Publications

The cell nucleus is continuously exposed to external signals, of both chemical and mechanical nature. To ensure proper cellular response, cells need to regulate the transmission, timing and duration of these signals. Although such timescale regulation is well described for chemical signals, whether and how it applies to mechanical signals reaching the nucleus is still not fully understood. Here we demonstrate that the formation of fibrillar adhesions locks the nucleus in a mechanically deformed conformation, setting the mechano-response timescale to that of fibrillar adhesion remodelling (similar to 1 h). This process encompasses both mechanical deformation and associated mechanotransduction (such as via YAP), in response to both increased and decreased mechanical stimulation. The underlying mechanism is the anchoring of the vimentin cytoskeleton to fibrillar adhesions and the extracellular matrix through plectin 1f, which maintains nuclear deformation. Our results reveal a mechanism to regulate the timescale of mechanical adaptation, effectively setting a low-pass filter to mechanotransduction.

JTD Keywords: Cells, F1, Forces, Mechanotransduction, Memory, Protein, Shape, Stiffness, Streptococcus-pyogenes, Translocation

Bacterial colonization on biomaterials is a major issue, leading to approximately 20% of implant failures due to infection and biofilm formation. To address this, peptide-based hydrogels incorporating tailored bioactive peptides have emerged as promising candidates for applications in tissue engineering and infection control. Here, we have designed peptide sequences that incorporate i) a self-assembling unit (SaU) and ii) bioactive motifs, including the well-known arginine-glycine-aspartate (RGD) sequence to promote cell adhesion or an antimicrobial peptide derived from lactoferrin (LF) to exhibit antibacterial properties. To aid in the gelation, these peptides were combined with hyaluronic acid (HA), rendering peptide-based hydrogels without the need for additional external assembly triggers, simplifying their application in biomedical contexts. This protocol allowed for a spontaneous formation of a 3D fibrillar network, with structural and physicochemical properties suitable for tissue engineering. The biological evaluation revealed the ability of RGD-based hydrogels to increase the adhesion and spreading of osteoblastic cells compared to controls, while the LF-based hydrogels significantly reduced the viability and attachment of both Gram-positive and Gram-negative strains, clearly affecting bacterial morphology. This report demonstrates the feasibility of this technology to produce hydrogels incorporating distinct biological cues, highlighting their potential as versatile biomaterials to address diverse biomedical challenges.

JTD Keywords: Alginate, Antimicrobial peptide, Bacterial adhesion, Biomaterial, Cell adhesion, Circular-dichroism, Design, Hlf1-11 peptide, Human lactoferrin, Hyaluronic-acid, Lf, Molecules, Peptide-based hydrogels, Rgd, Self-assembling peptide, Titanium

Hydrogels with cell adhesive moieties stand out as promising materials to enhance tissue healing and regeneration. Nonetheless, bacterial infections of the implants represent an unmet major concern. In the present work, we developed an alginate hydrogel modified with a multifunctional peptide containing the RGD cell adhesive motif in combination with an antibacterial peptide derived from the 1-11 region of lactoferrin (LF). The RGD-LF branched peptide was successfully anchored to the alginate backbone by carbodiimide chemistry, as demonstrated by 1H NMR and fluorescence measurements. The functionalized hydrogel presented desirable physicochemical properties (porosity, swelling and rheological behavior) to develop biomaterials for tissue engineering. The viability of mesenchymal stem cells (MSCs) on the peptide-functionalized hydrogels was excellent, with values higher than 85 % at day 1, and higher than 95 % after 14 days in culture. Moreover, the biological characterization demonstrated the ability of the hydrogels to significantly enhance ALP activity of MSCs as well as to decrease bacterial colonization of both Gram-positive and Gram-negative models. Such results prove the potential of the functionalized hydrogels as novel biomaterials for tissue engineering, simultaneously displaying cell adhesive activity and the capacity to prevent bacterial contamination, a dual bioactivity commonly not found for these types of hydrogels. In this work we report on the functionalization of an alginate hydrogel with a tailor-made multifunctional peptide containing the cell adhesive RGD motif and the LF1-11 antibacterial peptide. Such novel multifunctional biomaterial ensures the viability of human mesenchymal stem cells, enhances ALP activity and decreases bacterial infections of both Gram-positive and Gram-negative models. image

JTD Keywords: Alginate hydrogel, Alginates, Anti-bacterial agents, Antimicrobial peptid, Antimicrobial peptide, Antimicrobial peptides, Arginyl-glycyl-aspartic acid, Biocompatible materials, Biofunctionalization, Bone, Cell adhesion, Cell survival, Composite hydrogels, Cross-linking, Hlf1-11 peptide, Human lactoferrin, Humans, Hydrogels, Immobilization, Mesenchymal stem cells, Multifunctional peptide, Oligopeptides, Peptides, Physical-properties, Scaffolds, Surfac, Tissue engineering