History and status of embryology and developmental biology at Polish Medical Faculties and Schools

In Poland, medical embryology (both scientific research and teaching of the subject) has traditionally involved Chairs of Histology and Embryology rather than Obstetrics and Gynecology. Before World War II, the most buoyant centers for embryological research among the five universities at the time (in Warsaw, Krakow, Poznan, Lvov and Vilnius), were the Chairs of Embryology and Histology at Medical Faculties of the Jagiellonian University in Krakow and the University of Vilnius. After World War II, eleven Medical Academies (Universities of Medicine) came into being (Warsaw, Krakow, Poznan, Lodz, Gdansk, Bialystok, Bydgoszcz, Szczecin, Wroclaw, Katowice and Lublin). They conduct scientific research on normal development of the human embryo as well as teratology studies. In the XX century, eminent medicine-related embryologist included professors Emil Godlewski Jr., Stanislaw Hiller and Stefan Baginski.     

Scientific exchange: Jacques Loeb (1859-1924) and Emil Godlewski (1875-1944) as representatives of a transatlantic developmental biology

The German-American physiologist Jacques Loeb (1859-1924) and the Polish embryologist Emil Godlewski, jr. (1875-1944) contributed many valuable works to the body of developmental biology. Jacques Loeb was world famous at the beginning of the twentieth century for his development and demonstration of artificial parthenogenesis in 1899 and his experiments on regeneration. He served as a role model for the younger Polish experimenter Emil Godlewski, who began his career as a researcher like Loeb at the Zoological Station in Naples. Following Godlewski's first visit to Naples in 1901 a close relationship between the two scientists developed. Until Loeb's death in 1924 the two exchanged ideas via correspondence that was only interrupted during the First World War. The aim of the paper is to examine the transatlantic transfer of knowledge in the field of biological experimentation that was fostered by these two protagonists. Using a modification of Bruno Latour's model of the 'Circulatory System of Science' as a heuristic tool, different mechanisms of scientific exchange are displayed. With the help of Loeb's and Godlewski's correspondence the role of scientific communities, methods, allies, the public and institutions in the process of knowledge transfer are analysed. Preconditions for success and failure in transferring science are examined.     

An interview with Dr. Frank Slack on his highly cited paper published in Cell Cycle

Frank Slack received his B.Sc from the University of Cape Town in South Africa, before completing his Ph.D in molecular biology at Tufts University School of Medicine. He started work on microRNAs as a postdoctoral fellow in Gary Ruvkun’s laboratory at Harvard Medical School, where he co-discovered the second known microRNA, let-7. He is currently an Associate Professor in the Department of Molecular, Cellular and Developmental Biology at Yale University. The Slack laboratory studies the roles of microRNAs and their targets in development, disease and aging.     

Q & A

Gregory A. Petsko is Gyula and Katica Tauber Professor of Biochemistry and Chemistry and Director of the Rosenstiel Basic Medical Sciences Research Center at Brandeis University. He did his undergraduate work at Princeton and his graduate work as a Rhodes Scholar at Oxford University. He held faculty positions at Wayne State University School of Medicine and MIT before moving to Brandeis in 1990. A structural biologist, he is best known for his work, together with his colleague Dagmar Ringe, on the structural basis of enzyme catalytic power and the role of protein dynamics in protein function. He writes a regular opinion column for the journal Genome Biology.     

Direct physical formation of anatomical structures by cell traction forces. An interview with Albert Harris by Lev Beloussov

Albert Harris was educated at The Norfolk Academy, Norfolk, Virginia, USA (1961). He then earned a Batchelor of Arts Degree in Biology from Swarthmore College, in Pennsylvania, USA (1965), followed by a Ph.D. in Biology (1971) from Yale University, where his Dissertation Advisor was the great John Phillip Trinkaus. He held a Damon-Runyon Postdoctoral Fellowship in Cancer Research in 1970-72, under Michael Abercrombie, FRS, at the Strangeways Research Laboratory of Cambridge University, England. Then he accepted a position as Assistant Professor in the Zoology Department of the University of North Carolina at Chapel Hill, N.C. USA. In 1977, he was promoted to Associate Professor of Zoology, and in 1983 was promoted to Full Professor of Biology. In Oct.-Nov. 1991 he was honored to be Distinguished Visiting Professor of Zoology at the University of California at Davis.     

