Abstract: TH-PO0047
Novel Kidney-Specific Bmal1 Knockout Model Reveals Circadian Control of Renal Physiology
Session Information
- Bioengineering: MPS, Flow, and Delivery
November 06, 2025 | Location: Exhibit Hall, Convention Center
Abstract Time: 10:00 AM - 12:00 PM
Category: Bioengineering
- 400 Bioengineering
Authors
- Kim, Myung-Gyu, Korea University Anam Hospital, Seoul, Korea (the Republic of)
- Koo, Tai yeon, Korea University Anam Hospital, Seoul, Korea (the Republic of)
- Choi, Young Eun, Korea University Anam Hospital, Seoul, Korea (the Republic of)
- Oh, Sewon, Korea University Anam Hospital, Seoul, Korea (the Republic of)
- Lee, Hojin, Korea University Anam Hospital, Seoul, Korea (the Republic of)
- Heo, Ga Young, Korea University Anam Hospital, Seoul, Korea (the Republic of)
- Jo, Sang-Kyung, Korea University Anam Hospital, Seoul, Korea (the Republic of)
Background
he kidney contains a high number of circadian clock genes, but the impact of circadian disruption on renal physiology and disease progression remains unclear. This study aimed to establish a kidney-specific circadian clock gene knockout model and investigate its effects on renal function.
Methods
An inducible, kidney-specific Bmal1 knockout mouse model was generated using the Cre-loxP system. Three transgenic mouse lines—Pax8-rtTA, tetO-Cre, and floxed Bmal1—were bred, allowing doxycycline-inducible postnatal gene deletion. After doxycycline administration, the expression of central (brain) and peripheral (kidney, liver, lung, heart) clock genes was assessed.
Results
Doxycycline treatment for two weeks led to selective Bmal1 deletion in renal proximal and distal tubules and the collecting duct system. This loss disrupted diurnal variations in key physiological parameters, including glomerular filtration rate and urinary electrolyte excretion (sodium, potassium, chloride). Furthermore, the expression of key tubular transporter genes—NHE3, OAT3, SGLT2 (proximal tubules), V2 receptor (collecting ducts), and Na+/K+-ATPase—exhibited altered circadian patterns. These findings indicate that kidney Bmal1 is essential for maintaining normal renal rhythmicity.
Conclusion
We developed a novel, inducible kidney-specific circadian disruption model and demonstrated that the endogenous renal clock is critical for kidney function. This study provides new insights into how circadian rhythm disturbances affect kidney physiology and disease progression, potentially guiding future therapeutic strategies.
Funding
- Government Support – Non-U.S.