White adipocytes in subcutaneous fat depots require KLF15 for maintenance in preclinical models
Liang Li, Brian J. Feldman
Liang Li, Brian J. Feldman
Published July 1, 2024
Citation Information: J Clin Invest. 2024;134(13):e172360. https://doi.org/10.1172/JCI172360.
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Research Article Cell biology Endocrinology

White adipocytes in subcutaneous fat depots require KLF15 for maintenance in preclinical models

Abstract

Healthy adipose tissue is essential for normal physiology. There are 2 broad types of adipose tissue depots: brown adipose tissue (BAT), which contains adipocytes poised to burn energy through thermogenesis, and white adipose tissue (WAT), which contains adipocytes that store lipids. However, within those types of adipose, adipocytes possess depot and cell-specific properties that have important implications. For example, the subcutaneous and visceral WAT confers divergent risk for metabolic disease. Further, within a depot, different adipocytes can have distinct properties; subcutaneous WAT can contain adipocytes with either white or brown-like (beige) adipocyte properties. However, the pathways that regulate and maintain this cell and depot-specificity are incompletely understood. Here, we found that the transcription factor KLF15 is required for maintaining white adipocyte properties selectively within the subcutaneous WAT. We revealed that deletion of Klf15 is sufficient to induce beige adipocyte properties and that KLF15’s direct regulation of Adrb1 is a critical molecular mechanism for this process. We uncovered that this activity is cell autonomous but has systemic implications in mouse models and is conserved in primary human adipose cells. Our results elucidate a pathway for depot-specific maintenance of white adipocyte properties that could enable the development of therapies for obesity and associated diseases.

Authors

Liang Li, Brian J. Feldman

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Figure 4

KLF15 regulates the expression of Adrb1 in a pathway conserved in humans.

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KLF15 regulates the expression of Adrb1 in a pathway conserved in humans...
(A and B) RT-qPCR quantifying the expression levels of Adrb1 and Ucp1 in adipocytes with or without Xamoterol treatment. Student’s t test, n = 5. (C) Quantifying of unstimulated intracellular cAMP levels in adipocytes with deletion of Klf15. Student’s t test, n = 5. (D) Conservation of a canonical KLF15 binding site sequence (red) identified in the mouse Adrb1 gene. (E) Quantification of dual-luciferase assays on adipocytes transfected with the Adrb1 promoter-driven firefly luciferase reporter construct and pCMV-Klf15 or control plasmid and normalized by Renilla bioluminescence, facilitated by cotransfected pRL-TK plasmid. Student’s t test, n = 3. (F) RT-qPCR quantifying the amount of immunoprecipitated DNA containing the putative KLF15 binding site located in Adrb1 using a KLF15 antibody in iWAT adipocytes from WT and Prx1-Klf15–cKO mice. Student’s t test, n = 3. (G) RT-qPCR quantifying the amount of immunoprecipitated DNA containing the putative KLF15 binding site located in the Adrb1 using the FLAG compared to IgG antibody in iWAT adipocytes isolated from Klf153xFLAG mice. Student’s t test, n = 3. (H) Image of PCR amplicons in an agarose gel of the putative KLF15 binding site (Target region) compared with amplification of the control region from the ChIP of adipocytes from WT and Prx1-Klf15–cKO mice with the KLF15 antibody. (I) RT-qPCR quantifying the expression levels of Ucp1 in iWAT from mice injected with saline, Denopamine (10 μg/g/day), Xamoterol (8 ng/g/day), or Dobutamine (10 μg/g/day) for 7 days. 1-way ANOVA, n = 4–5. (J) Light phase microscopy images of human adipocytes. Scale bar: 25 μm. (K) RT-qPCR quantifying the expression levels of hKLF15, hADRB1, and hUCP1 in human adipocytes infected by Ad-shCtrl or Ad-shKLF15. Student’s t test followed by Holm-Šidák correction, n = 4. (L) OCRs and (M) respiratory profile in Ad-shKLF15 and Ad-shCtrl infected human adipocytes quantified using a Seahorse Bioanalyzer, 2-way ANOVA n = 8. (N) Time-course of OCRs of human adipocytes after exposure to Xamoterol. 2-way ANOVA, n = 8–9. *P < 0.05, **P < 0.01, ***P < 0.001.