Orthodontic Compression Enhances Macrophage M2 Polarization via Histone H3 Hyperacetylation

Integration of mechanics and immunology: Perspective for understanding fibrotic disease mechanisms and innovating therapeutic strategies

The treatment of fibrotic diseases has long posed a medical challenge due to the complex mechanisms underlying their occurrence and progression. Emerging evidence suggests that fibrosis development is influenced not only by biochemical factors but also by the activation of mechanotransduction in response to mechanical stimuli. Mechanoimmunology, an interdisciplinary field that examines how the immune system is influenced by physical forces and mechanical environments, has recently demonstrated significant importance and considerable potential for application in the study of fibrotic diseases. While the mechanisms by which biochemical signals regulate the immune system have been extensively explored, the progression of fibrosis is often impacted by both immune dysregulation and mechanical changes. During fibrosis, immune cells encounter strong mechanical stimuli, such as stiffer substrates and altered viscoelasticity, which activate their own mechanotransduction pathways and subsequently influence fibrosis progression. Targeting the mechanosensation of immune cells to enhance or inhibit their mechanoreception and mechanotransduction, thereby enhancing the anti-fibrotic role they play in the fibrotic process, could help innovate therapeutic strategies for fibrotic diseases. STATEMENT OF SIGNIFICANCE: Fibrotic disease progression is often associated with dysregulation of both tissue mechanical properties and immune responses. The fibrotic microenvironment's altered mechanical properties both result from and drive fibrosis, while immune cells actively sense and respond to these mechanical cues through mechanotransduction pathways. Emerging mechanoimmunology research highlights how mechanical stimuli influence immune cell behavior, yet the precise regulatory mechanisms remain unclear. This review examines mechanical communication in fibrosis, focusing on immune cells' mechanosensing capabilities and their role in disease progression, which helps to enhance our understanding of the pathogenesis of fibrosis and inform innovative strategies to open up mechano-immune pathways targeting fibrosis therapy.

Effect of Porphyromonas Gingivalis Infection on Epithelial Rests of Malassez

The epithelial cell rests of Malassez (ERM) are located within the periodontal ligament. They are reportedly involved in maintaining homeostasis, particularly with regards to the thickness of the periodontal ligament. Their role in apical periodontitis lesions remains unclear, however. This study investigated the response of ERM to infection with Porphyromonas gingivalis. After being infected, the morphology of the P. gingivalis-infected cells was observed using confocal laser-scanning microscopy. The gene expression of P. gingivalis-infected and uninfected cells was investigated by RNA-sequencing analysis. Morphological observation showed the invasion and adhesion of P. gingivalis to the surface of ERM. The RNA analysis showed that the gene expression profile significantly differed between the infected and uninfected cells. At an expression level of ≥2 and false discovery rate of <0.1, the infected cells showed a decrease in 99 genes and an increase in 6 compared with in the non-infected cells. Most of the upregulated genes were unique to epithelial cells, such as endothelial cell-specific molecules and cytokeratin 5; the upregulated genes were associated with the immune response, however. These results indicate that ERM upregulate genes associated with epithelial cells and suppress those associated with the immune response following P. gingivalis infection.

Regulating macrophage phenotypes with IL4I1-mimetic nanoparticles in IDD treatment

Intervertebral disc degeneration (IDD) is a degenerative spinal condition characterized by disc structural damage, narrowing of joint spaces, and nerve root compression, significantly reducing patients' quality of life. To address this challenge, a novel therapeutic strategy was developed using cellulose supramolecular hydrogel as a carrier to deliver IL4I1-modified MΦ membrane biomimetic nanoparticles (CHG@IL4I1-MNPs) to target tissues. This hydrogel exhibits excellent biocompatibility and mechanical properties while enabling sustained drug release in the degenerative disc microenvironment, enhancing therapeutic outcomes. CHG@IL4I1-MNPs effectively regulate MΦ polarization by promoting M2 MΦ activation, thereby improving immune microenvironment balance. Animal studies demonstrated that CHG@IL4I1-MNPs alleviated symptoms of IDD, reduced inflammation, and supported tissue repair, highlighting its potential to reduce reliance on long-term medication and improve quality of life. The strategy uniquely combines nanoparticle technology with immunomodulation, achieving precise targeting of MΦs. Beyond IDD, this approach offers potential applications in other immune-related diseases, providing a versatile platform for nanomedicine. This study introduces an innovative method to treat IDD and advances the integration of immunotherapy and nanotechnology, offering both clinical benefits and new directions for future research. These findings hold strong potential for improving patient outcomes and expanding treatment options for related diseases.

