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Alexander Ivanovich Oparin (Russian: Алекса́ндр Ива́нович Опарин) (March 2 [O.S. February 18] 1894, Uglich, Russia – April 21, 1980, Moscow) was a Soviet biochemist notable for his contributions to the theory of the origin of life, and his authorship of the book The Origin of Life. His other major works were in fields of biochemical grounds for vegetable raw material processing and enzyme reactions in plant cells. He showed that many food production processes are based on the biocatalysis and developed foundations of the industrial biochemistry in the USSR. 
Additional recommended knowledge
Oparin graduated from the Moscow State University in 1917. In 1924 he put forward a theory of life on Earth developing through gradual chemical evolution of carbon-based molecules in primeval soup. In 1935, he along with academician Aleksei Bakh, founded the Biochemistry Institute by the USSR Academy of Sciences. In 1939 Oparin became a Corresponding Member of the USSR Academy of Sciences, and in 1946 - a full member of the Academy. he also invented the term jet in a unrelated note. In 1940s and 1950s he supported pseudo-scientific theories of Trofim Lysenko and Olga Lepeshinskaya, who made claims about "the origin of cells from noncellular matter", and 'taking the party line' helped his career . In 1970, he was elected President of the International Society for the Study of the Origins of Life. On his passing on April 21, 1980, he was interred in Novodevichy Cemetery in Moscow.
Oparin became Hero of Socialist Labour in 1969, received the Lenin Prize in 1974 and was awarded the Lomonosov Gold Medal in 1979 "for outstanding achievements in biochemistry". He was also awarded five Orders of Lenin.
Theory of the origin of life
Oparin sometimes is called "Darwin of the 20th century." Although he began by reviewing the various panspermia theories, he was primarily interested in how life initially began. As early as 1922, he asserted the following tenets:
1. There is no fundamental difference between a living organism and lifeless matter. The complex combination of manifestations and properties so characteristic of life must have arisen in the process of the evolution of matter.
2. Taking into account the recent discovery of methane in the atmospheres of Jupiter and the other giant planets, Oparin postulated that the infant Earth had possessed a strongly reducing atmosphere, containing methane, ammonia, hydrogen, and water vapor. In his opinion, these were the raw materials for the evolution of life.
3. At first there were the simple solutions of organic substances, the behavior of which was governed by the properties of their component atoms and the arrangement of those atoms in the molecular structure. But gradually, as the result of growth and increased complexity of the molecules, new properties have come into being and a new colloidal-chemical order was imposed on the more simple organic chemical relations. These newer properties were determined by the spatial arrangement and mutual relationship of the molecules.
4. In this process biological orderliness already comes into prominence. Competition, speed of growth, struggle for existence and, finally, natural selection determined such a form of material organization which is characteristic of living things of the present time.
Oparin outlined a way in which basic organic chemicals might form into microscopic localized systems - possible precursors of cells - from which primitive living things could develop. He cited the work done by de Jong on coacervates and other experimental studies, including his own, into organic chemicals which, in solution, may spontaneously form droplets and layers. Oparin suggested that different types of coacervates might have formed in the Earth's primordial ocean and, subsequently, been subject to a selection process leading eventually to life.
While Oparin himself was unable to do extensive experiments to investigate any of these ideas, scientists were later able to. In 1953, for example, Stanley Miller performed what is perhaps the first experiment to investigate whether chemical self-organization would have been possible on the early earth. He showed that from a mixture of several simple components of a reducing atmosphere, with the input only of heat (to provide reflux) and electrial energy (sparks, to simulate lightning), a variety of familiar organic compounds such as amino acids were synthesised within a fairly short space of time. The compounds that formed were somewhat more complex than the molecules that were present at the beginning of the experiment.
Bibliography and references
|This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Alexander_Oparin". A list of authors is available in Wikipedia.|