I attempt to characterize the relationship of classical experimental embryology (CEE) and molecular developmental biology and compare it to the much-discussed case of classical genetics. These sciences are treated here as discovery practices rather than as definitive forms of knowledge. I first show that CEE had some causal knowledge and hence was able to answer specific why?-questions. A paradigm was provided by the case of eye induction, perhaps CEE’s greatest success. The case of the famous Spemann-Mangold organizer is (...) more difficult. I argue that before the advent of molecular biology, knowledge of its causal role in development was very limited. As a result, there was no functional definition of the concept of organizer. I argue that, like the classical gene concept, it is best viewed as an operational concept. This means that an account of reduction such as Kim’s functional reduction, which is still a mainstay in scientific metaphysics, cannot work in these cases. Nonetheless, again like in the classical gene case, the operational concepts of CEE played an important heuristic role in the discovery of molecules involved in morphogenesis and cell differentiation. This was made possible by what I call inter-level investigative practices. These are practices that combine experimental manipulations targeting two (or more) different levels. I conclude that the two sciences are more closely related via their experimental practices than by any inter-level explanatory relations. (shrink)

In the 1950s, embryology in socialist China underwent a series of changes that adjusted the disciplinary apparatus to suit socialism and the national goal of self-reliance. As the Communist state called on scientists to learn from the Soviets, embryologists’ comprehensive view on heredity, which did not contradict Trofim Lysenko (1898–1976)’s doctrines, provided a space for them to advance their discipline. Leading scientists, often trained abroad in the tradition of experimental embryology, rode on the tides of Maoist ideology (...) and repositioned their research. Some of their creative realignment of previous research questions, materials, and traditions to Marxist philosophy and agricultural objectives generated productive programs. In particular, Tong Dizhou (1902–1979) translated Engels’s dialectics of nature into a research question about cytoplasmic inheritance. His continuing investigation on it led to the first goldfish “clone” through a nuclear transplantation experiment; Zhu Xi and his associates transferred a goldfish model in embryology into studies on improving carp aquaculture, leading to a rare success in the Great Leap Forward of 1958. These directions for embryology continued well into the 1960s. At a time when global embryology was diversifying and began to be molecularized, eventually forming “developmental biology,” socialist embryology took shape in China with a different set of epistemic and practical commitments. The history of its development challenges and enriches our understanding of the concrete process of change in one discipline under Mao, showing ways in which scientists creatively adapted state-sanctioned ideologies and visions to do productive work outside the framework of molecular biology during the Cold War. (shrink)

In the 1950s, embryology in socialist China underwent a series of changes that adjusted the disciplinary apparatus to suit socialism and the national goal of self-reliance. As the Communist state called on scientists to learn from the Soviets, embryologists’ comprehensive view on heredity, which did not contradict Trofim Lysenko ’s doctrines, provided a space for them to advance their discipline. Leading scientists, often trained abroad in the tradition of experimental embryology, rode on the tides of Maoist ideology (...) and repositioned their research. Some of their creative realignment of previous research questions, materials, and traditions to Marxist philosophy and agricultural objectives generated productive programs. In particular, Tong Dizhou translated Engels’s dialectics of nature into a research question about cytoplasmic inheritance. His continuing investigation on it led to the first goldfish “clone” through a nuclear transplantation experiment; Zhu Xi and his associates transferred a goldfish model in embryology into studies on improving carp aquaculture, leading to a rare success in the Great Leap Forward of 1958. These directions for embryology continued well into the 1960s. At a time when global embryology was diversifying and began to be molecularized, eventually forming “developmental biology,” socialist embryology took shape in China with a different set of epistemic and practical commitments. The history of its development challenges and enriches our understanding of the concrete process of change in one discipline under Mao, showing ways in which scientists creatively adapted state-sanctioned ideologies and visions to do productive work outside the framework of molecular biology during the Cold War. (shrink)

