A. Cambi

Interplay between myosin IIA-mediated contractility and actin network integrity orchestrates podosome composition and oscillations

Tissue-resident dendritic cells patrol for foreign antigens while undergoing slow mesenchymal migration. Using actomyosin-based structures called podosomes, dendritic cells probe and remodel extracellular matrix topographical cues. Podosomes comprise an actin-rich protrusive core surrounded by an adhesive ring of integrins, cytoskeletal adaptor proteins and actin network filaments. Here we reveal how the integrity and dynamics of protrusive cores and adhesive rings are coordinated by the actomyosin apparatus. Core growth by actin polymerization induces podosome protrusion and provides tension within the actin network filaments. The tension transmitted to the ring recruits vinculin and zyxin and preserves overall podosome integrity. Conversely, myosin IIA contracts the actin network filaments and applies tension to the vinculin molecules bound, counterbalancing core growth and eventually reducing podosome size and protrusion. We demonstrate a previously unrecognized interplay between actin and myosin IIA in podosomes, providing novel mechanistic insights into how actomyosin-based structures allow dendritic cells to sense the extracellular environment.

C-Type Lectins on Dendritic Cells and Their Interaction with Pathogen-Derived and Endogenous Glycoconjugates

Human C-type lectin receptors (CLRs) characteristically bind glycosylated ligands in a Ca(2+)-dependent way via their carbohydrate recognition domain (CRD). Their carbohydrate preference is dependent on the amino acid sequence in the CRD domain and on the ability and flexibility of the CRD domain to accommodate sugar moieties that are located at different distances from each other in the glycoconjugate. Although microbial and vertebrate cells are able to produce similar polysaccharide chains, the density of carbohydrates on microbes is much higher compared to vertebrate cells. Despite this difference, carbohydrates present on both cell types can be recognized by the CLRs. These receptors are predominantly expressed by antigen presenting cells such as dendritic cells. In addition to the Toll-like receptor family, CLRs function as pattern recognition receptors by recognizing glycosylated patterns on pathogens. This usually results in internalization of the pathogen, lysosomal degradation and subsequent loading of pathogen-derived peptides into major histocompatibility complex molecules for antigen presentation. However, several pathogens have developed ways to exploit the CLRs to evade immune eradication by for example escaping from the lysosomal degradation pathway or by inducing anti-inflammatory cytokines. When CLRs bind endogenous glycosylated ligands they mediate several processes like cell-cell adhesion and clearance of aberrant cells like tumor cells or apoptotic cells.

Dynamic coupling of ALCAM to the actin cortex strengthens cell adhesion to CD6.

ABSTRACT At the immunological synapse, the activated leukocyte cell adhesion molecule (ALCAM) on a dendritic cell (DC) and CD6 molecules on a T cell contribute to sustained DC–T-cell contacts. However, little is known about how ALCAM–CD6 bonds resist and adapt to mechanical stress. Here, we combine single-cell force spectroscopy (SCFS) with total-internal reflection fluorescence microscopy to examine ALCAM–CD6-mediated cell adhesion. The combination of cells expressing ALCAM constructs with certain cytoplasmic tail mutations and improved SCFS analysis processes reveal that the affinity of ALCAM–CD6 bonds is not influenced by the linking of the intracellular domains of ALCAM to the actin cortex. By contrast, the recruitment of ALCAM to adhesion sites and the propensity of ALCAM to anchor plasma membrane tethers depend on actin cytoskeletal interactions. Furthermore, linking ALCAM to the actin cortex through adaptor proteins stiffens the cortex and strengthens cell adhesion. We propose a framework for how ALCAMs contribute to DC–T-cell adhesion, stabilize DC–T-cell contacts and form a mechanical link between CD6 and the actin cortex to strengthen cell adhesion at the immunological synapse.

Automated podosome identification and characterization in fluorescence microscopy images

Podosomes are cellular adhesion structures involved in matrix degradation and invasion that comprise an actin core and a ring of cytoskeletal adaptor proteins. They are most often identified by staining with phalloidin, which binds F-actin and therefore visualizes the core. However, not only podosomes, but also many other cytoskeletal structures contain actin, which makes podosome segmentation by automated image processing difficult. Here, we have developed a quantitative image analysis algorithm that is optimized to identify podosome cores within a typical sample stained with phalloidin. By sequential local and global thresholding, our analysis identifies up to 76% of podosome cores excluding other F-actin-based structures. Based on the overlap in podosome identifications and quantification of podosome numbers, our algorithm performs equally well compared to three experts. Using our algorithm we show effects of actin polymerization and myosin II inhibition on the actin intensity in both podosome core and associated actin network. Furthermore, by expanding the core segmentations, we reveal a previously unappreciated differential distribution of cytoskeletal adaptor proteins within the podosome ring. These applications illustrate that our algorithm is a valuable tool for rapid and accurate large-scale analysis of podosomes to increase our understanding of these characteristic adhesion structures.