Tissue expansion techniques physically expand swellable gel‐embedded biological specimens to overcome the resolution limit of light microscopy. As the benefits of expansion come at the expense of signal concentration, imaging volume and time, and mechanical integrity of the sample, the optimal expansion ratio may widely differ depending on the experiment. However, existing expansion methods offer only fixed expansion ratios that cannot be easily adjusted to balance the gain and loss associated with expansion. Here, a hydrogel conversion‐based expansion method is presented, that enables easy adjustment of the expansion ratio for individual needs, simply by changing the duration of a heating step. This method, termed ZOOM, isotropically expands samples up to eightfold in a single expansion process. ZOOM preserves biomolecules for post‐processing labelings and supports multi‐round expansion for the imaging of a single sample at multiple zoom factors. ZOOM can be flexibly and scalably applied to nanoscale imaging of diverse samples, ranging from cultured cells to thick tissues, as well as bacteria, exoskeletal Caenorhabditis elegans, and human brain samples.
Nictation is a behaviour in which a nematode stands on its tail and waves its head in three dimensions. This activity promotes dispersal of dauer larvae by allowing them to attach to other organisms and travel on them to a new niche. In this review, we describe our understanding of nictation, including its diversity in nematode species, how it is induced by environmental factors, and neurogenetic factors that regulate nictation. We also highlight the known cellular and signalling factors that affect nictation, for example, IL2 neurons, insulin/IGF-1 signalling, TGF-b signalling, FLP neuropeptides and piRNAs. Elucidation of the mechanism of nictation will contribute to increased understanding of the conserved dispersal strategies in animals.
A fundamental question in neurodevelopmental biology is how flexibly the nervous system can change during development. To address this question of developmental plasticity, we analyzed the connectome of dauer, an alternative developmental stage of nematodes with physiological and behavioral characteristics remarkably distinct from other developmental stages. We reconstructed the complete chemical connectome of a dauer by manual volumetric reconstruction and automated synapse detection using deep learning. While the basic architecture of the nervous system was preserved, there were also structural changes in neurons, large or small, that were closely associated with changes in the connectivity, some of which in turn evoked dauer-specific behaviors such as nictation. Combining the connectome data and optogenetic experiments were enough to reveal dauer-specific neural connections for the dauer-specific behavior. Graph theoretical analyses showed higher clustering of motor neurons and more feedback connections from motor to sensory neurons in the dauer connectome, suggesting that the dauer connectome allows a quick response to an ever-changing environment. We suggest that the nervous system in the nematode, which can be extended to animals in general, has evolved to obtain the ability to respond to harsh environments by reversibly developing a connectome quantitatively and qualitatively differentiated from other developmental stages.
In article number https://doi.org/10.1002/advs.201901673, Yan Lee, Sung‐Yon Kim, and co‐workers develop ZOOM, a new tissue expansion technique based on the hydrogel conversion reaction, to enable scalable and isotropic expansion of biological samples with easily tunable expansion ratio (up to eightfold). This method allows for simple and flexible expansion of a wide range of biological samples, from bacteria to human brain tissues, for super‐resolution imaging of samples with ordinary microscopes.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.