The cliché of the clergymen or the religious scholars battling against modern science oversimplifies the history of the encounter between modern science and religion, especially in the case of non-Western societies. Many religious scholars, Muslim and Christian, not only did not oppose modern science but used it instrumentally to propagate their religions. Marwa Elshakry, in her brilliant study of Darwin's opinions among the Arab World, concentrates more on Arab Christians and Sunni Muslims rather than on Shiite Muslims. Muḥammad-Riḍā Iṣfahānī, a (...) Shiite clergyman educated in Islamic theology in Najaf, composed A Critique of Darwin's Philosophy in 1912 as a review of the theory of evolution. However, even before the publication of this book, controversy concerning this topic had been raging in the Arab World for decades. Under the influence of Muslim scholars (Sunni and Shiite) to reconcile modern science with Islam, Iṣfahānī did his best to gather knowledge of modern biology. He applied his self-taught knowledge of modern biology to find new solutions to the difficulties of establishing a dialogue between Islam and modern science. Thanks to the rationalism of his premodern scientific education, Iṣfahānī was more sympathetic towards science than many of his Arab counterparts and able to deeply engage in these debates. Iṣfahānī believed that the theory of evolution in nonhumans did not contradict Islamic discourse nor experimental and rational facts. Nevertheless, he denied the theory of human evolution as a nonscientific hypothesis. He justified his opinion through a detailed refutation of Darwin's heuristic evidence for human evolution in the first chapter of Descent of Man, such as the similarities between anatomy, embryology, and vestigial organs in humans and other animals. He also referred to other Western evolutionists of his time, such as Alfred Russel Wallace and Rudolf Virchow, who also rejected human evolution, and added some other scientific refutations of his own. Undoubtedly, Iṣfahānī's final aim was to demonstrate the possibility of reconciliation between religion in general, and Islam in particular, with modern science. This article provides a detailed consideration of Iṣfahānī's opinions, identifying his Arabic sources and comparing them to the original non-Arabic sources. I also examine the scientific details of Iṣfahānī's achievements and the roots of his misunderstandings. (shrink)

The Plymouth Laboratory of the Marine Biological Association of the United Kingdom (1884) was founded in 1888. In addition to conducting morphological and other biological research, the founders of the laboratory aimed at promoting research in experimental zoology which will be used in this paper as a synonym for e. g. experimental embryology, comparative physiology or general physiology. This dream was not fully realized until 1920. The Great War and its immediate aftermath had a positive impact on (...) the development of the Plymouth Laboratory. The war greatly upset the operation of the Zoological Station in Naples and the ensuing crisis in its operations was closely related to the establishment of the physiological department in Plymouth in 1920. Two other key factors in the Plymouth story were the establishment of the Development Fund in 1909, which began contributing funds to the Plymouth Laboratory in 1912, and the patronage of the Cambridge zoologist George P. Bidder (1863-1954). This paper will focus on the combined influence of the Development Fund and Bidder on the development of the Plymouth Laboratory from around 1902 through the early 1920s, and the important role the laboratory played in promoting experimental zoology in Britain in the 1920s. (shrink)

Much of the early history of developmental and physiological genetics in Germany remains to be written. Together with Carl Correns and Richard Goldschmidt, Alfred Kühn occupies a special place in this history. Trained as a zoologist in Freiburg im Breisgau, he set out to integrate physiology, development and genetics in a particular experimental system based on the flour moth Ephestia kühniella Zeller. This paper is meant to reconstruct the crucial steps in the experimental pathway that led Kühn and (...) his collaborators at the University of Göttingen, and later at the Kaiser Wilhelm Institutes of Biology and Biochemistry in Berlin, to formulate, in their specific way, what later became known as the "one gene-one enzyme hypothesis." Special attention will be given to the interaction of the different parts of Kühn's Ephestia-based project, which were rooted in different research traditions. The paper retraces how, roughly between 1925 and 1945, these elements came to form a mixed experimental setup composed of genetic, embryological, physiological and, finally, biochemical constituents. Accordingly, emphasis is laid on the development of the terminology in which the results were cast, and how it reflected the hybrid state of an experimental system successively acquiring new epistemic layers. (shrink)

Romantic Naturphilosophie has been at the centre of almost every account of early nineteenth-century sciences, be it as an obstacle or as an aid for scientific advancement. The following paper suggests a change of perspective. I seek to read Naturphilosophie as one manifestation among others of a more general concern with the question of how experience enables the subject to acquire knowledge about objects. To illustrate such an approach, I focus on Johannes Muller's early work. Here one finds two contrasting (...) images of microscopical observation, its set-up, and the observer: the embryological study of 1830 demands a 'philosophical grasp' of the appearances. In contrast, the investigations of blood of 1832 are presented as a series of controlled experiments. I argue that an interpretation of this contrast in terms of an appropriation and casting aside of Naturphilosophie is not altogether convincing. Instead, both images of microscopy are manifestations of a more general problem, namely, the problem of exactly how subject and object came together in experience. I show how this concern not only shaped the methodological sensibilities particular to Muller's embryology and the investigation of bodily liquids but also provided the epistemological principles and the target for his sense-physiological experiments. It bound Muller's work together with Naturphilosophie and linked Naturphilosophie with other contemporaneous projects in philosophy. All of these enterprises sought to contribute to ongoing debates about how experience allowed the subject to acquire knowledge about the world. (shrink)

The history of developmental biology is interwoven with debates as to whether mechanistic explanations of development are possible or whether alternative explanatory principles or even vital forces need to be assumed. In particular, the demonstrated ability of embryonic cells to tune their developmental fate precisely to their relative position and the overall size of the embryo was once thought to be inexplicable in mechanistic terms. Taking a causal perspective, this Element examines to what extent and how developmental biology, having turned (...) molecular about four decades ago, has been able to meet the vitalist challenge. It focuses not only on the nature of explanations but also on the usefulness of causal knowledge – including the knowledge of classical experimental embryology – for further scientific discovery. It also shows how this causal perspective allows us to understand the nature and significance of some key concepts, including organizer, signal and morphogen. This title is also available as Open Access on Cambridge Core. (shrink)

