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Muriel Wheldale, a distinguished graduate of Newnham College, Cambridge, was a member of William Bateson's school of genetics at Cambridge University from 1903. Her investigation of flower color inheritance in snapdragons (Antirrhinum), a topic of particular interest to botanists, contributed to establishing Mendelism as a powerful new tool in studying heredity. Her understanding of the genetics of pigment formation led her to do cutting-edge work in biochemistry, culminating in the publication of her landmark work, The Anthocyanin Pigments of Plants (1916). (...) |
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The concept of mechanism is analyzed in terms of entities and activities, organized such that they are productive of regular changes. Examples show how mechanisms work in neurobiology and molecular biology. Thinking in terms of mechanisms provides a new framework for addressing many traditional philosophical issues: causality, laws, explanation, reduction, and scientific change. |
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This article examines to what extent a particular case of cross-disciplinary research in the 1930s was structured by mechanistic reasoning. For this purpose, it identifies the interfield theories that allowed biologists and chemists to use each other’s techniques and findings, and that provided the basis for the experiments performed to identify plant growth hormones and to learn more about their role in the mechanism of plant growth. In 1930, chemists and biologists in Utrecht and Pasadena began to cooperatively study plant (...) |
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In the years 1919 to 1923, Otto Warburg published four papers that were to revolutionise the field of photosynthesis. In these articles, he introduced a number of new techniques to measure the rate of photosynthesis, put forward a new model of the mechanism and added a completely new perspective to the topic by attempting to establish the process’s efficiency in terms of the light quantum requirement. In this paper I trace the roots of Warburg’s series of contributions to photosynthesis research (...) |
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If the work carried out to gain a detailed understanding of the process of photosynthesis, and probably other types of bioenergetic conversions as well, fulfills the criteria of a molecular biology, and if the groups funding this research and those who worked in the laboratory regarded it as such, why has it been necessary for me to argue here that bioenergetics should always have been counted as part of - indeed, may have been in the forefront in establishing — the (...) |
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The biologist Jacques Loeb (1859-1924) helped to shape the practice of modern biological research through his radical emphasis on reductionist experimentation. This biography traces his career and convincingly argues that Loeb's desire to control organisms, manifested in studies of both reproduction and animal behavior, contributed to a new self-image for biologists. The author places Loeb's experiments and the controversies they generated in their intellectual and institutional contexts, tracing his influence on the development of behaviorism, genetics, and reproductive biology. |
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This paper addresses theoretical challenges, still relevant today, that arose in the first decades of the twentieth century related to the concept of the organism. During this period, new insights into the plasticity and robustness of organisms as well as their complex interactions fueled calls, especially in the UK and in the German-speaking world, for grounding biological theory on the concept of the organism. This new organism-centered biology understood organisms as the most important explanatory and methodological unit in biological investigations. (...) |
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An analysis of two heuristic strategies for the development of mechanistic models, illustrated with historical examples from the life sciences. In Discovering Complexity, William Bechtel and Robert Richardson examine two heuristics that guided the development of mechanistic models in the life sciences: decomposition and localization. Drawing on historical cases from disciplines including cell biology, cognitive neuroscience, and genetics, they identify a number of "choice points" that life scientists confront in developing mechanistic explanations and show how different choices result in divergent (...) |
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In the 1930s Warburg's spare prose and disciplined respect for the facts set the style for a new generation of biochemists who had not known the conceptual revolutions of earlier years. Led by Warburg, they rejected the excesses of the colloid school and the false starts of the teens and twenties. Talk of active structure virtually disappeared as chemists began to identify enzymes, coenzymes, vitamins, and hormones. In the gradual transformation of the Atmungsferment from an ironcolloid complex to a specific (...) |
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In this fascinating study, the author analyzes the conceptual roots of molecular biology and the social matrix in which it was developed. |
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Historians and philosophers of twentieth-century life sciences have demonstrated that the choice of experimental organism can profoundly influence research fields, in ways that sometimes undermined the scientists’ original intentions. The present paper aims to enrich and broaden the scope of this literature by analysing the career of unicellular green algae of the genus Chlorella. They were introduced for the study of photosynthesis in 1919 by the German cell physiologist Otto H. Warburg, and they became the favourite research objects in this (...) |
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The Dutch microbiologist/biochemist Albert Jan Kluyver was an early proponent of the idea of biochemical unity, and how that concept might be demonstrated through the careful study of microbial life. The fundamental relatedness of living systems is an obvious correlate of the theory of evolution, and modern attempts to construct phylogenetic schemes support this relatedness through comparison of genomes. The approach of Kluyver and his scientific descendants predated the tools of modern molecular biology by decades. Kluyver himself is poorly recognized (...) |
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