Organizers: Ethan Garner, Harvard; and Susan Schlimpert, John Innes Center

Work over the last 25 years has revealed that, in contrast to previous beliefs, bacteria and archaea are not “bags of enzymes.” As fluorescent and electron microscopy approaches have improved, it has become more and more apparent that bacteria and archaea contain a great deal of spatial and temporal organization: there exists a growing number of cytoskeletal polymers that conduct various long-range tasks that segregate DNA and other cargos, define cell shape, and help divide the cell. It has also been revealed these organisms contain not only membrane-bound compartments but also protein-based microcompartments that sequester metabolic enzymes and storage granules that accumulate excess nutrients. Similar to findings in eukaryotic organisms, biomolecular condensates also form in bacteria and archaea, functioning to modulate transcription, RNA processing, and signaling. This subgroup will highlight recent progress in the identification of the self-organizing systems in bacteria and archaea that confer multiscale cellular organization, as well as the work dissecting their underlying mechanisms. The session also welcomes talks demonstrating new developments, approaches, and techniques that can be used to probe the function and dynamics of these systems. The target audience for this session includes not only prokaryotic and archaeal cell biologists but also eukaryotic cell biologists, biophysicists, and computational biologists interested in how the very different self-organizing systems found in archaea and bacteria accomplish similar long-range spatial tasks as eukaryotic cells, often with a far smaller number of components. After attending this session, participants should be able to: 1) Describe a diversity of mechanisms microbes use to establish cellular and temporal organization.2) Appraise new approaches to image and dissect cellular processes within small microorganisms.3) Compare and contrast mechanisms used by prokaryotes, and archaea to conduct long-range tasks.

Organizers: Hui Chen, University of South Carolina; Jan Skotheim, Stanford University; and Matthew Good, University of Pennsylvania

Proliferating eukaryotic cells coordinate growth, division, and differentiation processes. A broad variety of cell types, from fungi to human, utilize a cell size checkpoint, a mechanism which ensures that they grow a defined amount of or achieve a specific size to trigger cell division or differentiation. Recent discoveries have uncovered the molecular basis of cell and tissue growth regulation both in cultured cells ex vivo and in stem cells in situ. Underlying the importance of regulatory processes, alterations to cell growth, cytoplasmic density and cell size impact subcellular partitioning, cellular physiology, mechanics, and gene expression. Additionally, in developing tissues, changes to cell size and nucleocytoplasmic ratio regulate decision-making events essential for growth and cell fate determination. Highlighted in this session is cutting-edge research on how cells and tissues sense and regulate their dimensions and undergo compensatory growth or expression homeostasis. We will feature speakers presenting the latest insights on the mechanistic basis of cell size and growth control. Moreover, we will discuss the dysregulation of cell growth in disease, the links between cell size and shape in cell fate determination, and the extent to which organelle size and protein expression scales with dimensions of cells and tissues.

Organizers: Mustafa Aydogan, University of California San Francisco; and Qiong Yang, University of Michigan

This special interest subgroup will bring together a broad group of scientists who work on questions of biological time control, using approaches of biology, chemistry, physics, mathematics, and computer science to advance the field forward. The session will not only showcase groundbreaking findings in classic fields of the cell cycle and the circadian clock, but also highlight new discoveries on autonomous clocks – biological timing mechanisms that are normally entrained by the cell cycle and/or the circadian clock to run synchronously, but can also run independently of these major programs to execute a variety of sub-cellular functions. Similarly, the subgroup will host researchers who investigate clocks and timers as a function of space and patterns (particularly in development), seminally including the segmentation clock. As cutting-edge tools have been critical to explore aspects of biological timing, the session will also feature advances in networks and dynamics theories to study complex rhythms in biology, as well as new methods to investigate biological timing in vitro, in silico or at the systems levels. Our goal is to promote new interactions between biologists, physicists, and engineers, to invigorate fresh perspectives in the overarching field of biological timing.

Organizer: Qiong Annabel Wang, City of Hope

White, beige, and brown adipocytes play indispensable roles in regulating whole-body energy homeostasis and insulin sensitivity. Adipocytes exhibit remarkable plasticity in response to various physiological and pathophysiological stimuli. Traditional concepts of adipocyte plasticity encompass adipogenesis, the generation of adipocytes from adipose progenitor cells, as well as adipocyte hypertrophy and cell death. Recent technological advancements, particularly in single-cell and spatial technologies, alongside comprehensive genetic mouse models, have paved the way for uncovering new dimensions of adipocyte dynamics. Emerging research is shedding light on previously unexplored phenomena, including adipocyte dedifferentiation and redifferentiation, modulation of adipocyte heterogeneity to meet metabolic demands, and the remodeling of adipocyte function associated with aging. In this session, we will highlight the latest findings in adipocyte biology and their implications for developing innovative adipocyte-based therapeutic strategies.

Organizer: Maddalena Nano, University of California, Santa Barbara

Living systems are continually faced with potentially lethal challenges. Resilience is the ability to adapt to and resist environmental stress and is essential across cell types and organisms. While ensuring the continuation of life and driving evolution, resilience can also mediate the emergence of diseases and therapeutic resistance. It is therefore essential to understand the physiological and pathological mechanisms of resilience. Cellular resilience encompasses the ability of cells to survive environmental and intracellular challenges, and to escape regulated cell death. In the past decades, we have accumulated knowledge on the mechanisms, consequences and signaling networks sensing and relaying stress and lethal stimuli. However, the mechanisms and consequences of cellular resilience are only now coming into focus. This session brings together researchers studying different aspects of cellular resilience. It focuses on the strategies cells can use to overcome potentially lethal stimuli, and on the experimental methodologies we can use to investigate them. This session also aims to help addressing key challenges in the field, such as identifying the variables establishing commitment to cell survival or cell death, to build predictive models and to learn how to experimentally steer these decisions.

Organizers: G.W. Gant Luxton, University of California, Davis; Hanaa Hariri, Wayne State University; and Mary Mirvis, University of California, San Francisco

The last decade has seen a rapid acceleration in organelle interactions research, uncovering a wealth of knowledge on the molecular basis of inter-organelle membrane contact sites (MCS) and communication. This has given rise to an emerging integrative view of organelle structural and functional interconnectivity, featuring many interdependencies and redundancies. The next challenge is to understand the organelle network as a dynamic and highly complex system. The prospect of pursuing a simplified bottom-up view by building in vitro organelle interactions systems has been gaining traction as a promising emerging research area, but remains an untapped avenue of research. Such systems can potentially provide a new perspective on many open questions. What are the precise functions of MCS proteins within their complexes? How do MCS respond to environmental perturbations and changing functional states? How is information transmitted between organelles? What is the interplay between genetically programmed organelle interactions and passive self-organization? Can organelle contact and communication be engineered? This session will showcase cutting edge knowledge and technical advances from organelle biology, biochemistry, synthetic biology, bioengineering, systems biology, biophysics, and more, highlighting the potential for new applications and collaborative work toward the goal of in vitro organelle networks.