Loss of class IA PI3K signaling in muscle leads to impaired muscle growth, insulin response, and hyperlipidemia.

The evolutionarily conserved phosphoinositide 3-kinase (PI3K) signaling pathway mediates both the metabolic effects of insulin and the growth-promoting effects of insulin-like growth factor-1 (IGF-1). We have generated mice deficient in both the p85alpha/p55alpha/p50alpha and the p85beta regulatory subunits of class I(A) PI3K in skeletal muscles. PI3K signaling in the muscle of these animals is severely impaired, leading to a significant reduction in muscle weight and fiber size. These mice also exhibit muscle insulin resistance and whole-body glucose intolerance. Despite their ability to maintain normal fasting and fed blood glucose levels, these mice show increased body fat content and elevated serum free fatty acid and triglyceride levels. These results demonstrate that in vivo p85 is a critical mediator of class I(A) PI3K signaling in the regulation of muscle growth and metabolism. Our finding also indicates that compromised muscle PI3K signaling could contribute to symptoms of hyperlipidemia associated with human type 2 diabetes.

Class IA phosphoinositide 3-kinase regulates heart size and physiological cardiac hypertrophy.

Class I(A) phosphoinositide 3-kinases (PI3Ks) are activated by growth factor receptors, and they regulate, among other processes, cell growth and organ size. Studies using transgenic mice overexpressing constitutively active and dominant negative forms of the p110alpha catalytic subunit of class I(A) PI3K have implicated the role of this enzyme in regulating heart size and physiological cardiac hypertrophy. To further understand the role of class I(A) PI3K in controlling heart growth and to circumvent potential complications from the overexpression of dominant negative and constitutively active proteins, we generated mice with muscle-specific deletion of the p85alpha regulatory subunit and germ line deletion of the p85beta regulatory subunit of class I(A) PI3K. Here we show that mice with cardiac deletion of both p85 subunits exhibit attenuated Akt signaling in the heart, reduced heart size, and altered cardiac gene expression. Furthermore, exercise-induced cardiac hypertrophy is also attenuated in the p85 knockout hearts. Despite such defects in postnatal developmental growth and physiological hypertrophy, the p85 knockout hearts exhibit normal contractility and myocardial histology. Our results therefore provide strong genetic evidence that class I(A) PI3Ks are critical regulators for the developmental growth and physiological hypertrophy of the heart.

Modulation of epithelial neoplasia and lymphoid hyperplasia in PTEN+/- mice by the p85 regulatory subunits of phosphoinositide 3-kinase.

Mice with heterozygous deletion of the PTEN tumor suppressor gene develop a range of epithelial neoplasia as well as lymphoid hyperplasia. Previous studies suggest that PTEN suppresses tumor formation by acting as a phosphoinositide phosphatase to limit signaling by phosphoinositide 3-kinase (PI3K). Here, we examined the effect of deleting various regulatory subunits of PI3K (p85alpha and p85beta) on epithelial neoplasia and lymphoid hyperplasia in PTEN+/- mice. Interestingly, we found the loss of one p85alpha allele with or without the loss of p85beta led to increased incidence of intestinal polyps. Signaling downstream of PI3K was enhanced in the PTEN+/-p85alpha+/-p85beta-/- polyps, as judged by an increased fraction of both cells with cytoplasmic staining of the transcription factor FKHR and cells with positive staining for the proliferation marker Ki-67. In contrast, the incidence of prostate intraepithelial neoplasia was not significantly altered in PTEN+/- mice heterozygous for p85alpha or null for p85beta, whereas the fraction of proliferating cells in prostate intraepithelial neoplasia was reduced in mice lacking p85beta. Finally, there was no significant change in T lymphocyte hyperplasia in the PTEN+/- mice with various p85 deletions, although anti-CD3-stimulated AKT activation was somewhat reduced in the p85alpha+/- background. These results indicate that decreasing the levels of different p85 regulatory subunits can result in enhanced PI3K signaling in some tissues and decreased PI3K signaling in others, supporting the model that, although p85 proteins are essential for class I(A) PI3K signaling, they can function as inhibitors of PI3K signaling in some tissues and thus suppress tumor formation.