Go to The Journal of Clinical Investigation
  • About
  • Editors
  • Consulting Editors
  • For authors
  • Publication ethics
  • Publication alerts by email
  • Transfers
  • Advertising
  • Job board
  • Contact
  • Physician-Scientist Development
  • Current issue
  • Past issues
  • By specialty
    • COVID-19
    • Cardiology
    • Immunology
    • Metabolism
    • Nephrology
    • Oncology
    • Pulmonology
    • All ...
  • Videos
  • Collections
    • In-Press Preview
    • Resource and Technical Advances
    • Clinical Research and Public Health
    • Research Letters
    • Editorials
    • Perspectives
    • Physician-Scientist Development
    • Reviews
    • Top read articles

  • Current issue
  • Past issues
  • Specialties
  • In-Press Preview
  • Resource and Technical Advances
  • Clinical Research and Public Health
  • Research Letters
  • Editorials
  • Perspectives
  • Physician-Scientist Development
  • Reviews
  • Top read articles
  • About
  • Editors
  • Consulting Editors
  • For authors
  • Publication ethics
  • Publication alerts by email
  • Transfers
  • Advertising
  • Job board
  • Contact
Involvement of the metabolic sensor GPR81 in cardiovascular control
Kristina Wallenius, Pia Thalén, Jan-Arne Björkman, Petra Johannesson, John Wiseman, Gerhard Böttcher, Ola Fjellström, Nicholas D. Oakes
Kristina Wallenius, Pia Thalén, Jan-Arne Björkman, Petra Johannesson, John Wiseman, Gerhard Böttcher, Ola Fjellström, Nicholas D. Oakes
View: Text | PDF
Research Article Cardiology Metabolism

Involvement of the metabolic sensor GPR81 in cardiovascular control

  • Text
  • PDF
Abstract

GPR81 is a receptor for the metabolic intermediate lactate with an established role in regulating adipocyte lipolysis. Potentially novel GPR81 agonists were identified that suppressed fasting plasma free fatty acid levels in rodents and in addition improved insulin sensitivity in mouse models of insulin resistance and diabetes. Unexpectedly, the agonists simultaneously induced hypertension in rodents, including wild-type, but not GPR81-deficient mice. Detailed cardiovascular studies in anesthetized dogs showed that the pressor effect was associated with heterogenous effects on vascular resistance among the measured tissues: increasing in the kidney while remaining unchanged in hindlimb and heart. Studies in rats revealed that the pressor effect could be blocked, and the renal resistance effect at least partially blocked, with pharmacological antagonism of endothelin receptors. In situ hybridization localized GPR81 to the microcirculation, notably afferent arterioles of the kidney. In conclusion, these results provide evidence for a potentially novel role of GPR81 agonism in blood pressure control and regulation of renal vascular resistance including modulation of a known vasoeffector mechanism, the endothelin system. In addition, support is provided for the concept of fatty acid lowering as a means of improving insulin sensitivity.

Authors

Kristina Wallenius, Pia Thalén, Jan-Arne Björkman, Petra Johannesson, John Wiseman, Gerhard Böttcher, Ola Fjellström, Nicholas D. Oakes

×

Figure 10

The GPR81 agonist, AZ2, rapidly increases renal vascular resistance, by an effect that is at least partially dependent on endothelin (ET) receptor agonism and does not affect plasma renin levels.

Options: View larger image (or click on image) Download as PowerPoint
The GPR81 agonist, AZ2, rapidly increases renal vascular resistance, by ...
Adult male Wistar rats were anesthetized and implanted with jugular and carotid catheters. Laparotomy was performed and a flow probe attached to the left renal artery, abdomen closed, and animals were left to stabilize for 1 hour. Following a 10-minute baseline period (t = –10 to 0 minutes), either vehicle (blue symbols) or AZ2 (1 μM/kg/min) was given i.v. from 0–15 minutes. AZ2 was given alone (AZ2, red symbols) or on top of pretreatment (given before –10 minutes), with the dual ET-A/B receptor antagonist, bosentan, 15 mg/kg i.v. (Bos+AZ2, purple symbols). Changes in renal vascular resistance and renal artery blood flow are expressed as percentages of their respective averages during the baseline period. (A) Minute-by-minute change in renal vascular resistance. (B) Mean change in renal resistance averaged over 0–15 minutes. (C) Minute-by-minute change in renal artery blood flow. (D) Mean change in renal artery blood flow averaged over 0–15 minutes. (E) Plasma renin levels after 15 minutes of vehicle or AZ2 (n = 4). Results are the mean ± SEM (vehicle, n = 6; AZ2, n = 7; Bos+AZ2, n = 4). *P < 0.05, **P < 0.01 versus vehicle; #P < 0.05, ##P < 0.01 versus AZ2. ANOVA, followed up by multiple comparison test with Holm-Sidak correction.

Copyright © 2026 American Society for Clinical Investigation
ISSN 2379-3708

Sign up for email alerts