{"id":"CU23300","slug":"fine-tuning-neuroinflammation--CU23300","source":{"id":"CU23300","dataset":"techtransfer","title":"Fine-tuning neuroinflammation through bidirectional modulation of 3′UTR length","description_":"

This technology is a HuB-targeting therapeutic approach that modulates 3′ UTR length, altering immunostimulatory dsRNA levels and downstream interferon signaling to treat neuroinflammatory and neurodegenerative diseases.

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Unmet Need: Mechanism-based strategy for treating RNA-triggered neuroinflammation

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Neuroinflammatory and neurodegenerative diseases linked to disrupted RNA homeostasis, such as Aicardi-Goutières syndrome, lack effective, mechanism-based treatments that can safely reduce harmful, self-driven innate immune activation in neurons without undermining antiviral protection. Current care is largely supportive or relies on broad immunosuppression and anti-inflammatory strategies that do not correct the upstream source of aberrant immune triggering and can increase vulnerability to viral infection. This creates a need for more precise approaches to rebalance neuronal innate immune signaling, reducing pathological inflammation while preserving the necessary baseline antiviral immunity.

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The Technology: A versatile method to modulate neuronal dsRNA-driven inflammation

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This technology is a method for reducing neuroinflammation by delivering an effector that decreases the activity of the neuron-enriched RNA-binding proteins HuB and/or HuC. Lower HuB/HuC activity shifts neuronal RNA processing, including 3′ UTR regulation, to reduce the formation of endogenous immunostimulatory double-stranded RNA species that can inappropriately trigger innate immune sensors. As a result, downstream type I interferon signaling and associated inflammatory stress in neurons are dampened, helping treat neuroinflammatory or neurodegenerative pathology.

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This technology has been validated in neurons derived from human embryonic stem cells and the HEK293T cell line.

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Applications:

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Advantages:

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Lead Inventor:

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Hachung Chung, Ph.D.

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Patent Information:

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Patent Pending(US19/400,788)

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Related Publications:

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Tech Ventures Reference:

\r\r\r","tags":["Antiviral drug","Embryonic stem cell","Endogenous retrovirus","Gene therapy","HEK 293 cells","Homeostasis","Immune system","Immunosuppression","Immunotherapy","Inflammation","Innate immune system","Interferon","Interferon type I","Neurodegenerative disease","Pathology","RNA","RNA interference","Spinal cord injury","Stroke","Three prime untranslated region"],"file_number":"CU23300","collections":[{"key":427,"name":"Oncology"},{"key":428,"name":"CNS/Neurology"}],"meta_description":"Modulates neuronal 3′ UTRs via HuB/HuC to reduce immunostimulatory dsRNA, dampening neuroinflammation and interferon signaling.","apriori_judge_output":"{\"scores\":{\"novelty\":4.0,\"potential_impact\":4.0,\"readiness\":2.0,\"scalability\":3.0,\"timeliness\":2.0},\"weighted_score\":3.2,\"risks\":[\"Old enough to be 3+ years since date; potential regulatory/ translational hurdles\",\"Biological safety concerns modulating 3′UTR and innate immunity in neurons\",\"Translational readiness limited by in vitro models and need for in vivo validation\",\"Unclear commercialization pathway and manufacturing considerations\"],\"one_sentence_take\":\"High novelty with broad potential, but translational readiness and safety/regulatory hurdles reduce near-term commercialization prospects.\"}","inventors":["Hachung Chung","Heegwon Shin","Tyler Dorrity"],"manager":"Jerry Kokoshka","depts":["Microbiology"],"divs":["Columbia University Medical Center (CUMC)"],"date_released":"2023-07-01"},"highlight":{},"matched_queries":null,"score":0.0}