TGF-β Biology in Mammary Development and Breast Cancer

Transforming growth factor-β1 (TGF-β) was first implicated in mammary epithelial development by Daniel and Silberstein in 1987 and in breast cancer cells and hormone resistance by Lippman and colleagues in 1988. TGF-β is critically important for mammary morphogenesis and secretory function through specific regulation of epithelial proliferation, apoptosis, and extracellular matrix. Differential TGF-β effects on distinct cell types are compounded by regulation at multiple levels and the influence of context on cellular responses. Studies using controlled expression and conditional-deletion mouse models underscore the complexity of TGF-β biology across the cycle of mammary development and differentiation. Early loss of TGF-β growth regulation in breast cancer evolves into fundamental deregulation that mediates cell interactions and phenotypes driving invasive disease. Two outstanding issues are to understand the mechanisms of biological control in situ and the circumstances by which TGF-β regulation is subverted in neoplastic progression.The discovery of a “transforming growth factor” in normal tissue and serum in the early 1980s rapidly led to the identification of a large family of polypeptides whose action is involved in all aspects of development, homeostasis, and cancer (Moses and Roberts 2008). The activity of transforming growth factor-β1 (TGF-β) was first implicated in mammary epithelial development in 1987 by a canonical experiment by Daniel and Silberstein. Pellets containing TGF-β implanted into mouse mammary gland during ductal morphogenesis were shown to induce rapid regression of advancing endbuds, which was among the first demonstration of its potent inhibitory, rather than transforming, activity (Silberstein and Daniel 1987). However, soon after, Lippman and colleagues showed that TGF-β was produced by breast cancer cells, which in turn contributed to their hormone resistance (Knabbe et al. 1987). These two diametrically opposed actions have continued to fascinate those studying its sundry roles in mammary biology and breast cancer. After nearly a quarter century, this brief article underscores the major two themes in mammary biology: Although TGF-β orchestrates tissue composition and critical controls during mammary development, its subversion during cancer progressively undermines homeostasis and actively drives malignancy.     

Does the Segregation of Evolution in Biology Textbooks and Introductory Courses Reinforce Students’ Faulty Mental Models of Biology and Evolution?

The well-established finding that substantial confusion and misconceptions about evolution and natural selection persist after college instruction suggests that these courses neither foster accurate mental models of evolution’s mechanisms nor instill an appreciation of evolution’s centrality to an understanding of the living world. Our essay explores the roles that introductory biology courses and textbooks may play in reinforcing undergraduates’ pre-existing, faulty mental models of the place of evolution in the biological sciences. Our content analyses of the three best-selling introductory biology textbooks for majors revealed the conceptual segregation of evolutionary information. The vast majority of the evolutionary terms and concepts in each book were isolated in sections about evolution and diversity, while remarkably few were employed in other sections of the books. Standardizing the data by number of pages per unit did not alter this pattern. Students may fail to grasp that evolution is the unifying theme of biology because introductory courses and textbooks reinforce such isolation. Two goals are central to resolving this problem: the desegregation of evolution as separate “units” or chapters and the active integration of evolutionary concepts at all levels and across all domains of introductory biology.     

Water Biology and Security(ISSN 2772-7351)

Volume 1 Issue 1,2022中国科学院水生生物研究所创办的开放获取英文期刊Water Biology and Security(ISSN 2772-7351)第一期于2022年2月在Elsevier平台和KeAi平台同步发行。本期共计10篇文章,包括1篇开刊词、4篇综述文章和5篇研究性论文,作者分布在中国、美国、加拿大、英国、巴西等国家地区,领域涉及水生生物免疫学研究、基因组学研究、生物技术及遗传育种、水域生态学研究等各领域。     

Water Biology and Security(ISSN 2772-7351)

Volume 1 Issue 1,2022中国科学院水生生物研究所创办的开放获取英文期刊Water Biology and Security(ISSN 2772-7351)第一期于2022年2月在Elsevier平台和KeAi平台同步发行。本期共计10篇文章,包括1篇开刊词、4篇综述文章和5篇研究性论文,作者分布在中国、美国、加拿大、英国、巴西等国家地区,领域涉及水生生物免疫学研究、基因组学研究、生物技术及遗传育种、水域生态学研究等各领域。     

Why Are Computational Neuroscience and Systems Biology So Separate?

