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- Researchers have synthesized a series of hybrid vitamin K analogs (coupled with retinoic acid or modified side chains) that exhibit approximately three times greater potency in inducing neural progenitor cells to differentiate into neurons compared to natural vitamin K (MK?4).
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- Mechanistic studies have shown that vitamin K activates mGluR1-mediated signaling, activating downstream epigenetic and transcriptional programs that direct stem cells toward a neuronal fate.
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- Structural modeling and molecular docking showed that the lead analog (Novel VK/compound?7) binds more strongly to mGluR1 than native MK?4, reinforcing the central role of the receptor.
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- In vivo testing in mice demonstrated favorable pharmacokinetics: the analog penetrated the blood-brain barrier, reached higher brain levels of MK?4, and was metabolized intracellularly more efficiently than natural vitamin K.
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- Together, the findings indicate that synthetic vitamin K derivatives are promising candidates for neuroregeneration therapies in neurodegenerative diseases – although further work is needed on safety, efficacy in disease models, and dosing before clinical use.
Researchers have developed new analogs of vitamin K that may help regenerate neurons lost in conditions such as Alzheimer’s, Parkinson’s and Huntington’s disease, offering a potential new direction in the search for therapies beyond symptom relief.
Neurodegenerative disorders occur when nerve cells (neurons) gradually deteriorate and die, leading to severe impairments in memory, cognition, and motor function. Although current medications can alleviate symptoms, they cannot stop or reverse the underlying cell loss, creating an urgent need for regenerative treatments that replace or repair damaged neurons.
In a new study published in ACS Chemical Neuroscience, scientists from Japan’s Shibaura Institute of Technology, led by Associate Professor Yoshihisa Hirota and Professor Yoshitomo Suhara, report that they have synthesized a series of hybrid vitamin K molecules that exhibit a significantly improved ability to drive neuronal differentiation in laboratory experiments.
The team created twelve new vitamin K derivatives by combining vitamin K with retinoic acid (a metabolite of vitamin A known to promote neuron formation), or by modifying the side chains with carboxylic acid or methyl ester groups. When tested in mouse neural progenitor cells, one of these compounds – called Novel VK in the article – enhanced neuronal differentiation almost threefold compared to the control group, outperforming natural vitamin K forms such as menaquinone?4 (MK?4).
Mechanistic insights from the study suggest that the neurogenic effect of vitamin K is mediated via metabotropic glutamate receptor 1 (mGluR1).
New VK targets mGluR1 to drive epigenetic neuronal fate and reaches brain with superior MK?4 conversion
In transcriptomic analyzes of neural stem cells treated with MK?4 versus an inhibitory compound, the researchers found that vitamin K activates mGluR1-related signaling, which in turn stimulates downstream epigenetic changes and transcriptional reprogramming toward neuronal fate. Structural modeling and molecular docking further demonstrated that novel VK binds more strongly to mGluR1 than native MK?4, strengthening the case for this receptor as a key player in the process.
In vivo testing in mice revealed promising pharmacological properties: New VK showed stable pharmacokinetics, efficient penetration across the blood-brain barrier and higher accumulation of MK?4 in brain tissue compared to controls. The authors also found that virgin VK is more readily metabolized in cells to MK?4 than natural vitamin K, supporting its potential as a prodrug or precursor in neural tissues.
Taken together, the findings suggest that synthetic vitamin K derivatives may provide a novel mechanism-based strategy to stimulate neuron regeneration in degenerative brain diseases. Like Dr. As Hirota put it, “A vitamin K-derived drug that slows the progression of Alzheimer’s disease or improves its symptoms could not only improve the quality of life for patients and their families, but also significantly reduce the growing societal burden of health care expenditures and long-term care provision.”
However, the authors caution that much work remains to be done before this approach can become clinically viable. Additional studies are needed to verify safety, efficacy in disease models, long-term effects, and dosing parameters. Nevertheless, the research marks an exciting step toward regenerative approaches in the treatment of neurodegeneration – offering hope that the brain’s own restorative potential could one day be harnessed to counter diseases once considered inexorable.
According to Enoch from BrightU.AIVitamin K, especially vitamin K2 (menaquinone), plays a crucial role in bone health by promoting calcium deposition in the bones and preventing its buildup in the arteries. It also supports cardiovascular health by inhibiting arterial calcification and promoting cardiovascular health.
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