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Hermann Joseph Muller
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Hermann Joseph Muller |
Hermann Joseph Muller
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Scientist:
Hermann Joseph Muller |
American geneticist (1890–1967)
Born in New York City, Muller was awarded a scholarship to Columbia University in 1907 and specialized in heredity during his undergraduate studies. On graduation he took up a teaching fellowship in physiology at Cornell Medical School, gaining his master's degree in 1912 for research on the transmission of nerve impulses. During this period he continued working at Columbia in his spare time, contributing to the genetic researches on Drosophila fruit flies. He was employed officially at Columbia in 1912 and received his PhD in 1916 for his now classic studies on the crossing over of chromosomes. He was also a coauthor of The Mechanism of Mendelian Heredity (1915), a fundamental contribution to classical genetics.
In 1915, at the request of Julian Huxley, Muller moved to the Rice Institute, Houston, Texas, where he began studying mutation. By 1918 he had found evidence that raising the temperature increases mutation rate. In 1920, after a brief spell back at Columbia, he joined the University of Texas as an associate professor, becoming a professor in 1925. In 1926 he found that x-rays induce mutations, a discovery for which he eventually received the 1946 Nobel Prize for physiology or medicine.
In 1933 Muller spent the first of eight years in Europe at the Institute for Brain Research, Berlin. Hitler's rise to power forced him to leave Germany and he moved to the Academy of Sciences, Leningrad, at the invitation of Nikolai Vavilov. Muller believed that in a communist state he would be able to develop his own socialist ideas and apply his research to improve the human condition. However, the advent of Lysenkoism effectively hampered most genetic research in Russia and Muller left, volunteering to serve in the Spanish Civil War. He then worked at the Institute of Animal Genetics, Edinburgh, returning to America in 1940. He held a position at Amherst College, Massachusetts, from 1942 until 1945, when he became professor of zoology at Indiana University, remaining there for the rest of his life.
Muller made important theoretical contributions to genetics. He visualized the gene as the origin of life, because only genes can replicate themselves, and he believed all selection and therefore evolution acted at the level of the gene. He worried about the increasing number of mutations accumulating in human populations, which can survive because of modern medical technology, and proposed a program of eugenics to overcome the problem. He fully realized the harm to human chromosomes that can result from ionizing radiation and campaigned against excessive use of x-rays in medicine, careless handling of nuclear fuels, and testing of atomic bombs.
Muller is seen by many as the most influential geneticist of the 20th century, mainly through his appreciation of genetic mutation as fundamental to future genetic research. He published over 350 works, the most important paper being Artificial Transmutation of the Gene (1927).
Genetics Encyclopedia:
Hermann Muller |
Geneticist 1890-1967
Hermann Joseph Muller was one of the founding members of the "fly lab" that was initiated by Thomas Hunt Morgan. In the early part of the twentieth century, this lab was the center of important research into the role of chromosomes in inheritance, using the fruit fly Drosophila as a model organism in experiments. The major members included Morgan, Alfred Henry Sturtevant, Calvin Blackman Bridges, and Muller, all working at Columbia University around 1910 to 1915, when their major contributions to classical genetics were carried out. Muller was the only one of Morgan's students to also win a Nobel Prize.
Muller's career was unusual in that he worked in several countries. He was a third-generation American, but he left the United States in 1932 to work in Germany, the Soviet Union, and Edinburgh, Scotland, before returning to his homeland. He had a productive career as an experimental and theoretical geneticist, but he also had a life-long interest in seeing genetics applied to society. This made him controversial and sometimes put his life in jeopardy.
The first phase of Muller's career was spent at Columbia, where the fly lab was established, and at Rice University, where he held his first tenured position from 1915 to 1922. During this phase he did work that contributed to the understanding of crossing over and gene mapping (discovered by Morgan and Sturtevant). Muller also clarified the meaning of genetic mutation by limiting the concept to variations in the individual gene. He proposed the gene as the basis of life, arguing that only genes had the property of replicating their errors, essential for the evolution of life. He was the first to measure mutation rates, and he designed stocks of Drosophila to detect them.