The Molecular Mechanism of Macrophages in Response to Mechanical Stress

Macrophages, a type of functionally diversified immune cell involved in the progression of many physiologies and pathologies, could be mechanically activated. The physical properties of biomaterials including stiffness and topography have been recognized as exerting a considerable influence on macrophage behaviors, such as adhesion, migration, proliferation, and polarization. Recent articles and reviews on the physical and mechanical cues that regulate the macrophage's behavior are available; however, the underlying mechanism still deserves further investigation. Here, we summarized the molecular mechanism of macrophage behavior through three parts, as follows: (1) mechanosensing on the cell membrane, (2) mechanotransmission by the cytoskeleton, (3) mechanotransduction in the nucleus. Finally, the present challenges in understanding the mechanism were also noted. In this review, we clarified the associated mechanism of the macrophage mechanotransduction pathway which could provide mechanistic insights into the development of treatment for diseases like bone-related diseases as molecular targets become possible.

Reduced graphene oxide loaded with tetrahedral framework nucleic acids for combating orthodontically induced root resorption

Root resorption occurs outside the root or within the root canal. Regardless of its region, root resorption is irreversible and in severe cases, may even cause tooth loss. Clinically, the external surface root resorption is usually a side effect of orthodontic tooth movement. However, it is frustrating to note that there are almost no effective treatment strategies for orthodontically induced root resorption (OIRR) due to the complexity and ambiguity of etiology. In the current study, we successfully fabricated a delivery complex, reduced graphene oxide nanosheet loading with tetrahedral framework nucleic acids (tFNAs-rGO) through self-assembly. No significant cytotoxicity or organ-toxicity of the tFNAs-rGO complex was observed in cell counting kit-8 assay (CCK-8) and hematoxylin-eosin (HE) staining. Histological staining such as tartrate-resistant acid phosphatase (TRAP) staining and Micro-CT three-dimensional reconstruction were employed to explore the dynamic changes of root and peri-root tissues in OIRR mice. In vitro, we developed an induction microenvironment to testify the effects of the tFNAs-rGO delivery complex on periodontal ligament cells (PDLCs) and macrophages by quantitative RT-PCR, western blot, and immunofluorescence staining. The data showed the reduced the region of root resorption and downregulated osteoclastic activity in OIRR by the tFNAs-rGO complex treatment. Furthermore, our study demonstrated that the tFNAs-rGO delivery complex enhanced osteogenic differentiation of PDLCs and facilitated M2-phenotype polarization of macrophages to ameliorate OIRR. Collectively, the insight into the nanoscale dual-functional tFNAs-rGO delivery complex regulating the cell populations of PDLCs and macrophages in the root resorption remodeling proposes a promising therapeutic strategy for orthodontically induced root resorption.

Deciphering the dynamics: Exploring the impact of mechanical forces on histone acetylation

Living cells navigate a complex landscape of mechanical cues that influence their behavior and fate, originating from both internal and external sources. At the molecular level, the translation of these physical stimuli into cellular responses relies on the intricate coordination of mechanosensors and transducers, ultimately impacting chromatin compaction and gene expression. Notably, epigenetic modifications on histone tails govern the accessibility of gene-regulatory sites, thereby regulating gene expression. Among these modifications, histone acetylation emerges as particularly responsive to the mechanical microenvironment, exerting significant control over cellular activities. However, the precise role of histone acetylation in mechanosensing and transduction remains elusive due to the complexity of the acetylation network. To address this gap, our aim is to systematically explore the key regulators of histone acetylation and their multifaceted roles in response to biomechanical stimuli. In this review, we initially introduce the ubiquitous force experienced by cells and then explore the dynamic alterations in histone acetylation and its associated co-factors, including HDACs, HATs, and acetyl-CoA, in response to these biomechanical cues. Furthermore, we delve into the intricate interactions between histone acetylation and mechanosensors/mechanotransducers, offering a comprehensive analysis. Ultimately, this review aims to provide a holistic understanding of the nuanced interplay between histone acetylation and mechanical forces within an academic framework.

