Thiamine pyrophosphokinase-1 deficiency in neurons drives Alzheimer’s multiple pathophysiological alterations

  1. Shaoming Sang
  2. Xiangteng Zhao
  3. Ting Qian
  4. Yingfeng Xia
  5. Xiaoli Pan
  6. Qianhua Zhao
  7. Fang Cai
  8. Yeting Zeng
  9. Wenwen Cai
  10. Boru Jin
  11. Hongyan Qiu
  12. Yangqi Xu
  13. Qiang Huang
  14. Yun Zhang
  15. Shajin Huang
  16. Donglang Jiang
  17. Yun Wu
  18. Haiyang Tong
  19. Qing Zhang
  20. Changpeng Wang
  21. Xiaoqin Cheng
  22. Kai Zhong
  23. Yihui Guan
  24. Michael X. Zhu
  25. Xiang Yu
  26. Peng Yuan
  27. Weihong Song
  28. Chunjiu Zhong
  29. Benfotiamine Phase 2 Clinical Trial Investigators
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Abstract

Background

The mechanism driving multiple pathophysiological alterations in Alzheimer’s disease (AD) remains unclear. Thiamine deficiency, a well-known feature of AD, may contribute to these alterations.

Methods

The expressions of four known genes associated with thiamine metabolism were studied in brain samples from patients with AD and other neurodegenerative disorders. The results were further demonstrated in AD and diabetic mouse and cellular models. The phenotypes of mice with conditional Thiamine pyrophosphokinase-1 ( Tpk ) knockout in brain excitatory neurons were investigated. The therapeutic effects of thiamine diphosphate supplement and Tpk delivery on cellular and mouse models were explored. Phase 2 clinical trial of benfotiamine, a thiamine derivative, plus donepezil was performed.

Results

Only TPK expression was inhibited in brain samples of AD patients, while none of thiamine-associated genes were significantly changed in other neurodegenerative disorders. TPK inhibition in the brains and neurons was verified in AD and diabetic mouse and cellular models. Mice with Tpk deletion in neurons exhibited all major pathophysiological alterations of AD, including amyloid deposition, Tau hyperphosphorylation, and brain atrophy. TPK expression restoration and thiamine diphosphate supplement ameliorated the pathophysiological and behavioral phenotypes in mouse and cell models with Tpk insufficiency. Benfotiamine delayed cognitive decline in mild-to-moderate AD patients with a dose-effect relationship, particularly with a significant attenuation of the deterioration in moderate AD patients by post hoc analysis.

Conclusions

TPK deficiency and hence thiamine diphosphate reduction in neurons are a decisive factor driving multiple pathophysiologic alterations of AD, unveiling a new direction for the disease mechanism and treatment.

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  1. Version published to 10.1101/2024.09.20.24314010v1 on medRxiv