Editorial: ImmunoPhysics and ImmunoEngineering

© 2020 Bernardino de la Serna, Mellado, Dustin, Garcia-Parajo and Morikis.The immune system comprises a collection of specialized cells, tissues, and organs that protect the organisms against pathogens and can survey cancer cells. Immune responses are precisely coordinated events that take place in complex, specialized tissue microenvironments. For an integrated view of innate and adaptive immune responses at the molecular level, we ideally need a better understanding of how immune cells communicate and fulfill their tasks in vivo, following events spatially and temporally. Conventional biochemical and genetic methods consider the cell as an individual entity and ligand/receptor pairs as isolated systems. Often, the data obtained refers to the average behavior of a pool of cells and/or receptors removed from their real-life context. The use of new technologies, particularly real-time imaging approaches, is showing us that biological responses are very dynamic and extremely dependent on the context in which they take place and are therefore much more diverse than we initially thought. The combination of these new approaches is radically transforming and enriching immunology, as demonstrated by the increasing number of publications in which physical and/or engineering tools are applied to study the immune response. Whilst scientists are often questioned for the discipline their research is best framed in, we rather think that one scientific discipline cannot be reduced to the terms of another. However, defining and naming cross-disciplinary fields sets our minds on common ground and helps establish a fluent communication to eventually produce groundbreaking, beautiful pieces of science. For instance, ImmunoPhysics was probably first coined by Prof. Morikis a couple of decades ago (https://www.biophysics.org/profiles/dimitrios-morikis); nevertheless, ImmunoPhysics has not become widely regarded as a discipline, despite the continuously growing body of research that requires physical approaches to resolving immunological questions. Hence, with this special issue, we wanted to open a scientific platform compiling ImmunoPhysics and ImmunoEngineering research breakthroughs and future perspectives. Sadly, towards the end of this fascinating journey Prof. Morikis passed away; thus now, with this special issue, we would also like to pay tribute to his fundamental contributions to the field

Differential Scanning Fluorimetry provides high throughput data on silk protein transitions

Here we present a set of measurements using Differential Scanning Fluorimetry (DSF) as an inexpensive, high throughput screening method to investigate the folding of silk protein molecules as they abandon their first native melt conformation, dehydrate and denature into their final solid filament conformation. Our first data and analyses comparing silks from spiders, mulberry and wild silkworms as well as reconstituted ‘silk’ fibroin show that DSF can provide valuable insights into details of silk denaturation processes that might be active during spinning. We conclude that this technique and technology offers a powerful and novel tool to analyse silk protein transitions in detail by allowing many changes to the silk solutions to be tested rapidly with microliter scale sample sizes. Such transition mechanisms will lead to important generic insights into the folding patterns not only of silks but also of other fibrous protein (bio)polymers

On the role of electromagnetic boundary conditions in single molecule fluorescence lifetime studies of dyes embedded in thin films

Single molecule fluorescence lifetime studies are generally performed in thin polymer films, where the influence of the interface on the behaviour of fluorescing molecules is not negligible. In order to describe this influence, we investigate annealed films of different thickness. We show that the distribution of fluorescence lifetimes of the embedded dyes is shifted to lower values as the thickness of the film increases. We explain this shift by simple electromagnetic arguments related to the boundary conditions at the interfaces of the polymer film with air and glass, respectively. The conclusion is that extreme care must be taken in order to interpret single molecule data with respect to the true chemical nature of the phenomena

Galectin-9 binds IgM-BCR to regulate B cell signaling

The galectin family of secreted lectins are important regulators of immune cell function; however, their role in B cell responses is poorly understood. Here, the authors identify IgM-BCR as a ligand for galectin-9. In resting naive cells, they show that galectin-9 mediates a close association between IgM and CD22