Molecular signaling and mechanisms of low-level laser-induced gene expression in cells involved in orthodontic tooth movement

BACKGROUND

The study aimed to observe molecular signaling, including reactive oxygen species (ROS) and mitochondrial membrane potential (ΔΨm), to evaluate the alteration of gene expression by low-level laser therapy (LLLT) and the correlation between its mechanisms and the NF-kB pathway in cells involved in orthodontic tooth movement.

METHODS

Osteoblast-like cells (MG63), immortalized periodontal ligament cells (iPDL), and M1 macrophage-like cells were irradiated by 980-nm LLLT with energy densities of 1 and 10 J/cm2 ΔΨm and intracellular ROS were monitored using fluorescent probes. The changes of mRNA expression were assessed using reverse transcription polymerase chain reaction (RT-PCR). NF-kB inhibitor, ROS scavenger, and ΔΨm suppressor were used to analyze signals associated with the regulation of gene expression. Finally, Western blot analysis was performed to confirm NF-kB signaling after LLLT.

RESULTS

We found the increases of ΔΨm and ROS in all three cell types after LLLT, but no significant difference was observed between 1 and 10 J/cm2 LLLT. Regarding gene expression, some target genes were upregulated in MG63 6 h, 12 h, and 1 day after LLLT and in iPDL cells 12 h and 1 day after LLLT. However, no changes occurred in M1 cells. The inhibitor that significantly reduced most changes in gene expression was NF-kB inhibitor. Western blot analysis showed the increase in p-IkBα level after LLLT in iPDL and MG63, but not in M1.

CONCLUSION

The 980-nm LLLT increased ΔΨm and ROS production in all three cell types. However, changes in gene regulation were found only in MG63 and iPDL cells, which related to the NF-kB pathway.

Bioelectricity in dental medicine: a narrative review

BACKGROUND

Bioelectric signals, whether exogenous or endogenous, play crucial roles in the life processes of organisms. Recently, the significance of bioelectricity in the field of dentistry is steadily gaining greater attention.

OBJECTIVE

This narrative review aims to comprehensively outline the theory, physiological effects, and practical applications of bioelectricity in dental medicine and to offer insights into its potential future direction. It attempts to provide dental clinicians and researchers with an electrophysiological perspective to enhance their clinical practice or fundamental research endeavors.

METHODS

An online computer search for relevant literature was performed in PubMed, Web of Science and Cochrane Library, with the keywords "bioelectricity, endogenous electric signal, electric stimulation, dental medicine."

RESULTS

Eventually, 288 documents were included for review. The variance in ion concentration between the interior and exterior of the cell membrane, referred to as transmembrane potential, forms the fundamental basis of bioelectricity. Transmembrane potential has been established as an essential regulator of intercellular communication, mechanotransduction, migration, proliferation, and immune responses. Thus, exogenous electric stimulation can significantly alter cellular action by affecting transmembrane potential. In the field of dental medicine, electric stimulation has proven useful for assessing pulp condition, locating root apices, improving the properties of dental biomaterials, expediting orthodontic tooth movement, facilitating implant osteointegration, addressing maxillofacial malignancies, and managing neuromuscular dysfunction. Furthermore, the reprogramming of bioelectric signals holds promise as a means to guide organism development and intervene in disease processes. Besides, the development of high-throughput electrophysiological tools will be imperative for identifying ion channel targets and precisely modulating bioelectricity in the future.

CONCLUSIONS

Bioelectricity has found application in various concepts of dental medicine but large-scale, standardized, randomized controlled clinical trials are still necessary in the future. In addition, the precise, repeatable and predictable measurement and modulation methods of bioelectric signal patterns are essential research direction.