Muller's second phase was the decade he spent at the University of Texas, from 1922 to 1932. During this time he was heavily committed to the study of mutation, culminating in his Nobel Prize work on the induction of mutations by radiation. Muller rapidly followed up his initial reports and founded a new field of radiation genetics. He also used X rays as a tool to delete chromosomes, and used these small deleted chromosomes to reveal the mechanism of genetic functions such as dosage compensation, a phenomenon he was first to interpret. Muller showed that mutations are produced in proportion to radiation dosage and that chromosome rearrangements (such as translocations) were induced at higher dosages.
In his third phase, which ran from 1932 to 1940 and which he spent working in Berlin, the Soviet Union, and Scotland, Muller studied chromosome structure, gene structure, and changes in gene function when genes were moved from their normal chromosome location. He also introduced the idea that genes arise from preexisting genes, when he discovered that a fly mutation called Bar eyes arose from a physical duplication of genes. In his last phase, Muller was back in the United States (from 1940 to 1967), working mainly at Indiana University, where he worked out the mechanism of cell death from radiation exposure and calculated the amount of mutation normally occurring in humans (genetic load) each generation. He became a critic of the Cold War policies of the United States, favoring a strong nuclear defense as a protection against Stalinism but also calling for mutual treaties to limit nuclear arms. He also fought hard against the misuse of radiation by health practitioners and industry.
In addition to his fundamental work on fly genetics, Muller contributed to human genetics through studies of twins that he conducted in the 1920s. He argued that the relation of observable character traits to genes is very complex, a problem he had first studied in detail in Drosophila, when he investigated the verifiability of shape and size in the "truncate" and "beaded" wing mutations. Muller stressed that an observable trait such as intelligence or longevity will be influenced by many genes as well as by the environment, and that simple one-gene/one-trait relationships were the exception rather than the rule in complex organisms.
Muller felt that advocates of eugenics programs ignored environmental modifiers and the complex residual heredity that he called modifier genes. He denounced the American eugenics movement in 1932 at the Third (and last) International Congress of Eugenics. Yet he remained an idealist about eugenics, favoring a positive eugenics based on "germinal choice," a non-coercive way for educated people to choose the genetic character of their own children.
Bibliography
Carlson, Elof. The Gene: A Critical History. Philadelphia: Saunders Publishing Co.,1966.
Muller, Hermann J. "The Development of the Gene Theory." In Genetics in the Twentieth Century, L. C. Dunn, ed. New York: Macmillan, 1951.
Olby, Robert. The Path to the Double Helix. Seattle: University of Washington Press,1974.
—Elof Carlson
Biography:
Hermann Joseph Muller |
The American geneticist Hermann Joseph Muller (1890-1967) was the first to induce mutations in an organism by severe x-ray treatment.
Hermann J. Muller was born in New York City on Dec. 21, 1890. His father died before Hermann was 10 years old, but he had already been imbued by his father with a sense of the grandeur of evolution and a sympathy for oppressed people. After graduation from Morris High School in the Bronx, he entered Columbia University. After receiving a master's degree there in 1911, he continued his studies at the Medical School of Cornell University for a year, returning to Columbia University for his doctorate, which he received in 1916.
At Columbia University Muller came under the influence of Thomas Hunt Morgan, who had gathered together a group of young researchers to study genetic inheritance in fruit flies (Drosophila melanogaster). Muller worked with this group in 1910 and discovered a fly mutant which established the reality of the "M," or fourth, chromosome of the fruit fly. In 1915 Muller joined the biology department of Rice Institute, but 3 years later he returned to Columbia for 2 years of research and teaching. In 1920 he went to the University of Texas.
In 1926 Muller reported at the Sixth International Congress of Genetics in Berlin that he had succeeded in jolting the genes in the chromosomes of the fruit fly; that is, his x-rays had broken them apart and rearranged them, resulting in an increase in the mutation rate 150-fold. He had thus artificially accelerated the evolutionary process. Controlled mutation was now a fact, and overnight, at the age of 36, Muller became famous. For this classic experiment he was awarded the Nobel Prize in medicine in 1946. In 1945 Muller was called to Indiana University in Bloomington to become distinguished service professor of zoology. He remained there until his death.
