In vitro modeling of human dorsal root ganglion neurons for GCaMP6-based calcium imaging of sensory responses to HSV-1 infection

Dorsal root ganglion (DRG) neurons play a pivotal role in transmitting sensory information from the periphery to the central nervous system, mediating diverse stimuli such as pain, touch, and temperature. Despite advances, translating findings from rodent models to human applications remains challenging due to species-specific differences, necessitating reliable human DRG neuron models. The immortalized human DRG neuronal cell line HD10.6, derived from embryonic DRG cells and capable of differentiating into functional nociceptive-like neurons, offers a promising in vitro system for studying sensory neuron biology and drug screening. This study explores the utility of GCaMP6s, a genetically encoded calcium indicator, as a molecular tool for imaging sensory activation in HD10.6 cells. To establish HD10.6 as a robust human DRG model, we constructed and characterized adeno-associated virus (AAV9) vectors for efficient GCaMP6s delivery. Differentiated HD10.6 cells were efficiently transduced, and calcium dynamics were validated to assess functional responses to sensory stimuli. The results showed that AAV9 serotype was sufficient to infect HD10.6 and the GCaMP6s was successfully introduced into the cells. The HD10.6-GCaMP6s responded to capsaicin well under the appropriate condition. A series of viral infection studies indicated that herpesvirus HSV-1 triggered robust calcium influx within 5 min after the exposure to the virus. Our findings highlight the potential of GCaMP6s-expressing HD10.6 cells as a high-throughput platform for studying nociception, neuronal signaling, host cell responses to viruses, and therapeutic interventions, bridging the gap between preclinical research and clinical applications.