Contribution of late Professor T. C. Tung to the experimental embryology of Amphioxus

Professor T. C. Tung (Fig. 1) was a prominent experimental embryologist in China. He was born in Jin County, Zhejiang Province, China in 1902. After he obtained his Bachelor's degree from the Department of Biology, Fudan University, Shanghai in 1927, he was appointed as a teaching assistant in that department until he moved to Belgium in 1930. He studied as a graduate student in Professors A. Brachet and A. M. Dalcq's laboratory at the Universite Libre de Bruxelles, Belgium and obtained his Doctor of Science degree there in 1934. During that period, he made two short working visits to the Institute of Marine Biology in France and took one training course at Cambridge University (UK). In 1934, he was invited to return to China as a Full Professor to teach at several Chinese universities, (Shandong University in Qingdao, Shandong Province; the National University in Nanjing; and Fudan University in Shanghai). He spent 1 year at Yale University (USA) between 1948 and 1949 as an invited scientist in a joint research project and finally returned to China in 1949. He was Chairman of the Department of Zoology, Shandong University in Qingdao (1949-1952), Vice-President of Shandong University (1952-1960), Director of the Marine Biological Institute, the Chinese Academy of Sciences (CAS) in Qingdao (1949-1958), Director of the Institute of Oceanology (CAS) in Qingdao (1959-1966), Director of the Institute of Zoology (CAS) in Beijing (1960-1962), member of CAS since 1955, Vice-Chairman of the Biological and Geographical Division of CAS (1955-1958), Chairman of the Biological Division of CAS (1959-1979) and Vice-President of CAS in Beijing (1978-1979). In spite of his administrative duties, he spent most of his life conducting bench work in his laboratories at the Institutes of Oceanology and Zoology, CAS, respectively, until he passed away in March 1979. Professor Tung's main research interest was with classic experimental studies on the determination of the egg axis and symmetry planes of fertilized eggs, early differentiation and organizing substances of egg cytoplasm, induction between embryonic cells and cytoplasm in embryogenesis, immunological studies on nuclear transplanted eggs, and cell fusion etc., in several types of animals. He conducted his experiments on a number of invertebrates (ascidians and Amphioxus) and vertebrates (fish and amphibians) by means of very skillful microsurgical operations and the nuclear transplantation method. Among these topics, his studies on the organization and developmental potency of Amphioxus eggs were unique. His important contribution to this research field involved not only establishing a practical method for collecting and using this rare animal for experimental purposes, but also clarifying controversy about the nature and early development of its eggs. He also provided conclusive evidence to determine its evolutionary position between invertebrates and vertebrates. The present article briefly reviews the main results obtained by Professor Tung and his colleagues on Amphioxus. Although their original articles were written both in Chinese and English, many international readers may not even know those original works because they were only published in scientific journals inside China from the 1950s. Comments and discussion on the experimental results of Amphioxus research by Tung's group and those from other earlier authors are also included.     

Polysomes are associated with microtubules in fertilized eggs of Chinese pine (Pinus tabulaeformis)

Summary. Transmission electron microscopy of immunogold-labeled Chinese pine egg cells before and after fertilization revealed that polysomes are associated with microtubules (MTs) from fertilization to the 2-nucleate embryo stage. Ribosome aggregates of various size and shape were randomly distributed in the cytoplasm of the eggs before fertilization. Single MTs or clusters were observed to be free of polysomes at this stage. Upon fertilization, all polysomes were attached to MTs, and this association persisted until the formation of the polarized embryo. Thereafter, the polysomes spread into the cytoplasm and no polysome-MT association was observed in the embryo. Some of the polysomes were attached to one end of the MTs, while others appeared to form contacts along their entire length. No polysome-microfilament association was observed at any stage of the development. The polysome-MT association may provide a mechanism for MT-dependent mRNA localization in early embryo development of this plant. Correspondence and reprints: Department of Cell Biology and Physiology, University of Pittsburgh, Pittsburgh, U.S.A.     