Muller had a strong social awareness and believed that his own researches and the work of other scientists should be used to improve the genetic composition of mankind as well as the general living conditions of all people. He held that the ultimate objective of his own work was "the control of the evolution of man by man himself." After the severe depression that struck the United States in 1929, Muller, who had become sympathetic with some form of socialism, left Texas to work in Germany. But having seen the rise of Nazism, he went on to the Soviet Union in 1933. He was given a laboratory in the Institute of Genetics in Moscow, where he worked as senior geneticist for almost 4 years. However, Trofim Lysenko, who was violently opposed to the Morgan theory of the gene and preached the Lamarckian view of the inheritance of acquired characters, was able to win the political favor of Stalin, and his theory became the official doctrine of heredity in Russia. Those who taught and did research along the lines of Morgan's school of genetics were dismissed or harassed. Muller became disillusioned, left the country, and denounced Russian communism.
In 1955, together with Albert Einstein and other famous scientists, he signed an appeal to all countries to forswear war in view of the danger that the hydrogen bomb would threaten the health of future generations and even the existence of mankind. He campaigned vigorously against the use of nuclear bomb tests because of the harmful mutations that would result. Muller was also interested in the quality of man's life in the future and went so far as to urge the freezing of sperm of gifted men for use after their death in artificial insemination. He fought for the promotion of sperm banks, an idea that provoked bitter criticism.
Between 1955 and 1959 Muller served as president of the American Humanist Association and was president also of the newly launched American Society of Human Genetics. He was a member of many scientific societies as well as of the American Philosophical Society. Muller died of a heart ailment on April 5, 1967.
Further Reading
Muller's unpublished autobiographical notes, written in 1936, are now in the Lilly Rare Books Library of Indiana University. A popular account of his life and achievements is in Bernard Jaffe, Men of Science in America (1944; rev. ed. 1958).
Columbia Encyclopedia:
Hermann Joseph Muller |
Muller, Hermann Joseph (mŭl'ər), 1890-1967, American geneticist and educator, b. New York City, grad. Columbia (B.A., 1910; Ph.D., 1916). A student of Thomas Hunt Morgan, he taught (1915-18) at Rice Institute, Tex., at Columbia (1918-20), and at the Univ. of Texas from 1920 until he became senior geneticist (1933-37) of the Institute of Genetics in Moscow. In 1945 he became professor of zoology at Indiana Univ. His method for recognizing spontaneous gene mutation led to his discovery of a technique for artificially inducing mutations by means of X rays that has since had broad theoretical and practical application. For this discovery he was awarded the 1946 Nobel Prize in Physiology or Medicine. His writings include Out of the Night (1935), Genetics, Medicine, and Man (1947; written with others), and Studies in Genetics (1962). He also wrote articles on the biological effects of atomic radiation.
Wikipedia:
Hermann Joseph Muller |
For other persons of the same name, see Hermann Müller.
| Hermann Joseph Muller | |
|---|---|
| Born | December 21, 1890 New York City, New York, USA |
| Died | April 5, 1967 Indianapolis, Indiana, USA |
| Nationality | United States |
| Fields | Genetics, molecular biology |
| Doctoral advisor | Thomas Hunt Morgan |
| Doctoral students | H. Bentley Glass |
| Known for | The genetic effects of Radiation |
| Notable awards | 1946 Nobel Prize in Physiology or Medicine Linnean Society of London's Darwin-Wallace Medal (1958). 1963 Humanist of the Year (American Humanist Association) |
Hermann Joseph Muller (or H. J. Muller) (December 21, 1890 – April 5, 1967) was an American geneticist, educator, and Nobel laureate best known for his work on the physiological and genetic effects of radiation (X-ray mutagenesis) as well as his outspoken political beliefs. Muller frequently warned of the long-term dangers of radioactive fallout from nuclear war and nuclear testing, helping to raise public awareness in this area.[1] He was also the discoverer of irreducible complexity,[2] which has been an argument of creationism against the theory of evolution since Darwin's Black Box, a controversial book by Michael Behe. He did not find any contradictions between IC and evolution, but described the phenomenon as the result of evolution.
