PI3Kα inactivation in leptin receptor cells increases leptin sensitivity but disrupts growth and reproduction
David Garcia-Galiano, Beatriz C. Borges, Jose Donato Jr., Susan J. Allen, Nicole Bellefontaine, Mengjie Wang, Jean J. Zhao, Kenneth M. Kozloff, Jennifer W. Hill, Carol F. Elias
David Garcia-Galiano, Beatriz C. Borges, Jose Donato Jr., Susan J. Allen, Nicole Bellefontaine, Mengjie Wang, Jean J. Zhao, Kenneth M. Kozloff, Jennifer W. Hill, Carol F. Elias
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Research Article Reproductive biology

PI3Kα inactivation in leptin receptor cells increases leptin sensitivity but disrupts growth and reproduction

Abstract

The role of PI3K in leptin physiology has been difficult to determine due to its actions downstream of several metabolic cues, including insulin. Here, we used a series of mouse models to dissociate the roles of specific PI3K catalytic subunits and of insulin receptor (InsR) downstream of leptin signaling. We show that disruption of p110α and p110β subunits in leptin receptor cells (LRΔα+β) produces a lean phenotype associated with increased energy expenditure, locomotor activity, and thermogenesis. LRΔα+β mice have deficient growth and delayed puberty. Single subunit deletion (i.e., p110α in LRΔα) resulted in similarly increased energy expenditure, deficient growth, and pubertal development, but LRΔα mice have normal locomotor activity and thermogenesis. Blunted PI3K in leptin receptor (LR) cells enhanced leptin sensitivity in metabolic regulation due to increased basal hypothalamic pAKT, leptin-induced pSTAT3, and decreased PTEN levels. However, these mice are unresponsive to leptin’s effects on growth and puberty. We further assessed if these phenotypes were associated with disruption of insulin signaling. LRΔInsR mice have no metabolic or growth deficit and show only mild delay in pubertal completion. Our findings demonstrate that PI3K in LR cells plays an essential role in energy expenditure, growth, and reproduction. These actions are independent from insulin signaling.

Authors

David Garcia-Galiano, Beatriz C. Borges, Jose Donato Jr., Susan J. Allen, Nicole Bellefontaine, Mengjie Wang, Jean J. Zhao, Kenneth M. Kozloff, Jennifer W. Hill, Carol F. Elias

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Figure 3

Leptin supplementation does not restore pubertal timing in LRΔα mice.

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Leptin supplementation does not restore pubertal timing in LRΔα mice. (A...
(A) Day of vaginal opening in αfl (n = 31) and LRΔα (n = 18) mice (t47 = 0.9, P = 0.373) and (B) representative graphs of estrous cyclicity and day of first estrus (arrows). (C) Reduced body weight in LRΔα mice from normal litter size (LRΔα-NL, n = 18) and small litter size (LRΔα-SL, n = 17) compared with αfl-NL females [n = 26; F(2,58) = 41.05, P < 0.0001 for genotype analysis; F(18,522) = 11.56, P < 0.0001 for interaction] from 2 independent cohorts. (D) Reduced circulating leptin levels at P40 in LRΔα-NL (n = 9) compared with αfl-NL mice [n = 9; F(2,21) = 3.59, P = 0.046]; levels were similar to those of LRΔα-SL (n = 6). (E) Serum LH levels at P40 [αfl-NL, n = 9; LRΔα-SL, n = 10; LRΔα-NL, n = 7; F(2,23) = 2.93, P = 0.074] and (F) ovarian weight in αfl-NL (n = 9), LRΔα-SL (n = 10), and LRΔα-NL females [n = 9; F(2,25) = 7.44, P = 0.003 for genotype analysis]. (G) First estrus progression and (H) average age of first estrus detected differences among groups of mice: αfl-NL (n = 26), LRΔα-SL (n = 13), and LRΔα-NL females [n = 12; F(2,49) = 27.81, P < 0.0001]. (I) Effect of daily leptin supplementation on sexual maturation: αfl mice treated with vehicle (n = 12) or leptin (n = 9), and LRΔα mice treated with vehicle or leptin (n = 8/treatment). Each point represents 1 individual mouse, and all values are presented as mean ± SEM. *P < 0.05, **P < 0.01 versus LRΔα-SL; #P < 0.05 versus αfl-NL, by repeated-measures 2-way ANOVA with Holm-Sidak’s multiple comparisons test in C. Groups with different superscript letters are statistically different by 1-way ANOVA with Newman-Keuls post-hoc analysis in DH.