Q & A. [interview

Elaine and Gary Ostrander spent their youth in New Jersey and New York before heading to Nebraska for their teen years and eventually Washington State for High School and college, as their father moved around in library administration. Elaine was an undergraduate at the University of Washington, a graduate student at the Oregon Health Sciences University and a postdoc with James Wang at Harvard, studying DNA supercoiling. She next went to Berkeley, where she began the canine genome project, initiating the meiotic linkage map and working on human chromosome 21 at the Lawrence Berkeley National Labs. In 1993 she moved to the Fred Hutchinson Cancer Research Center where she is now a Member of the Divisions of Clinical Research and Human Biology. She is also an Affiliate Professor of Genome Sciences and Biology at the University of Washington, and heads the Program in Genetics at the Hutchinson Center. Gary completed his undergraduate degree in Biology at Seattle University, a M.S. degree at Illinois State University and a Ph.D at the University of Washington in Ocean and Fisheries Science. He went on to be a postdoc in the Department of Pathology at the University of Washington Medical School while being mentored by Senitroh Hakomori of the Fred Hutchinson Cancer Research Center and Eric Holmes of the Pacific Northwest Research Foundation. His work focused on using novel aspects of the biology of fishes to address fundamental questions about cancer. He subsequently held both faculty and administrative positions at Oklahoma State University. Since 1996, he has been at the Johns Hopkins University, where he currently holds academic appointments in the Departments of Biology and Comparative Medicine and is the Associate Provost for Research.     

Emil Starkenstein--one of the most important personalities of European continental pharmacology in the period between the two world wars

Emil Starkenstein (1884-1942), professor of pharmacology at the German Medical Faculty of Charles University in Prague, was not only an experimental pharmacologist, but also the pioneer of clinical pharmacology. During the World War I (1914-1918) he took advantage of his knowledge of experimental pharmacology for the new approaches to the treatment of bacillary dysentery, cholera and of epidemic typhus fever. In 1918 he published the article "Clinical Pharmacology--Theory and Praxis at the Patient's Bedside", in which he defined the main task of clinical pharmacology as the implementation and verification of experimental pharmacology achievements in clinical therapy. During the period 1921-1933, his scientific interests involved namely analgesic combinations, seasickness therapy and pharmacology of iron. He published more than 240 scientific articles and three textbooks. Emil Starkenstein died on November 6, 1942 as a victim of Holocaust. Starkenstein s collection of more than 20,000 reprints of scientific studies, which has been deposited recently in the Archives of Charles University in Prague is very valuable.     

A festschrift for J. Martyn Bailey, a biochemist extraordinaire

A festschrift for Dr. John Martyn Bailey, Professor of Biochemistry and Molecular Biology was organized by the Biochemistry department of the George Washington University School of Medicine and Health Sciences on December 4-5, 2006 to honor his 48 years of contributions. He made important contributions in the areas of essential fatty acids, prostaglandins, thromboxanes and lipoxygenase metabolites.     

Potential of adenovirus as a vector for sustained gene expression

Inder Verma received his Ph.D. in biochemistry from the Weizmann Institute of Science, Rehovot, Israel, in 1971, and was a postdoctoral fellow (with David Baltimore) in the Department of Biology, Massachussetts Institute of Technology. He is currently American Cancer Society Professor of Molecular Biology, Chair of the Laboratory of Genetics at the Salk Institute for Biological Studies, and Adjunct Professor in the Department of Biology, University of California at San Diego. Inder Verma is a member of the National Academy of Sciences (USA). He is a member of the editorial boards of The Journal of Gene Medicine, Journal of Virology and Gene, and serves on several other scientific advisory boards. His major fields of interest are molecular analysis of oncoproteins, and suppressor genes, gene therapy involving retroviral, adenoviral, AAV vectors, and generation of novel lentiviral vectors. Copyright © 1999 John Wiley & Sons, Ltd.     