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Contents
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Biography
Early life
Muller was born in New York City and excelled in the public schools. As an adolescent, he attended a Unitarian church and considered himself a pantheist; in high school he became an atheist. At 16 he entered Columbia College. From his first semester he was interested in biology; he became an early convert of the Mendelian-chromosome theory of heredity — and the concept of genetic mutations and natural selection as the basis for evolution. He formed a Biology Club and also became a proponent of eugenics; the connections between biology and society would be his perennial concern. Muller earned a B.A. degree in 1910.[3]
Muller remained at Columbia (the pre-eminent American zoology program at the time, thanks to E. B. Wilson and his students) for graduate school. He became interested in the Drosophila genetics work of Thomas Hunt Morgan's fly lab after undergraduate bottle washers Alfred Sturtevant and Calvin Bridges joined his Biology Club. In 1911-1912, he studied metabolism at Cornell University, but remained involved with Columbia. He followed the drosophilists as the first genetic maps emerged from Morgan's experiments, and joined Morgan's group in 1912 (after two years of informal participation).[4]
In the fly group, Muller's contributions were primarily theoretical: explanations for experimental results and ideas and predictions for new experiments. In the emerging collaborative culture of the drosophilists, however, credit was assigned based on results rather than ideas; Muller felt cheated when he was left out of major publications.[5]
Career
In 1914, Julian Huxley offered Muller a position at the recently founded William Marsh Rice Institute, now Rice University; he hurried to complete his Ph.D. degree and moved to Houston for the beginning of the 1915-1916 academic year (his degree was issued in 1916). At Rice, Muller taught biology and continued Drosophila lab work. In 1918, he proposed an explanation for the dramatic discontinuous alterations in Oenothera larmarckiana that were the basis of Hugo de Vries's theory of mutationism: "balanced lethals" allowed the accumulation of recessive mutations, and rare crossing over events resulted in the sudden expression of these hidden traits. In other words, de Vries's experiments were explainable by the Mendelian-chromosome theory. Muller's work was increasingly focused on mutation rate and lethal mutations. In 1918, Morgan—short-handed because many of his students and assistants were drafted for the U.S. entry into World War I—convinced Muller to return to Columbia to teach and to expand his experimental program.[6]
At Columbia, Muller and his collaborator and longtime friend Edgar Altenburg continued the investigation of lethal mutations. The primary method for detecting such mutations was to measure the sex ratios of the offspring of female flies. They predicted the ratio would vary from 1:1 due to recessive mutations on the X chromosome, which would only be expressed in males (who lacked the functional allele on a second X chromosome). Muller found a strong temperature dependence in mutation rate, leading him to believe that spontaneous mutation was the dominant mode (and to initially discount the role of external factors such as ionizing radiation or chemical agents). In 1920, Muller and Altenburg coauthored a seminal paper in Genetics on "modifier genes" that determine the size of mutant Drosophila wings. In 1919, Muller made the important discovery of a mutant (later found to be a chromosomal inversion) that appeared to suppress crossing-over, which opened up new avenues in mutation rate studies. However, his appointment at Columbia was not continued; he accepted an offer from the University of Texas and left Columbia after the summer of 1920.[7]
Muller taught at The University of Texas from 1920 until 1932. Soon after returning to Texas, he married mathematics professor Jesse Marie Jacobs, whom he had courted previously. In his early years at Texas, Muller's Drosophila work was slow going; the data from his mutation rate studies were difficult to interpret. In 1923, he began using radium and X-rays, but the relationship between radiation and mutation was difficult to measure because such radiation also sterilized the flies. In this period, he became more involved with eugenics and human genetics. He carried out a study of twins separated at birth that seemed to indicate a strong hereditary component to I.Q. Muller was critical of the new directions of the eugenics movement (such as anti-immigration), but was hopeful about the prospects for positive eugenics.[8]
Discovery of X-ray mutagenesis
1926 marked the beginning of a series of major breakthroughs. Beginning in November, Muller carried out two experiments with varied doses of X-rays, the second of which used the crossing over suppressor stock ("ClB") he had found in 1919. A clear, quantitative connection between radiation and lethal mutations quickly emerged. Muller's discovery created a media sensation after he delivered a paper entitled "The Problem of Genetic Modification" at the Fifth International Congress of Genetics in Berlin; it would make him one of the better known public intellectuals of the early 20th century. By 1928, others had replicated his dramatic results, expanding them to other model organisms such as wasps and maize. In the following years, he began publicizing the likely dangers of radiation exposure in humans (such as physicians who frequently operate X-ray equipment).[9]