The Greenough stereomicroscope, or “Stemi” as it is colloquially known among microscopists, is a stereoscopic binocular instrument yielding three-dimensional depth perception when working with larger microscopic specimens. It has become ubiquitous in laboratory practice since its introduction by the unknown scientist Horatio Saltonstall Greenough in 1892. However, because it enabled new experimental practices rather than new knowledge, it has largely eluded historical and epistemological investigation, even though its design, production, and reception in the scientific community was inextricably connected to (...) the new epistemological ideals of the life sciences caught between natural history and modern science. The development of the microscope will be contextualized within the scientific and technological landscape, showing how Greenough navigated his way through this terrain, and what led him to sow the seeds for the stereoscopic microscope. The historical controversy over the optical mechanism, through which the instrument would generate the desired depth perception, and how this quality was embedded into laboratory practice, will be examined. Subsequently, it will become evident that the specific image of nature produced by the stereoscopic microscope corresponded to the new ideals of the life sciences and their representation. (shrink)

The Greenough stereomicroscope, or “Stemi” as it is colloquially known among microscopists, is a stereoscopic binocular instrument yielding three-dimensional depth perception when working with larger microscopic specimens. It has become ubiquitous in laboratory practice since its introduction by the unknown scientist Horatio Saltonstall Greenough in 1892. However, because it enabled new experimental practices rather than new knowledge, it has largely eluded historical and epistemological investigation, even though its design, production, and reception in the scientific community was inextricably connected to (...) the new epistemological ideals of the life sciences caught between natural history and modern science. The development of the microscope will be contextualized within the scientific and technological landscape, showing how Greenough navigated his way through this terrain, and what led him to sow the seeds for the stereoscopic microscope. The historical controversy over the optical mechanism, through which the instrument would generate the desired depth perception, and how this quality was embedded into laboratory practice, will be examined. Subsequently, it will become evident that the specific image of nature produced by the stereoscopic microscope corresponded to the new ideals of the life sciences and their representation. (shrink)

Evolutionary developmental biology (or developmental evolution) is in the middle stages of its “development.” Its early ontogeny cannot be traced back to fertilization but pivotal developmental events included Gould’s (1977) treatment of heterochrony, Riedl’s (1978) analysis of “burden”, the Dahlem conference of 1981, a British Society of Developmental Biologists Symposium, as well as books that incorporated developmental genetics into older comparative themes. A major inductive process began with the discovery of widespread phylogenetic conservation in homeobox-containing genes. One interpretation of these (...) early developmental dynamics holds that an increasingly prominent problem agenda (e.g., how do novel structures and functions originate?), inherited from long-standing research programs in comparative embryology, morphology, and paleontology, was handed a powerful set of experimental tools from the lineage of experimental embryology. This allowed for an experimental probing of development and its evolution in an unprecedented fashion. Although the relationship between evolution and development has exhibited a protracted and complex history, we are still in the process of comprehending these early stages of “modern” EvoDevo’s ontogeny. (shrink)

Although there are many historical and philosophical analyses of evolutionary developmental biology (EvoDevo), its development in the 1980s, when many individual or collective attempts to synthesize evolution and development were made, has not been examined in detail. This article focuses on some interdisciplinary studies during the 1980s and argues that they had important characteristics that previous historical and philosophical work has not recognized. First, we clarify how each set of studies from the 1980s integrated the results or approaches from different (...) biological fields, such as paleontology, developmental genetics, comparative morphology, experimental embryology, theoretical developmental biology, and population genetics. Second, after close examination we show that the interdisciplinary studies during the 1980s adopted different and conflicting views of genes, such as developmental-genetic, epigenetic, or population-genetic ones. We conclude that EvoDevo in the 1980s was a motley aggregation of various kinds of local integration. Finally, we discuss the implications of our analysis by comparing these early EvoDevo studies with those of the Modern Synthesis and with the present state of EvoDevo. (shrink)

Developmental biology is the science of explaining how a variety of interacting processes generate the heterogeneous shapes, size, and structural features of an organism as it develops rom embryo to adult, or more generally throughout its life cycle (Love, 2008b; Minelli, 2011a). Although it is commonplace in philosophy to associate sciences with theories such that the individuation of a science is dependent on a constitutive theory or group of models, it is uncommon to find presentations of developmental biology making reference (...) to a theory or theories of development. For example, in the third edition of Essential Developmental Biology (Slack, 2013), three families of approaches are described (developmental genetics, experimental embryology, and molecular and cell biology), and the appendix contains a catalogue of ‘key molecular components’ (genes, transcription factor, families, inducing factor families, cytoskeleton, cell adhesion molecules, and extracellular matrix components); however, no standard theory or group of models provides a theoretical scaffolding to the book nor is any mentioned. (shrink)

