Cumulative Signaling Through NOD-2 and TLR-4 Eliminates the Mycobacterium Tuberculosis Concealed Inside the Mesenchymal Stem Cells

Exploring host-pathogen interactions in the Dictyostelium discoideum-Mycobacterium marinum infection model of tuberculosis

Mycobacterium tuberculosis is a pathogenic mycobacterium that causes tuberculosis. Tuberculosis is a significant global health concern that poses numerous clinical challenges, particularly in terms of finding effective treatments for patients. Throughout evolution, host immune cells have developed cell-autonomous defence strategies to restrain and eliminate mycobacteria. Concurrently, mycobacteria have evolved an array of virulence factors to counteract these host defences, resulting in a dynamic interaction between host and pathogen. Here, we review recent findings, including those arising from the use of the amoeba Dictyostelium discoideum as a model to investigate key mycobacterial infection pathways. D. discoideum serves as a scalable and genetically tractable model for human phagocytes, providing valuable insights into the intricate mechanisms of host-pathogen interactions. We also highlight certain similarities between M. tuberculosis and Mycobacterium marinum, and the use of M. marinum to more safely investigate mycobacteria in D. discoideum.

Revolutionizing medicine with toll-like receptors: A path to strengthening cellular immunity

Toll-like receptors play a vital role in cell-mediated immunity, which is crucial for the immune system's defense against pathogens and maintenance of homeostasis. The interaction between toll-like-receptor response and cell-mediated immunity is complex and essential for effectively eliminating pathogens and maintaining immune surveillance. In addition to pathogen recognition, toll-like receptors serve as adjuvants in vaccines, as molecular sensors, and recognize specific patterns associated with pathogens and danger signals. Incorporating toll-like receptor ligands into vaccines can enhance the immune response to antigens, making them potent adjuvants. Furthermore, they bridge the innate and adaptive immune systems and improve antigen-presenting cells' capacity to process and present antigens to T cells. The intricate signaling pathways and cross-talk between toll-like-receptor and T cell receptor (TCR) signaling emphasize their pivotal role in orchestrating effective immune responses against pathogens, thus facilitating the development of innovative vaccine strategies. This article provides an overview of the current understanding of toll-like receptor response and explores their potential clinical applications. By unraveling the complex mechanisms of toll-like-receptor signaling, we can gain novel insights into immune responses and potentially develop innovative therapeutic approaches. Ongoing investigations into the toll-like-receptor response hold promise in the future in enhancing our ability to combat infections, design effective vaccines, and improve clinical outcomes.

Development and challenges of antimicrobial peptide delivery strategies in bacterial therapy: A review

The escalating global prevalence of antimicrobial resistance poses a critical threat, prompting concerns about its impact on public health. This predicament is exacerbated by the acute shortage of novel antimicrobial agents, a scarcity attributed to the rapid surge in bacterial resistance. This review delves into the realm of antimicrobial peptides, a diverse class of compounds ubiquitously present in plants and animals across various natural organisms. Renowned for their intrinsic antibacterial activity, these peptides provide a promising avenue to tackle the intricate challenge of bacterial resistance. However, the clinical utility of peptide-based drugs is hindered by limited bioavailability and susceptibility to rapid degradation, constraining efforts to enhance the efficacy of bacterial infection treatments. The emergence of nanocarriers marks a transformative approach poised to revolutionize peptide delivery strategies. This review elucidates a promising framework involving nanocarriers within the realm of antimicrobial peptides. This paradigm enables meticulous and controlled peptide release at infection sites by detecting dynamic shifts in microenvironmental factors, including pH, ROS, GSH, and reactive enzymes. Furthermore, a glimpse into the future reveals the potential of targeted delivery mechanisms, harnessing inflammatory responses and intricate signaling pathways, including adenosine triphosphate, macrophage receptors, and pathogenic nucleic acid entities. This approach holds promise in fortifying immunity, thereby amplifying the potency of peptide-based treatments. In summary, this review spotlights peptide nanosystems as prospective solutions for combating bacterial infections. By bridging antimicrobial peptides with advanced nanomedicine, a new therapeutic era emerges, poised to confront the formidable challenge of antimicrobial resistance head-on.

