# α-Parvin promotes glucose uptake and metabolism in skeletal muscle with minimal influence on hepatic insulin sensitivity

**Authors:** Fabian Bock, Xinyu Dong, Kakali Ghoshal, David A. Cappel, John W. Deaver, Dan S. Lark, Luciano Cozzani, Deanna P. Bracy, Louise Lantier, Allison Do, Richard L. Printz, Santosh Thapa, Owen P. McGuinness, David H. Wasserman, Ambra Pozzi, Roy Zent, Nathan C. Winn

PMC · DOI: 10.1016/j.molmet.2026.102322 · Molecular Metabolism · 2026-01-21

## TL;DR

This study shows that α-Parvin is important for glucose uptake in skeletal muscle but has little effect on liver insulin sensitivity in mice.

## Contribution

The study reveals a tissue-specific role of α-Parvin in regulating skeletal muscle glucose metabolism and actin cytoskeleton function.

## Key findings

- Deleting α-Parvin in skeletal muscle reduces glucose uptake and impairs exercise capacity in lean mice.
- Muscle α-Parvin deletion causes GLUT4 membrane recruitment defects and mitochondrial dysfunction.
- α-Parvin has minimal impact on liver insulin resistance in obese or lean mice.

## Abstract

Skeletal muscle and liver insulin resistance are early features in the sequelae of type 2 diabetes. Integrins are extracellular matrix receptors expressed on skeletal muscle cells and hepatocytes, which have been implicated in modulating obesity-associated insulin resistance. Integrins regulate cell function through intracellular proteins including the ILK-PINCH-Parvin (IPP) complex. ILK signaling amplifies skeletal muscle and liver insulin resistance in diet-induced obesity in mice but the role of α-Parvin is unexplored. The hyperinsulinemic-euglycemic clamp was used to assess hepatic and muscle insulin action. We demonstrate that deletion of hepatocyte-specific α-Parvin had only minimal influence on obesity-induced liver or whole-body insulin resistance. In contrast, deletion of α-Parvin in skeletal muscle caused a striking reduction in muscle glucose uptake during an insulin clamp in lean mice which was not exacerbated by diet-induced obesity. The decrease in muscle glucose uptake in lean mice was due to a decrease in insulin-mediated GLUT4 membrane recruitment, which was associated with significant morphological abnormalities including actin cytoskeleton dysfunction. In addition, severe muscular dysfunction, blunted mitochondrial oxidative capacity and reduced aerobic exercise capacity were manifest in muscle α-Parvin KO mice. Thus, α-Parvin has a minor role in liver insulin action but is required for insulin-stimulated glucose uptake in skeletal muscle in lean mice due to its role in actin cytoskeleton regulation. These data suggest that individual IPP complex proteins link cell structure to metabolism via distinct mechanisms in a tissue-specific fashion.

•The ILK-PINCH-Parvin (IPP) complex regulates integrin function by linking cytoplasmic domains of integrins with cytoskeletal components.•We investigated the role of the scaffold protein α-Parvin in muscle and liver insulin resistance using conditional mouse models of α-Parvin deletion.•Deletion of α-Parvin in SkM caused reduced muscle glucose uptake, decreased mitochondrial respiration, and impaired exercise tolerance.•SkM α-Parvin regulates GLUT4 membrane recruitment and hexokinase compartmentation by controlling F-actin polymerization via GTPase-cofilin.•These data highlight the importance of α-Parvin in the regulation of actin turnover during increased nutrient flux rates (i.e. meal & exercise).

The ILK-PINCH-Parvin (IPP) complex regulates integrin function by linking cytoplasmic domains of integrins with cytoskeletal components.

We investigated the role of the scaffold protein α-Parvin in muscle and liver insulin resistance using conditional mouse models of α-Parvin deletion.

Deletion of α-Parvin in SkM caused reduced muscle glucose uptake, decreased mitochondrial respiration, and impaired exercise tolerance.

SkM α-Parvin regulates GLUT4 membrane recruitment and hexokinase compartmentation by controlling F-actin polymerization via GTPase-cofilin.

These data highlight the importance of α-Parvin in the regulation of actin turnover during increased nutrient flux rates (i.e. meal & exercise).

## Linked entities

- **Genes:** SLC2A4 (solute carrier family 2 member 4) [NCBI Gene 6517]
- **Proteins:** ILK (integrin linked kinase), LIMS1 (LIM zinc finger domain containing 1), parvin (parvin)
- **Diseases:** type 2 diabetes (MONDO:0005148)
- **Species:** Mus musculus (taxon 10090)

## Full-text entities

- **Genes:** Parva (parvin, alpha) [NCBI Gene 57342] {aka 2010012A22Rik, 5430400F08Rik, Actp, CH-ILKBP, Parvin}, Lims1 (LIM and senescent cell antigen-like domains 1) [NCBI Gene 110829] {aka 2310016J22Rik, 4921524A02Rik, C430041B13Rik, Lims1l, PINCH, PINCH1}, Slc2a4 (solute carrier family 2 (facilitated glucose transporter), member 4) [NCBI Gene 20528] {aka GT2, Glut-4, Glut4, twgy}, Ilk (integrin linked kinase) [NCBI Gene 16202] {aka ESTM24, ILK-1, ILK-2, p59ILK}
- **Diseases:** hyperinsulinemic (MESH:D044903), insulin resistance (MESH:D007333), type 2 diabetes (MESH:D003924), obesity (MESH:D009765), muscular dysfunction (MESH:D009135), actin (MESH:C579880)
- **Chemicals:** Glucose (MESH:D005947)
- **Species:** Mus musculus (house mouse, species) [taxon 10090]

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12887382/full.md

## References

84 references — full list in the complete paper: https://tomesphere.com/paper/PMC12887382/full.md

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Source: https://tomesphere.com/paper/PMC12887382