Despite similar computational approaches, there is surprisingly little interaction between the computational neuroscience and the systems biology research communities. In this review I reconstruct the history of the two disciplines and show that this may explain why they grew up apart. The separation is a pity, as both fields can learn quite a bit from each other. Several examples are given, covering sociological, software technical, and methodological aspects. Systems biology is a better organized community which is very effective at sharing resources, while computational neuroscience has more experience in multiscale modeling and the analysis of information processing by biological systems. Finally, I speculate about how the relationship between the two fields may evolve in the near future.     

A new journal – "Theoretical Biology and Medical Modelling"

Biology has a conceptual basis that allows one to build models and theorize across many life sciences, including medicine and medically-related disciplines. A dearth of good venues for publication has been perceived during a period when bioinformatics, systems analysis and biomathematics are burgeoning.     

Bionics and Structural Biology： A Novel Approach for Bio-energy Production

Cellular metabolism is a very complex process. The biochemical pathways are fundamental structures of biology. These pathways possess a number of regeneration steps which facilitate energy shuttling on a massive scale. This facilitates the biochemical pathways to sustain the energy currency of the cells. This concept has been mimicked using electronic circuit components and it has been used to increase the efficiency of bio-energy generation. Six of the carbohydrate biochemical pathways have been chosen in which glycolysis is the principle pathway. All the six pathways are interrelated and coordinated in a complex manner. Mimic circuits have been designed for all the six biochemical pathways. The components of the metabolic pathways such as enzymes, cofactors etc., are substituted by appropriate electronic circuit components. Enzymes are related to the gain of transistors by the bond dissociation energies of enzyme-substrate molecules under consideration. Cofactors and coenzymes are represented by switches and capacitors respectively. Resistors are used for proper orientation of the circuits. The energy obtained from the current methods employed for the decomposition of organic matter is used to trigger the mimic circuits. A similar energy shuttle is observed in the mimic circuits and the percentage rise for each cycle of circuit functioning is found to be 78.90. The theoretical calculations have been made using a sample of domestic waste weighing 1.182 kg. The calculations arrived at finally speak of the efficiency of the novel methodology employed.     

Excited States and Free Radicals in Biology and Medicine——Contributions from Flash Photolysis and Pulse Radiolysis

Excited states and free radicals are involved in the normal physiology of living systems; in pathological processes including lipid peroxidation, inflammation, Parkinson's disease, cancer, and ageing; in the mechanism of action of drugs, such as quinone antitumour agents, and in photochemotherapies such as the PUVA therapy of skin diseases and PDT of cancer. The chief aim of this text is to introduce the reader to this rapidly expanding field, which lies at the borderlines of physics, chemistry, biology, pharmacology, and medicine, and, in particular, to explore how time—resolved spectroscopic methods have found solutions at the molecular level to biological and medical problems.     

Cogongrass (Imperata cylindrica)—Biology,Ecology, and Management

Cogongrass is considered to be one of the ten most troublesome and problematic weedy species in the world. This species is found throughout tropical and subtropical regions, generally in areas disturbed by human activities. Over 100 common names have been associated with cogongrass, including japgrass, speargrass, alang-alang, and bladygrass. Although this species has several commercial uses, the problems associated with its weediness far outweigh most positive benefits. Cogongrass is a major impediment to reforestation efforts in southeast Asia, the number one weed in agronomic and vegetable production in many parts of Africa, and is responsible for thousands of hectares of lost native habitat in the southeastern U.S. Biologically, cogongrass possesses several features that foster its spread and persistence. Management efforts for cogongrass consist of an integrated approach with several control strategies. In agronomic production, the use of cover crops is widely successful, but incorporation into the overall production scheme is challenging. Success has been achieved with continuous deep tillage or chemical applications, but long-term eradication/suppression must employ sustainable revegetation strategies.     

Alexander Hollaender’s Postwar Vision for Biology: Oak Ridge and Beyond

Experimental radiobiology represented a long-standing priority for the U.S. Atomic Energy Commission (AEC), but organizational issues initially impeded the laboratory progress of this government-funded work: who would direct such interdisciplinary investigations and how? And should the AEC support basic research or only mission-oriented projects? Alexander Hollaender’s vision for biology in the post-war world guided AEC initiatives at Oak Ridge, where he created and presided over the Division of Biology for nearly two decades (1947–1966). Hollaender’s scheme, at once entrepreneurial and system-oriented, made good use of the unique resources provided by the AEC and by Oak Ridge’s national laboratory setting, while at the same time it restructured wartime research practices to better reflect biologists’ own priorities. Because Hollaender offered many academic experimental biologists a way of envisioning military-related patronage as integral – rather than antithetical – to their professional identities, his work provides an important lens through which to examine the early post-war intellectual and institutional development of radiobiology.