Proteomics data mining

Marc Wilkins completed his undergraduate and doctoral studies at Macquarie University, Sydney, Australia. During his doctoral studies, he defined the concept of the proteome and coined the term. After postdoctoral studies in Geneva, Switzerland, during which he co-edited the first book on proteomics, he returned to Australia, where he cofounded the company Proteome Systems. More recently, Marc took a position as Professor of Systems Biology at the University of New South Wales. He has established and directs the NSW Systems Biology Initiative, and is currently researching the role that protein post-translational modifications play in the regulation of protein-interaction networks.     

Richard G.W. Anderson (1940-2011) and the birth of receptor-mediated endocytosis

On March 19, 2011, the discipline of cell biology lost a creative force with the passing of Richard G.W. Anderson, Professor and Chairman of the Department of Cell Biology at the University of Texas Southwestern Medical School. An unabashed chauvinist for cell biology, Dick served for many years on the editorial board of The Journal of Cell Biology and the Council of the American Society for Cell Biology. He died of glioblastoma multiforme six days before his 71st birthday.     

Q & A. Philip Ingham

Philip Ingham grew up in Liverpool and graduated from Cambridge University in 1977. He did his D.Phil in Developmental Genetics at Sussex University and postdoctoral work in Strasbourg, France before joining the laboratory of David Ish-Horowicz at the ICRF Mill Hill Laboratories. Here he applied the emerging technique of tissue in situ hybridisation to the analysis of the Drosophila segmentation genes. After a short spell at the MRC Laboratory of Molecular Biology in Cambridge, he rejoined the ICRF as a Research Scientist at the Developmental Biology Unit in Oxford. His group pioneered the analysis of the Hedgehog signalling pathway in Drosophila and in collaboration with the labs of Andy McMahon and Cliff Tabin at Harvard University, discovered the Hedgehog gene family in vertebrates. In 1996 he was appointed Professor of Developmental Genetics at the University of Sheffield where he has established the Centre for Developmental Genetics.     

A preliminary biography of Armand de Ricqlès (1938–), the great synthesizer of bone histology

Armand de Ricqlès has had a long, successful career. From his start as an Assistant in the University of Paris in 1961, he defended his doctoral thesis in 1963, became Maître-Assistant (Assistant Professor) in 1970 (tenured 1971), defended his “doctorat d’état” (habilitation thesis) in 1973, was nominated Professor in the University Paris 7, was promoted to first class (Full Professor) in 1987, and was finally nominated to the prestigious chair “Biologie Historique et Évolutionnisme” (Historical and Evolutionary Biology) of the Collège de France in 1996. He lectured on a wide range of topics, especially in comparative and evolutionary biology, and assumed important administrative responsibilities, including responsibility of various master's programs, leadership of the team “Formations squelettiques” (1973–2002; till Professor Jacques Castanet took over leadership of the team), involvement in various committees, and in organizing scientific meetings. He served on several editorial committees and was co-editor of the “Annales des Sciences Naturelles”, as well as co-editor-in-chief of the “Comptes Rendus Palevol”. His scientific research always emphasized bone histology, especially paleohistology, but he also made contributions to systematic paleontology, phylogenetics, history of paleontology, and biological nomenclature, in decreasing order of importance. He has so far published over 100 scientific papers and 120 semi-popular papers.     

Q & A. Carl R. Woese. [interview

Carl R. Woese was born and raised in Syracuse, New York. His undergraduate training was at Amherst College (AB 1950) and graduate work at Yale University (PhD 1953). He is currently the Stanley O. Ikenberry University Professor and Center for Advanced Study Professor of Microbiology at the University of Illinois (Champaign-Urbana), where he has been for the past forty years. He was trained as a biophysicist and molecular biologist. He views himself as a molecular biologist in search of Biology. Consequently, his career has been devoted to using molecular methods to approach evolutionary problems. His most notable accomplishments have been determining the universal phylogenetic tree, through molecular sequence analysis, and the discovery of the Archaea, the so-called ‘third form’ of life. For these he has received numerous awards, including a John D. and Catherine T. MacArthur Award, the Leeuwenhoek Medal 1990 (Netherlands Royal Academy), the Waksman Award (National Academy of Science USA), and the Crafoord Prize (Swedish Royal Academy). At present he works on the evolution of cellular organization.     

