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1. Accelerating an integrative view of quantum biology

   https://doi.org/10.3389/fphys.2023.1349013  

   Kinsey, Luke J; Beane, Wendy S; Tseng, Kelly Ai-Sun (January 2024, Frontiers in Physiology)

   Quantum biology studies span multiple disciplines including physics, engineering, and biology with the goal of understanding the quantum underpinnings of living systems. Recent findings have brought wide attention to the role of quantum mechanisms in the function and regulation of biological processes. Moreover, a number of activities have been integral in building a vibrant quantum biology community. Due to the inherent interdisciplinary nature of the field, it is a challenge for quantum biology researchers to integrate and advance findings across the physical and biological disciplines. Here we outline achievable approaches to developing a shared platform—including the establishment of standardized manipulation tools and sensors, and a common scientific lexicon. Building a shared community framework is also crucial for fostering robust interdisciplinary collaborations, enhancing knowledge sharing, and diversifying participation in quantum biology. A unified approach promises not only to deepen our understanding of biological systems at a quantum level but also to accelerate the frontiers of medical and technological innovations. 

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2. A new era of synthetic biology—microbial community design

   https://doi.org/10.1093/synbio/ysae011  

   Matuszyńska, Anna; Ebenhöh, Oliver; Zurbriggen, Matias D; Ducat, Daniel C; Axmann, Ilka M (January 2024, Synthetic Biology)

   Abstract Synthetic biology conceptualizes biological complexity as a network of biological parts, devices, and systems with predetermined functionalities and has had a revolutionary impact on fundamental and applied research. With the unprecedented ability to synthesize and transfer any DNA and RNA across organisms, the scope of synthetic biology is expanding and being recreated in previously unimaginable ways. The field has matured to a level where highly complex networks, such as artificial communities of synthetic organisms, can be constructed. In parallel, computational biology became an integral part of biological studies, with computational models aiding the unravelling of the escalating complexity and emerging properties of biological phenomena. However, there is still a vast untapped potential for the complete integration of modelling into the synthetic design process, presenting exciting opportunities for scientific advancements. Here, we first highlight the most recent advances in computer-aided design of microbial communities. Next, we propose that such a design can benefit from an organism-free modular modelling approach that places its emphasis on modules of organismal function towards the design of multispecies communities. We argue for a shift in perspective from single organism–centred approaches to emphasizing the functional contributions of organisms within the community. By assembling synthetic biological systems using modular computational models with mathematical descriptions of parts and circuits, we can tailor organisms to fulfil specific functional roles within the community. This approach aligns with synthetic biology strategies and presents exciting possibilities for the design of artificial communities. Graphical Abstract   

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3. A Unifying Framework for Understanding Biological Structures and Functions Across Levels of Biological Organization

   https://doi.org/10.1093/icb/icab167  

   Herman, M A; Aiello, B R; DeLong, J D; Garcia-Ruiz, H; González, A L; Hwang, W; McBeth, C; Stojković, E A; Trakselis, M A; Yakoby, N (July 2021, Integrative and Comparative Biology)

   Abstract The relationship between structure and function is a major constituent of the rules of life. Structures and functions occur across all levels of biological organization. Current efforts to integrate conceptual frameworks and approaches to address new and old questions promise to allow a more holistic and robust understanding of how different biological functions are achieved across levels of biological organization. Here, we provide unifying and generalizable definitions of both structure and function that can be applied across all levels of biological organization. However, we find differences in the nature of structures at the organismal level and below as compared to above the level of the organism. We term these intrinsic and emergent structures, respectively. Intrinsic structures are directly under selection, contributing to the overall performance (fitness) of the individual organism. Emergent structures involve interactions among aggregations of organisms and are not directly under selection. Given this distinction, we argue that while the functions of many intrinsic structures remain unknown, functions of emergent structures are the result of the aggregate of processes of individual organisms. We then provide a detailed and unified framework of the structure–function relationship for intrinsic structures to explore how their unknown functions can be defined. We provide examples of how these scalable definitions applied to intrinsic structures provide a framework to address questions on structure–function relationships that can be approached simultaneously from all subdisciplines of biology. We propose that this will produce a more holistic and robust understanding of how different biological functions are achieved across levels of biological organization. 

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4. Preparing the Next Generation of Integrative Organismal Biologists

   https://doi.org/10.1093/icb/icae098  

   Padilla, Dianna K; Grünbaum, Daniel (July 2024, Integrative And Comparative Biology)

   Synopsis Pursuing cutting edge questions in organismal biology in the future will require novel approaches for training the next generation of organismal biologists, including knowledge and use of systems-type modeling combined with integrative organismal biology. We link agendas recommending changes in science education and practice across three levels: Broadening the concept of organismal biology to promote modeling organisms as systems interacting with higher and lower organizational levels; enhancing undergraduate science education to improve applications of quantitative reasoning and modeling in the scientific process; and K-12 curricula based on Next Generation Science Standards emphasizing development and use of models in the context of explanatory science, solution design, and evaluating and communicating information. Out of each of these initiatives emerges an emphasis on routine use of models as tools for hypothesis testing and prediction. The question remains, however, what is the best approach for training the next generation of organismal biology students to facilitate their understanding and use of models? We address this question by proposing new ways of teaching and learning, including the development of interactive web-based modeling modules that lower barriers for scientists approaching this new way of imagining and conducting integrative organismal biology. 

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5. Introduction to The Symposium: “The Role of Mechanosensation in Robust Locomotion”

   https://doi.org/10.1093/icb/icad088  

   Stanchak, Kathryn E; Katz, Hilary R (July 2023, Integrative And Comparative Biology)

   Synopsis Mechanosensory information is a critical component of organismal movement control systems. Understanding the role mechanosensation plays in modulating organismal behavior requires inherently multidisciplinary research programs that reach across biological scales. Recently, there have been rapid advances in discerning how mechanosensory mechanisms are integrated into neural control systems and the impact mechanosensory information has on behavior. Thus, the Symposium “The Role of Mechanosensation in Robust Locomotion” at the 2023 Annual Meeting of the Society for Integrative and Comparative Biology was convened to discuss these recent advances, compare and contrast different systems, share experimental advice, and inspire collaborative approaches to expand and synthesize knowledge. The diverse set of speakers presented on a variety of vertebrate, invertebrate, and robotic systems. Discussion at the symposium resulted in a series of manuscripts presented in this issue that address issues facing the broader field, mechanisms of mechanosensation, organismal function and biomechanics, and sensing in ecological and social contexts. 

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