Hydrogels for directed stem cell differentiation and tissue repair

Thanks to their tunable physical and biochemical properties, hydrogels are an attractive tool for tissue engineering applications. This review highlights the design parameters that have been shown to influence stem cell behaviour when cultured on or within hydrogels and presents the various types of materials and crosslinking methods currently used to produce hydrogels suitable for stem cell-based tissue engineering. We also focus on new generations of hydrogels with spatially and dynamically controllable physical and biochemical properties, which open up new perspectives in the study of stem cell behaviour and in the development of therapeutic solutions in regenerative medicine. In line with the current need for more tunable and dynamic properties, polyrotaxane hydrogels can be used to create spatially flexible structures at the molecular scale and are therefore emerging as a new player in the field of tissue engineering

Nanoscale surfaces for the long-term maintenance of mesenchymal stem cell phenotype and multipotency

There is currently an unmet need for the supply of autologous, patient-specific stem cells for regenerative therapies in the clinic. Mesenchymal stem cell differentiation can be driven by the material/cell interface suggesting a unique strategy to manipulate stem cells in the absence of complex soluble chemistries or cellular reprogramming. However, so far the derivation and identification of surfaces that allow retention of multipotency of this key regenerative cell type have remained elusive. Adult stem cells spontaneously differentiate in culture, resulting in a rapid diminution of the multipotent cell population and their regenerative capacity. Here we identify a nanostructured surface that retains stem-cell phenotype and maintains stem-cell growth over eight weeks. Furthermore, the study implicates a role for small RNAs in repressing key cell signalling and metabolomic pathways, demonstrating the potential of surfaces as non-invasive tools with which to address the stem cell niche.<br/

Complexity in biomaterials for tissue engineering

The molecular and physical information coded within the extracellular milieu is informing the development of a new generation of biomaterials for tissue engineering. Several powerful extracellular influences have already found their way into cell-instructive scaffolds, while others remain largely unexplored. Yet for commercial success tissue engineering products must be not only efficacious but also cost-effective, introducing a potential dichotomy between the need for sophistication and ease of production. This is spurring interest in recreating extracellular influences in simplified forms, from the reduction of biopolymers into short functional domains, to the use of basic chemistries to manipulate cell fate. In the future these exciting developments are likely to help reconcile the clinical and commercial pressures on tissue engineering

DDX3X acts as a live-or-die checkpoint in stressed cells by regulating NLRP3 inflammasome.

The cellular stress response has a vital role in regulating homeostasis by modulating cell survival and death. Stress granules are cytoplasmic compartments that enable cells to survive various stressors. Defects in the assembly and disassembly of stress granules are linked to neurodegenerative diseases, aberrant antiviral responses and cancer1-5. Inflammasomes are multi-protein heteromeric complexes that sense molecular patterns that are associated with damage or intracellular pathogens, and assemble into cytosolic compartments known as ASC specks to facilitate the activation of caspase-1. Activation of inflammasomes induces the secretion of interleukin (IL)-1β and IL-18 and drives cell fate towards pyroptosis-a form of programmed inflammatory cell death that has major roles in health and disease6-12. Although both stress granules and inflammasomes can be triggered by the sensing of cellular stress, they drive contrasting cell-fate decisions. The crosstalk between stress granules and inflammasomes and how this informs cell fate has not been well-studied. Here we show that the induction of stress granules specifically inhibits NLRP3 inflammasome activation, ASC speck formation and pyroptosis. The stress granule protein DDX3X interacts with NLRP3 to drive inflammasome activation. Assembly of stress granules leads to the sequestration of DDX3X, and thereby the inhibition of NLRP3 inflammasome activation. Stress granules and the NLRP3 inflammasome compete for DDX3X molecules to coordinate the activation of innate responses and subsequent cell-fate decisions under stress conditions. Induction of stress granules or loss of DDX3X in the myeloid compartment leads to a decrease in the production of inflammasome-dependent cytokines in vivo. Our findings suggest that macrophages use the availability of DDX3X to interpret stress signals and choose between pro-survival stress granules and pyroptotic ASC specks. Together, our data demonstrate the role of DDX3X in driving NLRP3 inflammasome and stress granule assembly, and suggest a rheostat-like mechanistic paradigm for regulating live-or-die cell-fate decisions under stress conditions.T.-D.K. is supported by NIH grants AI101935, AI124346, AR056296 and CA163507 and by the American Lebanese Syrian Associated Charities; the St. Jude Children's Research Hospital Cell and Tissue Imaging Center is supported by St. Jude Children's Research Hospital and by National Cancer Institute grant P30 CA021765-35; R.J.G. is supported by Cancer Research UK, the Mathile Family Foundation, Cure Search, the Sohn Foundation and NIH grants P01CA96832 and R0CA1129541