This article is concerned with the problem of the relation between the genetic information contained in the DNA and the emergence of visible structure in multicellular animals. The answer is sought in a reappraisal of the data of experimental embryology, considering molecular, cellular and organismal aspects. The presence of specific molecules only confers a tissue identity on the cells when their concentration exceeds the threshold of differentiation. When this condition is not fulfilled the activity of the genes that (...) code for the specific molecules in question only confers on them a histogenetic potency, i.e. the capacity to form the corresponding tissue in further development (or to transdifferentiate to that tissue). The progressive restriction of histogenetic potencies during development reflects the irreversible repression of more and more genes. The establishment of a given tissue identity under the influence of an inducing tissue (or a morphogenetic hormone) is only possible when the cells have acquired the competence to respond. Tissue differentiation proceeds progressively during development thanks to the cytoplasmic memory that cells retain collectively (or sometimes individually) of the items of information successively registered by their ancestors cells. The increasing complexity of visible structure emerging during development results only from the progression of tissue differentiation. This involves continual exchange of information among the cells and leads to (1) cell displacements and rearrangements, particularly during organogenesis and (2) extreme diversification of cell individualities within tissues, particularly during postembryonic growth. A mutation (just as a teratogenic factor) evokes an anomaly that is localized in both space and time because it alters a certain aspect of cell behaviour (particularly cell surface adhesiveness or mitotic activity) at the time when this is involved in the establishment of a particular structural trait. Neither the organization of the adult nor the modalities of development are encoded in the DNA. The automatic concatenation of cell interactions in the embryo and the structural amplification it entails is conditioned by the specific biochemical composition of the cytoplasm of the egg and by the heterogeneous distribution of its inclusions. (shrink)

In biology, the “field” concept is used in different ways. Therefore, its meaning in biology as compared to that in physics, and the relation between the conceptions of “gradient” and “field” are studied.In physics, scalar fields, vector fields and tensor fields are distinguished. In a scalar field, the variation of the scalar in space is expressed in form of a gradient. For the whole of a scalar field with its derived gradients the term “gradient-field” may be used.In biology, especially in (...) experimental embryology, the field concept is used both in a purely descriptive sense and as a means of causal analysis. To the first group belong the kinematic fields and growth fields. The kinematic field is a vector field; the growth field is generally a tensor field, but may be treated as a gradient-field in the most simple cases. In the causal analysis of development the gradient-field plays an important part, in the form of axial, superficial and spatial gradient-fields. In such a field by the combined action of the scalar and the gradients a great diversity of relations may occur. Probably, both the induction field and the organisation field belong to the class of gradient-fields. (shrink)

In biology, the “field” concept is used in different ways. Therefore, its meaning in biology as compared to that in physics, and the relation between the conceptions of “gradient” and “field” are studied.In physics, scalar fields, vector fields and tensor fields are distinguished. In a scalar field, the variation of the scalar in space is expressed in form of a gradient. For the whole of a scalar field with its derived gradients the term “gradient-field” may be used.In biology, especially in (...) experimental embryology, the field concept is used both in a purely descriptive sense and as a means of causal analysis. To the first group belong the kinematic fields and growth fields. The kinematic field is a vector field; the growth field is generally a tensor field, but may be treated as a gradient-field in the most simple cases. In the causal analysis of development the gradient-field plays an important part, in the form of axial, superficial and spatial gradient-fields. In such a field by the combined action of the scalar and the gradients a great diversity of relations may occur. Probably, both the induction field and the organisation field belong to the class of gradient-fields.Der Feldbegriff wird in der Biologie in sehr verschiedener Weise verwendet. Es wird daher versucht, das Wesen der „biologischen Felder” in Anlehnung an die Physik zu bestimmen, und das Verhältnis zwischen den Begriffen „Gradient” und „Feld” darzustellen.In der Physik unterscheidet man Skalarfelder, Vektorfelder und Tensorfelder. Im Skalarfeld lässt sich der Wechsel der Skalargrösse im Raume durch einen Gradienten darstellen. Für die Gesamtheit eines Skalarfeldes mit seinen abgeleiteten Gradienten wird der Ausdruck „Gradientfeld” vorgeschlagen.In der Biologie, im besonderen in der Entwicklungsmechanik, wird der Feldbegriff bald in rein-beschreibendem Sinne, bald als Mittel zur kausalen Analyse verwendet. Zur ersten Gruppe gehören das Bewegungsfeld und das Wachstumsfeld. Das Bewegungsfeld ist ein Vektorfeld; das Wachstumsfeld ist im allgemeinen ein Tensorfeld, kann aber im einfachsten Falle als ein Gradientfeld betrachtet werden. In der kausalen Analyse der Entwicklungserscheinungen spielt besonders das Gradientfeld eine grosse Rolle; dabei kann es sich um ein axiales, oberflächliches oder räumliches Gradientfeld handeln. Es wird darauf hingewiesen, dass in einem Gradientfelde durch das Zusammenwirken der Skalargrösse und des Gradienten eine grosse Mannigfaltigkeit der Beziehungen auftreten kann. Auch das Induktionsfeld und das Organisationsfeld gehören vermutlich zu den Gradientfeldern. (shrink)

