Cis-clustering of cadherin-23 controls the kinetics of cell-cell adhesion

Cis and trans-interactions in cadherins are the foundations of multicellularity. While the trans-interaction mediate cell-cell adhesion, the cis-interaction is postulated as strengthening to trans by clustering. The well-accepted model in cadherin-adhesion is that the trans precedes cis via a diffusion-trap kinetic model. Here we report that cadherin-23, a non-classical cadherin with an extended extracellular region, undergoes clustering in solution via lateral interactions independent of trans and phase separate as liquid droplets. In cellulo using fluorescence-recovery after the photobleaching, we noticed a significantly slow-diffusion of cadherin-23 at the intercellular junctions, indicating the diffusion of a cluster. The cis-clustering accelerates the cell-cell adhesion and, thus, kinetically controls cell-adhesion via cis precedes trans model. Though the connection of cis-clustering with the rapid adhesion is yet to explore, M2-macrophages that predominantly express cadherin-23 undergo fast attachments to circulatory tumor cells during metastasis.

Cis-clustering of cadherin-23 controls the kinetics of cell-cell adhesion

Cis and trans-interactions in cadherins are the foundations of cellular adhesions in multicellular organisms. While the trans-interactions mediate the intercellular attachment, the cis-interaction is presumed as reinforcement to trans. Thus, trans precedes cis has been the well-accepted model in cadherin adhesion. The stronger affinity of trans-binding over cis has been the decisive influence in the trans first model. Here we show that cadherin-23, a non-classical cadherin with an extended extracellular region, can undergo cis-clustering in solution independent of trans and phase separate as liquid droplets. Using single-molecule measurements, we decipher that weaker cis-interactions favor the cis-clustering. In-cellulo, the cis-clustering is manifested as puncta, a common feature in non-classical cadherin junctions, and accelerates the cell adhesion. The cis-clustering thus kinetically controls cell-adhesion before trans-binding. Notably, M2-macrophages predominantly express cadherin-23 and rapidly attach to circulatory tumor cells during metastatic migration. However, the relation of cis-clustering with rapid cell-cell adhesion in physiology is not yet established

The Molecular Logic Organizing the Functional Compartmentalization of Reciprocal Synapses

Reciprocal synapses are formed by neighboring dendritic processes that create the smallest possible neural circuit. Reciprocal synapses are widespread in brain and essential for information processing, but constitute a conceptual conundrum: How are adjacent pre- and post synaptic specializations maintained as separate functional units? Here, we reveal an organizational principle for reciprocal synapses, using dendrodendritic synapses between mitral and granule cells in the mouse olfactory bulb as a paradigm. We show that mitral cells secrete cerebellin-1 to block the cis-interaction of mitral cell neurexins with neuroligins, thereby enabling their separate trans-interactions. Ablating either cerebellin-1 or neuroligins in mitral cells severely impaired granule cell→mitral cell synapses, as did overexpression of postsynaptic neurexins that form ciscomplexes with neuroligins, but not of mutant neurexins unable to bind to neuroligins. Our data uncover a cis/trans-protein interaction network as a general design principle that organizes reciprocal dendro dendritic synapses by compartmentalizing neurexin-based trans-synaptic protein complexes.

Ultrastructural details of mammalian chromosome architecture

ABSTRACTOver the past decade, 3C-related methods, complemented by increasingly detailed microscopic views of the nucleus, have provided unprecedented insights into chromosome folding in vivo. Here, to overcome the resolution limits inherent to the majority of genome-wide chromosome architecture mapping studies, we extend a recently-developed Hi-C variant, Micro-C, to map chromosome architecture at nucleosome resolution in human embryonic stem cells and fibroblasts. Micro-C maps robustly capture well-described features of mammalian chromosome folding including A/B compartment organization, topologically associating domains (TADs), and cis interaction peaks anchored at CTCF binding sites, while also providing a detailed 1-dimensional map of nucleosome positioning and phasing genome-wide. Compared to high-resolution in situ Hi-C, Micro-C exhibits substantially improved signal-to-noise with an order of magnitude greater dynamic range, enabling not only localization of domain boundaries with single-nucleosome accuracy, but also resolving more than 20,000 additional looping interaction peaks in each cell type. Intriguingly, many of these newly-identified peaks are localized along stripe patterns and form transitive grids, consistent with their anchors being pause sites impeding the process of cohesin-dependent loop extrusion. Together, our analyses provide the highest resolution maps of chromosome folding in human cells to date, and provide a valuable resource for studies of chromosome folding mechanisms.