His lab grew quickly, but it shrunk again following the onset of the Great Depression. Especially after the stock market crash, Muller was increasingly pessimistic about the prospects of capitalism. Some of his visiting lab members were from the USSR, and he helped edit and distribute an illegal leftist student newspaper, The Spark. It was a difficult period for Muller both scientifically and personally: his marriage was falling apart, and he was increasingly dissatisfied with his life in Texas. Meanwhile, the waning of the eugenics movement, ironically hastened by his own work pointing to the previously ignored connections between environment and genetics, meant that his ideas on the future of human evolution had reduced impact in the public sphere.[10]
Work in Europe
In September 1932, Muller moved to Berlin to work with the Russian expatriate geneticist Nikolay Timofeeff-Ressovsky; a trip intended as a limited sabbatical stretched into an eight year, five country journey. In Berlin, he met two physicists who would later be significant to the biology community: Niels Bohr and Max Delbrück. The Nazi movement was precipitating the rapid emigration of scientific talent from Germany, and Muller was particularly opposed to the politics of National Socialism. But the FBI was investigating Muller because of his involvement with The Spark, so he chose instead to go to the Soviet Union (an environment better suited to his political beliefs). In 1933, Muller and his wife reconciled, and she and their son David E. Muller moved with Hermann to Leningrad. There, at the Institute of Genetics, he imported the basic equipment for a Drosophila lab—including the flies—and set up shop. The Institute was moved to Moscow in 1934, and Muller and his wife were divorced in 1935.[11]
In the USSR, Muller supervised a large and productive lab, and organized work on medical genetics. Most of his work involved further explorations of genetics and radiation. There he completed his eugenics book, Out of the Night. By 1936, however, Stalin's repressive policies and the rise of Lysenkoism was making the USSR an increasingly problematic place to live and work. Muller and much of the Russian genetics community did what they could to oppose Trofim Lysenko and his Larmarckian evolutionary theory, but Muller was soon forced to leave the Soviet Union after Stalin read a translation of his eugenics book and was "displeased by it, and...ordered an attack prepared against it."[12]
Muller—with about 250 strains of Drosophila—moved to Edinburgh in September 1937, after a brief stay in Madrid and Paris. In 1938, with war on the horizon, he began looking for a permanent position back in the United States. He also began courting Dorothea "Thea" Kantorowicz, a German refugee; they were married in May 1939. The Seventh International Congress on Genetics was held in Edinburgh later that year; Muller wrote a "Geneticists' Manifesto" in response to the question: "How could the world's population be improved most effectively genetically?" He also engaged in a debate with the perennial genetics gadfly Richard Goldschmidt over the existence of the gene, for which there remained little direct physical evidence.[13]
Later career
When Muller returned to the United States in 1940, he took an untenured research position at Amherst College, in the department of Otto Glaser. After the U.S. entry into World War II, his position was extended indefinitely and expanded to include teaching. His Drosophila work in this period focused on measuring the rate of spontaneous (as opposed to radiation-induced) mutations. Muller's publication rate decreased significantly in this period, from a combination of lack of lab workers and experimentally challenging projects. However, he also worked as an adviser to the Manhattan Project (though he did not know that was what it was), as well as a study of the mutational effects of radar. Muller's appointment was ended after the 1944-1945 academic year, and despite difficulties stemming from his socialist political activities, he found a position as professor of zoology at Indiana University.[14]
In 1946, Muller was awarded the 1946 Nobel Prize in Physiology or Medicine, "for the discovery that mutations can be induced by x-rays". Genetics, and especially the physical and physiological nature of the gene, was becoming a central topic in biology, and x-ray mutagenesis was a key to many recent advances—among them, George Beadle and Edward Tatum's work on Neurospora that established the one gene-one enzyme hypothesis.[15]
The Nobel Prize, in the wake of the atomic bombings of Hiroshima and Nagasaki, focused public attention on a subject Muller had been publicizing for two decades: the dangers of radiation. In 1952, nuclear fallout became a public issue; since Operation Crossroads, more and more evidence had been leaking out about radiation sickness and death caused by nuclear testing, and Muller was one of the foremost experts. Muller—and many other scientists—pursued an array of political activities to defuse the threat of nuclear war. With the Castle Bravo fallout controversy in 1954, the issue became even more urgent. In 1955 Muller was one of eleven prominent intellectuals to sign the Russell-Einstein Manifesto, the upshot of which was the first Pugwash Conference on Science and World Affairs in 1957, which addressed the control of nuclear weapons.[16][1] He was a signatory (with many other scientists) of the 1958 petition to the United Nations, calling for an end to nuclear weapons testing, which was initiated by the Nobel Prize-winning chemist Linus Pauling.[1]
He was awarded the Linnean Society of London's prestigious Darwin-Wallace Medal in 1958.