Antimicrobial Properties of Equine Stromal Cells and Platelets and Future Directions

Increasing antimicrobial resistance in veterinary practice has driven the investigation of novel therapeutic strategies including regenerative and biologic therapies to treat bacterial infection. Integration of biological approaches such as platelet lysate and mesenchymal stromal cell (MSC) therapy may represent adjunctive treatment strategies for bacterial infections that minimize systemic side effects and local tissue toxicity associated with traditional antibiotics and that are not subject to antibiotic resistance. In this review, we will discuss mechanisms by which biological therapies exert antimicrobial effects, as well as potential applications and challenges in clinical implementation in equine practice.

Comparative interleukins and chemokines analysis of mice mesenchymal stromal cells infected with Mycobacterium tuberculosis H37Rv and H37Ra

Inflammatory pathways involving Mesenchymal stromal cells (MSCs) play an important role in Mycobacterium tuberculosis (Mtb) infection. H37Rv (Rv) is a standard virulent strain, however, H37Ra (Ra) is a strain with reduced virulence. Interleukins and chemokines production are known to promote inflammation resistance in mammalian cells and is recently reported to regulate mycobacterial immunopathogenesis via inflammatory responses. MSCs are very important cells during Mtb infection. However, the different expressions of interleukins and chemokines in the process of Mtb-infected MSCs between Ra and Rv remain unclear. We used the techniques of RNA-Seq, Q-RT-PCR, ELISA, and Western Blotting. We have shown that Rv infection significantly increased mRNA expressions of Mndal, Gdap10, Bmp2, and Lif, thereby increasing more differentiation of MSCs compared with Ra infection in MSCs. Further investigation into the possible mechanisms, we found that Rv infection enhanced more inflammatory response (Mmp10, Mmp3, and Ptgs2) through more activation of the TLR2-MAP3K1-JNK pathway than did Ra infection in MSCs. Further action showed that Rv infection enhanced more Il1α, Il6, Il33, Cxcl2, Ccl3, and Ackr3 production than did Ra infection. Rv infection showed more expressions of Mmp10, Mmp3, Ptgs2, Il1α, Il6, Il33, Cxcl2, Ccl3, and Ackr3 possibly through more active TLR2-MAP3K1-JNK pathway than did Ra infection in MSCs. MSCs may therefore be a new candidate for the prevention and treatment of tuberculosis.

A nod to the bond between NOD2 and mycobacteria

Mycobacteria are responsible for several human and animal diseases. NOD2 is a pattern recognition receptor that has an important role in mycobacterial recognition. However, the mechanisms by which mutations in NOD2 alter the course of mycobacterial infection remain unclear. Herein, we aimed to review the totality of studies directly addressing the relationship between NOD2 and mycobacteria as a foundation for moving the field forward. NOD2 was linked to mycobacterial infection at 3 levels: (1) genetic, through association with mycobacterial diseases of humans; (2) chemical, through the distinct NOD2 ligand in the mycobacterial cell wall; and (3) immunologic, through heightened NOD2 signaling caused by the unique modification of the NOD2 ligand. The immune response to mycobacteria is shaped by NOD2 signaling, responsible for NF-κB and MAPK activation, and the production of various immune effectors like cytokines and nitric oxide, with some evidence linking this to bacteriologic control. Absence of NOD2 during mycobacterial infection of mice can be detrimental, but the mechanism remains unknown. Conversely, the success of immunization with mycobacteria has been linked to NOD2 signaling and NOD2 has been targeted as an avenue of immunotherapy for diseases even beyond mycobacteria. The mycobacteria-NOD2 interaction remains an important area of study, which may shed light on immune mechanisms in disease.

miR-124-Antagonist-Loaded Liposomal Nanoparticles Negatively Regulate the Toll-Like Receptor (TLR)-Signaling Pathway in Alveolar Epithelial Cells in Pulmonary Tuberculosis