The Marine Biological Laboratory in Woods Hole, MA provided opportunities for women to conduct research in the late 19th and early 20th century at a time when many barriers existed to their pursuit of a scientific career. One woman who benefited from the welcoming environment at the MBL was Mary Jane Hogue. Her remarkable career as an experimental biologist spanned over 55 years. Hogue was born into a Quaker family in 1883 and received her undergraduate degree from Goucher College. (...) She went to Germany to obtain an advanced degree, and her research at the University of Würzburg with Theodor Boveri resulted in her Ph.D.. Although her research interests included experimental embryology, and the use of tissue culture to study a variety of cell types, she is considered foremost a protozoologist. Her extraordinary demonstration of chromidia in the life history of a new species of Flabellula associated with diseased oyster beds is as important as it is ignored. We discuss Hogue’s career path and her science to highlight the importance of an informal network of teachers, research advisors, and other women scientists at the MBL all of whom contributed to her success as a woman scientist. (shrink)

The developmental history of the vertebrate eye begins at an early embryonic stage, with the formation of the body axes and induction of neural tissue. Several recent experimental embryological and genetic studies in teleost fish have produced new insights into the morphogenetic and molecular regulation of eye formation. Molecular signaling pathways and patterned expression of transcription factors implicated in eye determination are discussed, and the importance of morphogenetic cell movements is emphasized. BioEssays 24:519–529, 2002. © 2002 Wiley Periodicals, Inc.

This paper assesses a recent criticism of Michael Polanyi’s account of the origin of complex entities by Alicia Juarrero. According to Juarrero, Polanyi took higher-level complex entities like machines and organisms to come into existence through the imposition of external, top-down forces. This paper argues that while Polanyi took the emergence of machines to come about in such a way, Polanyi’s reading of 19th and early 20th-Century experimental embryology indicates his position is more sophisticated. Polanyi appears to have (...) thought a synthesis was possible between reductive-mechanical and holistic-vitalistic approaches in embryology and he appears to have relied on this synthesis in his account of the origin of complex organisms. While I argue that this synthesis is unclear, it suggests that Polanyi conceived of the emergence of organisms as the result of internal, complex, and non-deterministic processes. (shrink)

The history of centrifugation and the cell begins in the 1880s, with the history of experimental embryology. This scientific branch and cytology, had spectacular development in Germany, in the second half of the 19th century.During the period 1880-1900, cytologists discovered some of the particulate components of the cell cytoplasm : mitochondria, ergastoplasm end the Golgi apparatus. Today, these are known as the structural bases of life mechanisms and are called subcellular organites. Durin the same period, embryologists centrifuged eggs (...) of living marine organisms and observed several substances in the embryo. But they abandoned the project without identifying the substances in light of the cytologists'structures. This coincided with the disappearance of the structures from the concept of vital mechanism. The structures reappeared in the concept, only some decades later, when another model for studying cellular contents was developped, again by means of centrifugation. I show that the failure of the embryologists'model was not the only factor accounting for the lack of interest in the cytologists'structures and that the theoretical status of matter was probably the determinant factor. (shrink)

The discovery by Hans Spemann of the “organizer” tissue and its ability to induce the formation of the amphibian embryo's neural tube inspired leading embryologists to attempt to elucidate embryonic inductions’ underlying mechanism. Joseph Needham, who during the 1930s conducted research in biochemical embryology, proposed that embryonic induction is mediated by a specific chemical entity embedded in the inducing tissue, surmising that chemical to be a hormone of sterol-like structure. Along with embryologist Conrad H. Waddington, they conducted research aimed (...) at the isolation and functional characterization of the underlying agent. As historians clearly pointed out, embryologists came to question Needham's biochemical approach; he failed to locate the hormone he sought and eventually abandoned his quest. Yet, this study finds that the difficulties he ran into resulted primarily from the limited conditions for conducting his experiments at his institute. In addition, Needham's research reflected the interests of leading biochemists in hormone and cancer research, because it offered novel theoretical models and experimental methods for engaging with the function of the hormones and carcinogens they isolated. Needham and Waddington were deterred neither by the mounting challenges nor by the limited experimental infrastructure. Like their colleagues in hormone and cancer research, they anticipated difficulties in attempting to establish causal links between complex biological phenomena and simple chemical triggering. (shrink)

Achievements of Hans Driesch (1867–1941), German embryologist and philosopher, are contemporarily viewed almost exclusively from their later metaphysical phase of development, while his earlier scientific experimental researches are not appreciated sufficiently enough. They consisted in highlighting the specifically totipotential character of biological, and especially of embryological, processes what is still methodologically inspiring in many dimensions of contemporary biological investigations. The author postulates thus a deeper analysis of Driesch’s scientific accomplishments and broader assessment of their actual significance in contemporary biology.

