of the biological processes, thereby opening the way to their quantum chemical analysis. We have tried to do this by isolating and identifying the central catalysts of those processes. One of us (A.S.-G.) studied biological oxidations first in the plants that turn dark on exposure to air such as potatoes, apples and pears. He found the central catalyst of these oxidations to be a catechol derivative that oxidized to o-diquinol which forms dark complexes with protein. After this, he turned to the oxidation of plants that do not turn dark and identified two catalysts, one of which was ascorbic acid, the other succinic acid. His third problem was the generation of motion, the function of muscle. This study led to the discovery of a new protein, which he discovered with I. Banga at the University of Szeged, Hungary. They called it “actin” because it made the inactive myosin act to contract. This discovery has an unu...
Proceedings of the National Academy of Sciences of the United States of America | 1983
Ronald Pethig; Peter R. C. Gascoyne; Jane A. McLaughlin; Albert Szent-Györgyi
Proceedings of the National Academy of Sciences of the United States of America | 1962
Albert Szent-Györgyi; Andrew Hegyeli; Jane A. McLaughlin
Proceedings of the National Academy of Sciences of the United States of America | 1980
Jane A. McLaughlin; Ronald Pethig; Albert Szent-Györgyi
International Journal of Quantum Chemistry | 2009
Albert Szent-Györgyi; Jane A. McLaughlin
Proceedings of the National Academy of Sciences of the United States of America | 1984
Ronald Pethig; Peter R. C. Gascoyne; Jane A. McLaughlin; Albert Szent-Györgyi
Proceedings of the National Academy of Sciences of the United States of America | 1963
Albert Szent-Györgyi; Andrew Hegyeli; Jane A. McLaughlin
Proceedings of the National Academy of Sciences of the United States of America | 1985
Ronald Pethig; Peter R. C. Gascoyne; Jane A. McLaughlin; Albert Szent-Györgyi