H. J. Muller and science fiction writer Ursula Le Guin were second cousins; his father (Hermann J. Muller Sr.) and her father's mother (Johanna Muller Kroeber) were siblings, the children of Nicholas Müller who immigrated to the United States in 1848. Another cousin was Herbert J. Muller, whose grandfather Otto was another son of Nicholas and a sibling of Hermann Sr. and Johanna.[17]
Personal life
Muller is survived by his daughter, Helen J. Muller, now an Emeritus professor at the University of New Mexico. His son, David E. Muller, an Emeritus professor of mathematics at the University of Illinois and at New Mexico State University, died in 2008 in Las Cruces, NM. Dorothea Kantorowicz Muller was Helen Muller's mother, and Jessie Jacobs Muller Offermann was David Muller's mother. David E. Muller was the inventor of the Muller C-element, a device used to implement asynchronous circuitry in electronic computers.
Former graduate students
- H. Bentley Glass
- C.P. Oliver
- Wilson Stone
- Elof Axel Carlson
- Seymour Abrahamson
- William Edgar Trout III
- Dale Eugene Wagoner
- Sara Helen Frye
- Abraham P. Schalet
- Irwin I. Oster
- Former post-doctoral fellows
- Worked in lab as undergraduates
- Carl Sagan
- Margaret Edmondson
- List of Personnel who worked in his lab in Indiana
Bibliography
- Herman Joseph Muller, Modern Concept of Nature (SUNY Press, 1973). ISBN 0-87395-096-8
- Herman Joseph Muller, Man's Future Birthright (SUNY Press, 1973). ISBN 0-87395-097-6
See also
Notes
- ^ a b c John Bellamy Foster (2009). The Ecological Revolution: Making Peace with the Planet, Monthly Review Press, New York, pp. 71-72.
- ^ Genetic variability, twin hybrids and constant hybrids, in a case of balanced lethal factors, pp 463-464
- ^ Carlson, Genes, Radiation, and Society, pp 17-37
- ^ Carlson, Genes, Radiation, and Society, pp 37-69
- ^ Carlson, Genes, Radiation, and Society, pp 70-90; for more on the culture and norms of the fly lab, see Lords of the Fly: Drosophila Genetics and the Experimental Life, by Robert E. Kohler (University of Chicago Press, 1994).
- ^ Carlson, Genes, Radiation, and Society, pp 91-108
- ^ Carlson, Genes, Radiation, and Society, pp 109-119
- ^ Carlson, Genes, Radiation, and Society, pp 120-140
- ^ Carlson, Genes, Radiation, and Society, pp 141-164
- ^ Carlson, Genes, Radiation, and Society, pp 165-183
- ^ Carlson, Genes, Radiation, and Society, pp 184-203
- ^ Carlson, Genes, Radiation, and Society, pp 204-234; quotation from p 233, correspondence from Muller to Julian Huxley, March 9, 1937
- ^ Carlson, Genes, Radiation, and Society, pp 235-273
- ^ Carlson, Genes, Radiation, and Society, pp 274-288
- ^ Carlson, Genes, Radiation, and Society, pp 304-318
- ^ Carlson, Genes, Radiation, and Society, pp 336-379.
- ^ Carlson, Genes, Radiation, and Society, pp 10-11
References
- Elof Axel Carlson, Genes, radiation, and society: the life and work of H.J. Muller (Ithaca, New York : Cornell University Press, 1981). ISBN 0-8014-1304-4
- Nobel Biography
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