The progressive decline of the nervous system, including protein aggregate formation, reflects the subtle dysregulation of multiple functional pathways. Our previous work has shown intermittent fasting (IF) enhances longevity, maintains adult behaviors and reduces aggregates, in part, by promoting autophagic function in the aging Drosophila brain. To clarify the impact that IF-treatment has upon aging, we used high throughput RNA-sequencing technology to examine the changing transcriptome in adult Drosophila tissues. Principle component analysis (PCA) and other analyses showed ~1200 age-related transcriptional differences in head and muscle tissues, with few genes having matching expression patterns. Pathway components showing age-dependent expression differences were involved with stress response, metabolic, neural and chromatin remodeling functions. Middle-aged tissues also showed a significant increase in transcriptional drift-variance (TD), which in the CNS included multiple proteolytic pathway components. Overall, IF-treatment had a demonstrably positive impact on aged transcriptomes, partly ameliorating both fold and variance changes. Consistent with these findings, aged IF-treated flies displayed more youthful metabolic, behavioral and basal proteolytic profiles that closely correlated with transcriptional alterations to key components. These results indicate that even modest dietary changes can have therapeutic consequences, slowing the progressive decline of multiple cellular systems, including proteostasis in the aging nervous system.
Drosophila are widely used to study neural development, immunity, and inflammatory pathways and processes associated with the gut–brain axis. Here, we examine the response of adult Drosophila given an inactive bacteriologic (IAB; proprietary lysate preparation of Lactobacillus bulgaricus, ReseT®) and a probiotic (Lactobacillus rhamnosus, LGG). In vitro, the IAB activates a subset of conserved Toll-like receptor (TLR) and nucleotide-binding, oligomerization domain-containing protein (NOD) receptors in human cells, and oral administration slowed the age-related decline of adult Drosophila locomotor behaviors. On average, IAB-treated flies lived significantly longer (+23%) and had lower neural aggregate profiles. Different IAB dosages also improved locomotor function and longevity profiles after traumatic brain injury (TBI) exposure. Mechanistically, short-term IAB and LGG treatment altered baseline nuclear factor kappa-light-chain-enhancer of activated B cells (NF-kβ) signaling profiles in neural and abdominal tissues. Overall, at select dosages, IAB and LGG exposure has a positive impact on Drosophila longevity, neural aging, and mild traumatic brain injury (TBI)-related responses, with IAB showing greater benefit. This includes severe TBI (sTBI) responses, where IAB treatment was protective and LGG increased acute mortality profiles. This work shows that Drosophila are an effective model for testing bacterial-based biologics, that IAB and probiotic treatments promote neuronal health and influence inflammatory pathways in neural and immune tissues. Therefore, targeted IAB treatments are a novel strategy to promote the appropriate function of the gut–brain axis.
The full potential of cell therapy has yet to be realized in solid tumor indications and new approaches are urgently required. Macrophages are innate immune cells that can kill tumor cells and orchestrate the anti-tumor immune response. Macrophage cell therapy is an exciting new approach to treat cancer with the aim to harness the powerful activity of macrophages to reignite the immune system. Patient derived macrophages, however, are difficult to genetically engineer and do not proliferate, which makes generating high-quality cells at clinically relevant scales challenging. To address this, we have developed an induced pluripotent stem cell (iPSC) approach to macrophage cell therapy. These cells can be genetically engineered at the iPSC stage and then differentiated into billions of highly functional iPSC derived macrophages (iMACs). This allogenic cell therapy product can then be cryopreserved and stored for immediate use in the clinic when the patient is ready. Here we show that iMACs function like normal macrophages. They migrate towards tumor cells, respond to challenges through innate immune receptors, and produce immune recruiting and activating cytokines and chemokines. iMACs also express high levels of antibody receptors and we show that these cells can be directed to kill tumors in vitro and in vivo via antibody dependent cellular phagocytosis. Furthermore, we have conducted a robust screen to develop a novel CAR that is optimized for use in iMACs. These receptors can be engineered into iMACs at the iPSC stage and trigger robust tumor cell killing. In summary, these data highlight the therapeutic potential of iMACs in oncology and support the further development of this technology for clinical use. Citation Format: Huafeng Wang, May Sumi, Christine Huh, Fereshteh Parviz, Jessica Mastroianni, Jane Healy, Nicole Stevens, Leah Mitchell, Susanne Lang, Dan Kaufman, Robert Hollingsworth, David T. Rodgers. Developing an allogeneic iPSC derived macrophage cell therapy for oncology. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 4059.
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