Sir Hans Adolf Krebs

views updated May 21 2018

Sir Hans Adolf Krebs

The German-British biochemist Sir Hans Adolf Krebs (1900-1981) shared the Nobel Prize in Physiology or Medicine for his discovery of the citric, or tricarboxylic, acid cycle (Krebs cycle).

Hans A. Krebs, the son of Georg Krebs, an otolaryngologist, was born in Hildesheim, Germany, on April 25, 1900. He studied medicine at the universities of Göttingen, Freiburg im Breisgau, Munich, and Berlin, qualified in 1924, and in 1925 graduated as a doctor of medicine in the University of Hamburg. After a year's study of chemistry in Berlin, he was assistant to the biochemist Otto Warburg in Berlin-Dahlem from 1926 to 1930. Krebs then returned to university clinical work, first at Altona and then as assistant at the University Medical Clinic in Freiburg. In June of 1933 the Nazis terminated his appointment, and Sir Frederick Gowland Hopkins invited him to work, with a Rockefeller studentship, at the Biochemical Institute at Cambridge. In 1934 Krebs was appointed demonstrator of biochemistry at the University of Cambridge.

In 1935 Krebs went to the University of Sheffield as a lecturer in pharmacology. In 1938 he was appointed lecturer in biochemistry and director of the newly founded Institute of Biochemistry. In 1945 his appointment was upgraded to a professorship, and he was also director of a research unit of the Medical Research Council already established in his department. In 1954 he was appointed Whitley professor of biochemistry in the University of Oxford, and the Medical Research Council's research unit was transferred there. He was also elected a Fellow of Trinity College, Oxford.

The Ornithine Cycle

To keep organs and tissues alive for biochemical tests, they had been perfused with physiological salines as a substitute for blood. The results were often unsatisfactory. Early in his career Krebs devised the tissue-slice technique. The organ, rapidly removed after the death of the test animal, was cut into thin slices and kept in fresh saline for biochemical testing. He used this technique in his study of the synthesis of urea by the liver.

It was known that urea is produced in a liver undergoing autolysis, and in 1904 it was shown that the autolysis produces the amino acid arginine, which is acted on catalytically by the enzyme arginase to produce urea. In 1932 Krebs found that, when an amino acid is added to liver, ammonia is liberated and is converted approximately quantitatively into urea. All the amino acids tested gave this result except two. When ornithine was added, the urea production was 10 times the expected amount, and arginine also gave an excess yield of urea. He therefore suggested that ornithine reacted with added ammonia and carbon dioxide to form arginine. Under the action of arginase, the arginine was broken down to urea and ornithine. If ammonia was omitted, there was no appreciable formation of urea. Further, ornithine was not observed to disappear while, with added ammonia, the synthesis of urea was in progress. Krebs therefore concluded that the ornithine acted as a catalyst. Many other substances were tested, but the only one that acted like ornithine was citrulline, and he suggested that citrulline formed a stage midway between ornithine and arginine. His ornithine cycle is still regarded as a sound explanation of the synthesis of urea in the body.

The Citric Acid Cycle

Krebs then turned to the intermediary oxidation of carbohydrates. In 1935 Albert von Szent-Györgyi elucidated the sequence of oxidations of the C4-dicarboxylic acids as follows:

succinic acid→fumaric acid→malic acid→maoxaloacetic acid

He also showed that these reactions were at least in part catalytic. This was later proved, but the manner of action remained unknown. In 1936 C. Martius and F. Knoop showed that in biological material citrate yields alphaketoglutarate on oxidation. They further suggested that the intermediate products were cis -aconitic acid, isocitric acid, and oxalosuccinic acid. It was already known that alpha-ketoglutarate forms succinate. In 1937, when Krebs started his work, the following sequence of reactions was therefore known:

citric acid→cis -aconitic acid→iso-citric acid→oxalosuccinic acid→alpha-ketoglutamic acid→succinic acid→fumaric acid→malic acid→oxaloacetic acid

Krebs and W. A. Johnson found that citrate was not only rapidly broken down in muscle but was also readily formed provided that oxaloacetate was added. The assumption was that some of the oxaloacetate was broken down to pyruvate or acetate and that the formation of citrate was due to a combination of the remaining oxaloacetate with pyruvate or acetate. But pyruvate or acetate could be derived from carbohydrate. In 1937 Krebs conceived the whole process as a cycle in which an undefined derivative of pyruvate, resulting from the breakdown of carbohydrate, condensed with oxaloacetate to form citric acid. The citric acid then passed through the changes noted above until oxaloacetic acid was regenerated, and the cycle was repeated. The full cycle is therefore as follows:

citric acid→cis -aconitic acid→iso-citric acid→oxalosuccinic acid→alpha-ketoglutamic acid→succinic acid→fumaric acid→malic acid→oxaloacetic acid+pyruvic acid→citric acid

Since Krebs originally described this cycle, he and others did further work on it. In 1950 Fritz Lipmann showed that the derivative of pyruvic acid that combines with oxaloacetate to form citrate is acetyl-coenzyme A and that this coenzyme is also active at two other points in the cycle. It was shown that acetyl-coenzyme A, in addition to its formation from carbohydrate, is also formed from fatty acids and many amino acids. The Krebs cycle is therefore a most important concept of biochemistry. Krebs shared with Lipmann the Nobel Prize in Physiology or Medicine in 1953.

