Metrics of 2D immunological synapses in human T cells via high-content confocal cell imaging.

Immunological synapses (IS) are the privileged site of complex information transfer between T cells and antigen presenting cells. IS are highly structured in terms of actin and tubulin cytoskeleton organization, receptor and proximal signal patterning, and intracellular organelle polarization. The magnitude and quality of T cell responses upon antigen recognition is dependent on IS molecular organization. For that reason, methods to precisely assess IS parameters are crucial to monitor T cell activation and function in health and disease, but also for T cell centered therapeutic intervention. Confocal and super-resolution microscopy approaches have allowed to characterize the complex structure of the T cell IS. However, those approaches suffer from a low-throughput and low-content format precluding multi-parametric classification of IS across large numbers of samples or stimulatory conditions. Here, we present a protocol of high-content confocal cell imaging in a 384-well plate format adapted to the unbiased analysis of primary T cells forming IS over pre-coated stimulatory molecules. The protocol focuses on the staining of F-actin, pericentrin and granzyme B in CD8+ T cells, but is transposable to other IS molecular markers and lymphocyte subsets. We discuss potential applications offered by the multi-parametric characterization of T cell IS in a high-throughput format.

Kinetic measurements of human CD8+ T cell cytotoxic activity in a 384-well plate format.

The elimination of infected or cancerous cells by CD8+ cytotoxic T lymphocytes (CTL) is a crucial effector mechanism of the immune system. Upon antigen recognition, CTL stop migrating, establish a tight contact with target cells and deliver cytotoxic molecules such as perforin and granzymes that lead to target cell apoptosis. The ability of CTL to control a population of infected cells or a tumor depends on multiple parameters, such as the relative numbers of CTL and target cells, the intrinsic cytotoxic activity of CTL, the intrinsic resistance of target cells and the repertoire of immune checkpoints tuning cytotoxic activity at the CTL:target cell interface. In this context, in vitro assays to precisely measure CTL:target cell interactions and cytotoxic activity over time are required to monitor natural or therapeutic responses. We here present an image-based method that allows recording of positions and survival of CTL and target cells over time in a high-throughput format. The protocol relies on the staining of CTL and target cells with fluorescent dyes and the automated imaging of cells deposited in wells of a 384-well plate with an automated cell imaging device. We discuss potential applications offered by the kinetic assessment of CTL cytotoxic activity in a high-throughput format.

Deciphering actin remodelling in immune cells through the prism of actin-related inborn errors of immunity.

Actin cytoskeleton remodelling drives cell motility, cell to cell contacts, as well as membrane and organelle dynamics. Those cellular activities operate at a particularly high pace in immune cells since these cells migrate through various tissues, interact with multiple cellular partners, ingest microorganisms and secrete effector molecules. The central and multifaceted role of actin cytoskeleton remodelling in sustaining immune cell tasks in humans is highlighted by rare inborn errors of immunity due to mutations in genes encoding proximal and distal actin regulators. In line with the specificity of some of the actin-based processes at work in immune cells, the expression of some of the affected genes, such as WAS, ARPC1B and HEM1 is restricted to the hematopoietic compartment. Exploration of these natural deficiencies highlights the fact that the molecular control of actin remodelling is tuned distinctly in the various subsets of myeloid and lymphoid immune cells and sustains different networks associated with a vast array of specialized tasks. Furthermore, defects in individual actin remodelling proteins are usually associated with partial cellular impairments highlighting the plasticity of actin cytoskeleton remodelling. This review covers the roles of disease-associated actin regulators in promoting the actin-based processes of immune cells. It focuses on the specific molecular function of those regulators across various immune cell subsets and in response to different stimuli. Given the fact that numerous immune-related actin defects have only been characterized recently, we further discuss the challenges lying ahead to decipher the underlying patho-mechanisms.