STAT3 signalling is required for leptin regulation of energy balance but not reproduction.

Secretion of leptin from adipocytes communicates body energy status to the brain by activating the leptin receptor long form (LRb). LRb regulates energy homeostasis and neuroendocrine function; the absence of LRb in db/db mice results in obesity, impaired growth, infertility and diabetes. Tyr 1138 of LRb mediates activation of the transcription factor STAT3 during leptin action. To investigate the contribution of STAT3 signalling to leptin action in vivo, we replaced the gene encoding the leptin receptor (lepr) in mice with an allele coding for a replacement of Tyr 1138 in LRb with a serine residue (lepr(S1138)) that specifically disrupts the LRb-STAT3 signal. Here we show that, like db/db mice, lepr(S1138) homozygotes (s/s) are hyperphagic and obese. However, whereas db/db mice are infertile, short and diabetic, s/s mice are fertile, long and less hyperglycaemic. Furthermore, hypothalamic expression of neuropeptide Y (NPY) is elevated in db/db mice but not s/s mice, whereas the hypothalamic melanocortin system is suppressed in both db/db and s/s mice. LRb-STAT3 signalling thus mediates the effects of leptin on melanocortin production and body energy homeostasis, whereas distinct LRb signals regulate NPY and the control of fertility, growth and glucose homeostasis.

Regulation of Jak kinases by intracellular leptin receptor sequences.

Leptin signals the status of body energy stores via the leptin receptor (LR), a member of the Type I cytokine receptor family. Type I cytokine receptors mediate intracellular signaling via the activation of associated Jak family tyrosine kinases. Although their COOH-terminal sequences vary, alternatively spliced LR isoforms (LRa-LRd) share common NH(2)-terminal sequences, including the first 29 intracellular amino acids. The so-called long form LR (LRb) activates Jak-dependent signaling and is required for the physiologic actions of leptin. In this study, we have analyzed Jak activation by intracellular LR sequences under the control of the extracellular erythropoeitin (Epo) (Epo receptor/LRb chimeras). We show that Jak2 is the requisite Jak kinase for signaling by the LRb intracellular domain and confirm the requirement for the Box 1 motif for Jak2 activation. A minimal LRb intracellular domain for Jak2 activation includes intracellular amino acids 31-48. Although the sequence requirements for intracellular amino acids 37-48 are flexible, intracellular amino acids 31-36 of LRb play a critical role in Jak2 activation and contain a loose homology motif found in other Jak2-activating cytokine receptors. The failure of short form sequences to function in Jak2 activation reflects the absence of this motif.