miR-124 is intensively expressed in the alveolar epithelial cells of pulmonary tuberculosis. This study focused on exploring the negative regulation of miR-124-antagonist-loaded liposomal nanoparticles on the Toll-like receptor (TLR)-signal transduction pathway in the alveolar epithelial cells from pulmonary tuberculosis, aiming to provide theoretical evidence for the treatment of pulmonary tuberculosis. The purchased alveolar epithelial cells were grouped into Blank group, Empty-vector group, Bacillus Calmette-Guerin (BCG) group, Nanoparticle+MiR-124 Antagonist group, MiR-124 Antagonist group, and MiR-124 Agonist group. The liposomal nanoparticles were identified. The following aspects were investigated: mRNA level of miR-124, mRNA and protein levels of Myeloid differentiation factor 88 (MyD 88), Toll-like receptor the 6 (TLR 6) and their downstream molecules Nuclear Factor-κB (NF-κB) and Tumor necrosis factor TNF receptor-associated factor 6 (TRAF 6) secretion level of cytokines (NF-κB, IL-8, IL-1α, TNF-α and IL-6), as well as the regulatory link between miR-124-antagonists with TLR6 and MyD88. The liposomal nanoparticles were uniform in size, with an average particle size of (35.25±10.58) nm and an average Zeta potential of (−48.55±10.27) mV. The miR-124 level was the strongest in the MiR-124 Agonist group, while being the lowest in the Blank group. The miR-124 level was relatively higher in the BCG group and Empty-vector group, while being significantly reduced in the Nanoparticle+MiR-124 Antagonist group, which was higher than the Blank group. The miR-124 level in the MiR-124 Antagonist group was higher than that in the Nanoparticle+MiR-124 Antagonist group (P <0.05). The mRNA and protein levels of MyD88, TLR6, NF-κB and TRAF6 were the highest in the MiR-124 Agonist group, while being the lowest in the Blank group. The transcription and translation levels of TRAF6, TLR6, NF-κB and MyD88 were relatively higher in the BCG group and Empty-vector group, while being significantly reduced in the Nanoparticle+ MiR-124 Antagonist group, which were higher than in the Blank group. The transcription and translation levels of TRAF6, TLR6, NF-κB and MyD88 were in the MiR-124 Antagonist group were higher than that in the Nanoparticle+MiR-124 Antagonist group (P <0.05). The secretion levels of inflammatory factors (NF-κB, IL-8, IL-1α, TNF-α and IL-6) were the highest in the MiR-124 Agonist group, while being the lowest in the Blank group. The levels of these inflammatory factors were relatively higher in the BCG group and Empty-vector group, while being significantly reduced in the Nanoparticle+MiR-124 Antagonist group, which were elevated compared to that in the Blank group. The secretion quantities of these inflammatory factors in the MiR-124 Antagonist group were higher than that in the Nanoparticle+MiR-124 Antagonist group (P <0.05).Dual luciferase experiments indicated that miR-124-antagonists may retard TLR6 and MyD88 to affect the immune response of pulmonary alveolar epithelial cells in pulmonary tuberculosis. The fluorescence intensity of mutant plasmid was significantly stronger than that of wild-type plasmid (P < 0.05). In the alveolar epithelial cells from pulmonary tuberculosis, the miR-124-antagonistloaded liposomal nanoparticles can significantly reduce the expression of TLR6 and MyD88, and their downstream molecules (NF-κB and TRAF6), leading to the reduced secretion of the inflammatory factors. As a result, the inflammatory response of lung tissue was alleviated, while the immune function was restored. This regulation was achieved by the miR-124-antagonist-loaded liposomal nanoparticles via negatively regulating the TLR6/MyD88 pathways.

Immune Activated Cellular Therapy for Drug Resistant Infections: Rationale, Mechanisms, and Implications for Veterinary Medicine

Antimicrobial resistance and biofilm formation both present challenges to treatment of bacterial infections with conventional antibiotic therapy and serve as the impetus for development of improved therapeutic approaches. Mesenchymal stromal cell (MSC) therapy exerts an antimicrobial effect as demonstrated in multiple acute bacterial infection models. This effect can be enhanced by pre-conditioning the MSC with Toll or Nod-like receptor stimulation, termed activated cellular therapy (ACT). The purpose of this review is to summarize the current literature on mechanisms of antimicrobial activity of MSC with emphasis on enhanced effects through receptor agonism, and data supporting use of ACT in treatment of bacterial infections in veterinary species including dogs, cats, and horses with implications for further treatment applications. This review will advance the field's understanding of the use of activated antimicrobial cellular therapy to treat infection, including mechanisms of action and potential therapeutic applications.