Le but de cet ouvrage est de démontrer, à travers une reconstruction rationnelle des étapes historiques fondatrices de l'embryologie expérimentale, l'importance des concepts de préformation et d'épigenèse aux origines de cette discipline. L'analyse porte sur trois périodes charnières de l'histoire de l'embryologie : (1) la réforme mécaniste et darwinienne de l'embryologie descriptive par Ernst Haeckel (1866); (2) l'avènement d'une physiologie réductionniste du développement menée par Wilhelm His (1874); (3) la création d'une "mécanique du développement" par Wilhelm Roux (1885) et les (...) interprétations néo-darwinienne (A. Weismann), néo-vitaliste (H. Driesch) et organiciste (O. Hertwig) de ses résultats les plus significatifs (1888-1908). J'y défends qu'une logique de la découverte structurait ces développements, où les modèles mécaniques d'explication devaient constamment être renouvelés lorsque leur examen empirique engendrait la découverte de phénomènes épigénétiques inédits. L'étude réalisée traite d'un enjeu fondamental de la philosophie des sciences : le rapport entre la rationalité scientifique et la découverte. Elle offre aussi un éclairage sur une question très actuelle de la philosophie de la biologie, soit les transformations de la notion d'épigenèse en rapport avec les théories épigénétiques contemporaines. La méthodologie adoptée s'inscrit dans la tradition de l'épistémologie historique, consacrée à l'étude du développement des structures du savoir scientifique. Cette tâche exige l'analyse historique de diverses sources documentaires; mais un éclairage théorique constitué tant de modèles provenant de la philosophie des sciences que de connaissances scientifiques demeure indispensable. Ici le modèle d'Imre Lakatos, centré sur la notion de programme de recherche, est entre autres privilégié."--provided by publisher. (shrink)

Early in his career Thomas Hunt Morgan was interested in embryology and dedicated his research to studying organisms that could regenerate. Widely regarded as a regeneration expert, Morgan was invited to deliver a series of lectures on the topic that he developed into a book, Regeneration (1901). In addition to presenting experimental work that he had conducted and supervised, Morgan also synthesized and critiqued a great deal of work by his peers and predecessors. This essay probes into the (...) history of regeneration studies by looking in depth at Regeneration and evaluating Morgan's contribution. Although famous for his work with fruit fly genetics, studying Regeneration illuminates Morgan's earlier scientific approach which emphasized the importance of studying a diversity of organisms. Surveying a broad range of regenerative phenomena allowed Morgan to institute a standard scientific terminology that continues to inform regeneration studies today. Most importantly, Morgan argued that regeneration was a fundamental aspect of the growth process and therefore should be accounted for within developmental theory. Establishing important similarities between regeneration and development allowed Morgan to make the case that regeneration could act as a model of development. The nature of the relationship between embryogenesis and regeneration remains an active area of research. (shrink)

The present account aims to contribute to a better characterization of the state and the dynamics of embryological knowledge at the dawn of the molecular revolution in biology. In this study, Albert Dalcq (1893-1973) was chosen as a representative of a generation of embryologists who found themselves at the junction of two very different approaches to the study of life: the first, focusing on global properties of organisms; the second focusing on the characterization of basic molecular constituents. Though clearly belonging (...) to the organismic tradition, Dalcq was already blending his experimental and explanatory practices with biochemical aspects by the 1930s. Principally based on published sources, the present analysis focuses on the conceptual definitions, modifications and interrelations on which Dalcq's explanation of development rested. Among these are variant process concepts such as gradients and fields, which are often thought to have strongly holistic implications. I will argue that Dalcq's version of these concepts was compatible with a more reductionist treatment of embryos than was accepted by most embryologists as late as the 1950s, pointing to some extent toward the recent molecular characterization of gradients by molecular geneticists such as Christiane Nüsslein-Volhard. Moreover, I will show how the embryological research program of Dalcq and his pupil Jean Brachet has been largely instrumental in the development of molecular biology in Belgium. (shrink)

In vitro embryology not only makes possible the growing of human tissue to remedy infertility but also for many other experimental purposes. This paper examines the ethical issues involved in such work and outlines the circumstances in which such work is morally permissible and those in which it is not.

