4.8 Article

Smad3 deficiency improves islet-based therapy for diabetes and diabetic kidney injury by promoting β cell proliferation via the E2F3-dependent mechanism

Journal

THERANOSTICS
Volume 12, Issue 1, Pages 379-395

Publisher

IVYSPRING INT PUBL
DOI: 10.7150/thno.67034

Keywords

Smad3; islet transplantation; diabetes; E2F3; cell cycle

Funding

  1. Research Grants Council of Hong Kong [GRF 14163317, 14117418, 14104019, R4012-18]
  2. Health and Medical Research Fund of Hong Kong [HMRF 14152321, 05161326, 06173986, 07180516]
  3. Lui CheWoo Institute of Innovative Medicine (CARE program)
  4. Guangdong-Hong Kong-Macao-Joint Labs Program from Guangdong Science and Technology Department [2019B121205005]
  5. Luzhou Municipal-Southwest Medical University Joint Special Grant for the High-level Talents
  6. Luzhou Municipal-Southwest Medical University Joint grant [2020LZXNYDJ15]
  7. Southwest Medical University [2019ZZD010]
  8. basic research platform grant of Luzhou [2018LZXNYD-PT03]

Ask authors/readers for more resources

By inhibiting the Smad3 gene, beta cell proliferation can be promoted, thereby improving the efficacy of islet cell replacement therapy for diabetes.
Rationale: Poor beta cell proliferation is one of the detrimental factors hindering islet cell replacement therapy for patients with diabetes. Smad3 is an important transcriptional factor of TGF-beta signaling and has been shown to promote diabetes by inhibiting beta cell proliferation. Therefore, we hypothesize that Smad3-deficient islets may be a novel cell replacement therapy for diabetes. Methods: We examined this hypothesis in streptozocin-induced type-1 diabetic mice and type-2 diabetic db/db mice by transplanting Smad3 knockout (KO) and wild type (WT) islets under the renal capsule, respectively. The effects of Smad3KO versus WT islet replacement therapy on diabetes and diabetic kidney injury were examined. In addition, RNA-seq was applied to identify the downstream target gene underlying Smad3-regulated beta cell proliferation in Smad3KO-db/db versus Smad3WT-db/db mouse islets. Results: Compared to Smad3WT islet therapy, treatment with Smad3KO islets produced a much better therapeutic effect on both type-1 and type-2 diabetes by significantly lowering serum levels of blood glucose and HbA1c and protected against diabetic kidney injuries by preventing an increase in serum creatinine and the development of proteinuria, mesangial matrix expansion, and fibrosis. These were associated with a significant increase in grafted beta cell proliferation and blood insulin levels, resulting in improved glucose intolerance. Mechanistically, RNA-seq revealed that compared with Smad3WT-db/db mouse islets, deletion of Smad3 from db/db mouse islets markedly upregulated E2F3, a pivotal regulator of cell cycle G1/S entry. Further studies found that Smad3 could bind to the promoter of E2F3, and thus inhibit beta cell proliferation via an E2F3-dependent mechanism as silencing E2F3 abrogated the proliferative effect on Smad3KO beta cells. Conclusion: Smad3-deficient islet replacement therapy can significantly improve both type-1 and type-2 diabetes and protect against diabetic kidney injury, which is mediated by a novel mechanism of E2F3-dependent beta cell proliferation.

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