Among Krebs's other important contributions to biochemistry were his studies of the synthesis of glutamine in brain tissue under the influence of the enzyme glutaminase (1935), the passage of ions across cell membranes (1950), and the effect of primitive intrinsic regulating mechanisms in controlling the metabolism of metazoan cells (1957).

Later Life

In 1967 Krebs, having reached Oxford's mandatory retirement age of 67, retired from his Oxford chair and from his fellowship. He refused to stop researching, however. He was thereupon appointed a research scientist in the Nuffield Department of Clinical Medicine at Oxford and was elected a Supernumerary Fellow of St. Cross College. He was also appointed a visiting professor at the Royal Free Hospital School of Medicine in the University of London. Krebs died at Oxford in 1981 at the age of 81.

Krebs received many honors in addition to his Nobel Prize. In 1947 he was elected a Fellow of the Royal Society, and he was awarded its Royal (1954) and Copley (1961) Medals. He delivered its Croonian Lecture in 1963. He was a member of many foreign scientific societies, and he held honorary doctorates from 14 universities. He received the Gold Medal of the Royal Society of Medicine in 1965, and he was knighted in 1958.

Further Reading

There is a biography of Krebs in Nobel Lectures, Physiology or Medicine, 1942-1962 (1964), which also contains his Nobel Lecture. The Krebs cycle is discussed in all textbooks of biochemistry, such as A. White, P. Handler, and E. L. Smith, Principles of Biochemistry (3d ed. 1964), and E. Baldwin, Dynamic Aspects of Biochemistry (4th ed. 1963). A thorough two-volume chronicle of Krebs's life and work is Frederic Lawrence Holmes, Hans Krebs: Architect of Intermediary Metabolism (1993). □

Krebs, Sir Hans Adolf

views updated Jun 08 2018

KREBS, SIR HANS ADOLF

KREBS, SIR HANS ADOLF (1900–1981), British biochemist and Nobel Prize winner. Krebs was born in Hildesheim, Germany, and pursued research with Otto Heinrich *Warburg at the Kaiser Wilhelm Institute for Biology in Berlin for four years, subsequently working at Professor Thannhauser's clinic at Freiburg. He worked out the cyclic process for urea synthesis in the liver. Forced to leave Germany with the advent of Hitler, Krebs became a research fellow in the department of biochemistry at Cambridge. In 1935 he joined Sheffield University, where he became professor of biochemistry in 1945. In 1954 he was appointed professor of biochemistry at Oxford University. In 1953 Krebs received the Nobel Prize for medicine and physiology (which he shared with Fritz *Lipmann) for his discovery of the citric acid cycle. This is the sequence of processes by which foodstuffs are converted in the living cell into carbon dioxide, water, and energy. The "Krebs cycle" was first elucidated for pigeon-breast muscle, but is known to apply to most living cells of aerobic organisms. Krebs was elected a Fellow of the Royal Society in 1947 and was knighted in 1958.

bibliography:

T.N. Levitan, The Laureates: Jewish Winners of the Nobel Prize (1960), 169–72.

[Samuel Aaron Miller]

Krebs, Sir Hans Adolf

views updated May 11 2018

Krebs, Sir Hans Adolf (1900–81) British biochemist, b. Germany. In 1953 he shared (with F. A. Lipmann) the Nobel Prize for physiology or medicine for his discovery of the Krebs (or citric acid) cycle, the process that results in the production of energy in living organisms (respiration).

Krebs, Sir Hans Adolf

views updated May 09 2018

Krebs, Sir Hans Adolf (1900–81) German-born British biochemist, who emigrated to Britain in 1933, working at Sheffield University before moving to Oxford in 1954. Krebs is best known for the Krebs cycle, the basis of which he discovered in 1937. Details were later added by Fritz Lipmann (1899–1986), with whom Krebs shared the 1953 Nobel Prize for physiology or medicine.

Krebs, Sir Hans Adolf

views updated May 11 2018

Krebs, Sir Hans Adolf (1900–1981) German‐born biochemist; elucidated the pathways of urea synthesis (1932) and the citric acid cycle as the major pathway of intermediary metabolism (1937); performed first studies of requirements for vitamins A and C; Nobel Prize 1953.

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