Stanislaw Smreczynskis legacy and the Department of Zoology of the Jagiellonian University of Krakow (Poland)

This article covers the origin and development of scientific interest in insect and amphibian developmental biology at the Department of Systematic Zoology and Zoogeography of the Jagiellonian University. The greater part of this historical account is devoted to Professor Stanislaw Smreczynski (1899-1975), the founding father of the Department, and comments on his biography and research achievements in the field of animal experimental embryology. A particular emphasis is on Smreczynski's contributions to contemporary understanding of early embryonic development of amphibians and insects as well as his expertise in Pleistocene and extant weevils (Curculionidae). A concise survey of developmental phenomena studied by some of Smreczynski's co-workers and followers is also presented, including the early embryogenesis of entognathans as well as germ cell determination and gonad formation in Drosophila virilis conducted by Jura; analysis of oogenesis in Collembola carried out by Krzysztofowicz; investigations of insects and tradigrades by Weglarska, and finally research into various aspects of ovary structure in diverse insect taxa by the Bilinski group.     

The cytoskeleton in the unique cell reproduction by conidiogenesis of the long-neck yeast Fellomyces (Sterigmatomyces) fuzhouensis

Summary. The morphology of conidiogenesis and associated changes in microtubules, actin distribution and ultrastructure were studied in the basidiomycetous yeast Fellomyces fuzhouensis by phase-contrast, fluorescence, and electron microscopy. The interphase cell showed a central nucleus with randomly distributed bundles of microtubules and actin, and actin patches in the cortex. The conidiogenous mother cell developed a slender projection, or stalk, that contained cytoplasmic microtubules and actin cables stretched parallel to the longitudinal axis and actin patches accumulated in the tip. The conidium was produced on this stalk. It contained dispersed cytoplasmic microtubules, actin cables, and patches concentrated in the cortex. Before mitosis, the nucleus migrated through the stalk into the conidium and cytoplasmic microtubules were replaced by a spindle. Mitosis started in the conidium, and one daughter nucleus then returned to the mother via an eccentrically elongated spindle. The cytoplasmic microtubules reappeared after mitosis. A strong fluorescence indicating accumulated actin appeared at the base of the conidium, where the cytoplasm cleaved eccentrically. Actin patches then moved from the stalk together with the retracting cytoplasm to the mother and conidium. No septum was detected in the long neck by electron microscopy, only a small amount of fine “wall material” between the conidium and mother cell. Both cells developed a new wall layer, separating them from the empty neck. The mature conidium disconnected from the empty neck at the end-break, which remained on the mother as a tubular outgrowth. Asexual reproduction by conidiogenesis in the long-neck yeast F. fuzhouensis has unique features distinguishing it from known asexual forms of reproduction in the budding and fission yeasts. Fellomyces fuzhouensis develops a unique long and narrow neck during conidiogenesis, through which the nucleus must migrate into the conidium for eccentric mitosis. This is followed by eccentric cytokinesis. We found neither an actin cytokinetic ring nor a septum in the long neck, from which cytoplasm retracted back to mother cell after cytokinesis. Both the conidium and mother were separated from the empty neck by the development of a new lateral wall (initiated as a wall plug). The cytoskeleton is clearly involved in all these processes. Correspondence and reprints: Department of Biology, Faculty of Medicine, Masaryk University, Tomešova 12, 602 00 Brno, Czech Republic.     

Philip Cohen

Philip Cohen trained at University College London and, after postdoctoral research at the University of Washington, joined the University of Dundee Scotland, in 1971, where he has worked ever since. He is a Royal Society Research Professor and Director of the Medical Research Council Protein Phosphorylation Unit. His main contributions have been in the area of protein phosphorylation and its role in cell regulation and human disease. In 1998, he was knighted for his contributions to biochemistry and the development of Life Sciences at Dundee.