During the 1870s animal morphologists and embryologists at Cambridge University came to dominate British zoology, quickly establishing an international reputation. Earlier accounts of the Cambridge school have portrayed this success as short-lived, and attributed the school's failure to a more general movement within the life sciences away from museum-based description, towards laboratory-based experiment. More recent work has shown that the shift in the life sciences to experimental work was locally contingent and highly varied, often drawing on and incorporating aspects (...) of museum work. Thus in order to understand the more general changes, studies of particular sites are needed. Here I examine the organisation of teaching at Cambridge, both in terms of the spaces in which it was taught and the ways in which teaching and examining were organised, to bring out the complexities of the 'revolt from morphology' and to show in more detail the institutional aspects that intertwined with intellectual change. Francis Maitland Balfour, as head of the Cambridge school, was able to make use of family connections and his own personal wealth to promote morphology. His successor lacked these resources, and one competition within the natural sciences at Cambridge intensified, morphology was unable to compete properly. (shrink)

When Did I Begin? investigates the theoretical, moral, and biological issues surrounding the debate over the beginning of human life. With the continuing controversy over the use of in vitro fertilization techniques and experimentation with human embryos, these issues have been forced into the arena of public debate. Following a detailed analysis of the history of the question, Reverend Ford argues that a human individual could not begin before definitive individuation occurs with the appearance of the primitive streak about two (...) weeks after fertilization. This, he argues, is when it becomes finally known whether one or more human individuals are to form from a single egg. Thus, he questions the idea that the fertilized egg itself could be regarded as the beginning of the development of the human individual. The author also differs sharply, however, from those who would delay the beginning of the human person until the brain is formed, or until birth or the onset of conscious states. (shrink)

With historical hindsight, it can be little questioned that the view of protozoa as unicellular organisms was important for the development of the discipline of protozoology. In the early years of this century, the assumption of unicellularity provided a sound justification for the study of protists: it linked them to the metazoa and supported the claim that the study of these “simple” unicellular organisms could shed light on the organization of the metazoan cell. This prospect was significant, given the state (...) of cytology circa 1910. In the wake of the major gains made in understanding nuclear division in the last two decades of the nineteenth century, cytology was suddenly confronted with many, seemingly less penetrable, problems. Several aspects of nuclear organization still remained unexplained, and recent research had revealed the presence in the cytoplasm of structures whose functions in cell life were unknown. Classical methods of cytology, relying on descriptive, morphological analysis, seemed ill equipped to resolve these questions.Hertwig's program for protozoology, grounded in the assumption of the fundamental unity of organization in protozoa and metazoa, offered a potential means for investigating these and other problems of cell theory. Linked to mainstream cytology, protozoology was advocated as a means of experimentally investigating key biolobical processes — reproduction, metabolism, and organelle morphology and physiology — less accessible in higher organisms. Protozoa were hailed as prime experimental organisms, in which cell structure and function could be more easily studied. Unlike the metazoan cell, they could be subjected to controlled experiments in which the external environment was modified and the effects monitored. Protozoa offered, in other words, a promising experimental means by which to investigate the cell — its structures and its processes.The success of this program within Germany was soon apparent. In contrast to the rather neglected state of the discipline in 1900, protozoology began to be recognized as more than a somewhat obscure area of study for specialists. In practical terms, this translated into greater numbers of students attracted to the field, increased institutional support for the discipline, and its elevation in status within the biological sciences as new developments, particularly in connection with medical applications, began to draw attention to the field.64The unicellular hypothesis also promoted the internal development of the science. It provided a rationale for introducing the various techniques used in cytology, embryology, physiology, and the new field of biochemistry as suitable research tools for protozoology as well. This vastly extended the research possibilities and facilitated the understanding of, among other things, protozoan organization, modes of reproduction, and evolutionary relationships. The new experimental grounding of the discipline in turn fitted in well with developments in biology at large: in contrast to the descriptive methodology that had predominated in the nineteenth century, this new experimental program placed protozoology at the forefront of the early twentieth-century movement to make biology an experimental science comparable to physics and chemistry.Yet the criticism of the unicellular hypothesis can also be seen as having served a valuable function within the development of the discipline. It focused attention on the study of protists as organisms in their own right, not simply as models for metazoan cells. More generally, it helped to remind biologists of the particular evolutionary assumptions that supported this conception. Dobell and other British critics pointed out, among other things, the association between the theory of recapitulation and the interpretation of protozoa as unicellular organisms. At the time when the recapitulation theory and the germ-layer doctrine were in decline, it was important to stress how these evolutionary ideas also entered into the contemporary concepts of subsidiary specialties. This was as true for protozoology as it was for cell theory itself. The chromidial theory, in its various guises, and the binuclearity hypothesis did in fact contain elements of recapitulationist reasoning, and they were open to criticism for the same kind of overly speculative theorizing that characterized this evolution theory. Dobell's critique forced protozoologists and cell theorists alike to review the theoretical postulates guiding their investigations.In the absence of further historical studies, it is hard to evaluate the consequences of this debate in later years. The issue was not whether protozoa were the precursors of metazoa — both sides accepted this. They disagreed over which particular protozoon had served as the ancestral form, and this, in turn, influenced their stance on the question of unicellularity. The situation is little changed today. Because the former question is still an open one, the latter remains so too. Both of the models for the origin of multicellular organisms — colonies of ciliates versus multinucleate protists — are still presented as possible mechanisms in modern textbooks of evolution. Unable to judge the dispute in terms of the ultimate validity of the competing conceptions, the historian requires other criteria. It perhaps becomes more important to evaluate the issues in the context of the internal and external stimulus they provided the discipline.65 In these terms, and from the present historical vantage point, Hertwig's research program for protozoology, based upon the unicellular hypothesis, appears to have been a successful one. (shrink)

The concepts of hierarchical organization, genetic determinism and biological specificity have played a crucial role in biology as a modern experimental science since its beginnings in the nineteenth century. The idea of genetic information and genetic determination was at the basis of molecular biology that developed in the 1940s with macromolecules, viruses and prokaryotes as major objects of research often labelled “reductionist”. However, the concepts have been marginalized or rejected in some of the research that in the late 1960s (...) began to focus additionally on the molecularization of complex biological structures and functions using systems approaches. This paper challenges the view that ‘molecular reductionism’ has been successfully replaced by holism and a focus on the collective behaviour of cellular entities. It argues instead that there are more fertile replacements for molecular ‘reductionism’, in which genomics, embryology, biochemistry, and computer science intertwine and result in research that is as exact and causally predictive as earlier molecular biology. (shrink)

At the end of the nineteenth century, approaches from experimental physiology made inroads into embryological research. A new generation of embryologists felt urged to study the mechanisms of organ formation. This new program, most prominently defended by Wilhelm Roux, was called Entwicklungsmechanik. Named variously as “causal embryology”, “physiological embryology” or “developmental mechanics”, it catalyzed the movement of embryology from a descriptive science to one exploring causal mechanisms. This article examines the specific scientific and epistemological meaning of (...) the mechanistic approaches of embryological development by focusing on Wilhelm His’ histogenetic work. Roux was neither the first, nor the only one to argue for an experimental exploration of causes in embryology. At the time of Roux, physiological explanations of the genesis of the anatomical forms were developing in parallel, not only in German-speaking countries, but in France, Switzerland and English-speaking countries as well. The experimental approach and the cellular descriptions of embryogenesis were already omni-present when Roux proposed his Entwicklungsmechanik. However, these approaches remained disjointed. It appears that it was Wilhelm His who first succeeded in combining the question of the causal factors determining epigenesis, which was closely connected with experimentation on, and cellular descriptions of, development, in a coherent and concrete synthesis, making him one of the true initiators of the developmental mechanics. (shrink)

Many of the features that distinguish the vertebrates from other chordates are derived from the neural crest, and it has long been argued that the emergence of this multipotent embryonic population was a key innovation underpinning vertebrate evolution. More recently, however, a number of studies have suggested that the evolution of the neural crest was less sudden than previously believed. This has exposed the fact that neural crest, as evidenced by its repertoire of derivative cell types, has evolved through vertebrate (...) evolution. In this light, attempts to derive a typological definition of neural crest, in terms of molecular signatures or networks, are unfounded. We propose a less restrictive, embryological definition of this cell type that facilitates, rather than precludes, investigating the evolution of neural crest. While the evolutionary origin of neural crest has attracted much attention, its subsequent evolution has received almost no attention and yet it is more readily open to experimental investigation and has greater relevance to understanding vertebrate evolution. Finally, we provide a brief outline of how the evolutionary emergence of neural crest potentiality may have proceeded, and how it may be investigated. BioEssays 30:530–541, 2008. © 2008 Wiley Periodicals, Inc. (shrink)

Aron Arthur Moscona was an Israeli-American developmental biologist whose name is associated with research on cell interactions during embryonic development. His appearance on the international scene dates back to a paper published in 1952, while he was working, together with his wife Haya Sobel Moscona, at the Strangeways Research Laboratory of Cambridge. Together they demonstrated that cells from previously dissociated chick tissues undergo histiotypical and organotypical aggregation in vitro. From 1952 to 1997, Moscona focused his research on cell recognition mechanisms, (...) ultimately demonstrating the role of transmembrane proteins in cellular adhesiveness, tissue segregation, and organ tridimensional assemblage during development. However, who was Aron Moscona before 1952 and what brought him to developmental biology? A Polish Jew who immigrated to Mandatory Palestine in 1933, Moscona belonged to the first generation of biologists formed in the newly established Zoology Department of the Hebrew University. With a particular focus on the Israeli context, the paper reconstructs the evolution of Moscona’s scientific thought by emphasizing the cultural and experimental context of his training and early research at the Hebrew University. The aim is to investigate how local scientific traditions influenced Moscona’s eventual research as well as enabled the relevant experimental innovation he contributed to the field of developmental biology and pathology. The paper can be read both as a scientific biography of Aron Moscona and as a preliminary contribution to the historiography of embryology in the Mandatory Palestine/Israeli context. (shrink)